U.S. patent application number 13/361046 was filed with the patent office on 2013-07-25 for regulating metabolism by modifying the level of trehalose-6-phosphate.
This patent application is currently assigned to Syngenta Mogen B.V.. The applicant listed for this patent is Oscar Johannes Maria GODDIJN, Jan Pen, Josephus Christianus Maria Smeekens. Invention is credited to Oscar Johannes Maria GODDIJN, Jan Pen, Josephus Christianus Maria Smeekens.
Application Number | 20130191944 13/361046 |
Document ID | / |
Family ID | 27237548 |
Filed Date | 2013-07-25 |
United States Patent
Application |
20130191944 |
Kind Code |
A1 |
GODDIJN; Oscar Johannes Maria ;
et al. |
July 25, 2013 |
REGULATING METABOLISM BY MODIFYING THE LEVEL OF
TREHALOSE-6-PHOSPHATE
Abstract
Method for the inhibition of carbon flow in the glycolytic
direction in a cell by increasing the intracellular availability of
trehalose-6-phosphate.
Inventors: |
GODDIJN; Oscar Johannes Maria;
(Leider, NL) ; Pen; Jan; (Leiden, NL) ;
Smeekens; Josephus Christianus Maria; (Driebergen,
NL) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
GODDIJN; Oscar Johannes Maria
Pen; Jan
Smeekens; Josephus Christianus Maria |
Leider
Leiden
Driebergen |
|
NL
NL
NL |
|
|
Assignee: |
Syngenta Mogen B.V.
|
Family ID: |
27237548 |
Appl. No.: |
13/361046 |
Filed: |
January 30, 2012 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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11818157 |
Jun 13, 2007 |
8124840 |
|
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13361046 |
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|
10682456 |
Oct 9, 2003 |
7247770 |
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11818157 |
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09171937 |
Apr 28, 1999 |
6833490 |
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PCT/EP97/02497 |
May 2, 1997 |
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10682456 |
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Current U.S.
Class: |
800/284 ;
435/320.1; 800/298 |
Current CPC
Class: |
C12N 15/8261 20130101;
C12N 9/16 20130101; C12N 15/8242 20130101; C12N 15/8245 20130101;
C12N 15/8273 20130101; C12N 9/1051 20130101; C12N 15/8269 20130101;
C12N 9/1205 20130101; C12N 9/2402 20130101; C12Y 302/01028
20130101 |
Class at
Publication: |
800/284 ;
435/320.1; 800/298 |
International
Class: |
C12N 15/82 20060101
C12N015/82 |
Foreign Application Data
Date |
Code |
Application Number |
May 3, 1996 |
NL |
EP96201225-8 |
Jul 26, 1996 |
NL |
EP96202128.3 |
Aug 29, 1996 |
NL |
EP96202395.8 |
Claims
1. Method for the stimulation of photosynthesis in a cell by
increasing the intracellular availability of
trehalose-6-phosphate.
2. Method for the stimulation of sink-related activity by
increasing the intracellular availability of
trehalose-6-phosphate.
3. Method for obtaining a dwarfed organism by increasing the
intracellular availability of trehalose-6-phosphate.
4. Use of compounds influencing the intracellular availability of
trehalose-6-phosphate to affect the carbon flow in the glycolytic
pathway.
5. Method for the prevention of cold sweetening by increasing the
intracellular availability of trehalose-6-phosphate.
6. Method according to claim 5, characterized in that said increase
of the intracellular concentration of trehalose-6-phosphate is
effected by a decrease in TPP activity.
7. Method according to claim 6, characterized in that said increase
of the intracellular concentration of trehalose-6-phosphate is
effected by a decrease in TPP activity.
8. Method according to claim 8, characterized in that said increase
of the intracellular concentration of trehalose-6-phosphate is
effected by a decrease in TPP activity.
9. Method for the inhibition of carbon flow in the glycolytic
direction in a plant cell by increasing the intracellular
availability of trehalose-6-phosphate by transformation of said
plant cell with a vector comprising an antisense fragment of a
trehalose-6-phosphate phosphatase (TPP) coding region, which upon
expression is able to inhibit functional activity of the endogenous
trehalose-6-phosphate phosphatase (TPP) gene.
10. A cloning vector which comprises an antisense fragment of a
trehalose-6-phosphate phosphatase (TPP) coding region, which upon
expression is able to inhibit functional activity of the endogenous
trehalose-6-phosphate phosphatase (TPP) gene in a plant cell.
11. Plant characterized in that it or one of its ancestors is
transformed with a vector comprising an antisense fragment of a
trehalose-6-phosphate phosphatase (TPP) coding region, which upon
expression is able to inhibit functional activity of the endogenous
trehalose-6-phosphate phosphatase (TPP) gene in a cell of said
plant, said plant still containing said antisense fragment.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of U.S. patent
application Ser. No. 11/818,157 filed on Jun. 13, 2007, which is a
divisional of U.S. patent application Ser. No. 10/682,456 filed on
Oct. 9, 2003, which is a division of U.S. patent application Ser.
No. 09/171,937 filed on Apr. 28, 1999, which is a national state
application of International Application PCT/EP97/02497 filed on
May 2, 1997, and claims priority to Netherlands Application No.
EP96201225.8 filed May 3, 1996, Netherlands Application No.
EP96202128.3 filed Jul. 26, 1996, and Netherlands Application No.
EP96202395.8 filed Aug. 29, 1996, each of which is incorporated by
reference by its entirety.
FIELD OF THE INVENTION
[0002] Glycolysis has been one of the first metabolic processes
described in biochemical detail in the literature. Although the
general flow of carbohydrates in organisms is known and although
all enzymes of the glycolytic pathway(s) are elucidated, the signal
which determines the induction of metabolism by stimulating
glycolysis has not been unravelled. Several hypotheses, especially
based on the situation in yeast have been put forward, but none has
been proven beyond doubt.
[0003] Influence on the direction of the carbohydrate partitioning
does not only influence directly the cellular processes of
glycolysis and carbohydrate storage, but it can also be used to
influence secondary or derived processes such as cell division,
biomass generation and accumulation of storage compounds, thereby
determining growth and productivity.
[0004] Especially in plants, often the properties of a tissue are
directly influenced by the presence of carbohydrates, and the
steering of carbohydrate partitioning can give substantial
differences.
[0005] The growth, development and yield of plants depends on the
energy which such plants can derive from CO.sub.2-fixation during
photosynthesis.
[0006] Photosynthesis primarily takes place in leaves and to a
lesser extent in the stem, while other plant organs such as roots,
seeds or tubers do not essentially contribute to the
photoassimilation process. These tissues are completely dependent
on photosynthetically active organs for their growth and nutrition.
This then means that there is a flux of products derived from
photosynthesis (collectively called "photosynthate") to
photosynthetically inactive parts of the plants.
[0007] The photosynthetically active parts are denominated as
"sources" and they are defined as net exporters of photosynthate.
The photosynthetically inactive parts are denominated as "sinks"
and they are defined as net importers of photosynthate.
[0008] It is assumed that both the efficiency of photosynthesis, as
well as the carbohydrate partitioning in a plant are essential.
Newly developing tissues like young leaves or other parts like root
and seed are completely dependent on photosynthesis in the sources.
The possibility of influencing the carbohydrate partitioning would
have great impact on the phenotype of a plant, e.g. its height, the
internodium distance, the size and form of a leaf and the size and
structure of the root system.
[0009] Furthermore, the distribution of the photoassimilation
products is of great importance for the yield of plant biomass and
products. An example is the development in wheat over the last
century. Its photosynthetic capacity has not changed considerably
but the yield of wheat grain has increased substantially, i.e. the
harvest index (ratio harvestable biomass/total biomass) has
increased. The underlying reason is that the sink-to-source ratio
was changed by conventional breeding, such that the harvestable
sinks, i.e. seeds, portion increased. However, the mechanism which
regulates the distribution of assimilation products and
consequently the formation of sinks and sources is yet unknown. The
mechanism is believed to be located somewhere in the carbohydrate
metabolic pathways and their regulation. In the recent research it
has become apparent that hexokinases may play a major role in
metabolite signalling and control of metabolic flow. A number of
mechanisms for the regulation of the hexokinase activity have been
postulated (Graham et al. (1994), The Plant Cell 6: 761; Jang &
Sheen (1994), The Plant Cell 6, 1665; Rose et al. Eur. J. Biochem.
199, 511-518, 1991; Blazquez et al. (1993), FEBS 329, 51; Koch,
Annu. Rev. Plant Physiol. Plant. Mol. Biol. (1996) 47, 509; Jang et
al. (1997), The Plant Cell 9, 5, one of these theories of
hexokinase regulation, postulated in yeast mentions trehalose and
its related monosaccharides (Thevelein & Hohmann (1995). TIBS
20, 3). However, it is hard to see that this would be an universal
mechanism, as trehalose synthesis is believed to be restricted to
certain species.
[0010] Thus, there still remains a need for the elucidation of the
signal which can direct the modification of the development and/or
composition of cells, tissue and organs in vivo.
SUMMARY OF THE INVENTION
[0011] It has now been found that modification of the development
and/or composition of cells, tissue and organs in vivo is possible
by introducing the enzyme trehalose-6-phosphate synthase (TPS)
and/or trehalose-6-phosphatase phosphate (TPP) thereby inducing a
change in metabolic pathways of the saccharide
trehalose-6-phosphate (T-6-P) resulting in an alteration of the
intracellular availability of T-6-P. Introduction of TPS thereby
inducing an increase in the intracellular concentration of T-6-P
causes inhibition of carbon flow in the glycolytic direction,
stimulation of the photosynthesis, inhibition of growth stimulation
of sink-related activity and an increase in storage of resources.
Introduction of TPP thereby introducing a decrease in the
intracellular concentration of T-6-P causes stimulation of carbon
flow in the glycolytic direction, increase in biomass and a
decrease in photosynthetic activity.
[0012] The levels of T-6-P may be influenced by genetic engineering
of an organism with gene constructs able to influence the level of
T-6-P or by exogenously (orally, topically, parenterally etc.)
supplying compounds able to influence these levels.
[0013] The gene constructs that can be used in this invention are
constructs harboring the gene for trehalose phosphate synthase
(TPS) the enzyme that is able to catalyze the reaction from
glucose-6-phosphate and UDP-glucose to T-6-P. On the other side a
construct coding for the enzyme trehalose-phosphate phosphatase
(TPP) which catalyzes the reaction from T-6-P to trehalose will,
upon expression, give a decrease of the amount of T-6-P.
[0014] Alternatively, gene constructs harboring antisense TPS or
TPP can be used to regulate the intracellular availability of
T-6-P.
[0015] Furthermore, it was recently reported that an intracellular
phospho-alpha-(1,1)-glucosidase, TreA, from Bacillus subtilis was
able to hydrolyse T-6-P into glucose and glucose-6-phosphate
(Sch{hacek over (o)}ck et al., Gene, 170, 77-80, 1996). A similar
enzyme has already been described for E. coli (Rimmele and Boos
(1996), J. Bact. 176 (18), 5654-).
[0016] For overexpression heterologous or homologous gene
constructs have to be used. It is believed that the endogenous
T-6-P forming and/or degrading enzymes are under allosteric
regulation and regulation through covalent modification. This
regulation may be circumvented by using heterologous genes.
[0017] Alternatively, mutation of heterologous or homologous genes
may be used to abolish regulation.
[0018] The invention also gives the ability to modify source-sink
relations and resource allocation in plants. The whole carbon
economy of the plant, including assimilate production in source
tissues and utilization in source tissues can be modified, which
may lead to increased biomass yield of harvested products. Using
this approach, increased yield potential can be realized, as well
as improved harvest index and product quality. These changes in
source tissues can lead to changes in sink tissues by for instance
increased export of photosynthase. Conversely changes in sink
tissue can lead to change in source tissue.
[0019] Specific expression in a cell organelle, a tissue or other
part of an organism enables the general effects that have been
mentioned above to be directed to specific local applications. This
specific expression can be established by placing the genes coding
for TPS, TPP or the antisense genes for TPS or TPP under control of
a specific promoter.
[0020] Specific expression also enables the simultaneous expression
of both TPS and TPP enzymes in different tissues thereby increasing
the level of T-6-P and decreasing the level of T-6-P locally.
[0021] By using specific promoters it is also possible to construct
a temporal difference. For this purpose promoters can be used that
are specifically active during a certain period of the
organogenesis of the plant parts. In this way it is possible to
first influence the amount of organs which will be developed and
then enable these organs to be filled with storage material like
starch, oil or proteins.
[0022] Alternatively, inducible promoters may be used to
selectively switch on or off the expression of the genes of the
invention. Induction can be achieved by for instance pathogens,
stress, chemicals or light/dark stimuli.
DEFINITIONS
[0023] Hexokinase activity is the enzymatic activity found in cells
which catalyzes the reaction of hexose to hexose-6-phosphate.
Hexoses include glucose, fructose, galactose or any other C.sub.6
sugar. It is acknowledged that there are many isoenzymes which all
can play a part in said biochemical reaction. By catalyzing this
reaction hexokinase forms a key enzyme in hexose (glucose)
signalling.
[0024] Hexose signalling is the regulatory mechanism by which a
cell senses the availability of hexose (glucose).
[0025] Glycolysis is the sequence of reactions that converts
glucose into pyruvate with the concomitant production of ATP.
[0026] Cold sweetening is the accumulation of soluble sugars in
potato tubers after harvest when stored at low temperatures.
[0027] Storage of resource material is the process in which the
primary product glucose is metabolized into the molecular form
which is fit for storage in the cell or in a specialized tissue.
These forms can be divers. In the plant kingdom storage mostly
takes place in the form of carbohydrates and polycarbohydrates such
as starch, fructan and cellulose, or as the more simple mono- and
di-saccharides like fructose, sucrose and maltose; in the form of
oils such as arachic or oleic oil and in the form of proteins such
as cruciferin, napin and seed storage proteins in rapeseed. In
animal cells also polymeric carbohydrates such as glycogen are
formed, but also a large amount of energy rich carbon compounds is
transferred into fat and lipids.
[0028] Biomass is the total mass of biological material.
DESCRIPTION OF THE FIGURES
[0029] FIG. 1. Schematic representation of plasmid pVDH275
harboring the neomycin-phosphotransferase gene (NPTII) flanked by
the 35S cauliflower mosaic virus promoter (P35S) and terminator
(T35S) as a selectable marker; an expression cassette comprising
the pea plastocyanin promoter (pPCpea) and the nopaline synthase
terminator (Tnos); right (RB) and left (LB) T-DNA border sequences
and a bacterial kanamycin resistance (KanR) marker gene.
[0030] FIG. 2. Northern blot analysis of transgenic tobacco plants.
Panel A depicts expression of otsA mRNA in leaves of individual
pMOG799 transgenic tobacco plants. The control lane "C" contains
total RNA from a non-transformed N. tabacum plant.
[0031] FIGS. 3A and 3B. Lineup of plant derived TPS encoding
sequences compared with the TPS.sub.yeast sequence using the
Wisconsin GCG sequence analysis package (Devereux et al. (1984) A
comprehensive set of sequence analysis programs of the VAX. Nucl.
Acids Res., 12, 387).
[0032] FIG. 4. Alignment of PCR amplified tobacco TPS cDNA
fragments with the TPS encoding yeast TPS1 gene. Boxes indicate
identity between amino-acids of all four listed sequences.
[0033] FIG. 5. Alignment of PCR amplified tobacco TPP cDNA
fragments with the TPP encoding yeast TPS2 gene. Boxes indicate
identity between amino-acids of all four listed sequences.
[0034] FIG. 6. Alignment of a fragment of the PCR amplified
sunflower TPS/TPP bipartite cDNA (SEQ ID NO: 24) with the TPP
encoding yeast TPS2 gene. Boxes indicate identity between
amino-acids of both sequences.
[0035] FIG. 7. Alignment of a fragment of the Arabidopsis TPS 1 and
Rice EST clones with the TPS encoding yeast TPS 1 gene. Boxes
indicate identity between amino-acids of all three sequences.
[0036] FIG. 8. Alignment of a fragment of the PCR amplified human
TPS cDNA (SEQ ID NO: 10) with the TPS encoding yeast TPS1 gene.
Boxes indicate identity between amino-acids of both sequences.
[0037] FIG. 9. Trehalose accumulation in tubers of pMOG1027 (35S
astrehalase) transgenic potato plants.
[0038] FIG. 10. Hexokinase activity of a wild-type potato tuber
(Solanum tuberosum cv. Kardal) extract with and without the
addition of trehalose-6-phosphate.
[0039] FIG. 11. Hexokinase activity of a wild-type potato tuber
(Solanum tuberosum cv. Kardal) extract with and without the
addition of trehalose-6-phosphate. Frutose or glucose is used as a
substrate for the assay.
[0040] FIG. 12. Hexokinase activity of a wild-type tobacco leaf
extract (Nicotiana tabacum cv. SR1) with and without the addition
of trehalose-6-phosphate. Fructose or glucose is used as substrate
for the assay.
[0041] FIG. 13. Plot of a tobacco hexokinase activity
measurement.
Data series 1: Tobacco plant extract Data series 2: Tobacco plant
extract+1 mM trehalose-6-phosphate Data series 3: Commercial
hexokinase extract from yeast (1/8 unit)
[0042] FIG. 14. Hexokinase activity of a wild-type rice leaf
extract (Oryza sativa) extract with and without the addition of
trehalose-6-phosphate. Experiments have been performed in duplicate
using different amounts of extracts. Fructose or glucose is used as
substrate for the assay.
[0043] FIG. 15. Hexokinase activity of a wild-type maize leaf
extract (Zea mais) extract with and without the addition of
trehalose-6-phosphate. Fructose or glucose is used as substrate for
the assay.
[0044] FIG. 16. Fluorescence characteristics of wild-type
(triangle), PC-TPS (square) and 35S-TPP (cross) tobacco leaves. The
upper two panels show the electron transport efficiency (ETE) at
the indicated light intensities (PAR). Plants were measured after a
dark-period (upper-left panel) and after a light-period
(upper-right panel). The bottom panels show reduction of
fluorescence due to assimilate accumulation (non-photochemical
quenching). Left and right panel as above.
[0045] FIG. 17. Relative sink-activity of plant-parts of PC-TPS
(Famine) and 35S-TPP (Feast) transgenic tobacco plants. Indicated
is the nett C-accumulation expressed as percentage of total
C-content, for various plant-parts after a period of light (D) or
light+dark (D+N).
[0046] FIG. 18. Actual distribution of carbon in plant-parts of
PC-TPS (Famine) and 35S-TPP (Feast) transgenic tobacco plants.
Indicated is the nett C-accumulation expressed as percentage of
total daily accumulated new C for various plant-parts after a
period of light (D) or light+dark (D+N).
[0047] FIG. 19. Scanned images showing reduced_and enchanced
bolting in transgenic lettuce lines expressing PC-TPS or PC-TPP
compared to wild-type plants. The lower panel shows leaf morphology
and color.
[0048] FIGS. 20A-D. Profile of soluble sugars (FIGS. 20A and B) in
extracts of transgenic lettuce (upper panel) and transgenic beet
(lower panel) lines. In the upper pannel controls are GUS-trangenic
lines which are compared to lines trangenics for PC-TPS and PC-TPP.
