U.S. patent application number 10/225966 was filed with the patent office on 2003-01-16 for method and means for modulating plant cell cycle proteins and their use in plant cell growth control.
Invention is credited to Inze, Dirk, Mironov, Vladimir, Segers, Gerda, Veylder, Lieven De.
Application Number | 20030014777 10/225966 |
Document ID | / |
Family ID | 8228104 |
Filed Date | 2003-01-16 |
United States Patent
Application |
20030014777 |
Kind Code |
A1 |
Inze, Dirk ; et al. |
January 16, 2003 |
Method and means for modulating plant cell cycle proteins and their
use in plant cell growth control
Abstract
The present invention provides a new Arabidopsis thaliana
nucleotide sequence and polypeptide sequence having a molecular
weight of about 10.5 kDa. Modulation of the expression of the
polypeptides encoded by the nucleotide sequences according to the
invention has an advantageous influence on plant cell division
characteristics especially on the endoreduplication whereby plant
cell size and storage capacity of plant cells is influenced.
Inventors: |
Inze, Dirk; (Moorsel-Aalst,
BE) ; Segers, Gerda; (Gent, BE) ; Veylder,
Lieven De; (Aalst, BE) ; Mironov, Vladimir;
(Gent, GB) |
Correspondence
Address: |
Ann R. Pokalsky, Esq.
DILWORTH & BARRESE, LLP
333 Earle Ovington Blvd.
Uniondale
NY
11553
US
|
Family ID: |
8228104 |
Appl. No.: |
10/225966 |
Filed: |
August 22, 2002 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
10225966 |
Aug 22, 2002 |
|
|
|
09381150 |
Mar 13, 2000 |
|
|
|
6465718 |
|
|
|
|
09381150 |
Mar 13, 2000 |
|
|
|
PCT/EP98/01522 |
Mar 13, 1998 |
|
|
|
Current U.S.
Class: |
800/287 ;
435/200; 435/320.1; 435/419; 435/69.1; 536/23.2 |
Current CPC
Class: |
C12N 9/1205 20130101;
C07K 14/415 20130101; Y02A 40/146 20180101; C07K 14/315 20130101;
C12N 15/8261 20130101 |
Class at
Publication: |
800/287 ;
435/69.1; 435/200; 435/320.1; 435/419; 536/23.2 |
International
Class: |
A01H 005/00; C07H
021/04; C12N 009/24; C12N 005/04; C12P 021/02 |
Foreign Application Data
Date |
Code |
Application Number |
Mar 14, 1997 |
EP |
97200765.2 |
Claims
1. An isolated and/or recombinant nucleic acid molecule, preferably
DNA, encoding at least a functional part of a plant CKS1 protein,
which protein in Arabidopsis thaliana comprises the sequence as
depicted in SEQ.ID.NO.3 or SEQ.ID.NO.4 or a functional part
thereof.
2. A nucleic acid molecule according to claim 1 comprising at least
a part of the sequence as depicted in SEQ.ID.NO.1 or SEQ.ID.NO.2 or
a sequence at least substantially homologous thereto.
3. A nucleic acid molecule according to claim 1 comprising at least
a part of the sequence as depicted in SEQ.ID.NO.1 or SEQ.ID.NO.2 or
a sequence which hybridizes under conventional conditions to at
least a part of said sequence or its complementary sequence.
4. A polypeptide encoded by a nucleic acid sequence comprised in a
nucleic acid molecule according to any of the claims 1 to 3.
5. A polypeptide according to claim 4 comprising at least a
functional part of a plant CKS1.
6. An Arabidopsis thaliana polypeptide comprising the amino acid
sequence according to SEQ.ID.NO. 3 or SEQ.ID.NO.4 and/or fragments
thereof.
7. A chimeric gene comprising the following operably linked
polynucleotides: a. a nucleic acid molecule according to claim 1 to
3 b. one or more control sequences
8. A vector comprising a nucleic acid molecule according to claim 1
to 3 or comprising a chimeric gene according to claim 7.
9. A plant cell comprising a recombinant nucleic acid molecule
according to any of the claims 1 to 3 or comprising a chimeric gene
according to claim 7.
10. A plant cell comprising a recombinant polypeptide with an amino
acid sequence according to SEQ.ID.NO.3 or SEQ.ID.NO.4 and/or
functional fragments and/or functional derivatives thereof.
11. A plant comprising a recombinant nucleic acid molecule
according to any of the claims 1 to 3 or comprising a chimeric gene
according to claim 7.
12. Plant material such as roots, flowers, fruit, leaves, pollen,
seeds, seedlings or tubers obtainable from a plant according to
claim 11.
13. Progeny of a plant according to claim 11.
14. A method for transforming plants with a nucleic acid molecule
according to any of the claims 1 to 3 or with a chimeric gene
according to claim 7.
15. A process for producing a transgenic plant comprising the steps
of introducing a nucleic acid molecule of claim 1 to 3 or
introducing a chimeric gene according to claim 7 into at least one
plant cell and regenerating a plant from said cell.
16. A method for modulating plant cell division and/or growth
comprising modulation of the expression and/or activity of a
polypeptide and/or fragment thereof encoded by a nucleotide
sequence comprised in a nucleic acid molecule according to claim 1
to 3.
17. A method for modulating endoreduplication in plants or parts
thereof by modifying the plant cell division.
18. A method according to claim 17 whereby modulation of
endoreduplication in plants or parts thereof is achieved by means
of plant genetic engineering.
19. A method for modulating endoreduplication according to claim 17
or 18 wherein the expression of one or more plant cell cycle genes
and/or the activity of one or more plant cell cycle proteins is
modified.
20. Use of cell cycle genes, preferably plant cell cycle genes, to
modulate endoreduplication in plants or parts thereof.
21. Use of CKS1 genes, preferably plant CKS1 genes, to modulate
endoreduplication in plants or parts thereof.
22. Use of CDC2 genes, preferably plant CDC2 genes, to modulate
endoreduplication in plants or parts thereof
23. Use of plant CDC2b genes to modulate endoreduplication in
plants or parts thereof.
24. Use of dominant negative mutants of cyclin dependent kinases,
preferably dominant negative mutants of plant cyclin dependent
kinases and most preferably dominant negative mutants of plant
CDC2b genes to modulate endoreduplication in plants or parts
thereof.
25. Plant cells and/or plants obtainable by a method according to
claims 17 to 19.
Description
[0001] The present invention relates to a novel cell cycle gene in
plants and to a method for controlling or altering growth
characteristics of a plant and/or a plant cell comprising
introduction and/or expression of one or more cell cycle regulatory
protein functional in a plant or parts thereof and/or one or more
nucleic acid sequence encoding such proteins. Optionally, said
sequences are placed under the control of a foreign control
sequence in said plant and/or plant cell.
[0002] Also provided in the present invention is a method for
modulating endoreduplication in plants, plant cells or parts
thereof, by genetic engineering techniques. In a preferred
embodiment endoreduplication in plants, plant cells or parts
thereof is modulated by modifying the plant cell cycle.
[0003] Cell division is fundamental for growth in humans, animals
and plants. Prior to dividing in two daughter cells, the mother
cell needs to replicate its DNA. The cell cycle is traditionally
divided into 4 distinct phases:
[0004] G1: the gap between mitosis and the onset of DNA
synthesis;
[0005] S : the phase of DNA synthesis;
[0006] G2: the gap between S and mitosis.
[0007] M : mitosis, the process of nuclear division leading up to
the actual cell division.
[0008] The distinction of these 4. phases provides a convenient way
of dividing the interval between successive divisions. Although
they have served a useful purpose, a recent flurry of experimental
results, much of it as a consequence of cancer research, has
resulted in a more intricate picture of the cell cycle's "four
seasons" (K. Nasmyth, Science 274, 1643-1645, 1996; P. Nurse,
Nature, 344, 503-508, 1990)
[0009] The underlying mechanism controlling the cell cycle control
system has only recently been studied in greater detail. In all
eukaryotic systems, including plants, this control mechanism is
based on two key families of proteins which regulate the essential
process of cell division, namely protein kinases (cyclin dependent
kinases or CDKs) and their activating associated subunits, called
cyclins. The activity of these protein complexes is switched on and
off at specific points of the cell cycle. Particular CDK-cyclin
complexes activated at the G1/S transition trigger the start of DNA
replication. Different CDK-cyclin complexes are activated at the
G2/M transition and induce mitosis leading to cell division.
[0010] Each of the CDK-cyclin complexes execute their regulatory
role via modulating different sets of multiple target proteins.
Furthermore, the large variety of developmental and environmental
signals affecting cell division all converge on the regulation of
CDK activity. CDKs can therefore be seen as the central engine
driving cell division.
[0011] In animal systems and in yeast, knowledge about cell cycle
regulations is now quite advanced. The activity of CDK-cyclin
complexes is regulated at five levels: (i) transcription of the CDK
and cyclin genes; (ii) association of specific CDK's with their
specific cyclin partner; (iii) phosphorylation/dephosphorylation of
the CDK and cyclins; (iv) interaction with other regulatory
proteins such as SUC1/CKS1 homologues and cell cycle kinase
inhibitors (CKl); and (v) cell cycle phase-dependent destruction of
the cyclins and CKls.
[0012] The study of cell cycle regulation in plants has lagged
behind that in animals and yeast. Some basic mechanisms of cell
cycle control appear to be conserved among eukaryotes, including
plants. Plants were shown to also possess CDK's, cyclins and CKl's.
However plants have unique developmental features which are
reflected in specific characteristics of the cell cycle control.
These include for instance the absence of cell migration, the
formation of organs throughout the entire lifespan from specialized
regions called meristems, the formation of a cell wall and the
capacity of non-dividing cells to re-enter the cell cycle. Another
specific feature is that many plant cells, in particular those
involved in storage (e.g. endosperm), are polyploid due to rounds
of DNA synthesis without mitosis. This so-called endoreduplication
is intimately related with cell cycle control.
[0013] Due to these fundamental differences, multiple components of
the cell cycle of plants are unique compared to their yeast and
animal counterparts. For example, plants contain a unique class of
CDKs, such as CDC2b in Arabidopsis, which are both structurally and
functionally different from animal and yeast CDKs.
[0014] The further elucidation of cell cycle regulation in plants
and its differences and similarities with other eukaryotic systems
is a major research challenge. Strictly for the case of comparison,
some key elements about yeast and animal systems are described
below in more detail.
[0015] As already mentioned above, the control of cell cycle
progression in eukaryotes is mainly exerted at two transition
points: one in late G.sub.1, before DNA synthesis, and one at the
G.sub.2/M boundary. Progression through these control points is
mediated by cyclin-dependent protein kinase (CDK) complexes, which
contain, in more detail, a catalytic subunit of approximately
34-kDa encoded by the CDK genes. Both Saccharomyces cerevisiae and
Schizosaccharomyces pombe only utilise one CDK gene for the
regulation of their cell cycle. The kinase activity of their gene
products p34.sup.CDC2 and p34.sup.CDC28 in Sch. pombe and in S.
cerevisiae, respectively, is dependent on regulatory proteins,
called cyclins. Progression through the different cell cycle phases
is achieved by the sequential association of p34.sup.CDC2/CDC28
with different cyclins. Although in higher eukaryotes this
regulation mechanism is conserved, the situation is more complex
since they have evolved to use multiple CDKs to regulate the
different stages of the cell cycle. In mammals, seven CDKs have
been described, defined as CDK1 to CDK7, each binding a specific
subset of cyclins.
[0016] In animal systems, CDK activity is not only regulated by its
association with cyclins but also involves both stimulatory and
inhibitory phosphorylations. Kinase activity is positively
regulated by phosphorylation of a Thr residue located between amino
acids 160-170 (depending on the CDK protein). This phosphorylation
is mediated by the CDK-activating kinase (CAK) which interestingly
is a CDK/cyclin complex itself. Inhibitory phosphorylations occur
at the ATP-binding site (the Tyr15 residue together with Thr14 in
higher eukaryotes) and are carried out by at least two protein
kinases. A specific phosphatase, CDC25, dephosphorylates these
residues at the G.sub.2/M checkpoint, thus activating CDK activity
and resulting in the onset of mitosis.
[0017] CDK activity is furthermore negatively regulated by a family
of mainly low-molecular weight proteins, called cyclin-dependent
kinase inhibitors (CKls). Kinase activity is inhibited by the tight
association of these CKls with the CDK/cyclin complexes.
[0018] The SUC1/CKS1 proteins represent another class of components
of CDK complexes. The SUC1 and CKS1 genes were originally
identified in Sch. pombe and S.cerevisiae, respectively as
suppressors of certain temperature-sensitive CDC2/CDC28 alleles.
Mutant p34.sup.CDC2 proteins suppressible by SUC1 overexpression
were shown to have a reduced affinity for the SUC1 protein.
Homologues of SUC1/CKS1 have since then been identified in a wide
range of organisms, including human, Drosophila and Xenopus. The
conserved interaction between SUC1/CKS1 proteins with CDKs allows
purification of homologous CDKs from other species using affinity
chromatography.
[0019] More than one decade after their initial discovery, the
function of the SUC1/CKS1 genes is still not resolved. In yeasts,
both SUC1 and CKS1 are essential genes, as was demonstrated by gene
disruption. Cells deleted for SUC1 show mitotic spindles of varying
lengths and condensed chromosomes, typical for a late mitotic
arrest. The presence of high cyclin levels suggests that this
arrest is attributed to the inability to destroy the mitotic
cyclins, which is a prerequisite to leave M phase. Mitotic cyclins
are normally destroyed by the ubiquitin-dependent proteosomal
pathway. An essential component in this destruction pathway is a
multiprotein complex called the anaphase-promoting complex (APC) or
cyclosome. Mutations in the APC result in a stabilisation of
mitotic cyclins and cause an anaphase arrest.
[0020] However, in addition, the presence of high concentrations of
SUC1/CKS1 blocks cell cycle progression. Analysis of Xenopus
cell-free extracts indicates that the high SUC1/CKS1 levels inhibit
the onset of mitosis by interfering with the dephosphorylation of
the CDK Tyr15 residue by CDC25.
[0021] Taken together, the appearance of multiple phenotypes
suggests different roles for the SUC1/CKS1 protein. Amongst these,
it may function as a docking factor for both positive and negative
regulators of CDK complexes. This model is supported by a recent
crystallographic study of a human SUC1/CKS1 homologue, CKSHs1,
complexed with CDK2. As a monomer SUC1/CKS1 proteins have a large
hydrophobic surface and a cluster of positively charged residues,
which represents a putative phosphate anion-binding site. Binding
of CKSHs1 to CDK2 involves the hydrophobic surface and positions
the anion-binding site close to the substrate recognition site of
CDK2, suggesting that CKSHs1 may act in the targeting of CDK2 to
already phosphorylated substrates. Both CDC25 and APC are
positively regulated by CDK phosphorylation. The observed
phenotypes concerning SUC1/CKS1 overexpression and deletion may
therefore be a consequence of the inability of the CDK complexes to
recognise CDC25 and components of the APC as substrates, with cell
cycle arrest as a result.
[0022] With respect to cell cycle regulation in plants a summary of
the state of the art is given below. In Arabidopsis, thusfar only
two CDK genes have been isolated, CDC2aAt and CDC2bAt, of which the
gene products share 56% amino acid identity. Both CDKs are
distinguished by several features. First, only CDC2aAt is able to
complement yeast p34.sup.CDC2/CDC28 mutants. Second, CDC2aAt and
CDC2bAt bear different cyclin-binding motifs (PSTAIRE and PPTALRE,
respectively), suggesting they may bind distinct types of cyclins.
Third, although both CDC2aAt and CDC2bAt show the same spatial
expression pattern, they exhibit a different cell cycle
phase-specific regulation. The CDC2aAt gene is expressed
constitutively throughout the whole cell cycle. In contrast,
CDC2bAt mRNA levels oscillate, being most abundant during the S and
G.sub.2 phases.
[0023] In addition, multiple cyclins have been isolated from
Arabidopsis. The majority displays the strongest sequence
similarity with the animal A- or B-type class of cyclins, but also
D-type cyclins have been identified. Although the classification of
Arabidopsis cyclins is mainly based upon sequence similarity,
limited data suggests that this organisation corresponds with
differential functions of each cyclin class. Direct binding of any
cyclin with an Arabidopsis CDK subunit has, however, not yet been
demonstrated.
[0024] In order to manage problems related to plant growth, plant
architecture and/or plant diseases, it is believed to be of utmost
importance to identify and isolate plant genes and gene products
involved in the regulation of the plant cell division, and more
particularly coding for and interacting with CDK's and/or their
interacting proteins, responsible for the control of the cell cycle
and the completion of the S and M phase of the cell cycle. If such
novel genes and/or proteins have been isolated and analysed, the
growth of the plant as a whole can be influenced. Also, the growth
of specific tissues or organs and thus the architecture of the
plant can be modified.
[0025] In the present invention a two-hybrid screen was exploited
to isolate new gene products interacting with CDC2aAt. A positive
clone indicative of a hitherto unknown plant cell cycle regulatory
nucleotide sequence was identified. A homology search in databases
showed the identification of a very first plant homologue of the
SUC1 gene from Sch. pombe and the CKS1 gene from S. cerevisiae.
Surprisingly the novel plant CKS1 homologue (having less than 50%
homology at amino acid level with the corresponding yeast genes)
was able to rescue a Sch. pombe temperature-sensitive CDC2 mutant.
This confirmed that the newly isolated plant sequence could, also
from a functional viewpoint, be designated as a CKS1 homologue. The
Arabidopsis gene was designated CKS1At, for CDK-associating subunit
from Arabidopsis thaliana.
[0026] Thus a novel plant nucleotide sequence and polypeptide
sequence, having a molecular weight of about 10.5 kDa, are
provided
[0027] The DNA sequence of CKS1At comprises the nucleotide sequence
defined in SEQ.ID NO.1 encoding for a protein as defined in
SEQ.ID.NO.3 or for a protein having substantially the same amino
acid sequence as the protein defined in SEQ.ID.NO.3.
[0028] The coding nucleotide sequence for CKS1 At in SEQ.ID.NO. 1
starts at the first ATG codon (position 1) and terminates at codon
AAG (position 261).
[0029] Using a nucleic acid amplification technology, such as the
polymerase chain reaction (PCR), a genomic DNA fragment containing
introns was isolated comprising the sequence defined in SEQ.ID.NO.
2.
[0030] Thus the invention provides an isolated and/or recombinant
nucleic acid molecule, preferably DNA, encoding at least a
functional part of a plant CKS1 protein, which protein in
Arabidopsis thaliana comprises the sequence as depicted in
SEQ.ID.NO.3 or SEQ.ID.NO.4 or a functional part thereof.
[0031] A further part of the invention is a nucleic acid molecule
comprising at least a part of the sequence as depicted in
SEQ.ID.NO.1 or SEQ.ID.NO.2 or a sequence substantially homologous
thereto. In a preferred embodiment, this nucleic acid molecule is
isolated from a monocotyledonous or dicotyledonous plant
species.
[0032] A further embodiment of the current invention is a nucleic
acid molecule comprising at least a part of the sequence as
depicted in SEQ.ID.NO.1 or SEQ.ID.NO.2 or a sequence which
hybridizes under conventional, preferably under stringent,
conditions to at least a part of said sequence or its complementary
sequence.