In lower panel all transgenic are PC-TPS. Starch profiles are
depicted in FIGS. 20B and C.
[0049] FIG. 21. Scanned image showing plant and leaf morphology of
transgenic sugarbeet lines expressing PC-TPS (TPS) or PC-TPP (TPP)
compared to wild-type plants (Control). TPS A-type has leaves which
are comparable to wild-type while TPS D-type has clearly smaller
leaves. The leaves of the TPP transgenic line have a lighter green
color. A larger petiole and an increased size compared to the
control.
[0050] FIG. 22. Taproot diameter of transgenic sugarbeet lines
(PC-TPS). In the upper panel A, B, C and D indicate decreasing leaf
sizes as compared to control (A). In the lower panel individual
clones of control and PC-TPS line 286-2 are shown.
[0051] FIG. 23. Tuber yield of pMOG799 (35S TPS) transgenic potato
lines.
[0052] FIG. 24. Tuber yield of pMOG1010 (35S TPP) and pMOG1124
(PC-TPP) transgenic potato lines.
[0053] FIG. 25. Tuber yield of 22 independent wild-type S.
tuberosum clones.
[0054] FIG. 26. Tuber yield of pMOG1093 (PC-TPS) transgenic potato
lines in comparison to wild-type. B, C, D, E, F, G indicate
decreasing leaf sizes as compared to wild-type (B/C).
[0055] FIG. 27. Tuber yield of pMoG845 (Pat-TPS) transgenic potato
lines (FIG. 27-1) in comparison to wild-type (FIG. 27-2). B, C
indicate leaf sizes.
[0056] FIGS. 28A-C. Tuber yield of pMOG 1129 (845-11/22/28)
transgenic potato lines.
[0057] FIGS. 29A-B. Scanned images showing cross section through
leaves of TPP (FIG. 29B) and TPS (FIG. 29A) transgenic tobacco
plants. Additional cell layers and increased cell size are visible
in the TPS cross section.
[0058] FIG. 30. HPLC-PED analysis of tubers transgenic for
TPS.sub.E.coli before and after storage at 4.degree. C. Kardal C,
F, B, G and H are non-transgenic control lines.
[0059] FIG. 31. Scanned images showing leaf morphology, color and
size of tobacco lines transgenic for 35S TPS (upper leaf),
wild-type (middle leaf) and transgenic for 35S TPP (bottom
leaf).
[0060] FIGS. 32A-D. Metabolic profiling of 35S TPS (pMOG799), 35S
TPP (pMOG1010), wild-type (WT), PC-TPS (pMOG1177) and PC-TPP
(pMOG1124) transgenic tobacco lines. Shown are the levels of
trehalose, soluble sugars FIGS. 32A and B, starch and chlorophyll
FIGS. 32C and D.
[0061] FIG. 33. Tuber yield of pMOG1027 (35S as-trehalase) and
pMOG1027(845-11/22/28) (35S as-trehalase pat TPS) transgenic potato
lines in comparison to wild-type potato lines.
[0062] FIG. 34. Starch content of pMOG1027 (35S as-trehalase) and
pMOG1027 (845-11/22/28) (35S as-trehalase pat TPS) transgenic
potato lines in comparison to wild-type potato lines. The sequence
of all lines depicted is identical to FIG. 33.
[0063] FIGS. 35A-E. Yield of pMOG1028 (pat as-trehalase) and
pMOG1028(845-11/22/28) (pat as-trehalase pat TPS) transgenic potato
lines in comparison to wild-type potato lines.
[0064] FIG. 36. Yield of pMOG1092 (PC as-trehalase) transgenic
potato lines in comparison to wild-type potato lines as depicted in
FIGS. 35A-E.
[0065] FIG. 37. Yield of pMOG1130 (PC as-trehalase PC TPS)
transgenic potato lines in comparison to wild-type potato lines as
depicted in FIGS. 35A-E.
DETAILED DESCRIPTION OF THE INVENTION
[0066] The invention is concerned with the finding that metabolism
can be modified in vivo by the level of T-6-P. A decrease of the
intracellular concentration of T-6-P stimulates glycolytic
activity. On the contrary, an increase of the T-6-P concentration
will inhibit glycolytic activity and stimulate photosynthesis.
[0067] These modifications established by changes in T-6-P levels
are most likely a result of the signalling function of hexokinase,
which activity is shown to be regulated by T-6-P. An increase in
the flux through hexokinase (i.e. an increase in the amount of
glucose) that is reacted in glucose-6-phosphate has been shown to
inhibit photosynthetic activity in plants. Furthermore, an increase
in the flux through hexokinase would not only stimulate the
glycolysis, but also cell division activity.
Theory of Trehalose-6-Phosphate Regulation of Carbon Metabolism
[0068] In a normal plant cell formation of carbohydrates takes
place in the process of photosynthesis in which CO.sub.2 is fixed
and reduced to phosphorylated hexoses with sucrose as an
end-product. Normally this sucrose is transported out of the cell
to cells or tissues which through uptake of this sucrose can use
the carbohydrates as building material for their metabolism or are
able to store the carbohydrates as e.g. starch. In this respect, in
plants, cells that are able to photosynthesize and thus to produce
carbohydrates are denominated as sources, while cells which consume
or store the carbohydrates are called sinks.
[0069] In animal and most microbial cells no photosynthesis takes
place and the carbohydrates have to be obtained from external
sources, either by direct uptake from saccharides (e.g. yeasts and
other micro-organisms) or by digestion of carbohydrates (animals).
Carbohydrate transport usually takes place in these organisms in
the form of glucose, which is actively transported over the cell
membrane.
[0070] After entrance into the cell, one of the first steps in the
metabolic pathway is the phosphorylation of glucose into
glucose-6-phosphate catalyzed by the enzyme hexokinase. It has been
demonstrated that in plants sugars which are phosphorylated by
hexokinase (HXK) are controlling the expression of genes involved
in photosynthesis (Tang & Sheen (1994), The Plant Cell 6,
1665). Therefor, it has been proposed that HXK may have a dual
function and may act as a key sensor and signal transmitter of
carbohydrate-mediated regulation of gene-expression. It is believed
that this regulation normally signals the cell about the
availability of starting product, i.e. glucose. Similar effects are
observed by the introduction of TPS or TPP which influence the
level of T-6-P. Moreover, it is shown that in vitro T-6-P levels
affect hexokinase activity. By increasing the level of T-6-P, the
cell perceives a signal that there is a shortage of carbohydrate
input. Conversely, a decrease in the level of T-6-P results in a
signal that there is plenty of glucose, resulting in the
down-regulation of photosynthesis: it signals that substrate for
glycolysis and consequently energy supply for processes as cell
growth and cell division is sufficiently available. This signalling
is thought to be initiated by the increased flux through hexokinase
(J. J. Van Oosten, public lecture at RijksUniversiteit Utrecht
dated Apr. 19, 1996).
[0071] The theory that hexokinase signalling in plants can be
regulated through modulation of the level of trehalose-6-phosphate
would imply that all plants require the presence of an enzyme
system able to generate and break-down the signal molecule
trehalose-6-phosphate. Although trehalose is commonly found in a
wide variety of fungi, bacterial, yeasts and algae, as well as in
some invertebrates only a very limited range of vascular plants
have been proposed to be able to synthesize this sugar (Elbein
(1974), Adv. Carboh. Chem. Biochem. 30, 227). A phenomenon which
was not understood until now is that despite the apparent lack of
trehalose synthesizing enzymes, all plants do seem to contain
trehalases, enzymes which are able to break down trehalose into two
glucose molecules.
[0072] Indirect evidence for the presence of a metabolic pathway
for trehalose is obtained by experiments presented herein with
trehalase inhibitors such as Validamycin A or transformation with
anti-sense trehalase.
[0073] Production of trehalose would be hampered if its
intermediate T-6-P would influence metabolic activity too much.
Preferably, in order to accumulate high levels of trehalose without
affecting partitioning and allocation of metabolites by the action
of trehalose-6-phosphate, one should overexpress a bipartite
TPS/TPP enzyme. Such an enzyme would resemble a genetic
constitution as found in yeast, where the TPS2 gene product
harbours a TPS and TPP homologous region when compared with the E.
coli otsA and otsB gene (Kaasen et al. (1994), Gene 145, 9). Using
such an enzyme, trehalose-6-phosphate will not become freely
available to other cell components. Another example of such a
bipartite enzyme is given by Zentella & Iturriaga (Plant
Physiol. (1996), 111 Abstract 88) who isolated a 3.2 kb cDNA from
Selaginella lepidophylla encoding a putative trehalose-6-phosphate
synthase/phosphatase. It is also envisaged that construction of a
truncated TPS-TPP gene product, whereby only the TPS activity would
be retained, would be as powerful for synthesis of T-6-P as the
otsA gene of E. coli, also when used in homologous systems.
[0074] On a molecular level we have data that indicate that next to
Selaginella also trehalose synthesizing genes are present in
Arabidopsis, tobacco, rice and sunflower. Using degenerated
primers, based on conserved sequences between TPS.sub.E.coli and
TPS.sub.yeast, we have been able to identify genes encoding
putative trehalose-6-phosphate generating enzymes in sunflower and
tobacco. Sequence comparison revealed significant homology between
these sequences, the TPS genes from yeast and E. coli, and EST
(expressed sequences tags) sequences from Arabidopsis and rice (see
also Table 6b which contains the EST numbers of homologous EST's
found).
[0075] Recently an Arabidopsis gene has been elucidated (disclosed
in GENBANK Acc. No. Y08568, depicted in SEQ ID NO: 39) that on
basis of its homology can be considered as a bipartite enzyme.
These data indicate that, in contrast to current beliefs, most
plants do contain genes which encode trehalose-phosphate-synthases
enabling them to synthesize T-6-P. As proven by the accumulation of
trehalose in TPS expressing plants, plants also contain
phosphatases, non-specific or specific, able to dephosphorylate the
T-6-P into trehalose. The presence of trehalase in all plants may
be to effectuate turnover of trehalose.
[0076] Furthermore, we also provide data that T-6-P is involved in
regulating carbohydrate pathways in human tissue. We have
elucidated a human TPS gene (depicted in SEQ ID NO: 10) which shows
homology with the TPS genes of yeast, E. coli and plants.
Furthermore, we show data that also the activity of hexokinase is
influenced in mammalian (mouse) tissue.
[0077] Generation of the "plenty" signal by decreasing the
intracellular concentration of trehalose-6-phosphate through
expression of the enzyme TPP (or inhibition of the enzyme TPS) will
signal all cell systems to increase glycolytic carbon flow and
inhibit photosynthesis. This is nicely shown in the experimental
part, where, for instance in Experiment 2 transgenic tobacco plants
are described in which the enzyme TPP is expressed having increased
leaf size, increased branching and a reduction of the amount of
chlorophyll. However, since the "plenty" signal is generated in the
absence of sufficient supply of glucose, the pool of carbohydrates
in the cell is rapidly depleted.
[0078] Thus, assuming that the artificial "plenty" signal holds on,
the reduction in carbohydrates will finally become limiting for
growth and cell division, i.e. the cells will use up all their
storage carbohydrates and will be in a "hunger"-stage. Thus, leaves
are formed with a low amount of stored carbohydrates. On the other
hand, plants that express a construct with a gene coding for TPS,
which increases the intracellular amount of T-6-P, showed a
reduction of leaf size, while also the leaves were darker green,
and contained an increased amount of chlorophyll.
[0079] In yeast, a major role of glucose-induced signalling is to
switch metabolism from a neogenetic/respirative mode to a
fermentative mode. Several signalling pathways are involved in this
phenomenon (Thevelein and Hohmann, (1995) TIBS 20, 3). Besides the
possible role of hexokinase signalling, the RAS-cyclic-AMP (cAMP)
pathway has been shown to be activated by glucose. Activation of
the RAS-cAMP pathway by glucose requires glucose phosphorylation,
but no further glucose metabolism. So far, this pathway has been
shown to activate trehalase and 6-phosphofructo-2-kinase (thereby
stimulating glycolysis), while fructose-1,6-bisphosphatase is
inhibited (thereby preventing gluconeogenesis), by cAMP-dependent
protein phosphorylation. This signal transduction route and the
metabolic effects it can bring about can thus be envisaged as one
that acts in parallels with the hexokinase signalling pathway, that
is shown to be influenced by the level of
trehalose-6-phosphate.
[0080] As described in our invention, transgenic plants expressing
as-trehalase reveal similar phenomena, like dark-green leaves,
enhanced yield, as observed when expressing a TPS gene. It also
seems that expression of as-trehalase in double-constructs enhances
the effects that are caused by the expression of TPS. Trehalase
activity has been shown to be present in e.g. plants, insects,
animals, fungi and bacteria while only in a limited number of
species, trehalose is accumulated.
[0081] Up to now, the role of trehalase in plants is unknown
although this enzyme is present in almost all plant-species. It has
been proposed to be involved in plant pathogen interactions and/or
plant defense responses. We have isolated a potato trehalase gene
and show that inhibition of trehalase activity in potato leaf and
tuber tissues leads to an increase in tuber-yield. Fruit-specific
expression of as-trehalase in tomato combined with TPS expression
dramatically alters fruit development.
[0082] According to one embodiment of the invention, accumulation
of T-6-P is brought about in cells in which the capacity of
producing T-6-P has been introduced by introduction of an
expressible gene construct encoding trehalose-phosphate-synthase
(TPS). Any trehalose phosphate synthase gene under the control of
regulatory elements necessary for expression of DNA in cells,
either specifically or constitutively, may be used, as long as it
is capable of producing a trehalose phosphate synthase capable of
T-6-P production in said cells. One example of an open reading
frame according to the invention is one encoding a TPS-enzyme as
represented in SEQ ID NO: 2. Other examples are the open reading
frames as represented in SEQ ID NO's: 10, 18-23, 41 and 45-53. As
is illustrated by the above-mentioned sequences it is well known
that more than one DNA sequence may encode an identical enzyme,
which fact is caused by the degeneracy of the genetic code. If
desired, the open reading frame encoding the trehalose phosphate
synthase activity may be adapted to codon usage in the host of
choice, but this is not a requirement.
[0083] The isolated nucleic acid sequence represented by for
instance SEQ ID NO: 2, may be used to identify trehalose phosphate
synthase genes in other organisms and subsequently isolating and
cloning them, by PCR techniques and/or by hybridizing DNA from
other sources with a DNA- or RNA fragment obtainable from the E.
coli gene. Preferably, such DNA sequences are screened by
hybridizing under more or less stringent conditions (influenced by
factors such as temperature and ionic strength of the hybridization
mixture). Whether or not conditions are stringent also depends on
the nature of the hybridization, i.e. DNA:DNA, DNA:RNA, RNA:RNA, as
well as the length of the shortest hybridizing fragment. Those of
skill in the art are readily capable of establishing a
hybridization regime stringent enough to isolate TPS genes, while
avoiding non-specific hybridization. As genes involved in trehalose
synthesis from other sources become available these can be used in
a similar way to obtain an expressible trehalose phosphate synthase
gene according to the invention. More detail is given in the
experimental section.
[0084] Sources for isolating trehalose phosphate synthase
activities include microorganisms (e.g. bacteria, yeast, fungi),
plants, animals, and the like. Isolated DNA sequences encoding
trehalose phosphate synthase activity from other sources may be
used likewise in a method for producing T-6-P according to the
invention. As an example, genes for producing T-6-P from yeast are
disclosed in WO 93/17093.
[0085] The invention also encompasses nucleic acid sequences which
have been obtained by modifying the nucleic acid sequence
represented in SEQ ID NO: 1 by mutating one or more codons so that
it results in amino acid changes in the encoded protein, as long as
mutation of the amino acid sequence does not entirely abolish
trehalose phosphate synthase activity.
[0086] According to another embodiment of the invention the
trehalose-6-phosphate in a cell can be converted into trehalose by
trehalose phosphate phosphatase encoding genes under control of
regulatory elements necessary for the expression of DNA in cells. A
preferred open reading frame according to the invention is one
encoding a TPP-enzyme as represented in SEQ ID NO: 4 (Kaasen et al.
(1994) Gene, 145, 9). It is well known that more than one DNA
sequence may encode an identical enzyme, which fact is caused by
the degeneracy of the genetic code. If desired, the open reading
frame encoding the trehalose phosphate phosphatase activity may be
adapted to codon usage in the host of choice, but this is not a
requirement.
[0087] The isolated nucleic acid sequence represented by SEQ ID NO:
3, may be used to identify trehalose phosphate phosphatase genes in
other organisms and subsequently isolating and cloning them, by PCR
techniques and/or by hybridizing DNA from other sources with a DNA-
or RNA fragment obtainable from the E. coli gene. Preferably, such
DNA sequences are screened by hybridizing under more or less
stringent conditions (influenced by factors such as temperature and
ionic strength of the hybridization mixture). Whether or not
conditions are stringent also depends on the nature of the
hybridization, i.e. DNA:DNA, DNA:RNA, RNA:RNA, as well as the
length of the shortest hybridizing fragment. Those of skill in the
art are readily capable of establishing a hybridization regime
stringent enough to isolate TPP genes, while avoiding aspecific
hybridization. As genes involved in trehalose synthesis from other
sources become available these can be used in a similar way to
obtain an expressible trehalose phosphate phosphatase gene
according to the invention. More detail is given in the
experimental section.
[0088] Sources for isolating trehalose phosphate phosphatase
activities include microorganisms (e.g. bacteria, yeast, fungi),
plants, animals, and the like. Isolated DNA sequences encoding
trehalose phosphate phosphatase activity from other sources may be
used likewise.
[0089] The invention also encompasses nucleic acid sequences which
have been obtained by modifying the nucleic acid sequence
represented in SEQ ID NO: 3 by mutating one or more codons so that
it results in amino acid changes in the encoded protein, as long as
mutation of the amino acid sequence does not entirely abolish
trehalose phosphate phosphatase activity.
[0090] Other enzymes with TPS or TPP activity are represented by
the so-called bipartite enzymes. It is envisaged that the part of
the sequence which is specifically coding for one of the two
activities can be separated from the part of the bipartite enzyme
coding for the other activity. One way to separate the activities
is to insert a mutation in the sequence coding for the activity
that is not selected, by which mutation the expressed protein is
impaired or deficient of this activity and thus only performs the
other function. This can be done both for the TPS- and TPP-activity
coding sequence. Thus, the coding sequences obtained in such a way
can be used for the formation of novel chimaeric open reading
frames capable of expression of enzymes having either TPS or TPP
activity.
[0091] According to another embodiment of the invention, especially
plants can be genetically altered to produce and accumulate the
above-mentioned enzymes in specific parts of the plant. Preferred
sites of enzyme expression are leaves and storage parts of plants.
In particular potato tubers are considered to be suitable plant
parts. A preferred promoter to achieve selective TPS-enzyme
expression in microtubers and tubers of potato is obtainable from
the region upstream of the open reading frame of the patatin gene
of potato.
[0092] Another suitable promoter for specific expression is the
plastocyanin promoter, which is specific for photoassimilating
parts of plants. Furthermore, it is envisaged that specific
expression in plant parts can yield a favourable effect for plant
growth and reproduction or for economic use of said plants.