[0033] Alternatively, the nucleotide sequence depicted in
SEQ.ID.NO.1 or SEQ.ID.NO.2 can be used to design so-called
amplification primers for use in a nucleic acid amplification
technique. Said primers can be used in a particular amplification
technique to identify and isolate substantially homologous nucleic
acid molecules from other plant species. The design and use of said
primers is known by a person skilled in the art. Preferably such
amplification primers comprise a contiguous sequence of at least 6
nucleotides, in particular 13 nucleotides or more, identical or
complementary to the nucleotide sequence depicted in SEQ.ID.NO.1 or
SEQ.ID.NO.2.
[0034] In addition, the nucleic acid molecule provided in
SEQ.ID.NO.1 or SEQ.ID.NO.2 or parts of these sequences can be used
to select substantially homologous sequences present in other
plants than Arabidopsis thaliana. It has been shown according to
the invention that for instance riboprobes from CKS1At hybridize
with CKS1 RNA from different plant species.
[0035] The Arabidopsis thaliana polypeptide according to the
invention comprises the amino acid sequence as defined in
SEQ.ID.NO.3.
[0036] CKS1At protein binds, in vitro and in vivo, to CDKs such as
CDC2aAt and CDC2bAt. The CKS1At protein can also be used to
complement Sch.pombe SUC1 disruptants. Furthermore the CKS1At
protein can be used to rescue a Sch.pombe temperature-sensitive
CDC2 mutant.
[0037] Therefore a further part of the invention are polypeptides,
preferably plant polypeptides which have, compared to the CKS1At
protein, comparable or identical characteristics in terms of
binding to cyclin dependent kinases, in particular plant cyclin
dependent kinases.
[0038] To the scope of the current invention also belong plant
polypeptides which have, compared to the CKS1At protein, similar
properties to complement Sch.pombe SUC1 disruptants and/or to
rescue Sch.pombe temperature-sensitive, CDC2 mutants such as the
CDC2-L7 strain.
[0039] Fragments of the above mentioned polypeptide, such as the
first 72 amino acids as illustrated in SEQ.ID.NO. 4, also belong to
the invention. The last 15 amino acids of CKS1At, including the
polyglutamine stretch, are dispensable for the binding of both
CDC2aAt and CDC2bAt. It is likely that these amino acids are
involved in interactions with other proteins.
[0040] The CKS1At mutant E61Q (which means a mutant protein where
at position 61 of the wild type CKS1At, the Glu residue is replaced
by the Gln residue) has reduced binding affinity for CDKs.
Overexpression of the CKS1At protein caused a G2-specific cell
cycle arrest in fission yeast. In contrast, the E61Q mutated
protein does not arrest cell cycle progression. This demonstrates
that the E61-residue is an important amino acid in CKS1At for
interaction with CDKs. A second point mutation (P62G, replacement
of proline at position 62 by glycine) in CKS1At also showed reduced
binding activity for CDK. The use of this inactive mutants to
modulate the cell cycle in plant cells, plant tissues, plant organs
or whole plants is part of this invention.
[0041] Increased expression levels in maturing leaves indicate a
role for CKS1At in endoreduplication, whereas the lack of CDC2aAt
and CDC2bAt expression in these tissues suggest the presence of an
as yet unidentified CDK protein in Arabidopsis, specifically
involved in endoreduplication. These results suggest that CKS1At
can also interact with a novel, as yet unidentified CDK protein in
Arabidopsis.
[0042] Part of the invention is also a polypeptide comprising at
least a functional part of a plant CKS1 protein encoded by a
nucleic acid sequence comprised in a nucleic acid molecule
according to the invention. An example for this is that the
polypeptide or a fragment thereof according to the invention is
embedded in another amino acid sequence.
[0043] To the scope of the present invention also belong numerous
variations on the disclosed sequences which could be prepared by
those skilled in the art using known techniques. The polypeptides
encoded by the nucleic acid sequences above mentioned may be
modified by varying their amino acid sequence without substantially
altering their function. Derivatives of the polypeptides disclosed
herein, such as polypeptides carrying single or multiple amino acid
substitutions, deletion and/or additions, are included within the
present invention.
[0044] A further part of the invention is a polypeptide comprising
at least a part of the sequence as provided in SEQ.ID.NO3 or
SEQ.ID.NO4 or a polypeptide with at least 40%, and preferably more
than 69% homology at amino acid level, such sequence preferably
being a plant polypeptide.
[0045] Plant cell division can conceptually be influenced in three
ways: (i) inhibiting or arresting cell division, (ii) maintaining,
facilitating or stimulating cell division or (iii) uncoupling DNA
synthesis from mitosis and cytokinesis. Being able to uncouple S
phase from M phase would create opportunities to inhibit or
stimulate the level of endoreduplication in specific cells, tissues
and/or organs from living organisms, and more in particular in
plant cells, plant tissues, plant organs or whole plants.
[0046] To analyse the industrial applicabilities of CKS1At and any
plant homologue, for the first time transformed plants
overproducing CKS1At were created. Surprisingly, the transformed
plants do show modulated endoreduplication. To further analyse
whether other plant cell cycle genes could also modulate
endoreduplication in plants, transformed plants overproducing a
plant cyclin dependent kinase were created, and more in particular
plants overexpressing a plant specific dependent kinase such as
CDC2b from Arabidopsis thaliana were created. Surprisingly,
modulated (and more particular enhanced) endoreduplication could
clearly be demonstrated in these transformed plants. In yet an
alternative set of experiments, transformed plants expressing a
dominant negative mutant of a cyclin dependent kinase were created.
More in particular, plants were created which express a mutant
cyclin dependent kinase still able to bind to other regulatory cell
cycle proteins but with no or limited activity. Even more
surprisingly, also these transformed plants demonstrated a
significantly modulated level of endoreduplication in comparison
with control plants.
[0047] Therefore part of this invention is the use of plant cell
cycle genes and/or plant cell cycle proteins to modulate
endoreduplication in plant cells, plant tissues, plant organs
and/or whole plants. The man skilled in the art can use cell cycle
genes and proteins from other organisms such as yeast and animals
to modulate endoreduplication in plant cells, plant tissues, plant
organs and/or whole plants since the functionality of plant cell
cycle genes and proteins to modulate endoreduplication is herewith
disclosed. The use of these genes and proteins to modulate
endoreduplication is therefore also an embodiment of this
invention.
[0048] In a further preferred embodiment endoreduplication in plant
cells, plant tissues, plant organs or whole plants is modulated via
enhancing or reducing the expression and/or the activity of a CKS1
gene or CKS1 gene product, preferably a plant CKS1 gene or plant
CKS1 gene product. In a further preferred embodiment overexpression
of CKS1At is used to enhance endoreduplication in plant cells,
plant tissues, plant organs or whole plants.
[0049] In yet another preferred embodiment, cyclin dependent
kinases, preferably plant cyclin dependent kinase and more
preferably plant specific cyclin dependent kinase such as CDC2b
from Arabidopsis thaliana, are used to modulate endoreduplication
in plant cells, plant tissues, plant organs and/or whole plants. In
a further preferred embodiment overexpression of a CDC2b from
Arabidopsis is used to enhance endoreduplication in plant cells,
plant tissues, plant organs or whole plant.
[0050] In a further preferred embodiment expression of a dominant
negative mutant of cyclin dependent kinases, such as mutant cyclin
dependent kinases which still have binding activities for
regulatory cell cycle proteins but have no or only limited kinase
activity, is used to modulate endoreduplication in plant cells,
plant tissues, plant organs and/or whole plants. One example of
such dominant negative mutant is an Arabidopsis thaliana CDC2b
variant wherein the aspartic acid at position 161 is replaced by
asparagine.
[0051] In a further preferred embodiment, expression of the
dominant negative mutant of a plant CDC2b is used to modulate the
endoreduplication in plant cells, plant tissue, plant organs or
whole plants.
[0052] Because the present invention for the first time clearly
demonstrates that it is possible to modulate endoreduplication in
plants or parts thereof by modulating the expression and/or
activity of a gene or protein through genetic engineering, the
scope of the invention also contemplates a general method for
modulating endoreduplication by modifying the expression and/or
activity of specific genes or gene products through genetic
engineering. A preferred embodiment provides the use of genetic
engineering to modulate endoreduplication in plant cells, plant
tissue, plant organs and/or whole plants.
[0053] With reference to the above, an important aspect of the
current invention is a method for modulating endoreduplication in
monocotyledonous or dicotyledonous plants or parts thereof by
modifying the plant cell division. In a preferred embodiment one or
more cell cycle genes or plant cell cycle genes, preferably
operably linked to control sequences, are for instance used to
specifically modulate endoreduplication in transformed plants,
particularly:
[0054] in the complete plant
[0055] in selected plant organs, tissues or cell types
[0056] under specific environmental conditions, including abiotic
stress such as cold, heat, drought or salt stress or biotic stress
such as pathogen attack
[0057] during specific developmental stages.
[0058] In a further preferred embodiment, one or more cell cycle
genes or plant cell cycle genes, preferably operably linked to a
control sequence are used to modulate endoreduplication in storage
cells, storage tissues and/or storage organs of plants or parts
thereof. Preferred target storage organs and parts thereof for the
modulation of endoreduplication according to the invention, are for
instance seeds (such as from cereals, oilseed crops), roots (such
as in sugar beet), tubers (such as in potato) and fruits (such as
in vegetables and fruit species). Furthermore it is expected that
increased endoreduplication in storage organs and parts thereof
correlates with enhanced storage capacity and as such with improved
yield.