Promoters which are useful in this respect are: the E8-promoter (EP
0 409 629) and the 2A11-promoter (van Haaren and Houck (1993),
Plant Mol. Biol., 221, 625) which are fruit-specific; the
cruciferin promoter, the napin promoter and the ACP promoter which
are seed-specific; the PAL-promoter; the chalcon-isomerase promoter
which is flower-specific; the SSU promoter, and ferredoxin
promoter, which are leaf-specific; the TobRb7 promoter which is
root-specific, the RolC promoter which is specific for phloem and
the HMG2 promoter (Enjuto et al. (1995). Plant Cell 7, 517) and the
rice PCNA promoter (Kosugi et al. (1995), Plant J. 7, 877) which
are specific for meristematic tissue.
[0093] Another option under this invention is to use inducible
promoters. Promoters are known which are inducible by pathogens, by
stress, by chemical or light/dark stimuli. It is envisaged that for
induction of specific phenoma, for instance sprouting, bolting,
seed setting, filling of storage tissues, it is beneficial to
induce the activity of the genes of the invention by external
stimuli. This enables normal development of the plant and the
advantages of the inducibility of the desired phenomena at control.
Promoters which qualify for use in such a regime are the pathogen
inducible promoters described in DE 4446342 (fungus and auxin
inducible PRP-1), WO 96/28561 (fungus inducible PRP-1), EP 0 586
612 (nematode inducible), EP 0 712 273 (nematode inducible), WO
96/34949 (fungus inducible), PCT/EP96/02437 (nematode inducible),
EP 0 330 479 (stress inducible), U.S. Pat. No. 5,510,474 (stress
inducible), WO 96/12814 (cold inducible), EP 0 494 724
(tetracycline inducible), EP 0 619 844 (ethylene inducible), EP 0
337 532 (salicylic acid inducible), WO 95/24491 (thiamine
inducible) and WO 92/19724 (light inducible). Other chemical
inducible promoters are described in EP 0 674 608, EP 637 339, EP
455 667 and U.S. Pat. No. 5,364,780.
[0094] According to another embodiment of the invention, cells are
transformed with constructs which inhibit the function of the
endogenously expressed TPS or TPP. Inhibition of undesired
endogenous enzyme activity is achieved in a number of ways, the
choice of which is not critical to the invention. One method of
inhibition of gene expression is achieved through the so-called
`antisense approach.` Herein a DNA sequence is expressed which
produces an RNA that is at least partially complementary to the RNA
which encodes the enzymatic activity that is to be blocked. It is
preferred to use homologous antisense genes as these are more
efficient than heterologous genes.
[0095] An alternative method to block the synthesis of undesired
enzymatic activities is the introduction into the genome of the
plant host of an additional copy of an endogenous gene present in
the plant host. It is often observed that such an additional copy
of a gene silences the endogenous gene: this effect is referred to
in the literature as the co-suppressive effect, or co-suppression.
Details of the procedure of enhancing substrate availability are
provided in the Examples of WO 95/01446, incorporated by reference
herein.
[0096] Host cells can be any cells in which the modification of
hexokinase-signalling can be achieved through alterations in the
level of T-6-P. Thus, accordingly, all eukaryotic cells are subject
to this invention. From an economic point of view the cells most
suited for production of metabolic compounds are most suitable for
the invention. These organisms are, amongst others, plants animals,
yeast, fungi. However, also expression in specialized animal cells
(like pancreatic beta-cells and fat cells) is envisaged.
[0097] Preferred plant hosts among the Spermatophytae are the
Angiospermae, notably the Dicotyledoneae, comprising inter alia the
Solanaceae as a representative family, and the Monocotyledoneae,
comprising inter alia the Gramineae as a representative family.
Suitable host plants, as defined in the context of the present
invention include plants (as well as parts and cells of said
plants) and their progeny which contain a modified level of T-6-P,
for instance by using recombinant DNA techniques to cause or
enhance production of TPS or TPP in the desired plant or plant
organ. Crops according to the invention include those which have
flowers such as cauliflower (Brassica oleracea), artichoke (Cynara
scolymus), cut flowers like carnation (Dianthus caryophyllus), rose
(Rosa spp), Chrysanthemum, Petunia, Alstromeria, Gerbera,
Gladiolus, lily (Lilium spp), hop (Humulus lupulus), broccoli,
potted plants like Rhododendron, Azalia, Dahlia, Begonia, Fuchsia,
Geranium etc.; fruits such as apple (Malus, e.g. domesticus),
banana (Musa, e.g. Acuminata), apricot (Prunus armeniaca), olive
(Oliva sativa), pineapple (Ananas comosus), coconut (Cocos
nucifera), mango (Mangifera indica), kiwi, avocado (Persea
americana), berries (such as the currant, Ribes, e.g. rubrum),
cherries (such as the sweet cherry, Prunus, e.g. avium), cucumber
(Cucumis, e.g. sativus), grape (Vitis, e.g. vinifera), lemon
(Citrus limon), melon (Cucumis melo), mustard (Sinapis alba and
Brassica nigra), nuts (such as the walnut, Juglans, e.g. regia;
peanut, Arachis hypogeae), orange (Citrus, e.g. maxima), peach
(Prunus, e.g. persica), pear (Pyra, e.g. Communis), pepper
(Solanum, e.g. capsicum), plum (Prunus, e.g. domestica), strawberry
(Fragaria, e.g. moschata), tomato (Lycopersicon, e.g. esculentum);
leaves, such as alfalfa (Medicago sativa), cabbages (such as
Brassica oleracea), endive (Cichoreum, e.g. endivia), leek (Allium
porruin), lettuce (Lactuca sativa), spinach (Spinacia oleraceae),
tobacco (Nicociana tabacum), grasses like Festuca, Poa, rye-grass
(such as Lolium perenne, Lolium multiflorum and Arrenatherum spp.),
amenity grass, turf, seaweed, chicory (Cichorium intybus), tea
(Thea sinensis), celery, parsley (Pecroselinum crispum), chevil and
other herbs; roots, such as arrowroot (Maranta arundinacea), beet
(Beta vulgaris), carrot (Daucus carota), cassaya (Manihot
esculenta), ginseng (Panax ginseng), turnip (Brassica rapa), radish
(Raphanus sativus), yam (Dioscorea esculenta), sweet potato
(Ipomoea batatas), taro; seeds, such as beans (Phaseolus vulgaris),
pea (Pisum sativum), soybean (Glycin max), wheat (Triticum
aestivum), barley (Hordeum vulgare), corn (Zea mays), rice (Oryza
sativa), bush beans and broad beans (Vicia faba), cotton (Gossypium
spp.), coffee (Coffea arabica and C. canephora); tubers, such as
kohlrabi (Brassica oleraceae), potato (Solanum tuberosum); bulbous
plants as onion (Allium cepa), scallion, tulip (Tulipa spp.),
daffodil (Narcissus spp.), garlic (Allium sativum); stems such as
cork-oak, sugarcane (Saccharum spp.), sisal (Sisal spp.), flax
(Linum vulgare), jute; trees like rubber tree, oak (Quercus spp.),
beech (Betula spp.), alder (Alnus spp.), ashtree (Acer spp.), elm
(Ulmus spp.), palms, ferns, ivies and the like.
[0098] Transformation of yeast and fungal or animal cells can be
done through normal state-of-the art transformation techniques
through commonly known vector systems like pBluescript, pUC and
viral vector systems like RSV and SV40.
[0099] The method of introducing the expressible
trehalose-phosphate synthase gene, the expressible
trehalose-phosphate-phosphatase gene, or any other sense or
antisense gene into a recipient plant cell is not crucial, as long
as the gene is expressed in said plant cell.
[0100] Although some of the embodiments of the invention may not be
practicable at present, e.g. because some plant species are as yet
recalcitrant to genetic transformation, the practicing of the
invention in such plant species is merely a matter of time and not
a matter of principle, because the amenability to genetic
transformation as such is of no relevance to the underlying
embodiment of the invention.
[0101] Transformation of plant species is now routine for an
impressive number of plant species, including both the
Dicotyledoneae as well as the Monococyledoneae. In principle any
transformation method may be used to introduce chimeric DNA
according to the invention into a suitable ancestor cell. Methods
may suitably be selected from the calcium/polyethylene glycol
method for protoplasts (Krens et al. (1982), Nature 296, 72;
Negrutiu et al. (1987), Plant Mol. Biol. 8, 363, electroporation of
protoplasts (Shillito et al. (1985) Bio/Technol. 3, 1099),
microinjection into plant material (Crossway et al. (1986), Mol.
Gen. Genet. 202), (DNA or RNA-coated) particle bombardment of
various plant material (Klein at al. (1987), Nature 327, 70),
infection with (non-integrative) viruses, in planta Agrobacterium
tumefaciens mediated gene transfer by infiltration of adult plants
or transformation of mature pollen or microspores (EP 0 301 316)
and the like. A preferred method according to the invention
comprises Agrobacterium-mediated DNA transfer. Especially preferred
is the use of the so-called binary vector technology as disclosed
in EP A 120 516 and U.S. Pat. No. 4,940,838).
[0102] Although considered somewhat more recalcitrant towards
genetic transformation, monocotyledonous plants are amenable to
transformation and fertile transgenic plants can be regenerated
from transformed cells or embryos, or other plant material.
Presently, preferred methods for transformation of monocots are
microprojectile bombardment of embryos, explants or suspension
cells, and direct DNA uptake or (tissue) electroporation (Shimamoto
et al. (1989), Nature 338, 274-276). Transgenic maize plants have
been obtained by introducing the Screptomyces hygroscopicus
bar-gene, which encodes phosphinothricin acetyltransferase (an
enzyme which inactivates the herbicide phosphinothricin), into
embryogenic cells of a maize suspension culture by microprojectile
bombardment (Gordon-Kamm (1990), Plant Cell, 2, 603). The
introduction of genetic material into aleurone protoplasts of other
monocot crops such as wheat and barley has been reported (Lee
(1989), Plant Mol. Biol. 13, 21). Wheat plants have been
regenerated from embryogenic suspension culture by selecting
embryogenic callus for the establishment of the embryogenic
suspension cultures (Vasil (1990) Bio/Technol. 8, 429). The
combination with transformation systems for these crops enables the
application of the present invention to monocots.
[0103] Monocotyledonous plants, including commercially important
crops such as rice and corn are also amenable to DNA transfer by
Agrobacterium strains (vide WO 94/00977, EP 0 159 418 B1; Gould et
al. (1991) Plant. Physiol. 95, 426-434).
[0104] To obtain transgenic plants capable of constitutively
expressing more than one chimeric gene, a number of alternatives
are available including the following:
A. The use of DNA, e.g a T-DNA on a binary plasmid, with a number
of modified genes physically coupled to a second selectable marker
gene. The advantage of this method is that the chimeric genes are
physically coupled and therefore migrate as a single Mendelian
locus. B. Cross-pollination of transgenic plants each already
capable of expressing one or more chimeric genes, preferably
coupled to a selectable marker gene, with pollen from a transgenic
plant which contains one or more chimeric genes coupled to another
selectable marker. Afterwards the seed, which is obtained by this
crossing, maybe selected on the basis of the presence of the two
selectable markers, or on the basis of the presence of the chimeric
genes themselves. The plants obtained from the selected seeds can
afterwards be used for further crossing. In principle the chimeric
genes are not on a single locus and the genes may therefore
segregate as independent loci. C. The use of a number of a
plurality chimeric DNA molecules, e.g. plasmids, each having one or
more chimeric genes and a selectable marker. If the frequency of
co-transformation is high, then selection on the basis of only one
marker is sufficient. In other cases, the selection on the basis of
more than one marker is preferred. D. Consecutive transformation of
transgenic plants already containing a first, second, (etc),
chimeric gene with new chimeric DNA, optionally comprising a
selectable marker gene. As in method B, the chimeric genes are in
principle not on a single locus and the chimeric genes may
therefore segregate as independent loci. E. Combinations of the
above mentioned strategies.
[0105] The actual strategy may depend on several considerations as
maybe easily determined such as the purpose of the parental lines
(direct growing, use in a breeding programme, use to produce
hybrids) but is not critical with respect to the described
invention.
[0106] It is known that practically all plants can be regenerated
from cultured cells or tissues. The means for regeneration vary
from species to species of plants, but generally a suspension of
transformed protoplasts or a petri plate containing transformed
explants is first provided. Shoots may be induced directly, or
indirectly from callus via organogenesis or embryogenesis and
subsequently rooted. Next to the selectable marker, the culture
media will generally contain various amino acids and hormones, such
as auxin and cytokinins. It is also advantageous to add glutamic
acid and proline to the medium, especially for such species as corn
and alfalfa. Efficient regeneration will depend on the medium, on
the genotype and on the history of the culture. If these three
variables are controlled regeneration is usually reproducible and
repeatable. After stable incorporation of the transformed gene
sequences into the transgenic plants, the traits conferred by them
can be transferred to other plants by sexual crossing. Any of a
number of standard breeding techniques can be used, depending upon
the species to be crossed.
[0107] Suitable DNA sequences for control of expression of the
plant expressible genes (including marker genes), such as
transcriptional initiation regions, enhancers, non-transcribed
leaders and the like, may be derived from any gene that is
expressed in a plant cell. Also intended are hybrid promoters
combining functional portions of various promoters, or synthetic
equivalents thereof. Apart from constitutive promoters, inducible
promoters, or promoters otherwise regulated in their expression
pattern, e.g. developmentally or cell-type specific, may be used to
control expression of the expressible genes according to the
invention.
[0108] To select or screen for transformed cells, it is preferred
to include a marker gene linked to the plant expressible gene
according to the invention to be transferred to a plant cell. The
choice of a suitable marker gene in plant transformation is well
within the scope of the average skilled worker; some examples of
routinely used marker genes are the neomycin phosphotransferase
genes conferring resistance to kanamycin (EP-B 131 623), the
glutathion-S-transferase gene from rat liver conferring resistance
to glutathione derived herbicides (EP-A 256 223), glutamine
synthetase conferring upon overexpression resistance to glutamine
synthetase inhibitors such as phosphinothricin (WO 87/05327), the
acetyl transferase gene from Streptomyces viridochromogenes
conferring resistance to the selective agent phosphinothricin (EP-A
275 957), the gene encoding a 5-enolshikimate-3-phosphate synthase
(EPSPS) conferring tolerance to N-phosphonomethylglycine, the bar
gene conferring resistance against Bialaphos (e.g. WO 91/02071) and
the like. The actual choice of the marker is not crucial as long as
it is functional (i.e. selective) in combination with the plant
cells of choice.
[0109] The marker gene and the gene of interest do not have to be
linked, since co-transformation of unlinked genes (U.S. Pat. No.
4,399,216) is also an efficient process in plant
transformation.
[0110] Preferred plant material for transformation, especially for
dicotyledonous crops are leaf-discs which can be readily
transformed and have good regenerative capability (Horsch et al.
(1985), Science 227, 1229).
[0111] Specific use of the invention is envisaged in the following
ways: as can be seen from the Examples the effects of the
expression of TPP (which causes a decrease in the intracellular
T-6-P concentration) are an increased leaf size, increased
branching leading t6 an increase in the number of leaves, increase
in total leaf biomass, bleaching of mature leaves, formation of
more small flowers and sterility. These effects are specifically
useful in the following cases: increased leaf size (and increase in
the number of leaves) is economically important for leafy
vegetables such as spinach, lettuce, leek, alfalfa, silage maize;
for ground coverage and weed control by grasses and garden plants;
for crops in which the leaves are used as product, such as tobacco,
tea, hemp and roses (perfumes!); for the matting up of cabbage-like
crops such as cauliflower.
[0112] An additional advantage of the fact that these leaves are
stimulated in their metabolic activity is that they tend to burn
all their intracellular resources, which means that they are low in
starch-content. For plants meant for consumption a reduction in
starch content is advantageous in the light of the present tendency
for low-calorie foodstuffs. Such a reduction in starch content also
has effects on taste and texture of the leaves. An increase in the
protein/carbohydrate balance as can be produced by the expression
of TPP is especially important for leafy crops as silage maize.
[0113] Increased branching, which is accompanied by a tendency to
have stems with a larger diameter, can be advantageous in crops in
which the stem is responsible for the generation of an economically
attractive product. Examples in this category are all trees for the
increased production of wood, which is also a starting material for
paper production; crops like hemp, sisal, flax which are used for
the production of rope and linen; crops like bamboo and sugarcane;
rubber-tree, cork-oak; for the prevention of flattening in crops or
crop parts, like grains, corn, legumes and strawberries.
[0114] A third phenomenon is increased bleaching of the leaves
(caused by a decrease of photosynthetic activity). Less colorful
leaves are preferred for crops such as chicory and asparagus. Also
for cut flowers bleaching in the petals can be desired, for
instance in Alstromeria.
[0115] An overall effect is the increase in biomass resulting from
an increase in metabolic activity. This means that the biomass
consists of metabolized compounds such as proteins and fats.
Accordingly, there is an increased protein/carbohydrate balance in
mature leaves which is an advantage for crops like silage maize,
and all fodder which can be ensilaged. A similar increased
protein/carbohydrate balance can be established in fruits, tubers
and other edible plant parts.
[0116] Outside the plant kingdom an increased metabolism would be
beneficial for protein production in microorganisms or eukaryotic
cell cultures. Both production of endogenous but also of
heterologous proteins will be enhanced which means that the
production of heterologous proteins in cultures of yeast or other
unicellular organisms can be enhanced in this way. For yeast this
would give a more efficient fermentation, which would result in an
increased alcohol yield, which of course is favourable in brewery
processes, alcohol production and the like.
[0117] In animals or human beings it is envisaged that diseases
caused by a defect in metabolism can be overcome by stable
expression of TPP or TPS in the affected cells. In human cells, the
increased glucose consumption of many tumour cells depends to a
large extent on the overexpression of hexokinase (Rempel et al.
(1996) FEBS Lett. 385, 233). It is envisaged that the flux of
glucose into the metabolism of cancer cells can be influenced by
the expression of trehalose-6-phosphate synthesizing enzymes. It
has also been shown that the hexokinase activation is potentiated
by the cAMP/PKA (protein kinase A pathway). Therefore, inactivation
of this signal transduction pathway may affect glucose uptake and
the proliferation of neoplasias. Enzyme activities in mammalian
cells able to synthesize trehalose-6-phosphate and trehalose and
degrade trehalose have been shown in e.g. rabbit kidney cortex
cells (Sacktor (1968) Proc. Natl. Acad. Sci. USA 60, 1007).
[0118] Another example can be found in defects in insulin secretion
in pancreatic beta-cells in which the production of
glucose-6-phosphate catalyzed by hexokinase is the predominant
reaction that couples rises in extracellular glucose levels to
insulin secretion (Efrat et al. (1994), TIBS 19, 535). An increase
in hexokinase activity caused by a decrease of intracellular T-6-P
then will stimulate insulin production in cells which are deficient
in insulin secretion.
[0119] Also in transgenic animals an increased protein/carbohydrate
balance can be advantageous. Both the properties of on increased
metabolism and an enhanced production of proteins are of large
importance in farming in which animals should gain in flesh as soon
as possible. Transformation of the enzyme TPP into meat-producing
animals like chickens, cattle, sheep, turkeys, goats, fish,
lobster, crab, shrimps, snails etc, will yield animals that grow
faster and have a more proteinaceous meat.
[0120] In the same way this increased metabolism means an increase
in the burn rate of carbohydrates and it thus prevents obesity.
[0121] More plant-specific effects from the decrease of
intracellular T-6-P concentration are an increase in the number of
flowers (although they do not seem to lead to the formation of
seed). However, an increase in the number of flowers is
advantageous for cutflower plants and pot flower plants and also
for all plants suitable for horticulture.
[0122] A further effect of this flowering phenomenon is sterility,
because the plants do not produce seed. Sterile plants are
advantageous in hybrid breeding.
[0123] Another economically important aspect is the prohibiting of
bolting of culture crops such as lettuce, endive and both
recreational and fodder grasses. This is a beneficial property
because it enables the crop to grow without having to spend
metabolic efforts to flowering and seed production. Moreover, in
crops like lettuce, endive and grasses the commercial
product/application is non-bolted.
[0124] Specific expression of TPP in certain parts (sinks) of the
plant can give additional beneficial effects. It is envisaged that
expression of TPP by a promoter which is active early in e.g. seed
forming enables an increased growth of the developing seed. A
similar effect would be obtained by expressing TPP by a
flower-specific promoter. To put it shortly: excessive growth of a
certain plant part is possible if TPP is expressed by a suitable
specific promoter. In fruits specific expression can lead to an
increased growth of the skin in relation to the flesh. This enables
improvement of the peeling of the fruit, which can be advantageous
for automatic peeling industries.
[0125] Expression of TPP during the process of germination of
oil-storing seeds prevents oil-degradations. In the process of
germination, the glyoxylate cycle is very active. This metabolic
pathway converts acetyl-CoA via malate into sucrose which can be
transported and used as energy source during growth of the
seedling. Key-enzymes in this process are malate synthase and
isocitrate lyase. Expression of both enzymes is supposed to be
regulated by hexokinase signalling. One of the indications for this
regulation is that both 2-deoxyglucose and mannose are
phosphorylated by hexokinase and able to transduce their signal,
being reduction of malate synthase and isocitrate lyase expression,
without being further metabolised. Expression of TPP in the seed,
thereby decreasing the inhibition of hexokinase, thereby inhibiting
malate synthase and isocitrate lyase maintains the storage of oil
into the seeds and prevents germination.
[0126] In contrast to the effects of TPP the increase in T-6-P
caused by the expression of TPS causes other effects as is
illustrated in the Examples. From these it can be learnt that an
increase in the amount of T-6-P causes dwarfing or stunted growth
(especially at high expression of TPS), formation of more
lancet-shaped leaves, darker color due to an increase in
chlorophyll and an increase in starch content. As is already
acknowledged above, the introduction of an anti-sense trehalase
construct will also stimulate similar effects as the introduction
of TPS. Therefore, the applications which are shown or indicated
for TPS will equally be established by using as-trehalase.
Moreover, the use of double-constructs of TPS and as-trehalase
enhances the effects of a single construct.
[0127] Dwarfing is a phenomenon that is desired in horticultural
plants, of which the Japanese bonsai trees are a proverbial
example. However, also creation of mini-flowers in plants like
allseed, roses, Amaryllis, Hortensia, birch and palm will have
economic opportunities. Next to the plant kingdom dwarfing is also
desired in animals. It is also possible to induce bolting in
culture crops such as lettuce. This is beneficial because it
enables a rapid production of seed. Ideally the expression of TPS
for this effect should be under control of an inducible
promoter.
[0128] Loss of apical dominance also causes formation of multiple
shoots which is of economic importance for instance in alfalfa.
[0129] A reduction in growth is furthermore desired for the
industry of "veggie snacks", in which vegetables are considered to
be consumed in the form of snacks. Chemy-tomatoes is an example of
reduced size vegetables which are successful in the market. It can
be envisaged that also other vegetables like cabbages, cauliflower,
carrot, beet and sweet potato and fruits like apple, pear, peach,
melon, and several tropical fruits like mango and banana would be
marketable on miniature size.
[0130] Reduced growth is desired for all cells that are detrimental
to an organism, such as cells of pathogens and cancerous cells. In
this last respect a role can be seen in regulation of the growth by
changing the level of T-6-P. An increase in the T-6-P level would
reduce growth and metabolism of cancer tissue. One way to increase
the intracellular level of T-6-P is to knock-out the TPP gene of
such cells by introducing a specific recombination event which
causes the introduction of a mutation in the endogenous TPP-genes.
One way in which this could be done is the introduction of a
DNA-sequence able of introducing a mutation in the endogenous gene
via a cancer cell specific internalizing antibody. Another way is
targeted microparticle bombardment with said DNA. Thirdly a cancer
cell specific viral vectors having said DNA can be used.
[0131] The phenomenon of a darker green color seen with an
increased concentration of T-6-P, is a property which is desirable
for pot flower plants and, in general, for species in horticulture
and for recreational grasses.
[0132] Increase in the level of T-6-P also causes an increase in
the storage carbohydrates such as starch and sucrose. This then
would mean that tissues in which carbohydrates are stored would be
able to store more material. This can be illustrated by the
Examples where it is shown that in plants increased biomass of
storage organs such as tubers and thickened roots as in beets
(storage of sucrose) are formed.
[0133] Crops in which this would be very advantageous are potato,
sugarbeet, carrot, chicory and sugarcane.
[0134] An additional economically important effect in potatoes is
that after transformation with DNA encoding for the TPS gene
(generating an increase in T-6-P) it has been found that the amount
of soluble sugars decreases, even after harvest and storage of the
tubers under cold conditions (4.degree. C.). Normally even colder
storage would be necessary to prevent early sprouting, but this
results in excessive sweetening of the potatoes. Reduction of the
amount of reducing sugars is of major importance for the food
industry since sweetened potato tuber material is not suitable for
processing because a Maillard reaction will take place between the
reducing sugars and the amino-acids which results in browning.
[0135] In the same way also inhibition of activity of invertase can
be obtained by transforming sugarbeets with a polynucleotide
encoding for the enzyme TPS. Inhibition of invertase activity in
sugarbeets after harvest is economically very important.
[0136] Also in fruits and seeds, storage can be altered. This does
not only result in an increased storage capacity but in a change in
the composition of the stored compounds. Crops in which
improvements in yield in seed are especially important are maize,
rice, cereals, pea, oilseed rape, sunflower, soybean and legumes.
Furthermore, all fruitbearing plants are important for the
application of developing a change in the amount and composition of
stored carbohydrates. Especially for fruit the composition of
stored products gives changes in solidity and firmness, which is
especially important in soft fruits like tomato, banana,
strawberry, peach, berries and grapes.
[0137] In contrast to the effects seen with the expression of TPP,
the expression of TPS reduces the ratio of protein/carbohydrate in
leaves. This effect is of importance in leafy crops such as fodder
grasses and alfalfa. Furthermore, the leaves have a reduced
biomass, which can be of importance in amenity grasses, but, more
important, they have a relatively increased energy content. This
property is especially beneficial for crops as onion, leek and
silage maize.
[0138] Furthermore, also the viability of the seeds can be
influenced by the level of intracellularly available T-6-P.
[0139] Combinations of expression of TPP in one part of a plant and
TPS in an other part of the plant can synergize to increase the
above-described effects. It is also possible to express the genes
sequential during development by using specific promoters. Lastly,
it is also possible to induce expression of either of the genes
involved by placing the coding the sequence under control of an
inducible promoter. It is envisaged that combinations of the
methods of application as described will be apparent to the person
skilled in the art.
[0140] The invention is further illustrated by the following
examples. It is stressed that the Examples show specific
embodiments of the inventions, but that it will be clear that
variations on these examples and use of other plants or expression
systems are covered by the invention.
EXPERIMENTAL
DNA Manipulations
[0141] All DNA procedures (DNA isolation from E. coli, restriction,
ligation, transformation, etc.) are performed according to standard
protocols (Sambrook et al. (1989) Molecular Cloning: a laboratory
manual, 2nd ed. Cold Spring Harbor Laboratory Press, CSH, New
York).
Strains
[0142] In all examples E. coli K-12 strain DH5a is used for
cloning. The Agrobacterium tumefaciens strains used for plant
transformation experiments are EHA 105 and MOG 101 (Hood et al.
(1993) Trans. Research 2, 208).
Construction of Agrobacterium Strain MOG101 Construction of
Agrobacterium strain MOG101 is described in WO 96/21030. Cloning of
the E. Coli otsA Gene and Construction of pMOG799
[0143] In E. coli trehalose phosphate synthase (TPS) is encoded by
the otsA gene located in the operon otsBA. The cloning and sequence
determination of the otsA gene is described in detail in Example I
of WO95/01446, herein incorporated by reference. To effectuate its
expression in plant cells, the open reading frame has been linked
to the transcriptional regulatory elements of the CaMV 35S RNA
promoter, the translational enhancer of the ALMV leader, and the
transcriptional terminator of the nos-gene, as described in greater
detail in Example I of WO95/01446, resulting in pMOG799. A sample
of an E. coli strain harboring pMOG799 has been deposited under the
Budapest Treaty at the Centraal Bureau voor Schimmelcultures,
Oosterstraat 1, P.O. Box 273, 3740 AG Baarn, The Netherlands, on
Monday 23 Aug. 1993: the Accession Number given by the
International Depositary Institution is CBS 430.93.
Isolation of a Patatin Promoter/Construction of pMOG546
[0144] A patatin promoter fragment is isolated from chromosomal DNA
of Solanum.sub.--tuberosum cv. Bintje using the polymerase chain
reaction. A set of oligonucleotides, complementary to the sequence
of the upstream region of Apat21 patatin gene (Bevan et al. (1986)
Nucl. Acids Res. 14, 5564), is synthesized consisting of the
following sequences:
TABLE-US-00001 (SEQ ID NO: 5) 5' AAG CTT ATG TTG CCA TAT AGA GTA G
3' PatB33.2 (SEQ ID NO: 6) 5' GTA GTT GCC ATG GTG CAA ATG TTC 3'
PatATG.2
[0145] These primers are used to PCR amplify a DNA fragment of 1123
bp, using chromosomal DNA isolated from potato cv. Bintje as a
template. The amplified fragment shows a high degree of similarity
to the Apat21 patatin sequence and is cloned using EcoRI linkers
into a pUC18 vector resulting in plasmid pMOG546.
Construction of pMOG845
[0146] Construction of pMOG845 is described in WO 96/21030.
Construction of pVDH318, Plastocvanin-TPS
[0147] Plasmid pMOG79B (described in WO95/01446) is digested with
HindIII and ligated with the oligonucleotide duplex TCV11 and TCV12
(see construction of pMOG845). The resulting vector is digested
with PstI and HindIII followed by the insertion of the PotPiII
terminator resulting in pTCV118. Plasmid pTCV118 is digested with
SmaI and HindIII yielding a DNA fragment comprising the TPS coding
region and the PotPiII terminator. BglII linkers were added and the
resulting fragment was inserted in the plant binary expression
vector pVDH275 (FIG. 1) digested with BamHI, yielding pVDH318.
pVDH275 is a derivative of pMOG23 (Sijmons et al. (1990),
Bio/Technol. 8, 217) harboring the NPTII selection marker under
control of the 35S CaMV promoter and an expression cassette
comprising the pea plastocyanin (PC) promoter and nos terminator
sequences. The plastocyanin promoter present in pVDH275 has been
described by Pwee & Gray (1993) Plant J. 3, 437. This promoter
has been transferred to the binary vector using PCR amplification
and primers which contain suitable cloning sites.
Cloning of the E. Coli otsB Gene and Construction of pMOG100 (35S
CaMV TPP)
[0148] A set of oligonucleotides, TPP I (5' CTCAGATCTGGCCACAAA 3')
(SEQ ID NO: 56) and TPP II (5' GTGCTCGTCTGCAGGTGC 3') (SEQ ID NO:
57), was synthesized complementary to the sequence of the E. coli
TPP gene (SEQ ID NO: 3). These primers were used to PCR amplify a
DNA fragment of 375 bp harboring the 3' part of the coding region
of the E. coli TPP gene, introducing a PstI site 10 bp down-stream
of the stop codon, using pMOG748 (WO 95/01446) as a template. This
PCR fragment was digested with BglII and PstI and cloned into
pMG445 (EP 0 449 376 A2 example 7a) and linearized with BglII and
PstI. The resulting vector was digested with PstI and HindIII and a
PotPiII terminator was inserted (see construction pMOG845). The
previous described vector was digested with BglII and HindIII, the
resulting 1325 by fragment was isolated and cloned together with
the 5'TPP PCRed fragment digested with SmaI and BglII into pUC18
linearized with SmaI and HindIII. The resulting vector was called
pTCV124. This vector was linearized with EcoRI and SmaI and used to
insert the 35S CaMV promoter (a 850 bp EcoRI-`NcoI` (the NcoI site
was made blunt by treatment with mungbean nuclease) fragment
isolated from pMOG18 containing the 35S CaMV double enhancer
promoter). This vector was called pTCV 127. From this vector a 2.8
kb EcoRI-HindIII fragment was isolated containing the complete 35S
TPP expression cassette and cloned in binary vector pMOG800
resulting in vector pMOG1010.
Construction of pVDH321, Plastocyanin (PC) TPP
[0149] The BamHI site of plasmid pTCV124 was removed by BamHI
digestion, filling-in and subsequent religation. Subsequent
digestion with HindIII and EcoRI yields a DNA fragment comprising
the TPP coding region and the PotPiII terminator. BamHI linkers
were added and the resulting fragment was inserted in the plant
binary expression vector pVDH275 (digested with BamHI) yielding
pVDH321.
Construction of a Patatin TPP Expression Vector
[0150] Similar to the construction of the patatin TPS expression
vector (see construction of pMOG845), a patatin TPP expression
vector was constructed yielding a binary vector (pMOG1128) which,
after transformation, can effectuate expression of TPP in a
tuber-specific manner.
Construction of Other Expression Vectors
[0151] Similar to the construction of the above mentioned vectors,
gene constructs can be made where different promoters are used, in
combination with TPS, TPP or trehalase using binary vectors with
the NPTII gene or the Hygromycin-resistance gene as selectable
marker gene. A description of binary vector pMOG22 harboring a HPT
selection marker is given in Goddijn et al. (1993) Plant J. 4,
863.
Triparental Matings
[0152] The binary vectors are mobilized in triparental matings with
the E. coli strain HB 101 containing plasmid pRK2013 (Ditta et al.
(1980) Proc. Natl. Acad. Sci. USA 77, 7347) into Agrobacterium
tumefaciens strain MOG101 or EHA105 and used for
transformation.
Transformation of Tobacco (Nicotiana tabacum Cv. SR1 or Cv, Samsun
NN)
[0153] Tobacco was transformed by cocultivation of plant tissue
with Agrobacterium tumefaciens strain MOG101 containing the binary
vector of interest as described. Transformation was carried out
using cocultivation of tobacco leaf disks as described by Horsch et
al. (1985) Science 227, 1229. Transgenic plants are regenerated
from shoots that grow on selection medium containing kanamycin,
rooted and transferred to soil.
Transformation of Potato
[0154] Potato (Solanum tuberosum cv. Kardal) was transformed with
the Agrobacterium strain EHA 105 containing the binary vector of
interest. The basic culture medium was MS30R3 medium consisting of
MS salts (Murashige and Skoog (1962) Physiol. Plant. 14, 473), R3
vitamins (Ooms et al. (1987) Theor. Appl. Genet. 73, 744), 30 g/l
sucrose, 0.5 g/l MES with final pH 5.8 (adjusted with KOH)
solidified when necessary with 8 g/l Daichin agar. Tubers of
Solanum tuberosum cv. Kardal were peeled and surface sterilized by
burning them in 96% ethanol for 5 seconds. The flames were
extinguished in sterile water and cut slices of approximately 2 mm
thickness. Disks were cut with a bore from the vascular tissue and
incubated for 20 minutes in MS30R3 medium containing
1-5.times.10.sup.8 bacteria/ml of Agrobacterium EHA 105 containing
the binary vector. The tuber discs were washed with MS30R3 medium
and transferred to solidified postculture medium (PM). PM consisted
of M30R3 medium supplemented with 3.5 mg/l zeatin riboside and 0.03
mg/l indole acetic acid (IAA). After two days, discs were
transferred to fresh PM medium with 200 mg/i cefotaxim and 100 mg/l
vancomycin. Three days later, the tuber discs were transferred to
shoot induction medium (SIM) which consisted of PM medium with 250
mg/l carbenicillin and 100 mg/l kanamycin. After 4-8 weeks, shoots
emerging from the discs were excised and placed on rooting medium
(MS30R3-medium with 100 mg/l cefotaxim, 50 mg/l vancomycin and 50
mg/l kanamycin). The shoots were propagated axenically by meristem
cuttings.
Transformation of Lettuce
[0155] Transformation of lettuce, Lattuca sativa cv. Evola was
performed according to Curtis et al. (1994) J. Exp. Bot. 45,
1441.
Transformation of Sugarbeet
[0156] Transformation of sugarbeet, Beta vulgaris (maintainer
population) was performed according to Fry et al. (1991) Third
International Congress of ISPMB, Tucson USA Abstract No. 384, or
according to Krens et al. (1996), Plant Sci. 116, 97.
Transformation of Lycopersicon esculentum Tomato transformation was
performed according to Van Roekel et al. (1993) Plant Cell Rep. 12,
644.
Transformation of Arabidopsis
[0157] Transformation of Arabidopsis thaliana was carried out
either by the method described by Clarke et al. (1992) Plant. Mol.
Biol. Rep. 10, 178 or by the method described by Valvekens et al.
(1988) Proc. Natl. Acad. Sci. USA, 85, 5536.
Induction of Micro-Tubers
[0158] Stem segments of in vitro potato plants harboring an
auxiliary meristem were transferred to micro-tuber inducing medium.
Micro-tuber inducing medium contains 1 X MS-salts supplemented with
R3 vitamins, 0.5 g/l MES (final pH=5.8, adjusted with KOH) and
solidified with 8 g/l Daichin agar, 60 g/l sucrose and 2.5 mg/l
kinetin. After 3 to 5 weeks of growth in the dark at 24.degree. C.,
micro-tubers were formed.
Isolation of Validamycin A
[0159] Validamycin A has been found to be a highly specific
inhibitor of trehalases from various sources ranging from
(IC.sub.50) 10.sup.-6M to 10.sup.-1.degree. M (Asano et al. (1987)
J. Antibiot. 40, 526; Kameda et al. (1987) J. Antibiot 40, 563).
Except for trehalase, it does not significantly inhibit any
.alpha.- or .beta.-glycohydrolase activity. Validamycin A was
isolated from Solacol, a commercial agricultural formulation
(Takeda Chem. Indust., Tokyo) as described by Kendall et al. (1990)
Phytochemistry 29, 2525. The procedure involves ion-exchange
chromatography (QAE-Sephadex A-25 (Pharmacia), bed vol. 10 ml,
equilibration buffer 0.2 mM Na-Pi pH 7) from a 3% agricultural
formulation of Solacol. Loading 1 ml of Solacol on the column and
eluting with water in 7 fractions, practically all Validamycin was
recovered in fraction 4. Based on a 100% recovery, using this
procedure, the concentration of Validamycin A was adjusted to
1.10.sup.-3 M in MS-medium, for use in trehalose accumulation
tests. Alternatively, Validamycin A and B may be purified directly
from Streptomyces hygroscopicus var. limoneus, as described by
Iwasa et al. (1971) J. Antibiot. 24, 119, the content of which is
incorporated herein by reference.