[0059] In yet another embodiment of the invention, a plant with
modulated endoreduplication in the whole plant or parts thereof can
be obtained from a single plant cell by transforming the cell, in a
manner known to the skilled person, with a cell cycle gene,
preferably a plant cell cycle gene and, not necessarily but
preferably operably linked to a control sequence. In a preferred
embodiment such transformation is performed with a CKS1 gene, a
CDC2 gene and/or a dominant negative mutant of a CDC2 gene.
[0060] In a further preferred embodiment such transformed plants
can be obtained by transforming with a plant CKS1 gene, a plant
CDC2 gene and/or a dominant negative mutant of a plant CDC2
gene.
[0061] In a further preferred embodiment such transformation is
performed with a nucleic acid molecule according to claim 1 and/or
the Arabidopsis CDC2b gene and/or a dominant negative mutant of the
Arabidopsis CDC2b gene.
[0062] Any obtained transformed plant with modulated
endoreduplication can be used in a conventional breeding scheme or
in in vitro plant propagation to produce more transformed plants
with the same characteristics and/or can be used to introduce the
same characteristic in other varieties of the same or related
species. Such plants are also part of the invention. Seeds obtained
from the transformed plants genetically also contain the same
characteristic and are part of the invention.
[0063] The current invention also demonstrates that CKS1,
preferably a plant CKS1 and more preferably CKS1At, can be used to
interfere with the plant cell cycle and can be used more
specifically to prevent entering mitosis and thus inhibit or even
arrest cell division in plants or parts thereof. In a particular
preferred embodiment of this invention, cell division is inhibited
or arrested in plant meristems.
[0064] Alternatively, expression studies (see examples) strongly
indicate that in plants or parts thereof, low levels of expression
and/or activity of CKS1 are correlated with non-dividing cells. The
present invention therefor further embraces a method to use CKS1
preferably a plant CKS1 and more preferably CKS1At, to maintain,
facilitate or stimulate cell division in plants or parts thereof.
In a particular preferred embodiment, cell division is maintained,
facilitated or enhanced in plant meristems. In another preferred
embodiment cell division is induced in resting cells.
[0065] A further part of this invention is a method for
transforming plants with CKS1, preferably plant CKS1 according to
the present invention, not necessarily but preferably operably
linked to a control sequence. Using this approach, and since cell
division is a crucial element in determining the growth and shape
of a plant or parts thereof, it is expected that defined modulation
of the expression and/or activity of plant CKS1 will allow the
production of transformed plants, with modulated growth.
[0066] Methods to modify the expression levels and/or the activity
of CKS1 preferably plant CKS1, are known to persons skilled in the
art and include for instance overexpression, co-suppression, the
use of ribozymes, anti-sense strategies, gene silencing
approaches.
[0067] The invention is in principle applicable to any plant and
crop that can be transformed with any of the transformation method
known to those skilled in the art and includes for instance corn,
wheat, barley, rice, oilseed crops, cotton, tree species, sugar
beet, cassaya, tomato, potato, numerous other vegetables,
fruits.
[0068] Similarly, the invention can also be used to modulate the
cell division and the growth of cells, preferentially plant cells,
in in vitro cultures.
[0069] Further in accordance with the invention chimeric genes are
provided, comprising the following operably linked
polynucleotides:
[0070] a. a nucleic acid molecule according to claim 1 to 3
[0071] b. one or more control sequences
[0072] Alternatively, said chimeric genes comprise the following
operably linked polynucleotides:
[0073] a. a dominant negative plant CDC2 mutant with
characteristics such as the D161N mutant of Arabidopsis CDC2b
[0074] b. one or more control sequences
[0075] Vectors or expression vectors comprising a nucleic acid
molecule according to claim 1 or comprising chimeric genes such as
described above are also considered as part of the invention.
[0076] Part of the invention is also a plant cell carrying at least
a functional part of the nucleic acid molecule according to the
invention or a chimeric gene as described above.
[0077] The present invention is also directed to a transgenic plant
carrying a plant cell comprising a nucleic acid molecule according
to claim 1 or a chimeric gene as described above.
[0078] A transgenic plant is obtained through a process of
regenerating said plant starting from a plant cell having as part
of its genetic material the nucleic acid molecule according to the
invention or a chimeric gene as described above. Progeny of the
plant and/or plant material such as flowers, fruit, leaves, pollen,
seeds, seedlings or tubes obtainable from said transgenic plant
also belong to the current invention.
[0079] Also part of the invention are antibodies recognising a
plant CKS1 protein or a part thereof. Another part of the invention
is the use of antibodies raised against CKS1At to identify and
isolate other plant CKS1 proteins and genes.
[0080] In order to clarify what is meant in this description by
some terms a further explanation is hereunder given.
[0081] The polypeptides of the present invention are not
necessarily translated from a designated nucleic acid sequence; the
polypeptides may be generated in any manner, including for example,
chemical synthesis, or expression of a recombinant expression
system, or isolation from a suitable viral system. The polypeptides
may include one or more analogs of amino acids, phosphorylated
amino acids or unnatural amino acids. Methods of inserting analogs
of amino acids into a sequence are known in the art. The
polypeptides may also include one or more labels, which are known
to those skilled in the art.
[0082] The terms "gene(s)", "polynucleotide", "nucleic acid
sequence", "nucleotide sequence", "DNA sequence" or "nucleic acid
molecule(s)" as used herein refers to a polymeric form of
nucleotides of any length, either ribonucleotides or
deoxyribonucleotides. This term refers only to the primary
structure of the molecule. Thus, this term includes double- and
single-stranded DNA, and RNA. It also includes known types of
modifications, for example, methylation, "caps" substitution of one
or more of the naturally occuring nucleotides with an analog.
[0083] "Recombinant nucleic acid molecule" as used herein refers to
a polynucleotide of genomic, cDNA, semisynthetic or synthetic
origin which, by virtue of its origin or manipulation (1) is linked
to a polynucleotide other than that to which it is linked in nature
or, (2) does not occur in nature.
[0084] An "expression vector" is a construct that can be used to
transform a selected host cell and provides for expression of a
coding sequence in the selected host. Expression vectors can for
instance be cloning vectors, binary vectors or integrating
vectors.
[0085] A "coding sequence" is a nucleotide sequence which is
transcribed into mRNA and/or translated into a polypeptide when
placed under the control of appropriate regulatory sequences. The
boundaries of the coding sequence are determined by a translation
start codon at the 5'-terminus and a translation stop codon at the
3'-terminus. A coding sequence can include, but is not limited to
mRNA, cDNA, recombinant nucleotide sequences or genomic DNA, while
introns may be present as well under certain circumstances.
[0086] "Control sequence" refers to regulatory DNA sequences which
are necessary to effect the expression of coding sequences to which
they are ligated. The nature of such control sequences differs
depending upon the host organism. In prokaryotes, control sequences
generally include promoter, ribosomal binding site, and
terminators. In eukaryotes generally control sequences include
promoters, terminators and, in some instances, enhancers,
transactivators or transcription factors. The term "control
sequence" is intended to include, at a minimum, all components the
presence of which are necessary for expression, and may also
include additional advantageous components.
[0087] "Operably linked" refers to a juxtaposition wherein the
components so described are in a relationship permitting them to
function in their intended manner. A control sequence "operably
linked" to a coding sequence is ligated in such a way that
expression of the coding sequence is achieved under conditions
compatible with the control sequences. In case the control sequence
is a promoter, it is obvious for a skilled person that
double-stranded nucleic acid is used.
[0088] The terms "protein" and "polypeptide" used in this
application are interchangeable. "Polypeptide" refers to a polymer
of amino acids (amino acid sequence) and does not refer to a
specific length of the molecule. Thus peptides and oligopeptides
are included within the definition of polypeptide. This term does
also refer to or include post-translational modifications of the
polypeptide, for example, glycosylations, acetylations,
phosphorylations and the like. Included within the definition are,
for example, polypeptides containing one or more analogs of an
amino acid (including, for example, unnatural amino acids, etc.),
polypeptides with substituted linkages, as well as other
modifications known in the art, both naturally occurring and
non-naturally occurring.
[0089] "Fragment of a sequence" or "part of a sequence" means a
truncated sequence of the original sequence referred to. The
truncated sequence (nucleic acid or protein sequence) can vary
widely in length; the minimum size being a sequence of sufficient
size to provide a sequence with at least a comparable function
and/or activity of the original sequence referred to, while the
maximum size is not critical. In some applications, the maximum
size usually is not substantially greater than that required to
provide the desired activity and/or function(s) of the original
sequence. Typically, the truncated amino acid sequence will range
from about 5 to about 60 amino acids in length. More typically,
however, the sequence will be a maximum of about 50 amino acids in
length, preferably a maximum of about 30 amino acids. It is usually
desirable to select sequences of at least about 10, 12 or 15 amino
acids, up to a maximum of about 20 or 25 amino acids. The term
"antibody" includes, without limitation, chimeric antibodies,
altered antibodies, univalent antibodies, bi-specific antibodies,
Fab proteins or single-domain antibodies. In many cases, the
binding phenomena of antibodies to antigens is equivalent to other
ligand/anti-ligand binding. The antibody can be a monoclonal or a
polyclonal antibody.
[0090] "Transformation" as used herein, refers to the transfer of
an exogenous polynucleotide into a host cell, irrespective of the
method used for the transfer. The polynucleotide may be transiently
or stably introduced into the host cell and may be maintained
non-integrated, for example, as a plasmid, or alternatively, may be
integrated into the host genome. Many types of vectors can be used
to transform a plant cell and many methods to transform plants are
available. Examples are direct gene transfer, pollen-mediated
transformation, plant RNA virus-mediated transformation,
Agrobacterium-mediated transformation, liposome-mediated
transformation, transformation using wounded or enzyme-degraded
immature embryos, or wounded or enzyme-degraded embryogenic callus.