Carbohydrate Analysis
[0160] Carbohydrates were determined quantitatively by anion
exchange chromatography with pulsed electrochemical detection.
Extracts were prepared by extracting homogenized frozen material
with 80% EtOH. After extraction for 15 minutes at room temperature,
the soluble fraction is evaporated and dissolved in distilled
water. Samples (25 .mu.l) were analyzed on a Dionex DX-300 liquid
chromatograph equipped with a 4.times.250 mm Dionex 35391 carbopac
PA-1 column and a 4.times.50 mm Dionex 43096 carbopac PA-1
precolumn Elution was with 100 mM NaOH at 1 ml/min followed by a
NaAc gradient. Sugars were detected with a pulsed electrochemical
detector (Dionex, PED). Commercially available carbohydrates
(Sigma) were used as a standard.
Starch Analysis
[0161] Starch analysis was performed as described in: Aman et al.
(1994) Methods in Carbohydrate Chemistry, Volume X (eds. BeMiller
et al.), pp 111-115.
Expression Analysis
[0162] The expression of genes introduced in various plant species
was monitored using Northern blot analysis.
Trehalose-6-Phosnhate Phosphatase Assay TPP was assayed at
37.degree. C. by measuring the production of [.sup.14C]trehalose
from [.sup.14C]trehalose-6-phosphate (Londesborough and Vuorio
(1991) J. of Gen. Microbiol. 137, 323). Crude extracts were
prepared in 25 mM Tris, HCl pH 7.4, containing 5.5 mM MgCl.sub.2.
Samples were diluted to a protein concentration of 1 mg/ml in
extraction buffer containing 1 mg/ml BSA. Standard assay mixtures
(50 .mu.l final volume) contained 27.5 mM Tris, HCl pH 7.4, 5.5 mM
MgCl.sub.2, 1 mg/ml BSA and 0.55 mM T-6-P (specific activity 854
cpm/nmol). Reactions were initiated by the addition of 5 .mu.l
enzyme and terminated after 1 hour by heating for 5 minutes in
boiling water. AG1-X8 (formate) anion-exchange resin (BioRad) was
added and the reaction mixtures were centrifuged after 20 minutes
of equilibration at room temperature. The radioactivity in the
supernatant of the samples (400 .mu.l) was measured by liquid
scintillation counting.
Preparation of Plant Extracts for Hexokinase Assays
[0163] Frozen plant material was grinded in liquid nitrogen and
homogenized for 30 seconds with extraction buffer (EB: 100 mM HEPES
pH7.0 (KOH), 1% (w/v) PVP, 5 mM MgCl.sub.2, 1.5 mM EDTA, 0.1% v/v
.beta.-MeOH) including Proteinase Inhibitors Complete (Boehringer
Mannheim). After centrifugation, proteins in the supernatant were
precipitated using 80% ammoniumsulphate and dissolved in Tris-HCl
pH 7.4 and the extract was dialyzed overnight against 100 mM
Tris-HCl pH 7.4. Part of the sample was used in the hexokinase
assay.
Hexokinase Assay
[0164] Hexokinase activity was measured in an assay containing 0.1
M Hepes-KOH pH 7.0, 4 mM MgCl.sub.2, 5 mM ATP, 0.2 mM NADP.sup.+,
10 U/ml Creatine Phosphate Kinase (dissolved in 50% glycerol, 0.1%
BSA, 50 mM Hepes pH 7.0), 3.5 mM Creatine Phosphate, 7 U/ml
Glucose-6-Phosphate Dehydrogenase and 2 mM Glucose by measuring the
increase in OD at 340 nm at 25.degree. C.
[0165] When 2 mM Fructose was used instead of glucose as substrate
for the hexokinase reaction, 3.8 U/ml Phosphoglucose Isomerase was
included. Alternatively, a hexokinase assay as described by Gancedo
et al. (1977) J. Biol. Chem. 252, 4443 was used.
Example 1
Expression of the E. Coli otsA Gene (TPS) in Tobacco and Potato
[0166] Transgenic tobacco plants were generated barbouring the otsA
gene driven by the de35SCaMV promoter (pMOG799) or the plastocyanin
promoter (pVDH318).
[0167] Transgenic potato plants were generated harboring the otsA
gene driven by the potato tuber-specific patatin promoter
(pMOG845).
[0168] Tobacco leaf discs were transformed with the binary vector
pMOG799 using Agrobacterium tumefaciens. Transgenic shoots were
selected on kanamycin.
[0169] Leaves of some soil-grown plants did not fully expand in
lateral direction, leading to a lancet-shaped morphology (FIG.
31).
[0170] Furthermore, apical dominance was reduced resulting in
stunted growth and formation of several axillary shoots. Seven out
of thirty-two plants showed severe growth reduction, reaching plant
heights of 4-30 cm at the time of flowering (Table 1).
TABLE-US-00002 TABLE 1 Trehalose accumulation in leaf samples of
otsA transgenic tobacco plants and their plant length at the time
of flowering. trehalose height plant-line mg g fresh weight cm
controls 0.00 60-70 799-1 0.04 ND 799-3 0.02 10 799.5 0.08 4 799-15
0.055 30 799-24 0.02 12 799-26 0.05 25 799-32 0.055 30 799-40 0.11
25 ND: not determined
[0171] Control plants reached lengths of 60-70 cm at the time of
flowering. Less seed was produced by transgenic lines with the
stunted growth phenotype. Northern blot analysis confirmed that
plants having the stunted growth phenotype expressed the otsA gene
from E. coli (FIG. 2). In control plants no transcript could be
detected. The functionality of the introduced gene was proven by
carbohydrate analyses of leaf material from 32 transgenic
greenhouse-grown tobacco plants, revealing the presence of 0.02 to
0.12 mgg.sup.-1 fresh weight trehalose in plants reduced in length
(Table 1) indicating that the product of the TPS-catalyzed reaction
is dephosphorylated by plant phosphatases. Further proof for the
accumulation of trehalose in tobacco was obtained by treating crude
extracts with porcine trehalase. Prolonged incubation of a tobacco
leaf extract with trehalase resulted in complete degradation of
trehalose (data not shown). Trehalose was not detected in control
plants or transgenic tobacco plants without an aberrant
phenotype.
TABLE-US-00003 TABLE 1a Primary PC-TPS tobacco transformants Leaf
Leaf Plant Fw/ Dry Dry Plant- tw area No. of height Leaf Axillary
area matter matter/area line cm.sup.2 cm.sup.2 branches cm color
shoots g/cm.sup.2 % g/cm.sup.2 ctrl. 1 8.18 349.37 1 wt 0.023 7.21
0.0017 ctrl. 2 10.5 418.89 1 wt 0.025 9.52 0.0024 ctrl. 3 9.99
373.87 1 wt 0.027 12.91 0.0035 ctrl. 4 9.91 362.92 1 wt 0.027 9.59
0.0026 ctrl. 5 9.82 393.84 1 wt 0.025 11.51 0.0029 average 0.0254
10.148 0.0026 2 8.39 290 2 105 wt 0.029 12.16 0.0035 3 9.34 296 1
123 wt 0.032 12.21 0.0039 4 8.36 254 2 130 wt many 0.033 10.05
0.0033 6 2.28 106 5 90 wt 0.022 11.40 0.0025 8 5.21 133 4 100 dark
many 0.039 7.49 0.0029 10 8.08 258 2 165 dark many 0.031 12.25
0.0038 11 2.61 64 12 95 dark many 0.041 9.20 0.0038 13 2.83 92 1
150 dark many 0.031 8.48 0.0026 16 5.86 209 3 130 dark many 0.028
10.58 0.0030 17 5.15 224 2 155 wt 0.023 11.65 0.0027 18 17.2 547 1
133 wt 0.031 10.35 0.0033 19 2.13 63 4 80 dark many 0.034 11.74
0.0040 20 3.44 113 4 90 wt + Da many 0.030 8.14 0.0025 21 9.88 246
1 105 dark many 0.040 8.50 0.0034 22 13.1 409 1 135 wt 0.032 10.68
0.0034 23 2.50 73 6 55 dark many 0.034 8.80 0.0030 24 8.76 286 2
130 wt 0.031 15.07 0.0046 27 7.91 219 1 124 wt 0.036 14.41 0.0052
28 10.0 269 2 117 dark many 0.038 8.62 0.0032 29 4.17 142 1 85 dark
many 0.029 10.07 0.0030 30 10.2 343 1 160 wt 0.030 9.56 0.0029 32
1.95 61 3 75 dark many 0.032 8.21 0.0026 33 2.85 96 5 95 wt + Da
many 0.030 11.23 0.0033 34 8.38 244 1 123 wt 0.034 13.60 0.0047 35
5.59 173 3 126 wt 0.032 14.49 0.0047 36 3.28 84 3 100 dark many
0.039 11.28 0.0044 37 7.80 222 1 125 wt + Da many 0.035 11.28
0.0040 39 3.70 131 2 123 wt 0.028 17.84 0.0050 40 2.40 68.5 3 108
dark many 0.035 9.58 0.0034 average 0.032 11.00 0.0035
[0172] Transgenic pVDH318 transgenic tobacco plants developed
stunted growth and development of small leaves which were darker
green and slightly thicker than control leaves, a phenotype similar
to the pMOG799 transgenic plants (Table 1a). Further analysis of
these leaves showed an increased fresh and dry weight per leaf-area
compared to the controls (Tables 1a and 2). The dark green leaves
indicate the presence of more chlorophyll in the transgenic leaves
(Table 1b). Plants transgenic for pNOG799 (35STPS) and pMCG1177
(PCTPS) were analyzed on soluble carbohydrates, chlorophyll,
trehalose and starch (FIG. 32). pMOG1177 is functionally identical
to pVDH318.
TABLE-US-00004 TABLE 1b Chlorophyll content of N. tabacum leaves
(T.sub.0) transgenic for PC-TPS Chlorophyll Sample (mg/g leaf)
Control 1 0.59 PC TPS 10-1 0.75 PC TPS 10-2 0.80 PC TPS 11 0.60 PC
TPS 13 0.81 PC TPS 16 0.90 PC TPS 19 0.64 PC TPS 37 0.96 Note:
light conditions during growth will influence the determined levels
of chlorophyll significantly. The calculated amounts of chlorophyll
may thus only be compared between plants harvested and analyzed
within one experiment!
TABLE-US-00005 TABLE 2 Fresh weight and dry weight data of leaf
material transgenic for plastocyanin-TPS.sub.E. coli N. tabacum cv.
Samsun NN transgenic for PC-TPS Transgene Control Fresh weight (g)
0.83 0.78 Dry weight (g) 0.072 0.079 % dry matter 8.70% 10.10%
FW/area 39 (139%) 28 (100%) DW/area 3.46 (121%) 2.87 (100%) area
(units) 208 275
[0173] Calculation of the ratio between the length and width of the
developing leaves clearly indicate that leaves of plants transgenic
for PC-TPS are more lancet-shaped (Table 3).
[0174] Potato Solanum tuberosum cv. Xardal tuber discs were
transformed with Agrobacterium tumefaciens EHA105 harboring the
binary vector pMOG845, transgenics were obtained with
transformation frequencies comparable to empty vector controls. All
plants obtained were phenotypically indistinguishable from wild
type plants indicating that use of a tissue specific promoter
prevents the phenotypes observed in plants where a constitutive
promoter drives the TPS gene. Micro-tubers were induced on stem
segments of transgenic and wild-type plants cultured on
microtuber-inducing medium supplemented with 10.sup.-3 M
Validamycin A. As a control, microtubers were induced on medium
without Validamycin A. Microtubers induced on medium with
Validamycin A showed elevated levels of trehalose in comparison
with microtubers grown on medium without Validamycin A (Table 4).
The presence of small amounts of trehalose in wild-type plants
indicates the presence of a functional trehalose biosynthetic
pathway.
TABLE-US-00006 TABLE 3 Tobacco plants (cv. Samsun NN) transgenic
for pVDH318 Transformant Length (cm) Width (cm) Ratio 1/w control 1
12 8 1.50 control 2 13 8.5 1.53 control 3 12 7.5 1.60 control 4 15
9 1.67 control 5 25 16 1.56 control 6 24 16.5 1.45 control 7 28 20
1.40 control 8 25 16 1.56 control 9 26 19 1.37 control 10 21 15
1.40 1318-28 16 8.5 1.88* 1318-29 11 6.5 1.69 1318-30 19 14 1.36
1318-35 19 12 1.58 1318-39 21 16.5 1.27 1318-40 14 7 2.00* 1318-34
21 13 1.62 1318-36 13.5 7 1.93* 1318-37 17 9 1.89* 1318-4 20.5 12
1.71 1318-23 14 4.5 3.78* 1318-22 27 18 1.50 1318-19 9 4 2.25*
1318-2 27 19 1.42 1318-15 11 5 2.20* 1318-10 20 13 1.54 1318-3 25
18 1.39 1318-21 17 8.5 2.00* 1318-16 20 10 2.00* 1318-6 19 10.5
1.81 1318-20 13 5 2.60* 1318-33 12 5 2.40* 1318-27 23 20 1.15
1318-11 12 5 2.40 1318-8 18.5 6.5 2.85* 1318-24 27 17 1.59 1318-13
15 7 2.14* 1318-17 24 16 1.50 1318-18 23 16.5 1.39 * typical TPS
phenotypes Ratio 1/w average of controls is 1.50
TABLE-US-00007 TABLE 4 Trehalose (% fresh weight) +Validamycin A
-Validamycin A 845-2 0.016 -- 845-4 -- -- 845-8 0.051 -- 845-11
0.015 -- 845-13 0.011 -- 845-22 0.112 -- 845-25 0.002 -- 845-28
0.109 -- wild type Kardal 0.001 --
Example 2
Expression of the E. Coli otaB Gene (TPP) in Tobacco
[0175] Transgenic tobacco plants were generated harboring the
ots.beta.gene driven by the double enhanced 35SCaMV promoter
(pMOG1010) and the plastocyanin promoter (pVDH321).
[0176] Tobacco plants (cv. Samsun NN) transformed with pMOG1010
revealed in the greenhouse the development of very large leaves
(leaf area increased on average up to approximately 140%) which
started to develop chlorosis when fully developed (FIG. 31).
Additionally, thicker stems were formed as compared to the
controls, in some instances leading to bursting of the stems. In
some cases, multiple stems were formed (branching) from the base of
the plant (Table 5). Leaf samples of plants developing large leaves
revealed 5-10 times enhanced trehalose-6-phosphate phosphatase
activities compared to control plants proving functionality of the
gene introduced. The dry and fresh weight/cm.sup.2 of the abnormal
large leaves was comparable to control leaves, indicating that the
increase in size is due to an increase in dry matter and not to an
increased water content. The inflorescence was also affected by the
expression of TPP. Plants which had a stunted phenotype, probably
caused by the constitutive expression of the TPP gene in all plant
parts, developed many small flowers which did not fully mature and
fell off or necrotized. The development of flowers and seed setting
seems to be less affected in plants which were less stunted.
TABLE-US-00008 TABLE 5 Tobacco plants transgenic for pMOG1010,
de35S CaMV TPP Leaf Stem Height area Bleaching Fw/cm.sup.2
DW/cm.sup.2 Inflorescence diameter Line (cm) cm.sup.2 (5-severe)
Branching (g) (g) Norm./ (mm) 1 63 489 5 + 0.096 0.0031 A 13 2 90
472 3 + 0.076 0.0035 A 19 3 103 345 0 0.072 0.0023 N 16 4 90 612 4
+ 0.096 0.0039 A 5, 6, 7, 8, 14 5 104 618 1 + 0.08 0.0035 N 17 6
110 658 3 + 0.078 0.0035 N/A 19 7 120 427 0 0.074 0.0037 N 18 8 90
472 2 + 0.076 0.0023 A 6, 7, 18 9 60 354 3 + 0.092 0.0031 N .sup.
9.13 10 103 342 0 0.084 0.0025 N 16 11 110 523 1 + 0.076 0.0031 A
18 12 90 533 1 + 0.098 0.0023 N .sup. 5.16 13 53 432 4 + 0.084
0.0043 A 5, 6, 6, 14 14 125 335 0 0.086 0.0023 N 17 15 85 251 0
0.094 0.0031 N 14 16 64 352 0 + 0.076 0.0028 A .sup. 9.13 17 64 267
0 0.11 0.0018 N 15 18 71 370 2 0.086 0.0032 A 5, 7, 8, 14 19 92 672
4 + 0.076 0.0034 N 16 20 21 94 517 4 + 0.07 0.0044 N 17 22 96 659 3
+ 0.082 0.0031 N 17 23 110 407 0 0.082 0.0042 N 16 24 90 381 0 0.1
0.0034 A 15 25 120 535 0 0.076 0.003 N 16 26 42 511 5 0.08 0.0038 ?
15 27 100 468 0 0.086 0.0018 N 17 28 83 583 3 0.072 0.0034 N/A 17
29 27 452 5 + 0.104 0.004 ? 7, 7, 15 30 23 479 4 + 0.076 0.0027 ?
6, 6, 7, 9, 14 31 103 308 1 0.086 0.0027 N 14 32 48 286 0 0.108
0.002 N 16 33 67 539 5 + 0.102 0.0056 A 18 34 40 311 5 + 0.084
0.0051 A 7, 7, 12
TABLE-US-00009 TABLE 6 Primary PC-TPP tobacco transformants Leaf
Leaf Plant Dry Dry Plant- fw area No. of height Leaf Fw/ matter
matter/ line (g) cm.sup.2 branches cm color Bleaching area % area
ctrl. 1 8.18 349.37 0.023 7.213 ctrl. 2 10.5 418.89 0.025 9.524
ctrl. 3 9.99 373.87 0.027 12.913 ctrl. 4 9.91 362.92 0.027 9.586
ctrl. 5 9.82 393.84 0.025 11.507 average 0.0255 10.149 0.0026 11
11.5 338 3 114 wt 0.0340 6.43 0.0022 12 20.1 742 pale bleaching
0.0272 9.82 0.0027 14 9.61 345 1 150 wt 0.0279 11.65 0.0032 16 5.99
234 5 54 pale bleaching 0.0256 12.85 0.0033 17 9.10 314 3 105 wt
0.0290 8.79 0.0025 18 3.78 158 3 75 pale 0.0239 7.67 0.0018 19 2.98
130 1 70 pale 0.0229 10.74 0.0025 20 8.33 296 3 70 pale bleaching
0.0281 7.56 0.0021 22 11.5 460 1 117 pale bleaching 0.0251 3.03
0.0008 24 9.42 369 1 155 wt 0.0255 10.62 0.0027 25 15.9 565 1 170
wt 0.0282 9.54 0.0027 26 8.07 343 2 155 wt 0.0235 15.37 0.0036 28
11.7 411 2 65 pale bleaching 0.0286 6.90 0.0020 29 11.6 420 1 117
pale Bleaching 0.0277 3.53 0.0010 31 8.21 307 2 153 wt 0.0267 12.79
0.0034 32 4.03 175 1 70 pale 0.0230 18.86 0.0043 34 4.81 203 1 107
pale 0.0237 20.58 0.0049 35 7.86 307 3 130 pale 0.0256 11.45 0.0029
36 4.90 206 2 95 pale 0.0238 22.65 0.0054 37 13.9 475 1 135 wt
0.0293 4.82 0.0014 38 16.6 614 1 90 pale bleaching 0.0271 3.31
0.0009 39 14.9 560 1 112 wt bleaching 0.0267 6.08 0.0016 40 24.5
843 0.0292 9.80 0.0029 41 8.86 343 1 115 wt 0.0258 2.93 0.0008 42
6.93 289 1 wt 0.0240 3.32 0.0008 43 11.3 433 136 135 wt 0.0261 6.73
0.0018 44 10.0 341 2 135 wt 0.0294 6.49 0.0019 45 9.40 327 2 135 wt
0.0287 8.51 0.0024 46 9.18 284 2 115 wt 0.0323 15.69 0.0051 average
0.027 9.60 0.0025 wt = wild-type
[0177] Tobacco plants (cv. Samsun NN) transformed with pVDH321
revealed in the greenhouse a pattern of development comparable to
pMOG1010 transgenic plants (Table 6).
[0178] Plants transgenic for pMOG1010 (35S-TPP) and pMOG1124
(PC-TPP) were analyzed on carbohydrates, chlorophyll, trehalose and
starch FIGS. 32 A-D. For chlorophyll data see also Table 6a.
TABLE-US-00010 TABLE 6a Chlorophyll content of N. tabacum leaves
(T.sub.0) transgenic for PC-TPP Chlorophyll sample (mg/g leaf) Leaf
phenotype control 1 1.56 wild-type control 2 1.40 wild-type control
3 1.46 wild-type control 4 1.56 wild-type control 5 1.96 wild-type
PC TPP 12 0.79 bleaching PC TPP 22 0.76 bleaching PC TPP 25 1.30
wild-type PC TPP 37 0.86 wild-type PC TPP 38 0.74 bleaching Note:
light conditions during growth will influence the determined levels
of chlorophyll significantly. The calculated amounts of chlorophyll
may thus only be compared between plants harvested and analyzed
within one experiment!
Example 3
Isolation of Gene Fragments Encoding Trehalose-6-Phosphate
Synthases from Selaginella legidophylla and Helianthus annuus
[0179] Comparison of the TPS protein sequences from E. coli and S.
cerevisiae revealed the presence of several conserved regions.
These regions were used to design degenerated primers which were
tested in PCR amplification reactions using genomic DNA of E. coli
and yeast as a template. A PCR program was used with a temperature
ramp between the annealing and elongation step to facilitate
annealing of the degenerate primers.
[0180] PCR amplification was performed using primer sets TPSdeg 1/5
and TPSdeg 2/5 using cDNA of Selaginella lepidophylla as a
template.
[0181] Degenerated primers used (IUB code):
TABLE-US-00011 TPSdeg1: (SEQ ID NO: 7) GAY ITI ATI TGG RTI CAY GAY
TAY CA TPSdeg2: (SEQ ID NO: 8) TIG GIT KIT TYY TIC AYA YIC CIT TYC
C TPSdeg5: (SEQ ID NO: 9) GYI ACI ARR TTC ATI CCR TCI C
[0182] PCR fragments of the expected size were cloned and
sequenced. Since a large number of homologous sequences were
isolated, Southern blot analysis was used to determine which clones
hybridized with Selaginella genomic DNA. Two clones were isolated,
clone 8 of which the sequence is given in SEQ ID NO: 42 (PCR primer
combination 1/5) and clone 43 of which the sequence is given in SEQ
ID NO: 44 (PCR primer combination 2/5) which on the level of amino
acids revealed regions with a high percentage of identity to the
TPS genes from E. coli and yeast.
[0183] One TPS gene fragment was isolated from Helianthus annuus
(sunflower) using primer combination TPSdeg 2/5 in a PCR
amplification with genomic DNA of H. annuus as a template. Sequence
and Southern blot analysis confirmed the homology with the TPS
genes from E. coli, yeast and Selaginella. Comparison of these
sequences with EST sequences (expressed sequence tags) from various
organisms, see Table 6b and SEQ ID NOS 45-53 and 41, indicated the
presence of highly homologous genes in rice and Arabidopsis, which
supports our invention that most plants contain TPS homologous
genes (FIGS. 3A and 3B).
TABLE-US-00012 TABLE 6b Genbank dbest ID. Accession No. Organism
Function 35567 D22143 Oryza sativa TPS 58199 D35348 Caenorhabditis
elegans TPS 60020 D36432 Caenorhabditis elegans TPS 87366 T36750
Saccharomyces TPS cerevisiae 35991 D22344 Oryza sativa TPS 57576
D34725 Caenorhabditis elegans TPS 298273 H37578 Arabidopsis
thaliana TPS 298289 H37594 Arabidopsis thaliana TPS 315344 T76390
Arabidopsis thaliana TPS 315675 T76758 Arabidopsis thaliana TPS
317475 R65023 Arabidopsis thaliana TPS 71710 D40048 Oryza sativa
TPS 401677 D67869 Caenorhabditis elegans TPS 322639 T43451
Arabidopsis thaliana TPS 76027 D41954 Oryza sativa TPP 296689
H35994 Arabidopsis thaliana TPP 297478 H36783 Arabidopsis thaliana
TPP 300237 T21695 Arabidopsis thaliana TPP 680701 AA054930 Brugia
malayi trehalase 693476 C12818 Caenorhabditis elegans trehalase
311652 T21173 Arabidopsis thaliana TPP 914068 AA273090 Brugia
malayi trehalase 43328 T17578 Saccharomyces TPP cerevisiae 267495
H07615 Brassica napus trehalase 317331 R64855 Arabidopsis thaliana
TPP 15008 T00368 Caenorhabditis elegans trehalase 36717 D23329
Oryza sativa TPP 71650 D39988 Oryza sativa TPP 147057 D49134 Oryza
sativa TPP 401537 D67729 Caenorhabditis elegans trehalase 680728
AA054884 Brugia malayi trehalase 694414 C13756 Caenorhabditis
elegans trehalase 871371 AA231986 Brugia malayi trehalase 894468
AA253544 Brugia malayi trehalase 86985 T36369 Saccharomyces TPP
cerevisiae
Example 4
Isolation of Plant TPS Ad TPP Genes from Nicotiana tabacum
[0184] Fragments of plant TPS- and TPP-encoding cDNA were isolated
using PCR on cDNA derived from tobacco leaf total RNA preparations.
The column "nested" in Table 7 indicates if a second round of PCR
amplification was necessary with primer set 3 and 4 to obtain the
corresponding DNA fragment. Primers have been included in the
sequence listing (Table 7). Subcloning and subsequent sequence
analysis of the DNA fragments obtained with the primer sets
mentioned revealed substantial homology to known TPS genes (FIGS. 4
& 5).
TABLE-US-00013 TABLE 7 Amplification of plant derived TPS and TPP
cDNAs TPS-cDNA primer 1 primer 2 nested primer 3 primer 4 "825" bp
Tre-TPS-14 Deg 1 No SEQ ID NO SEQ ID NO SEQ ID NO 22 & 23 30 7
"840" bp Tre-TPS-14 Tre-TPS-12 Yes Tre-TPS-13 Deg 5 SEQ ID NO SEQ
ID NO SEQ ID NO SEQ ID NO SEQ ID NO 18 & 19 30 31 32 9 "630" bp
Tre-TPS-14 Tre-TPS-12 Yes Deg 2 Deg 5 SEQ ID NO SEQ ID NO SEQ ID NO
SEQ ID NO SEQ ID NO 20 & 21 30 31 8 9 TPP-cDNA primer 1 primer
2 nested "723" bp Tre-TPP-5 Tre-TPP-16 No SEQ ID NO 16 & 17 SEQ
ID NO 35 SEQ ID NO 38 "543" bp Tre-TPP-7 Tre-TPP-16 No SEQ ID NO 14
SEQ ID NO 36 SEQ ID NO 38 "447" bp Tre-TPP-11 Tre-TPP-16 No SEQ ID
NO 12 SEQ ID NO 37 SEQ ID NO 38
Example 5
Isolation of a Bipartite TPS/TPP Gene from Helianthus annuus and
Nicotiana tabacum
[0185] Using the sequence information of the TPS gene fragment from
sunflower (Helianthus annuus), a full length sunflower TPS clone
was obtained using RACE-PCR technology.
[0186] Sequence analysis of this full length clone and alignment
with TPS2 from yeast (FIG. 6) and TPS and TPP encoding sequences
indicated the isolated clone encodes a TPS/TPP bipartite enzyme
(SEQ ID NO: 24, 26 and 28). The bipartite clone isolated (pMOG1192)
was deposited at the Central Bureau for Strain collections under
the rules of the Budapest treaty with accession number CBS692.97 at
Apr. 21, 1997. Subsequently, we investigated if other plant species
also contain TPS/TPP bipartite clones. A bipartite TPS/TPP cDNA was
amplified from tobacco. A DNA product of the expected size (i.e.
1.5 kb) was detected after PCR with primers TPS deg1/TRE-TPP-16 and
nested with TPS deg2/TRE-TPP-15 (SEQ ID NO: 33). An identical band
appeared with PCR with TPS deg1/TRE-TPP-6 (SEQ ID NO: 34) and
nested with TPS deg2/TRE-TPP-15. The latter fragment was shown to
hybridize to the sunflower bipartite cDNA in a Southern blot
experiment. Additionally, using computer database searches, an
Arabidopsis bipartite clone was identified (SEQ ID NO: 39)
Example 6
Expression of Plant Derived TPS Genes in Plants
[0187] Further proof for the function of the TPS genes from
sunflower and Selaginella lepidophylla was obtained by isolating
their corresponding full-length cDNA clones and subsequent
expression of these clones in plants under control of the 35S CaMV
promoter. Accumulation of trehalose by expression of the
Seliganella enzyme has been reported by Zentella and Iturriaga
(1996) (Plant Physiol. 111. Abstract 88).
Example 7
Genes Encoding TPS and TPP from Monocot Species
[0188] A computer search in Genbank sequences revealed the presence
of several rice EST-sequences homologous to TPS 1 and TPS2 from
yeast (FIG. 7) which are included in the sequence listing (SEQ ID
NO: 41, 51, 52 and 53).
Example 8
Isolation Human TPS Gene
[0189] A TPS gene was isolated from human cDNA. A PCR reaction was
performed on human cDNA using the degenerated TPS primers deg2 and
deg5. This led to the expected TPS fragment of 0.6 kb. Sequence
analysis (SEQ ID NO: 10) and comparison with the TPSyeast sequence
indicated that isolated sequence encodes a homologous TPS protein
(FIG. 8).
Example 9
Inhibition of Endogenous TPS Expression by Anti-Sense
Inhibition
[0190] The expression of endogenous TPS genes can be inhibited by
the anti-sense expression of a homologous TPS gene under control of
promoter sequences which drive the expression of such an anti-sense
TPS gene in cells or tissue where the inhibition is desired. For
this approach, it is preferred to use a fully identical sequence to
the TPS gene which has to be suppressed although it is not
necessary to express the entire coding region in an anti-sense
expression vector. Fragments of such a coding region have also
shown to be functional in the anti-sense inhibition of
gene-expression. Alternatively, heterologous genes can be used for
the anti-sense approach when these are sufficiently homologous to
the endogenous gene.
[0191] Binary vectors similar to pMOG845 and pMOG1010 can be used
ensuring that the coding regions of the introduced genes which are
to be suppressed are introduced in the reverse orientation. All
promoters which are suitable to drive expression of genes in target
tissues are also suitable for the anti-sense expression of
genes.
Example 10
Inhibition of Endogenous TPP Expression by Anti-Sense
Inhibition
[0192] Similar to the construction of vectors which can be used to
drive anti-sense expression of tps in cells and tissues (Example
9), vectors can be constructed which drive the anti-sense
expression of TPP genes.
Example 11
Trehalose Accumulation in Wild-Type Tobacco and Potato Plants Grown
on Validamycin A
[0193] Evidence for the presence of a trehalose biosynthesis
pathway in tobacco was obtained by culturing wild-type plants in
the presence of 10.sup.-3M of the trehalase inhibitor Validamycin
A. The treated plants accumulated very small amounts of trehalose,
up to 0.0021% (fw). Trehalose accumulation was never detected in
any control plants cultured without inhibitor. Similar data were
obtained with wild-type microtubers cultured in the presence of
Validamycin A. Ten out of seventeen lines accumulated on average
0.001% trehalose (fw)/(Table 4). No trehalose was observed in
microtubers which were induced on medium without Validamycin A.
Example 12
Trehalose Accumulation in Potato Plants Transgenic for
Astrehalase
[0194] Further proof for the presence of endogenous trehalose
biosynthesis genes was obtained by transforming wild-type potato
plants with a 35S CaMV anti-sense trehalase construct (SEQ ID NO:
54 and 55, pMOG1027; described in WO 96/21030). A potato shoot
transgenic for pMOG1027 showed to accumulate trehalose up to 0.008%
on a fresh weight basis. The identity of the trehalose peak
observed was confirmed by specifically breaking down the
accumulated trehalose with the enzyme trehalase. Tubers of some
pMOG1027 transgenic lines showed to accumulate small amounts of
trehalose (FIG. 9).
Example 13
Inhibition of Plant Hexokinase Activity by
Trehalose-6-Phosphate
[0195] To demonstrate the regulatory effect of
trehalose-6-phosphate on hexokinase activity, plant extracts were
prepared and tested for hexokinase activity in the absence and
presence of trehalose-6-phosphate.
[0196] Potato tuber extracts were assayed using fructose (FIG. 10,
FIG. 11) and glucose (FIG. 11) as substrate. The potato tuber assay
using 1 mM T-6-P and fructose as substrate was performed according
to Gancedo et al. (1997) J. Biol. Chem. 252, 4443. The following
assays on tobacco, rice and maize were performed according to the
assay described in the section experimental. Tobacco leaf extracts
were assayed using fructose (FIG. 12) and glucose (FIG. 12, FIG.
13) as substrate. Rice leaf extracts were assayed using fructose
and glucose (FIG. 14) as substrate. Maize leaf extracts were
assayed using fructose and glucose (FIG. 15) as substrate.
Example 14
Inhibition of Hexokinase Activity in Animal Cell Cultures by
Trehalose-6-Phosphate
[0197] To demonstrate the regulation of hexokinase activity in
animal cells, total cell extracts were prepared from mouse
hybridoma cell cultures. A hexokinase assay was performed using
glucose or fructose as substrate under conditions as described by
Gancedo et al. (see above). Mouse hybridoma cells were subjected to
osmotic shock by exposing a cell pellet to 20% sucrose, followed by
distilled water. This crude protein extract was used in the
hexokinase assay (50 .mu.l) extract corresponding to ca. 200 .mu.g
protein).
TABLE-US-00014 TABLE 8 Inhibition of animal hexokinase activity for
T-6-P Concen- Inhi- tration T6P V0 V2 bition Substrate (mM)
(ODU/min) (ODU/min) (ODU/min) (%) Glucose 2 0.83 0.0204 0.0133 35
Glucose 20 0.83 0.0214 0.0141 35 Glucose 100 0.83 0.0188 0.0125 34
Fructose 20 0.23 0.0207 0.0205 1 Fructose 20 0.43 0.0267 0.0197 26
Fructose 20 0.83 0.0234 0.0151 35 Fructose 20 1.67 0.0246 0.0133
46
[0198] The data obtained clearly showed that hexokinase activity in
mouse cell extracts is inhibited by trehalose-6-phosphate. The
T-6-P concentration range in which this effect is noted is
comparable to what has been observed in crude plant extracts. No
difference is noted in the efficiency of hexokinase inhibition by
trehalose-6-phosphate using glucose or fructose as substrate for
the enzyme.
Example 15
Photosynthesis and Respiration of TPS and TPP Expressing Tobacco
Plants
[0199] Using tobacco plants transgenic for 35S-TPP (1010-5), PC-TPS
(1318-10 and 1318-37) and wild-type Samsun NN plants, effects of
expression of these genes on photosynthesis and respiration were
determined in leaves.
[0200] Measurements were performed in a gas exchange-experimental
set-up. Velocities of gas-exchange were calculated on the basis of
differences in concentration between ingoing and outgoing air using
infra-red gas-analytical equipment. Photosynthesis and respiration
were measured from identical leaves. From each transgenic plant,
the youngest, fully matured leaf was used (upper-leaf) and a leaf
that was 3-4 leaf-"stores" lower (lower-leaf).
[0201] Photosynthesis was measured as a function of the
photosynthetic active light intensity (PAR) from 0-975
.mu.molm.sup.-2s.sup.-1 (200 Watt m.sup.-2), in four-fold at
CO.sub.2-concentrations of 350 vpm and 950 vpm.
[0202] Respiration was measured using two different time-scales.
Measurements performed during a short dark-period after the
photosynthesis experiments are coded RD in table 9. These values
reflect instantaneous activity since respiration varies
substantially during the dark-period. Therefor, the values for the
entire night-period were also summed as shown in Table 10 (only
measured at 350 vpm CO.sub.2).
TABLE-US-00015 TABLE 9 Rate of photosynthesis and respiration, STD
is standard deviation 350 ppm 950 ppm micromol/m.sup.2/s STD
micromol/m.sup.2/s STD Upper leaf Wild-type RD 0.0826 0.048 1.016
0.142 EFF 0.060 0.004 0.087 0.004 AMAX 11.596 0.588 19.215 0.942
1010-5 RD 0.873 0.060 1.014 0.134 EFF 0.059 0.002 0.090 0.007 AMAX
12.083 1.546 18.651 1.941 1318-10 RD 0.974 0.076 1.078 0.108 EFF
0.064 0.003 0.088 0.008 AMAX 16.261 2.538 24.154 1.854 1318-37 RD
1.067 0.140 1.204 0.116 EFF 0.061 0.002 0.084 0.011 AMAX 16.818
2.368 25.174 2.093 Lower leaf Wild-type RD 0.0438 0.079 0.526 0.112
EFF 0.068 0.002 0.085 0.004 AMAX 6.529 1.271 11.489 1.841 1010-5 RD
0.455 0.068 0.562 0.118 EFF 0.064 0.002 0.085 0.006 AMAX 8.527
0.770 13.181 1.038 1318-10 RD 0.690 0.057 0.828 0.086 EFF 0.064
0.008 0.085 0.005 AMAX 11.562 1.778 20.031 1.826 1318-37 RD 0.767
0.033 0.918 0.099 EFF 0.073 0.006 0.103 0.004 AMAX 13.467 1.818
19.587 1.681
TABLE-US-00016 TABLE 10 Respiration during 12 hour dark period
(mmol CO.sub.2) Upper leaf STD Lower leaf STD Wild-type 25.17 0.82
13.19 1.98 1010-5 30.29 5.09 13.08 1.52 1318-10 28.37 4.50 20.47
0.87 1318-37 32.53 2.01 17.7 1.03
[0203] In contrast to the respiration in the upper-leaves, in lower
leaves the respiration of TPS transgenic plants is significantly
higher than for wild-type and TPP plants (Table 10) indicating a
higher metabolic activity. The decline in respiration during aging
of the leaves is significantly less for TPS transgenic plants.