All these methods and several more are known to persons skilled in
the art. The resulting transformed plant cell can then be used to
regenerate a transformed plant in a manner known by a skilled
person.
[0091] "Functional part of" means that said part to which subject
it relates has substantially the same activity as the subject
itself, although the form, length or structure may vary.
[0092] The term "substantially homologous" refers to a subject, for
instance a nucleic acid, which is at least 50% identical in
sequence to the reference when the entire ORF (open reading frame)
is compared, where the sequence identity is preferably at least
70%, more preferably at least 80%, still more preferably at least
85%, especially more than about 90%, most preferably 95% or
greater, particularly 98% or greater. Thus, for example, a new
nucleic acid isolate which is 80% identical to the reference is
considered to be substantially homologous to the reference.
Sequences that are substantially homologous can be identified by
comparing the sequences using standard software available in
sequence data banks, or in a Southern hybridisation experiment
under, for instance, conventional or preferably stringent
conditions as defined for that particular system.
[0093] Similarly, in a particular embodiment, two amino acid
sequences, when proper aligned in a manner known to a skilled
person, are "substantially homologous" when more than 40% of the
amino acids are identical or similar, or when more preferably more
than about 60% and most preferably more than 69% of the amino acids
are identical or similar (functionally identical).
[0094] "Sense strand" refers to the strand of a double-stranded DNA
molecule that is homologous to a mRNA transcript thereof. The
"anti-sense strand" contains an inverted sequence which is
complementary to that of the "sense strand".
[0095] "Cell cycle" or "cell division" means the cyclic biochemical
and structural events associated with growth and with division of
cells, and in particular with the regulation of the replication of
DNA and mitosis. The cycle is divided into periods called: G.sub.0,
Gap.sub.1 (G.sub.1), DNA synthesis (S), Gap.sub.2 (G.sub.2), and
mitosis (M).
[0096] "Cell cycle genes" are genes encoding proteins involved in
the regulation of the cell cycle or fragments thereof.
[0097] "Plant cell cycle genes" are cell cycle genes originally
present or isolated from a plant or fragments thereof.
[0098] "Plant cell" comprises any cell derived from any plant and
existing in culture as a single cell, a group of cells or a callus.
A plant cell may also be any cell in a developing or mature plant
in culture or growing in nature.
[0099] "Plants" comprises all plants, including monocotyledonous
and dicotyledonous plants.
[0100] "Plant sequence" is a sequence naturally occurring in a
plant.
[0101] "Plant polypeptide" is a polypeptide naturally occurring in
a plant.
[0102] "Cyclin-dependent protein kinase complex" means the complex
formed when a, preferably functional, cyclin associates with a,
preferably, functional cyclin dependent kinase. Such complexes may
be active in phosphorylating proteins and may or may not contain
additional protein species.
[0103] "Cell-cycle kinase inhibitor" (CKl) is a protein which
inhibit CDK/cyclin activity and is produced and/or activated when
further cell division has to be temporarily or continuously
prevented.
[0104] "Expression" means the production of a protein or nucleotide
sequence in the cell itself or in a cell-free system. It includes
transcription into an RNA product, post-transcriptional
modification and/or translation to a protein product or polypeptide
from a DNA encoding that product, as well as possible
post-translational modifications.
[0105] "Modulation of expression or activity" means control or
regulation, positively or negatively, of the expression or activity
of a particular protein or nucleotide sequence by methods known to
a skilled person.
[0106] "Endoreduplication" means recurrent DNA replication without
consequent mitosis and cytokinesis.
[0107] "Foreign" with regard to a DNA sequence means that such a
DNA is not in the same genomic environment in a cell, transformed
with such a DNA in accordance with this invention, as is such DNA
when it is naturally found in a cell of the plant, bacteria,
fungus, virus or the like, from which such a DNA originates.
[0108] In the description of the current invention reference is
made to the following sequences of the Sequence Listing:
[0109] SEQ.ID.NO. 1: coding nucleotide sequence (position 1-261)
for CKS1At with flanking non-coding sequences.
[0110] SEQ.ID.NO. 2: genomic nucleotide sequence with introns
[0111] SEQ.ID.NO. 3 :amino acid sequence (position 1-87) obtainable
from the coding nucleotide sequence represented in SEQ.ID.NO.
1.
[0112] SEQ.ID.NO.4: amino acid sequence (position 1-72) obtainable
from the coding nucleotide sequence represented in SEQ.ID.NO.
1.
[0113] The present invention is further described by reference to
the following non-limiting figures and examples.
[0114] Unless stated otherwise in the Examples, all recombinant DNA
techniques are performed according to protocols as described in
Sambrook et al. (1989), Molecular Cloning: A Laboratory Manual.
Cold Spring Harbor Laboratory Press, NY or in Volumes 1 and 2 of
Ausubel et al. (1994), Current Protocols in Molecular Biology,
Current Protocols. Standard materials and methods for plant
molecular work are described in Plant Molecular Biology Labfase
(1993) by R. D. D. Croy, jointly published by BIOS Scientific
Publications Ltd (UK) and Blackwell Scientific Publications
(UK).
EXAMPLE 1
[0115] Two Hybrid Screen Using CDC2aAt as Bait
[0116] To identify CDC2aAt-interacting proteins a two-hybrid system
was used based on GAL4 recognition sites to regulate the expression
of both his3 and lacZ reporter genes (Fields et al., 1989). The
pGBTCDC2A vector, encoding a fusion protein between the C terminus
of the GAL4 DNA-binding domain and CDC2aAt, was constructed by
cloning the full-length coding region of CDC2aAt into the pGBT9
vector. For the screening a GAL4 activation domain cDNA fusion
library was used, constructed with RNA isolated from 3-week-old
Arabidopsis vegetative tissues. The pGBTCDC2A plasmid was
cotransformed with the library into the yeast HF7c reporter strain.
A total of 10.sup.7 independent cotransformants were screened for
their ability to grow on histidine-free medium. A 3-day incubation
at 30.degree. C. yielded 300 colonies. These 300 colonies were then
tested for their growth on medium without histidine in the presence
of 10 mM 3-amino-1, 2, 4-triazole (3-AT), reducing the number of
positives to 235. Next, these colonies were tested for activation
of the lacZ gene, and 143 turned out to be both His.sup.+ and
LacZ.sup.+. After DNA preparation and restriction fragment
analysis, of all 143 positive clones three different types of genes
were identified.
[0117] One class of genes, represented by 139 cDNA clones,
contained a small open reading frame coding for a protein of 87
amino acids, with a calculated molecular mass of 10.5 kDa. This
gene was represented by at least two independent clones, as
indicated by the varying length of their 5' and 3' untranslated
regions. The longest clone contained a 5' untranslated region of 15
bp and a 3' untranslated region of 208 bp. A BLAST data base search
revealed that this clone (called pGADCKS) encoded a SUC1/CKS1
homologue, whereas the gene is of plant origin. The gene was
designated CKS1At for CDK-associating subunit from Arabidopsis
thaliana.
[0118] The specificity of the interaction between CDC2aAt and
CKS1At was verified by the retransformation of yeast with pGBTCDC2A
and pGADCKS. As controls, pGBTCDC2A and reverse pGADCKS were
cotransformed with a vector containing only the GAL4 activation
domain (pGAD424) and with the pGBT9 plasmid encoding the GAL4
DNA-binding domain only, respectively. Transformants were plated on
medium with or without histidine. Only transformants containing
both pGBTCDC2A and pGADCKS were able to grow in the absence of
histidine.
EXAMPLE 2
[0119] Characterisation of the CKS1At Gene
[0120] An alignment of the amino acid sequence of CKS1At, encoding
a protein of about 10.5 kDa, according to the invention with
SUC1/CKS1 homologues from yeasts, human, Drosophila melanogaster,
Xenopus laevis, and Patella vulgata shows a highly conserved region
of 70 amino acids (from Gly2 to Leu71) of CKS1At with all non-yeast
homologues (67-69% amino acid identity).The level of amino acid
identity between CKS1At and SUC1 of Sch.pombe on the one hand and
CKS1 of S.cerevisiae on the other hand, is limited to 49.3% and
49.4% respectively. This is due to the presence of a 9 amino acid
sequence inserted into the yeast proteins (from Tyr55 to Leu63 in
Sch.pombe and from Tyr58 to Leu66 in S.cerevisiae). These 9 amino
acids are not present in the CKS1At protein. In contrast to other
non-yeast homologues, the CKS1At protein has a C-terminal extension
of 10-14 amino acids rich in glutamine residues, resembling the
situation found for CKS1 of S. cerevisiae. Polyglutamine segments
are found in a broad variety of proteins and are thought to be
involved in protein-protein interactions.
[0121] The need for this C-terminal domain for the interaction with
CDC2At was assayed using the two-hybrid system. A gene encoding a
truncated CKS1At protein was created by mutating the Tyr73 codon to
a stop codon, thereby deleting the last 15 amino acids.
Subsequently, this mutated gene was cloned in frame with the GAL4
activation domain, resulting in the pGADCDSQ plasmid. This vector
was introduced into the HF7c yeast reporter strain, together with
pGBTCDC2A or the empty pGBT9 vector. Only transformants harbouring
both pGADCKSQ and pGBTCDC2A grew in the absence of histidine,
demonstrating that the C-terminal part of CKS1At was not essential
for the binding of CDC2aAt in the yeast system. Therefore, this
part of the CKS1At protein might be involved in the interaction
with other proteins or may improve the stability of the CDK-CKS1At
interaction.
[0122] To study the genomic organisation of CKS1At, Arabidopsis DNA
was digested with four different enzymes. Hybridisation with the
CKS1At-coding region at low stringency showed only one band for
every digest, indicating the presence of only one CKS1At gene per
haploid genome of Arabidopsis.