[0204] Also, the photosynthetic characteristics differed
significantly between on the one hand TPS transgenic plants and on
the other hand TPP transgenic and wild-type control plants. The
AMAX values (maximum of photosynthesis at light saturation),
efficiency of photosynthesis (EFF) and the respiration velocity
during a short dark-period after the photosynthetic measurements
(RD) are shown in table 9. On average, the upper TPS leaves had a
35% higher AMAX value compared to the TPP and wild-type leaves. The
lower leaves show even a higher increased rate of photosynthesis
(88%).
[0205] To exclude that differences in light-absorption were causing
the different photosynthetic rates, absorption values were measured
with a SPAD-502 (Minolta). No significant differences in absorption
were measured (Table 11).
TABLE-US-00017 TABLE 11 Absorbtion values of transgenic lines
Absorbtion (%) Upper-leaf Lower-leaf Wild-type Samsun NN 84 83
1010-5 84 82 1318-10 85 86 1318-37 86 86
Example 16
Chlorophyll-Fluorescence of TPS and TPP Expressing Tobacco
Plants
[0206] Using tobacco plants transgenic for 35S-TPP (1010-5), PC-TPS
(1318-10 and 1318-37) and wild-type Samsun NN plants, effects of
expressing these genes were determined on chlorophyll fluorescence
of leaf material. Two characteristics of fluorescence were
measured:
1) ETE (electron transport efficiency), as a measure for the
electron transport velocity and the generation of reducing power,
and 2) Non-photochemical quenching, a measure for
energy-dissipation caused by the accumulation of assimilates.
[0207] Plants were grown in a greenhouse with additional light of
100 .mu.molm.sup.-2s.sup.-1 (04:00-20:00 hours). Day/night
T=21.degree. C./18.degree. C.; R.H..+-.75%. During a night-period
preceding the measurements (duration 16 hours), two plants of each
genotype were transferred to the dark and two plants to the light
(.+-.430 .mu.molm.sup.-2s.sup.-1, 20.degree. C., R.H..+-.70%). The
youngest fully matured leaf was measured. The photochemical
efficiency of PSII (photosystem II) and the "non-photochemical
quenching" parameters were determined as a function of increasing,
light intensity. At each light intensity, a 300 sec. stabilisation
time was taken. Measurements were performed at 5, 38, 236, 422 and
784 .mu.molm.sup.-2s.sup.-1 PAR with a frequency of 3 light-flashes
min.sup.-1, 350 ppm CO.sub.2 and 20% O.sub.2. Experiments were
replicated using identical plants, reversing the pretreatment from
dark to light and vice versa. The fluorescence characteristics are
depicted in FIG. 16.
[0208] The decrease in electron-transport efficiency (ETE) was
comparable between TPP and wild-type plants. TPS plants clearly
responded less to a increase of light intensity. This difference
was most clear in the light pretreatment. These observations are in
agreement with the "non-photochemical" quenching data. TPS plants
clearly responded less to the additional supply of assimilates by
light compared to TPP and wild-type plants. In the case of TPS
plants, the negative regulation of accumulating assimilates on
photosynthesis was significantly reduced.
Example 17
Export and Allocation of Assimilates in TPS and RPP Expressing
Tobacco Plants
[0209] Using tobacco plants transgenic for 35S-TPP (1010-5) and
PC-TPS (1318-37),
1) the export of carbon-assimilates from a fully grown leaf
(indicating "relative source activity", Koch (1996) Annu. Rev.
Plant Physiol. Plant. Mol. Biol. 47, 509 and 2) the net
accumulation of photo-assimilates in sinks ("relative sink
activity"), during a light and a dark-period, were determined
[0210] Developmental stage of the plants: flowerbuds just visible.
Labelling technique used: Steady-state high abundance 13C-labelling
of photosynthetic products (De Visser et al. (1997) Plant Cell
Environ 20, 37). Of both genotypes, 8 plants, using a fully grown
leaf, were labelled with 5.1 atom % .sup.13CO.sub.2 during a
light-period (10 hours), when appropriate followed by a dark-period
(14 hours). After labelling, plants were split in: 1) shoot-tip, 2)
young growing leaf, 3) young fully developed leaf (above the leaf
being labelled), 4) young stem (above the leaf being labelled), 5)
labelled leaf, 6) petiole and base of labelled leaf, 7) old,
senescing leaf, 8) other and oldest leaves lower than the labelled
leaf. 9) stem lower than the labelled leaf, 10) root-tips. Number,
fresh and dry weight and .sup.13C percentage (atom % .sup.13C) of
carbon were determined Next to general parameters as biomass, dry
matter and number of leaves, calculated were: 1) Export of C out of
the labelled leaf; 2) the relative contribution of imported C in
plant parts; 3) the absolute amount of imported C in plant parts;
4) the relative distribution of imported C during a light period
and a complete light and dark-period.
[0211] The biomass above soil of the TPP transgenics was 27% larger
compared to the TPS transgenics (P<0.001); also the root-system
of the TPP transgenics were better developed. The TPP plants
revealed a significant altered dry matter distribution, +39% leaf
and +10% stem biomass compared to TPS plants. TPS plants had a
larger number of leaves, but a smaller leaf-area per leaf. Total
leaf area per TPS plant was comparable with wild-type (0.4 m.sub.2
plant.sup.-1).
Relative Source Activity of a Fully Developed Leaf
[0212] The net export rate of photosynthates out of the labelled
leaf is determined by the relative decrease of the % "new C" during
the night (for TPP 39% and for TPS 56%) and by the total fixated
amount present in the plant using the amount of "new C" in the
plant (without the labelled leaf) as a measure. After a light
period, TPP leaves exported 37% compared to 51% for TPS leaves
(Table 11). In a following dark-period, this percentage increased
to respectively 52% and 81%. Both methods support the conclusion
that TPS transgenic plants have a significantly enhanced export
rate of photosynthetic products compared to the TPP transgenic
plants. [0213] Absolute Amount of "New c", in Plant Parts
[0214] Export by TPS transgenics was significantly higher compared
to TPP transgenics. Young growing TPS leaves import C stronger
compared to young growing TPP leaves.
Relative Increase of "New c" in Plant Parts: Sink-Strength
[0215] The relative contribution of "new C" to the concerning plant
part is depicted in FIG. 17. This percentage is a measure for the
sink-strength. A significant higher sink-strength was present in
the TPS transgenics, especially in the shoot-top, the stem above
and beneath the labelled leaf and the petiole of the labelled
leaf.
TABLE-US-00018 TABLE 11 Source activity of a full grown labelled
leaf: C accumulation and -export. Nett daily accumulation and
export of C-assimilates in labelled leaf and the whole plant (above
soil) after steady-state 13.sup.c-labelling during a light period
(day). N = 4: LSD values indicated the smallest significant
differences for P < 0.05 Source activity grown leaf new C in new
C in nett C export source leaf nett C export source leaf to plant
Time Trans- (% of total during night (% of new C (% of total (end
of) gene C in leaf) % of "Day" in plant) new C) Day TPS 17.8 --
48.7 51 TPP 22.6 -- 63.0 37 Day + night TPS 7.8 56 16.6 81 TPP 13.8
39 48.4 52 LSD 0.05 2.4 6.1
Relative Distribution, within the Plant, of "New C" Between the
Plant Parts: Relative Sink Strength
[0216] The distribution of fixed carbon between plant organs (FIG.
18) confirmed the above mentioned conclusions. TPS transgenic
plants revealed a relative large export of assimilates to the
shoot-top, the young growing leaf (day) and even the oldest leaf
(without axillary meristems), and to the young and old stem.
Example 18
Lettuce
Performance of Lettuce Plants Transgenic for PC-TPS and PC-TPP
[0217] Constructs used in lettuce transformation experiments:
PC-TPS and PC-TPP. PC-TPS transgenics were rescued during
regeneration by culturing explants on 60 g/l sucrose. The
phenotypes of both TPS and TPP transgenic plants are clearly
distinguishable from wild-type controls; TPS transgenic plants have
thick, dark-green leaves and TPP transgenic plants have light-green
leaves with a smoother leaf-edge when compared to wild-type
plants.
[0218] The morphology of the leaves, and most prominent the
leaf-edges, was clearly affected by the expression of TPS and TPP.
Leaves transgenic for PC-TPS were far more "notched" than the
PC-TPP transgenic leaves that had a more smooth and round
morphology (FIG. 19). Leaf extracts of transgenic lettuce lines
were analyzed for sugars and starch (FIGS. 20A-D).
Example 19
Sugarbeet
Performance of Sugarbeet Plants Transgenic for PC-TPS and
PC-TPP
[0219] Constructs used in sugarbeet transformation experiments:
PC-TPS and PC-TPP. Transformation frequencies obtained with both
the TPS and the TPP construct were comparable to controls. The
phenotypes of both TPS and TPP transgenic plants were clearly
distinguishable from wild-type controls; TPS transgenic plants had
thick, dark-green leaves and TPP transgenic plants had light-green
colored leaves with slightly taller petioles when compared to
wild-type plants (FIG. 21). Taproot diameter was determined for all
plants after ca. 8 weeks of growth in the greenhouse. Some PC-TPS
transgenic lines having a leaf size similar to the control plants
showed a significant larger diameter of the tap-root (FIG. 22).
PC-TPP transgenic lines formed a smaller taproot compared to the
non-transgenic controls. Leaf extracts of transgenic sugarbeet
lines were analyzed for sugars and starch (FIGS. 20A-D).
Example 20
Arabidopsis
Performance of Arabidopsis Plants Transgenic for PC-TPS and
PC-TPP
[0220] Constructs used in Arabidopsis transformation experiments:
PC-TPS and PC-TPP. The phenotypes of both TPS and TPP transgenic
plants were clearly distinguishable from wild-type controls; TPS
transgenic plants had thick, dark-green leaves and TPP transgenic
plants had larger, bleaching leaves when compared to wild-type
plants. Plants with high levels of TPP expression did not set
seed.
Example 21
Potato
Performance of Solanum tuberosum Plants Transgenic for TPS and TPP
Constructs
[0221] Construct: 35S-TPS pMOG799
[0222] Plants transgenic for pMOG799 were grown in the greenhouse
and tuber-yield was determined (FIG. 23). The majority of the
transgenic plants showed smaller leaf sizes when compared to
wild-type controls. Plants with smaller leaf-sizes yielded less
tuber-mass compared to control lines (FIG. 25).
Construct: 35S-TPP pMOG1010 and PC-TPP pMOG1124
[0223] Plants transgenic for PMOG 1010 and pMOG1124 were grown in
the greenhouse and tuber-yield was determined Tuber-yield (FIG. 24)
was comparable or less than the wild-type control lines (FIG.
25).
Construct: PC-TPS pMOG1093
[0224] Plants transgenic for pMOG1093 were grown in the greenhouse
and tuber-yield was determined A number of transgenic lines having
leaves with a size comparable to wild-type (B-C) and that were
slightly darker green in color yielded more tuber-mass compared to
control plants (FIG. 26). Plants with leaf sizes smaller (D-G) than
control plants yielded less tuber-mass.
Construct: Pat-TPP pMOG1128
[0225] Microtubers were induced in vitro on explants of pat-TPP
transgenic plants. The average fresh weight biomass of the
microtubers formed was substantially lower compared to the control
lines.
Construct: Pat-TPS pMOG845
[0226] Plants transgenic for pMOG 845 were grown in the greenhouse
and tuber-yield was determined. Three Pat-TPS lines produced more
tuber-mass compared to control lines (FIG. 27).
Construct: PC TPS Pat TPS; pMOG 1129(845-11/22/28)
[0227] Plants expressing PC TPS and Pat-TPS simultaneously were
generated by retransforming Pat-TPS lines (resistant against
kanamycin) with construct pMOG1129, harboring a PC TPS construct
and a hygromycin resistance marker gene, resulting in genotypes
pMOG1129(845-11), pMOG1129(845-22) and pMOG1129(845-28). Tuber-mass
yield varied between almost no yield up to yield comparable or
higher then control plants (FIGS. 28A-C).
Example 22
Tobacco
Performance of N. tabacum Plants Transgenic for TPS and TPP
Constructs
Root System
[0228] Tobacco plants transgenic for 35S TPP (pMOG1010) or 35S TPS
(pMOG799) were grown in the greenhouse. Root size was determined
just before flowering. Lines transgenic for pMOG1010 revealed a
significantly smaller/larger root size compared to pMOG795 and
non-transgenic wild-type tobacco plants.
Influence of Expressing TPS and/or TPP on Flowering
[0229] Tobacco plants transgenic for 35S-TPS, PC-TPS, 35S-TPP or
PC-TPP were cultured in the greenhouse. Plants expressing high
levels of the TPS gene revealed significantly slower growth rates
compared to wild-type plants. Flowering and senescence of the lower
leaves was delayed in these plants resulting in a stay-green
phenotype of the normally senescing leaves. Plants expressing high
levels of the TPP gene did not make any flowers or made aberrant,
not fully developing flower buds resulting in sterility.
Influence of Expressing TPS and/or TPP on Seed Setting
[0230] Tobacco plants transgenic for 35S-TPS, PC-TPS, 35S-TPP or
PC-TPP were cultured in the greenhouse. Plants expressing high
levels of the TPP gene revealed poor or no development of flowers
and absence of seed-setting.
Influence of Expressing TPS and/or TPP on Seed Germination
[0231] Tobacco plants transgenic for 35S TPP (pMOG11010) or PC TPP
were grown in the greenhouse. Some of the transgenic lines, having
low expression levels of the transgene, did flower and set seed.
Upon germination of S1 seed, a significantly reduced germination
frequency was observed (or germination was absent) compared to S1
seed derived from wild-type plants (Table 12).
TABLE-US-00019 TABLE 12 Germination of transgenic 35S-TPP seeds
Rel. Seedlot Bleaching (TPPmRNA) Germination 1010-2 + 15.8 delayed
1010-3 - 5.3 delayed 1010-4 + 4.2 delayed 1010-5 + 5.2 delayed
1010-6 + 3.9 delayed 1010-7 - 2.8 delayed 1010-8 + 6.5 delayed
1010-9 + 4.6 delayed 1010-10 - 1.9 normal 1010-11 - 5.7 normal
1010-12 + 1.4 normal 1010-14 - 0.1 normal 1010-15 - 0.3 normal
1010-18 + 5.6 delayed 1010-20 + 6.4 delayed 1010-21 + 9.5 delayed
1010-22 + 8.8 not 1010-23 - 4.5 normal 1010-24 - 10.2 delayed
1010-25 - 4.7 delayed (less) 1010-27 - 4.8 normal 1010-28 + 22.1
delayed 1010-31 + 9.4 delayed (less) 1010-32 - 0.3 delayed (less)
1010-33 + 14.7 delayed
Influence of Expressing TPS and/or TPP on Seed Yield
[0232] Seed-yield was determined for S1 plants transgenic for
pMOG1010-5. On average, pMOG1010-5 yielded 4.9 g seed/plant (n=8)
compared to 7.8 g seed/plant (n=8) for wild-type plants. The
"1000-grain" weight is 0.06 g for line pMOG1010-5 compared to 0.08
g for wild-type Samsun NN. These data can be explained by a reduced
export of carbohydrates from the source leaves, leading to poor
development of seed "sink" tissue.
Influence of TPS and TPP Expression on Leaf Morphology
[0233] Segments of greenhouse grown PC-TPS transgenic, PC-TPP
transgenic and non-transgenic control tobacco leaves were fixed,
embedded in plastic and coupes were prepared to study cell
structures using light-microscopy. Cell structures and morphology
of cross-sections of the PC-TPP transgenic plants were comparable
to those observed in control plants. Cross-sections of PC-TPS
transgenics revealed that the spongy parenchyme cell-layer
constituted of 7 layers of cells compared to 3 layers in wild-type
and TPP transgenic plants (FIGS. 29A and B). This finding agrees
with our observation that TPS transgenic plant lines form thicker
and more rigid leaves compared to TPP and control plants.
Example 23
Inhibition of Cold-Sweetening by the Expression of Trehalose
Phosphate Synthase
[0234] Transgenic potato plants (Solanum tuberosum cv. Kardal) were
generated harboring the TPS gene under control of the potato
tuber-specific patatin promoter (pMOG845; Example 1). Transgenic
plants and wild-type control plants were grown in the greenhouse
and tubers were harvested. Samples of tuber material were taken for
sugar analysis directly after harvesting and after 6 months of
storage at 4.degree. C. Data resulting from the HPLC-PED analysis
are depicted in FIG. 30.
[0235] What is clearly shown is that potato plants transgenic for
TPS.sub.E.coli have a lower amount of total sugar (glucose,
fructose and sucrose) accumulating in tubers directly after
harvesting. After a storage period of 6 months at 4.degree. C., the
increase in soluble sugars is significantly less in the transgenic
lines compared to the wild-type control lines.
Example 24
Improved Performance of 358 TPS 358 TPP (pMOG851) Transgenic
Tobacco Plants Under Drought Stress
[0236] Transgenic tobacco plants were engineered harboring both the
TPS and TPP gene from E. coli under control of the 35S CaMV
promoter. The expression of the TPS and TPP genes was verified in
the lines obtained using Northern blot and enzyme activity
measurements. pMOG851-2 was shown to accumulate 0.008 mg
trehaloseg.sup.-1 fw and pMOGB51-5 accumulated 0.09 mg
trehaloseg.sup.-1 fw. Expression of both genes had a pronounced
effect on plant morphology and growth performance under drought
stress. When grown under drought stress imposed by limiting water
supply, the two transgenic tobacco lines tested, pMOGS51-2 and
pMOG851-5, yielded total dry weights that were 28% (P<0.01) and
39% (P<0.001) higher than those of wild-type tobacco. These
increases in dry weight were due mainly to increased leaf
production: leaf dry weights were up to 85% higher for pMOG851-5
transgenic plants. No significant differences were observed under
well-watered conditions.
Drought Stress Experiments
[0237] F1 seeds obtained from self-fertilization of primary
transformants pMOG851-2 and pMOG851-5 (Goddijn et al. (1997) Plant
Physiol. 113, 181) were used in this study. Seeds were sterilized
for 10 minutes in 20% household bleach, rinsed five times in
sterile water, and sown on half-strength Murashige and Skoog medium
containing 10 gL.sup.-1 sucrose and 100 mgL.sup.-1 kanamycin.
Wildtype SR1 seeds were sown on plates without kanamycin. After two
weeks seedlings from all lines were transferred to soil (sandy
loam), and grown in a growth chamber at 22.degree. C. at
approximately 100 .mu.Em.sup.-2 light intensity, 14 hd.sup.-1. All
plants were grown in equal amounts of soil, in 3.8 liter pots. The
plants were watered daily with half-strength Hoagland's nutrient
solution. The seedlings of pMOG851-2 and pMOG851-5 grew somewhat
slower than the wildtype seedlings. Since we considered it most
important to start the experiments at equal developmental stage, we
initiated the drought stress treatments of each line when the
seedlings were at equal height (10 cm), at an equal developmental
stage (4-leaves), and at equal dry weight (as measured from two
additional plants of each line). This meant that the onset of
pMOG851-2 treatment was two days later than wildtype, and that of
pMOG851-5 seven days later than wildtype. From each line, six
plants were subjected to drought stress, while four were kept under
well-watered conditions as controls. The wildtype tobacco plants
were droughted by maintaining them around the wilting point: when
the lower half of the leaves were wilted, the plants were given so
much nutrient solution that the plants temporarily regained turgor.
In practice, this meant supplying 50 ml of nutrient solution every
three days; the control plants were watered daily to keep them at
field capacity. The pMOG851-2 and pMOG851-5 plants were then
watered in the exact same way as wildtype, i.e., they were supplied
with equal amounts of nutrient solution and after equal time
intervals as wildtype. The stem height was measured regularly
during the entire study period. All plants were harvested on the
same day (32 d after the onset of treatment for the wildtype
plants), as harvesting the transgenic plants at a later stage would
complicate the comparison of the plant lines. At the time of
harvest the total leaf area was measured using a Delta-T Devices
leaf area meter (Santa Clara, Calif.). In addition, the fresh
weight and dry weight of the leaves, stems and roots was
determined
[0238] A second experiment was done essentially in the same way, to
analyze the osmotic potential of the plants. After 35 days of
drought stress, samples from the youngest mature leaves were taken
at the beginning of the light period (n=3).
Air-Drying of Detached Leaves
[0239] The water loss from air-dried detached leaves was measured
from well-watered, four-week old pMOG851-2, pMOG851-5 and wildtype
plants. Per plant line, five plants were used, and from each plant
the two youngest mature leaves were detached and airdried at 25%
relative humidity. The fresh weight of each leaf was measured over
32 hours. At the time of the experiment samples were taken from
comparable, well-watered leaves, for osmotic potential measurements
and determination of soluble sugar contents.
Osmotic Potential Measurements
[0240] Leaf samples for osmotic potential analysis were immediately
stored in capped 1 ml syringes and frozen on dry ice. Just before
analysis the leaf sap was squeezed into a small vial, mixed, and
used to saturate a paper disc. The osmotic potential was then
determined in Wescor C52 chambers, using a Wescor HR-33T dew point
microvolt meter.
Chlorophyl Fluorescence
[0241] Chlorophyll fluorescence of the wildtype, pMOG851-2 and
pMOG851-5 plants was measured for each plant line after 20 days of
drought treatment, using a pulse modulation (PAM) fluorometer
(Walz, Effeltrich, Germany). Before the measurements, the plants
were kept in the dark for two hours, followed by a one-hour light
period. Subsequently, the youngest mature leaf was dark-adapted for
20 minutes. At the beginning of each measurement, a small (0.05
.mu.mol m.sup.-2 s.sup.-1 modulated at 1.6 KHz) measuring light
beam was turned on, and the minimal fluorescence level (F.sub.0)
was measured. The maximal fluorescence level (F.sub.m) was then
measured by applying a: saturation light pulse of 4000 .mu.mol
m.sup.-2 s.sup.-1, 800 ms in duration. After another 20 s, when the
signal was relaxed to near F.sub.0, brief saturating pulses of
actinic light (800 ms in length, 4000 .mu.mol m.sup.-2 s.sup.-1)
were given repetitively for 30 s with 2 s dark intervals. The
photochemical (q.sub.Q) and non-photochemical (q.sub.E) quenching
components were determined from the fluorescence/time curve
according to Bolhar-Nordenkampf and Oquist (1993). At the moment of
measurement, the leaves in question were not visibly wilted.
Statistical data were obtained by one-way analysis of variance
using the program Number Cruncher Statistical System (Dr. J. L.
Hintze, 865 East 400 North, Kaysville, Utah 84037, USA).
[0242] Chlorophyll fluorescence analysis of drought-stressed plants
showed a higher photochemical quenching (q.sub.Q) and a higher
ratio of variable fluorescence over maximal fluorescence
(F.sub.v/F.sub.m) in pMOG851-5, indicating a more efficiently
working photosynthetic machinery (Table 13).
TABLE-US-00020 TABLE 13 Chlorophyll fluorescence parameters of
wild-type (wt) and trehalose-accumulating (pMOG851-2, pMOG851-5)
transgenic tobacco plants. P (probability) values were obtained
from ANOVA tests analyzing differences per plant line between
plants grown under well-watered (control) or dry conditions, as
well as differences between each of the transgenic lines and WT,
grown under well-watered or dry conditions. 8-51- WT pMOG851-1
pMOG851-5 2/WT 815-5 F.sub.m control 174.4 180.4 175.6 ns ns dry
151.5 155.7 167.8 ns 0.0068 P(ctrl. 0.0004 0.0000 ns dry) F.sub.v
control 134.6 143.3 142.8 ns ns dry 118.4 122.1 135.6 ns 0.0011 P
(ctrl. 0.006 0.0000 ns dry) F.sub.v/ control 0.771 0.794 0.813
0.059 0.0052 F.sub.m dry 0.782 0.784 0.809 ns 0.0016 P (ctrl. Ns Ns
Ns dry) q.sub.E control 15.2 23.8 29.9 0.259 0.0085 dry 25.4 21.6
23.5 ns ns P (ctrl. 0.048 ns ns dry) q.sub.Q control 91.3 92.4 90.4
ns ns dry 73.69 78.5 92.75 ns 0.0005 P (ctrl. 0.005 0.006 ns dry)
F.sub.m: maximal fluorescence; F.sub.v: variable fluorescence
(F.sub.m-F.sub.0): q.sub.Q: photochemical quenching: q.sub.E:
non-photochemical quenching. F.sub.m, F.sub.v are expressed in
arbitrary units (chart mm).
Carbohydrate Analysis
[0243] At the time of harvest, pMOG851-5 plants contained 0.2
mgg.sup.-1 dry weight trehalose, whereas in pMOG851-2 and wildtype
the trehalose levels were below the detection limit, under both
stressed and unstressed conditions. The trehalose content in
pMOG851-5 plants was comparable in stressed and unstressed plants
(0.19 and 0.20 mgg.sup.-1 dry weight, respectively). Under
well-watered conditions, the levels of glucose and fructose were
twofold higher in pMOG851-5 plants than in wildtype. Leaves of
stressed pMOG851-5 plants contained about threefold higher levels
of each of the four nonstructural carbohydrates starch, sucrose,
glucose and fructose, than leaves of stressed wildtype plants. In
pMOG851-2 leaves, carbohydrate levels, like chlorophyll
fluorescence values, did not differ significantly from those in
wildtype. Stressed plants of all lines contained increased levels
of glucose and fructose compared to unstressed plants.
Osmotic Potential of Drought Stressed and Control Plants
[0244] During a second, similar experiment under greenhouse
conditions, the transgenic plants showed the same phenotypes as
described above, and again the pMOG851-5 plants showed much less
reduction in growth under drought stress than pMOG851-2 and
wildtype plants. The osmotic potential in leaves of droughted
pMOG851-5 plants (-1.77.+-.0.39 Mpa) was significantly lower
(P=0.017) than in wildtype leaves (-1.00.+-.0.08 Mpa); pMOG851-2
showed intermediate values (-1.12.+-.0.05 Mpa). Similarly, under
well-watered conditions the osmotic potential of pMOG851-5 plants
(-0.79.+-.0.05 Mpa) was significantly lower (P=0.038) than that of
wildtype leaves (-0.62.+-.0.03 Mpa), with pMOG851-2 having
intermediate values (-0.70.+-.0.01 Mpa).
Airdrying of Detached Leaves
[0245] Leaves of pMOG851-2, pMOG851-5 and wildtype were detached
and their fresh weight was measured over 32 hours of airdrying.
Leaves of pMOG851-2 and pMOG851-5 plants lost significantly less
water (P<0.05) than wildtype leaves: after 32 h leaves of
pMOG851-5 and pMOG851-2 had 44% and 41% of their fresh weight left,
respectively, compared to 30% for wildtype. At the time of the
experiment samples were taken from comparable, well-watered leaves
for osmotic potential determination and analysis of trehalose,
sucrose, glucose and fructose. The two transgenic lines had lower
osmotic potentials than wildtype (P<0.05), with pMOG851-5 having
the lowest water potential (-0.63.+-.0.03 Mpa), wildtype the
highest (-0.51.+-.0.02 Mpa) and pMOG851-2 intermediate
(-0.57.+-.0.04 Mpa). The levels of all sugars tested were
significantly higher in leaves of pMOG851-5 plants than for
wildtype leaves resulting in a threefold higher level of the four
sugars combined (P=0.002). pMOG851-2 plants contained twofold
higher levels of the four sugars combined (P=0.09). The trehalose
levels were 0.24.+-.0.02 mgg.sup.-1 DW in pMOG851-5 plants, and
below detection in pMOG851-2 and wildtype.
Example 25
Performance of TPS and TPP Transgenic Lettuce Plant Lines Under
Drought Stress
[0246] Primary TPS and TPP transformants and wild-type control
plants were subjected to drought-stress. Lines transgenic for TPP
reached their wilting point first, then control plants, followed by
TPS transgenic plants indicating that TPS transgenic lines, as
observed in other plant species, have a clear advantage over the
TPP and wild-type plants during drought stress.
Example 26
Bolting of Lettuce Plants is Affected in Plants Transgenic for
PC-TPS or PC-TPP
[0247] Bolting of lettuce is reduced in plants transgenic for
PC-TPP (Table 14). Plant lines transgenic for PC-TPS show enhanced
bolting compared to wild-type lettuce plants.
TABLE-US-00021 TABLE 14 Bolting of lettuce plants 3. PC- Total 1.
2. Visible 4. 5. TPP # of Normal Reduced inflo- Possible Completely
lines plants bolting bolting rescence fasciation vegetative 1A 4 4
2A 3 1 2 3A 2 2 4A 5 1 1 1 2 5A 5 1 1 3 7A 1 1 8A 5 4 1 9A 5 5 10A
3 1 2 11A 5 2 3 12A 4 4 Con- 5 5 trol
Example 27
Performance of Tomato Plants Transgenic for TPS and TPP
[0248] Constructs used in tomato transformation experiments: 35S
TPP, PC-TPS, PC-TPS as-trehalase, PC-TPP, E8-TPS, E8-TPP, E8TPS E8
as-trehalase. Plants transgenic for the TPP gene driven by the
plastocyanin promoter and 35S promoter revealed phenotypes similar
to those observed in other plants: bleaching of leaves, reduced
formation of flowers or absent flower formation leading to small
fruits or absence of fruits. A small number of 35S-TPP transgenic
lines generated extreme large fruits. Those fruits revealed
enhanced outgrow of the pericarp. Plants transgenic for the TPS
gene driven by the plastocyanin promoter and 35S promoter did not
form small lancet shaped leaves. Some severely stunted plants did
form small dark-green leaves. Plants transgenic for PC-TPS and
PC-as-trehalase did form smaller and darker green leaves as
compared to control plants.
[0249] The color and leaf-edge of the 35S or PC driven TPS and TPP
transgenic plants were clearly distinguishable similar to what is
observed in other crops.
[0250] Plants harboring the TPS and TPP gene under control of the
fruit-specific E8 promoter did not show any phenotypical
differences compared to wild-type fruits. Plants transgenic for E8
TPS E8 astrehalase produced aberrant fruits with a yellow skin and
incomplete ripening.
Example 28
Performance of Potato Plants Transgenic for as-Trehalase and/or
TPS
[0251] Constructs: 35S as-trehalase (pMOG1027) and 35S as-trehalase
Pat TPS (PMOG1027(845-11/22/28).
[0252] Plants expressing 35S as-trehalase and pat-TPS
simultaneously were generated by retransforming pat-TPS lines
(resistant against kanamycin) with construct pMOG1027, harboring
the 35S as-trehalase construct and a hygromycin resistance marker
gene, resulting in genotypes pMOG1027(845-11), pMOG1027(845-22) and
pMOG1027(845-28). Microtubers were induced in vitro and fresh
weight of the microtubers was determined. The average fresh weight
yield was increased for transgenic lines harboring pMOG1027
(pMOG845-11/22/28). The fresh weight biomass of microtubers
obtained from lines transgenic for pMOG1027 only was slightly
higher then wild-type control plants. Resulting plants were grown
in the greenhouse and tuber yield was determined (FIG. 33). Lines
transgenic for 35S as-trehalase or a combination of 35S
as-trehalase and pat-TPS yielded significantly more tuber-mass
compared to control lines. Starch determination revealed no
difference in starch content of tubers produced by plant lines
having a higher yield (FIG. 34). A large number of the
1027(845-11/22/28) lines produced tubers above the soil out of the
axillary buds of the leaves indicating a profound influence of the
constructs used on plant development. Plant lines transgenic for
35S as-trehalase only did not form tubers above the soil.
[0253] Constructs: Pat as-trehalase (pMOG1028) and Pat as-trehalase
Pat TPS (pMOG1028(845-11/22/28))
[0254] Plants expressing Pat as-trehalase and Pat-TPS
simultaneously were generated by retransformiing Pat-TPS lines
(resistant against kanamycin) with construct pMOG1028, harboring
the Pat as-trehalase construct and a hygromycin resistance marker
gene, resulting in genotypes pMOG1028(845-11), pMOG1028(845-22) and
pMOG1028(845-28). Plants were grown in the greenhouse and tuber
yield was determined (FIGS. 35A-E). A number of pMOG1028 transgenic
lines yielded significantly more tuber-mass compared to control
lines. Individual plants transgenic for both Pat TPS and Pat
as-trehalase revealed a varying tuber-yield from almost no yield up
to a yield comparable to or higher then the control-lines (FIGS.
35A-E).
Construct: PC as-trehalase (pMOG1092)
[0255] Plants transgenic for pMOG1092 were grown in the greenhouse
and tuber-yield was determined Several lines formed darker-green
leaves compared to controls. Tuber-yield was significantly enhanced
compared to non-transgenic plants (FIG. 36).
Construct: PC as-trehalase PC-TPS (PMOG 1130)
[0256] Plants transgenic for pMOG 1130 were grown in the greenhouse
and tuber-yield was determined Several transgenic lines developed
small dark-green leaves and severely stunted growth indicating that
the phenotypic effects observed when plants are transformed with
TPS is more severe when the as-trehalase gene is expressed
simultaneously (see Example 21). Tuber-mass yield varied between
almost no yield up to significantly more yield compared to control
plants (FIG. 37).
Example 29
Overexpression of a Potato Trehalase cDNA in N. tabacum
[0257] Construct: de35S CaMV trehalase (pMOG1078)
[0258] Primary tobacco transformants transgenic for pMOG1078
revealed a phenotype different from wild-type tobacco, some
transgenics have a dark-green leaf color and a thicker leaf (the
morphology of the leaf is not lancet-shaped) indicating an
influence of trehalase gene-expression on plant metabolism. Seeds
of selfed primary transformants were sown and selected on
kanamycin. The phenotype showed to segregate in a mendelian fashion
in the 51 generation.
Deposits
[0259] The following deposits were made under the Budapest Treaty.
The clones were deposited at the Centraal Bureau voor
Schimnelcultures, Oosterstraat 1, P.O. Box 273, 3740 AG Baarn, The
Netherlands on Apr. 21, 1997 and received the following
numbers:
Escherichia coli DH5alpha/pMOG1192 CBS 692.97 [0260]
DH5alpha/pMOG1240 CBS 693.97 [0261] DH5alpha/pMOG1241 CBS 694.97
[0262] DH5alpha/pMOG1242 CBS 695.97 [0263] DH5alpha/pMOG1243 CBS
696.97 [0264] DH5alpha/pMOG1244 CBS 697.97 [0265] DH5alpha/pMOG1245
CBS 698.97
Deposited Clones:
[0265] [0266] pMOG1192 harbors the Helianchus annuus TPS/TPP
bipartite cDNA inserted in the multi-copy vector PGEM-T (Promega).
[0267] pMOG1240 harbors the tobacco TPS "825" by cDNA fragment
inserted in pCRscript (Stratagene). [0268] pMOG1241 harbors the
tobacco TPS "840" by cDNA fragment inserted in pGEM-T (Promega).
[0269] pMOG1242 harbors the tobacco TPS "630" by cDNA fragment
inserted in pGEM-T (Promega). [0270] pMOG1243 harbors the tobacco
TPP "543", by cDNA fragment inserted in pGEM-T (Promega). [0271]
pMOG1244 harbors the tobacco TPP "723" by cDNA fragment inserted in
a pUC18 plasmid. [0272] pMOG1245 harbors the tobacco TPP "447" by
fragment inserted in PGEM-T (Promega). List of Relevant pMOG### and
pVDH### Clones
1. Binary Vectors
[0272] [0273] pMOG23 Binary vector (ca. 10 Kb) harboring the NPTII
selection marker [0274] pMOG22 Derivative of pMOG23, the NPTII-gene
has been replaced by the HPT-gene which confers resistance to
hygromycine [0275] pVDH 275 Binary vector derived from pMOG23,
harbors a plastocyanin promoter-nos terminator expression cassette.
[0276] pMOG402 Derivative of pMOG23, a point-mutation in the
NPTII-gene has been restored, no KpnI restriction site present in
the polylinker [0277] pMOG800 Derivative of pMOG402 with restored
KpnI site in polylinker
2. TPS/TPP Expression Constructs
[0277] [0278] pMOG 799 35S-TPS-3' nos' [0279] pMOG 810 idem with
Hyg marker [0280] pMOG 845 Pat-TPS-3'PotPiII [0281] pMOG 925 idem
with Hyg marker [0282] pMOG 851 35S-TPS-3' nos 35S-TPP(atg).sup.2
[0283] pMOG 1010 de35S CaMV any leader TPP(gtg), PotPiII [0284]
pMOG 1142 idem with Hyg marker [0285] pMOG 1093 Plastocyanin-TPS-3'
nos [0286] pMOG 1129 idem with Hyg marker [0287] pMOG 1177
Plastocyanin-TPS-3'PotPiII 3' nos [0288] pVDH 318 Identical to
pMOG1177 [0289] Functionally identical to pMOG1093 [0290] pMOG 1124
Plastocyanin-TPP(gtg) 3'PotPiII 3' nos [0291] pVDH 321 Identical to
pMOG1124 [0292] pMOG 1128 Patatin TPP(gtg) 3'PotPiII [0293] pMOG
1140 E8-TPS-3' nos [0294] pMOG 1141 E8-TPP(gtg)-3'PotPiII
3. Trehalase Constructs
[0294] [0295] pMOG 1028 Patatin as-trehalase 3'PotPiII, Hygromycin
resistance marker [0296] pMOG 1078 de35S CaMV amv leader trehalase
3' nos [0297] pMOG 1090 de35S CaMV amv leader as-trehalase 3' nos
[0298] pMOG 1027 idem with Hyg marker [0299] pMOG 1092
Plastocyanin-as trehalase-3' nos [0300] pMOG 1130 Plastocyanin-as
trehalase-3' nos Plastocyanin-TPS-3' nos [0301] pMOG 1153 E8-TPS-3'
nos E8-as trehalase-3'PotPiII 1. All constructs harbour the NPTII
selection marker unless noted otherwise 2. Two types of TPP
constructs have been used as described in Goddijn et al. (1997)
Plant Physio1.133, 181.
Sequence CWU 1
1
* * * * *