EXAMPLE 3
[0123] Isolation of a Genomic Clone of CKS1At
[0124] A genomic sequence of the CKS1At clone was obtained by PCR
using standard conditions (30 cycles of 1min. 95.degree. C.
denaturation; 1 min. 55.degree. C. annealing and 2 min.of
72.degree. C. elongation). As template 25 ng of genomic A.thaliana
DNA was used. Primers used were 5'-GAGAGCCATGGGTCAGATCC-3' and
5'-CCAATACTCATAGATCTGTTGC-3'. The obtained PCR product was cloned
and sequenced (SEQ.ID.NO.2). Comparison with the cDNA sequence
(SEQ.ID.NO.1) revealed the presence of 2 introns in the genomic
clone.
EXAMPLE 4
[0125] CKS1At can rescue a Sch. pombe Temperature-Sensitive CDC2
Mutant
[0126] Both SUC1 from Sch. pombe and CKS1 from S. cerevisiae were
initially identified as suppressors of temperature-sensitive
alleles of CDC2 and CDC28, respectively. To determine the
functionality of the CKS1At protein, we tested whether it is able
to rescue the temperature-sensitive Sch. pombe CDC2-L7 strain. For
this purpose, the full-length CKS1At-coding region was cloned in
the pREP3, pREP41, and pREP81 vectors (Maundrell, 1990; Basi et
al., 1993), resulting in pREP3CKS, pREP41CKS, and pREP81CKS,
respectively. These three vectors contained the
thiamine-repressible promoter nmt1 and allowed inducible expression
of CKS1At to different levels. Strongest induction could be
achieved using the pREP3CKS vector, intermediate with pREP41CKS,
and lowest with pREP81CKS. All constructs were introduced into
wild-type and CDC2-L7 yeast.
[0127] Wild-type Sch. pombe cells transformed with pREP81CKS grew
normally under both inductive (without thiamine) and non-inductive
(with thiamine) conditions. In contrast, in the absence of
thiamine, cell growth of wild-type Sch.pombe was completely or
partially inhibited in cells transformed with pREP3CKS and
pREP41CKS, respectively. Microscopic analysis revealed the
CKS1At-overexpressing cells to have an elongated phenotype. No cell
elongations was seen under non-inductive conditions, nor in cells
harboring the empty pREP3 or pREP41 vector, demonstrating that the
observed phenotype was linked with CKS1At expression.
[0128] The CDC2-L7 transformants were grown in the presence and
absence of thiamine, both at the permissive (28.degree. C.) and
restrictive (35.degree. C.) temperature. At the permissive
temperature a behaviour similar to that of the wild-type strain was
observed: cell growth was inhibited in the absence of thiamine for
cells transformed with pREP41CKS or pREP3CKS, but not for pREP81CKS
transformants. At the restrictive temperature only pREP81CKS- and
pREP41CKS-transformed cells grew in the absence of thiamine. No
growth was observed in the presence of thiamine, showing that the
rescue of the CDC2-L7 strain was specifically associated with the
low to intermediate expression levels of CKS1At. At the microscopic
level, the rescued CDC2-L7 cells showed a cellular morphology
intermediate to that of cells grown at the restrictive temperature
and at the permissive temperature.
[0129] These results demonstrate that CKS1At has the same
properties as the Sch.pombe SUC1 gene showing that CKS1At is a true
functional homologue of the yeast SUC1 protein.
EXAMPLE 5
[0130] Complementation of the Schizosaccharomyces pombe SUC1
Disruptant.
[0131] The SUC1 gene of Schizosaccharomyces pombe was initially
identified as a suppressor of specific temperature-sensitive
alleles of CDC2 (Hayles et al., 1986,Mol.Gen.Genet.202,291-293).The
CKS1At gene of Arabidopsis thaliana is capable of rescuing such a
temperature sensitive yeast CDC2 allele, demonstrating that CKS1At
encodes a true functional homologue of the SUC1 protein (see
example 3 of this application). More direct prove was obtained by
the complementation of a S. pombe SUC1 deleted strain. Deletion of
the SUC1 gene is lethal. Cells become either elongated indicating a
cell cycle arrest, or are impaired in cellular growth.
[0132] The full length coding region of CKS1At was cloned under the
control of the thiamine-repressible nmt1 promoter, resulting in the
pREP81CKS vector. This vector was introduced in a diploid yeast
strain in which one genomic copy of the SUC1 gene was replaced by
the ura3 marker. As control the same strain was transformed with
the empty pREP81 vector. The transformants were induced to
sporulate and the obtained spores were subsequently germinated on
nmt1 inducible medium (in the absence of thiamine) and in the
absence of uracil. PhloxinB, a dye which marks diploid cells as
dark colonies, was added to the medium to be able to distinguish
haploid from diploid colonies. Spores obtained from the pREP81CKS
transformed cells gave rise to a mixed population of haploid and
diploid cells. In contrast, germinating pREP81 spores only formed
diploid colonies. Haploid pREP81CKS cells were restreaked on medium
with or without thiamine. Only in the absence of thiamine cell
growth was observed, demonstrating that the rescue of the SUC1
disruptant is correlated with the expression of the CKS1At gene and
that CKS1At can functionally replace SUC1.
EXAMPLE 6
[0133] Expression Analysis of CKS1At
[0134] The CKS1At expression levels in different Arabidopsis
tissues were studied by RNA blot hybridization analysis. Total RNA
was extracted from roseffe leaves, roots, stems, flowers, siliques,
and actively dividing cell suspensions. Using a CKS1At antisense
riboprobe a hybridizing band of approximately 600 bp was detected
in all tissues, excluding siliques. CKS1At transcripts were most
abundant in stems and cell suspensions and only slightly lower in
flowers and roots.
[0135] To analyze CKS1At expression at the cellular level, in situ
hybridizations were performed using both antisense and sense
riboprobes. For gene expression analysis in roots we used radish,
which is closely related to Arabidopsis, but which offers the
advantage of an increased root diameter and cell number in each
tissue, facilitating interpretation of the results. Strong CKS1At
expression was seen in the meristematic and elongation zone of the
main root. Expression decreased in the differentiating zone, but
was still detectable in the vascular tissue. No detectable
expression was seen in the root cap and the quiescent centre, which
have low mitotic activity. During lateral root formation CKS1At
expression was strongly induced in the meristem and adjacent
vascular system.
[0136] Whole-mount in situ hybridizations performed on 7-day-old
Arabidopsis seedlings confirmed the expression pattern seen in the
radish roots. Whole-mount hybridizations also revealed strong
expression in the shoot apical meristem and in leaf primordia.
During flower development a strong hybridization signal was
observed in flower buds, but its intensity decreased in maturing
flowers. In all tissues analyzed, no signal was observed using the
sense control probe.
[0137] In situ hybridizations performed on sections of shoot
meristems of 2-month-old Arabidopsis plants exhibited strong CKS1At
expression in the tunica and periphery of the apical dome. A lower
hybridization signal was observed in the central zone of the
meristem. The observed signal was not uniformly distributed, but
rather showed some patchiness. Signals were often associated with
vascular tissue. Interestingly, an increase of the CKS1At
hybridization signal was noticed as leaves matured. No signals were
observed using a sense probe as a control. All these
characteristics point to a correlation between CKS1 AT expression
and cell division.
[0138] A strong CKS1At hybridisation signal was also observed in
maturing leaves. Mitotic index determination showed that these
cells stop to divide. However, visualization of the pattern of DNA
replication by [.sup.3H]-thymidine incorporation demonstrated that
in these tissues endoreduplication occured. The matching of the
pattern of CKS1At expression with that of endoreduplication in the
maturing leaves demonstrates that the CKS1At protein is involved in
the process of endoreduplication. The lack of CDC2aAt and CDC2bAt
expression in maturing leaves points to the possible presence of a
third, yet unidentified, class of CDK proteins in Arabidopsis. The
CKS1At apparently interacts with this novel class of CDK
proteins.
EXAMPLE 7
[0139] Production of CKS1At in Plants
[0140] Following the polymerase chain reaction technology (PCR) the
CKS1At coding region was amplified using the primers
5'GAGAGCCATGGGTCAGATCC3' and 5'CCAATACTCATAGATCTGTTGC3'. The PCR
fragment was cut with NcoI and Bgl II and cloned into the NcoI and
BamHI restriction sites of the vector pH 35S (Hemerly et al., 1995,
The EMBO Journal Vol.14,p.3925-3936). The cassette 35S-CKS1At-3'
NOS was cloned in the binary vector pGSV4 (Herouart et al., 1994,
Plant Physiol.104, p.873-880) and transfered to Agrobacterium
tumefaciens. The constructs were introduced in Niciotiana tabacum
cv. petit havana (SR1) plants by the leaf disk protocol (Horsch et
al., 1985,Science 227, p.1229-1231) and in Arabidopsis thaliana
using the root transformation protocol.
[0141] Primary transformants were selfed and characterized by
Northern and Western blotting using 3 week old plantlets.
Expression levels were compared with those of a non-transformed
plant. In the control plants low levels of mRNA and protein were
only visible upon long exposure times since expression of CKS1At is
mainly restricted to the mitotic and endoreduplicating cells of the
meristems. Among the Arabidopsis thaliana CKS1At transformed
plants, 5 lines showed moderate CKS1At mRNA expression levels and 1
line showed high mRNA levels. Western blotting using a CKS1At
specific antibody showed that the detected amount of CKS1At protein
correlates with the observed mRNA levels. For tobacco, CKS1At
transformed plants were also regenerated. Two plants showed strong
CKS1At mRNA expression while 7 plants showed a moderate expression
level. Western blotting using a CKS1At specific antibody showed
that the detected amount of CKS1At protein also correlates with the
observed mRNA levels.
EXAMPLE 8
[0142] Anatomical Analyses of Root and Shoot Meristems of
CKS1At-Overproducing Transgenic Arabidopsis Plants.
[0143] Several independent CKS1At-overproducing lines were grown on
vertical plates on standard growth medium (Valvekens et al.,1988,
Proc. Natl. Acad. Sci. 85: 5536-5540) in a 16-hr-light/8-hr-dark
cycle at 23.degree. C. and 60% room humidity. Root elongation was
measured and compared with wild-type (C24) plants. No stricking
differences in root growth could be determined and the overall
morphology of the transgenic plants looked completely normal.
[0144] Subsequently, a detailed microscopically analysis was
performed on wild-type and transgenic plants in order to detect
anatomical deviations from wild-type shoot and root meristem
structure. Therefore shoot and root meristems were embedded in a
plastic resin (Technovit 7100, Heraeaus Kulzer, Wehrheim, Germany)
in such a way that perfectly longitudinally oriented sections could
be performed (Scheres et al., 1994, Development 120:
2475-2487).
[0145] The sections were stained using different procedures to
visualise cells, nuclei, nucleoli and chromosomes: 0.05% toluidine
blue-O (Merck), Haematoxyline Heidenheim (Gurr, 1965, Leonard Hill,
London), DAPI (Kuroiwa et al., 1991, Appl. Fluor. Techn. 3 (2):
23-25).
[0146] On the level of the cellular pattern, no stricking
differences could be found as compared to wild-type root and shoot
meristems. All tissue layers were present and were organised as is
the case for wild type.
[0147] Furthermore, the shape and dimensions of the meristematic
cells were comparable with the ones found in wild-type
meristems.
[0148] However the length of transgenic root meristems are much
shorter. The epidermal and cortical cells seem to leave the cell
cycle earlier and start elongating in the region where in wild-type
roots still divisions occur. In the shoot apical meristem the cells
underneath the L1, L2 and L3 layers were larger than cells at the
same positions in wild-type shoot meristems. In plants the cell
size is often correlated with the basic nuclear DNA content. This
demonstrates that the cells in the CKS1At overproducing plants
underwent endoreduplication. This is further supported by the
observation of large nuclei in the cells of the root meristem of
CKS1At overproducing plants.
[0149] In conclusion, overproduction of the CKS1At protein did not
strikingly affect the global structure and organisation of the
meristems itself but accelerated the onset of endoreduplication
with cells bigger than normal, containing enlarged nuclei as
result. Similar results were obtained in other plant species.
EXAMPLE 9
[0150] Generation of a CKS1At-specific antibody A CKS1At specific
antibody was raised by the immunization of rabbits with the CKS1At
antigen. The antiserum detected a specific band of approximately 10
kDa in protein extracts prepared from actively dividing cell
suspension cells. No signal was observed using the pre-immune
serum.
[0151] The CKS1At antibody was also able to precipitate CKS1At
containing complexes from protein extracts. Protein extracts of
actively dividing cells were incubated with the CKS1At antibody
(diluted {fraction (1/20)}) for 2 hours on a rotating wheel at
4.degree. C. Subsequently, the extracts were loaded upon 1/3volume
of Sepharose-proteinA beads. After 1 hour incubation at 4.degree.
C. the Sepharose-proteinA bound complexes were eluded from the
beads by adding SDS PAGE loading buffer and heating for 5 minutes
at 95.degree. C. Immunoblotting with the CKS antibody recognized
specifically the CKS1At protein in the precipitates. This signal
was not observed in precipitates obtained with the use of the
pre-immune serum.
EXAMPLE 10
[0152] Mutational analysis of the Arabidopsis thaliana CKS1At
protein.
[0153] CKS1At was shown to bind both CDC2aAt and CDC2bAt in vivo
using the two-hybrid system (this application). It has been
demonstrated that the last 15 amino-acids of the 87 amino-acids
long CKS1At protein are dispensable for this interaction. The
recently published structure of the human CDK2 protein in complex
with the human CKS1At homologue CKSHs1 helped to identify the
amino-acids in the CKS/SUC1 proteins important for interaction with
CDKs. Based upon this information the E61 residue of CKS1At was
mutated into Q61 by PCR. The consequences of this mutation upon the
binding affinity for CDC2aAt and CDC2bAt were tested with the use
of a two-hybrid system utilizing the his3 gene as reporter gene.
The coding region of both the wild type CKS1At and the mutated
CKS1At.Q61 gene was cloned in frame with the GAL4 activation domain
in the pGAD424 vector, resulting in the pGADCKS and pGADCKS.Q61
respectively. These vectors were used to cotransform the HF7c yeast
cells with pGBTCDC2A or pGBTCDC2B. The pGBTCDC2A and pGBTCDC2B
vectors encode for a fusion protein between the GAL4 DNA-binding
domain and CDC2aAt or CDC2bAt respectively. The transformants were
plated on selective medium in the absence of histidine to test the
interactions between CKS1At and CKS1At.Q61 with CDC2aAt and
CDC2bAt. Transformants were also streaked on medium containing 10,
20, 40, 80 or 160 mM 3-amino-1,2,4-triazole (3-AT). 3-AT acts as a
competitive inhibitor of the his3 gene product. Since the strength
of interaction between the different partners in the two-hybrid
system is correlated with the level of his3 transcription, the
resistance towards increasing concentrations of 3-AT reflects an
increasing affinity between the different proteins.
[0154] Colonies containing the pGADCKS plasmid in combination with
pGBTCDC2A or pGBTCDC2B were able to grow on selective medium
containing up to 160 mM 3-AT. In contrast, yeast cells harboring
the pGADCKS.Q61 plasmid in combination with pGBTCDC2A grew in the
absence of histidine, but growth was completely inhibited in the
presence of 10 mM 3-AT, demonstrating that the interaction between
CKS1At and CDC2aAt was strongly impaired upon the substitution of
the E61 residue. Cotransformants containing pGADCKS.Q61 and
pGBTCDC2B were even unable to grow on medium lacking histidine.
These results pinpoint the E61 residue in CKS1At as an important
amino-acid in CKS1At for the interaction with CDKs.
[0155] It has been shown that the induced expression of the wild
type CKS1At gene in S. pombe caused cells to arrest in the G2
interphase, displaying an elongated phenotype and growth inhibition
(this application). The effects of overexpression of CKS1At.Q61
gene was studied by cloning this gene under the control of the
thiamine-repressible nmt1 promoter in the pREP3 vector. In contrast
to expression of the wild type CKS1At, expression of CKS1At.Q61
caused no cell cycle arrest. Cells revealed a normal cell cycle and
phenotype when grown in the absence of thiamine, although western
blotting demonstrated that cells showed an equal accumulation of
the CKS1At.Q61 protein as cells getting arrested by the
overexpression of the wild type CKS1At gene. These results
demonstrate that the inhibition of cell division seen by CKS1At
overexpression must be mediated through its binding with CDKs.
EXAMPLE 11
[0156] Translational Control of CKS1At in Arabidopsis Cell
Suspension Cultures.
[0157] With the use of a CKS1At-specific antibody the accumulation
of the CKS1At protein was followed on a time-dependent manner in A.
thaliana cell suspension cultures. Stationary cells were diluted
{fraction (1/10)}in fresh medium and cultivated for 15 days. Every
day a sample of cells was collected and frozen for later analysis.
Growth curve determination, by measuring the cell mass weight of 50
ml of culture, demonstrated that after dilution a lag phase
occurred from approximately 2 days. From day 2 onwards cells show
exponential growth until day 6-7, after which the cells entered the
stationary phase.
[0158] On western blotting a clear CKS1At signal was observed in a
1 day-old culture. Protein levels increased slightly at day 2 and
stayed constant until day 4-5. As cells entered the early
stationary growth phase the level of CKS1At decreased and was
totally absent in the stationary phase. In comparison, the level of
the CDC2aAt protein remained constant during the whole cultivation,
while the protein levels of CDC2bAt showed an accumulation pattern
similar to that of CKS1At.
[0159] Surprisingly, the pattern of CKS1At mRNA did not correlate
with levels of CKS1At protein. Northern blotting showed low CKS1At
expression at day 1. Expression increased at day 2 and remained
approximately constant during the rest of the cultivation. High
mRNA levels and low protein levels in stationary cells suggest that
a specific degradation mechanism is activated in these cells,
repressing the accumulation of the CKS1At protein.
EXAMPLE 12
[0160] CKS1At Associates in vivo with CDC2aAt at the G1/S
Transition Point but not During the G2 Phase.
[0161] Arabidopsis thaliana cell suspensions were partially
synchronized by the addition of aphidicolin to freshly diluted cell
suspension cells. After 24 hours the drug was washed away and cells
were cultivated in new medium. Samples were collected at several
time points and partly used for nuclei preparation, partly for
protein extraction. Flow cytometric analysis showed that cells
harvested immediately after removal of the drug were predominantly
at the G1/S boundary. In contrast, cells harvested 12 hours later
showed an accumulation of cells in G2, just before the onset of
mitosis (G2/M). Western blotting demonstrated that for both CDC2aAt
and CKS1At equal amounts of the proteins were present at both the
G1/S and G2 timepoints. The CKS1At containing complexes were
precipitated with the use of a CKS1At specific antibody (see
example 9 of this application). These complexes were resolved on a
SDS PAGE gel and immunoblotted. The presence of CDC2aAt as a
component of the immuno-precipitated complexes was verified by
probing this blot with a CDC2aAt specific antibody. This antibody
detected a specific band of the correct molecular size in the
extracts of the G1/S cells. In contrast, no signal was seen in the
extracts of the G2 cells. These results demonstrate the presence of
a complex formed in vivo between CDC2aAt and CKS1At at G1/S. During
the G2, although both proteins are present at the same level as in
G1/S, this complex is not formed.
[0162] Dominant Negative Mutants of CDC2b Show
Endoreduplication
EXAMPLE 13
[0163] Generation of the Mutant CDC2bAt-D161N Allele.
[0164] The D161 residue in CDC2bAt is essential for binding a
co-factor, ATP. A mutation into 161N renders an inactive CDK. The
dominant effect of the CDC2bAt.N161 mutant is related to the
observation that the inactive CDK is still capable to bind other
regulatory proteins, necessary for CDK activation. This results in
a competition between the CDC2b.N161 mutant and wild type CDKs for
the same regulatory proteins.
[0165] Mutation D161N (which means that at position 161 the Asp
residue is replaced by the Asn residue) was introduced in CDC2bAt
cDNA with the use of site directed mutagenesis (sequence of CDC2bAt
is disclosed in database with accession number X57840). The cDNA
was cloned in pUC18 vector to produce the plasmid pCDC2b-20. The
site directed mutagenesis was performed according to the following
strategy. The whole plasmid was amplified by PCR using two
divergent primers, aatttgggtcttggtcgtg and agcaatcttaagaagctctt,
the one bearing the mutation being underlined. The PCR conditions
used were:200 ng template, 125 pmol of each primer, 2,5 .mu.l of 10
mM dNTPs and 0,5 U of Pfu polymerase (Stratagene) and 95.degree. C.
1'and 30 cycles of (92.degree. C. 20", Tm 10", 75.degree. C. 5')
and then 75.degree. C. 5". After PCR amplification 10U of Dpnl were
added to the tube (37.degree. C. for 1 hr) to digest the template.
The products of the reactions were separated in 1% low melting
point agarose and purified from the gel with the use of gelase
(Epicenter Technologies) and then resuspended in TE. After a
kinasing reaction the fragments were self ligated and transformed
into E.coli XL1 Blue. The presence of the mutation and the absence
of PCR introduced errors in the resulting plasmid pCDC2b-DN were
confirmed by sequencing.
EXAMPLE 14
[0166] Analysis of CDC2bAt and CDC2bAt-DN Expression in S.
pombe.
[0167] The cDNAs (for wild-type CDC2bAt and for dominant negative
CDC2bAt as well) were cloned under the control of the nmt1 promoter
and its attenuated derivative T4 in expression vectors pRep3
(Maundrell,1990, J.Biol.Chem,265,10857-10864) and pRep41(Basi et
al. 1993, Gene, 123,131-136) respectively. The nmt1 promoter is
repressed while the cells are grown in the presence of thiamine and
can be fully induced after 14h of incubation in thiamine free
medium.
[0168] Production of pRep3 Constructs.
[0169] pRep3/CDC2bAt.
[0170] CDC2bAt cDNA was introduced in pRep3 by replacing CDC2aAt
cDNA in the pRep3 based plasmid constructed by Hemerly et al. 1995,
EMBO J.,14,3925-3936 to express CDC2aAt cDNA in fission yeast. The
plasmid was first restricted with NcoI, blunted by Mung Bean
exonuclease digestion, and finally restricted with Xmal. The
CDC2bAt cDNA was then ligated to the vector as Hpal-Xmal fragment
from pCDC2b-20, resulting in pRep3/CDC2bAt.
[0171] pRep3/CDC2bAt-DN.
[0172] The CDC2bAt-DN mutation was introduced into pRep3 by
replacing the Sall-BamHI fragment of pRep3/CDC2bAt with the
respective fragment carrying the mutation from pCDC2b-DN. The
result is pRep3/CDC2bAt-DN.
[0173] Production of pRep41Constructs.
[0174] pRep41/CDC2bAt.
[0175] CDC2bAt cDNA was ligated as Kpnl (blunted)-BamHI fragment
into pRep41 opened with Ndel (filled in) and BamHI, resulting in
pRep41/CDC2bAt.
[0176] pRep41/CDC2bAt-DN.
[0177] The CDC2bAt-DN mutation was cloned by replacing the
Sall-BamHI fragment of the construct above with the respective
fragment carrying the mutation. The result is pRep41/CDC2bAt-DN.
Because the pRep3 vector gave a basal expression level in the
non-induced conditions, most analyses were done with the
pRep41constructs. In general, however, both vectors gave similar
results.
[0178] Effect of CDC2bAt and CDC2bAt-DN on Cell-Cycle Progression
in Yeast.
[0179] The described above expression plasmids were introduced into
the yeast strain CDC2-33 leu1-32 h-s (Nurse,1976,
Mol.Gen.Genet.,146,167-178)- . Yeast cells were grown first for 24h
in non-inductive conditions (in the presence of 5 .mu.g/ml
thiamine) at 25.degree. C. till mid exponential growth phase.
Subsequently the thiamine was washed out of the medium and cells
were cultivated for 38h. Samples were harvested after Oh, 16h, 20h,
24h, 27h and 38h after removal of the thiamine. The samples were
used for cell number determination, staining of nuclei with the DNA
binding fluorochrome DAPI and flow cytometry as described in Sazer
and Sherwood et al.(1990,J.Cell.Sci.,97,509-516). A
Becton-Dickinson FACScan was used for flow cytometry. Cells were
viewed with a Zeiss Axioscokop microscope. Analysis of the growth
curves indicated that cell division was strongly inhibited 6h after
full induction of the promoter for all the constructs tested.
Microscopic analysis revealed that upon the expression of CDC2bAt,
cells became elongated, characteristic of continued growth in the
absence of cell division, and staining with DAPI showed interphase
nuclei. Flow cytometric analysis indicated that most of the cells
over-expressing CDC2bAt had a 2C DNA content pointing to the arrest
in G2 phase of the cell cycle. Similarly over-expression of
CDC2bAt-DN in S. pombe also leads to a tight cell-cycle arrest with
highly elongated cells. However analysis of DAPI stained cells
provided clear evidence for the occurrence of
endoreduplication--the majority of cells contained oversized nuclei
and, at later time points, a subpopulation of cells developed
grossly swollen nuclei that distended the yeast cell wall.
[0180] Determination of the Intrinsic Kinase Activity Associated
with the Arabidopsis CDKs Upon Their Over-Expression in S
pombe.
[0181] The intrinsic histone H1 kinase activity associated with
CDC2bAt and CDC2bAt-DN was determined in protein extracts prepared
from S. pombe strain CDC2-L7 leu1-32 h-, which was reported to have
negligible CDC2 kinase activity at 370C (Moreno et al., 1989, Cell,
58, 361-372). The strains transformed with pRep41/CDC2bAt and
pRep41/CDC2bAt-DN were grown in medium without thiamine for 16
hours at 25.degree. C. to induce the nmt1 promoter, while control
cultures were grown in the same conditions but in presence of 5
.mu.g/ml thiamine. For H1 kinase assay extracts were made using the
HB 15 buffer (Moreno et al. 1989, 1991, Methods
Enzymol.,194,795-823), spun at 4 C in a microfuge for 15', before
assaying the concentration of the supernatant and adjusting the
sample volume to give an uniform concentration. Kinase assay in the
total protein extract was performed at the restrictive temperature
37.degree. C. according to Moreno et al (1989). Neither CDC2bAt nor
CDC2bAt-DN showed any detectable kinase activity upon
overexpression in the CDC2-L7.
[0182] Determination of the Total Histone H1 Kinase Activity in
CDC2-33 Background.
[0183] To correlate the described above alterations in the cell
cycle with changes in CDK activity the total histone H1 kinase
activity was analysed in the same strains which were used for the
cytological studies. The assays were performed at the permissive
temperature 25.degree. C. in protein extracts prepared from S.
pombe CDC2-33 strain transformed with pRep41/CDC2bAt and
pRep41/CDC2bAt-DN which have been grown for 16h in the inducing
conditions (no thiamine). The time point chosen corresponds to 2h
after full induction of the promoter and one generation time before
the first changes to the cell division were observed. The protein
extracts were prepared as described above and total histone H1
kinase assays were performed with CDK complexes purified from total
yeast extract by p13.sup.SUC1 affinity chromatography according to
Azzi et al. (1992,Eur.J.Biochem.,203,353-360). Briefly total yeast
extract (100 .mu.g) were incubated with 50 .mu.l 50% (v/v)
p13.sup.SUC1-Sepharose beads for 2h at 4.degree. C. The washed
beads were combined with 30 .mu.l kinase buffer containing 1 mg/ml
histone H1, 50 .mu.M ATP and 1 .mu.C of gamma .sup.32P-ATP. After
15' incubation, samples were separated by SDS PAGE and analysed by
phosphorimager (Molecular Dynamics)
[0184] Over-expression of both CDC2bAt and CDC2bAt-DN in the
CDC2-33 strain induced a reduction in the total histone H1 kinase
activity, consistently with the observed cell cycle arrest. These
results suggest that CDC2bAt alleles though catalytically inactive
in yeast cells are still able of binding some cell cycle regulators
thus sequestering them from the endogenous CDC2.
EXAMPLE 15
[0185] Analysis of CDC2bAt and CDC2bAt-DN Expression in
Tobacco.
[0186] The plasmid pUCA7-TX, bearing the `Triple-Op` promoter (Gatz
1992, Plant.J.,2,397-404, dubbed Top3 hereafter) in pUC18, was
opened with BamHI and Sphl and a fragment BamHI-Sphl containing the
nos gene polyadenylation site (polyA.sup.nos) was ligated to. Then
an XbaI linker was inserted in the Sphl site (trimmed off with T4
DNA polymerase) downstream of polyA.sup.nos to produce the plasmid
pUCA7-TXnosX. This plasmid was opened with BamHI and Kpnl and the
fragments containing either CDC2bAt or CDC2bAt-DN cDNAs were cloned
to as Kpnl-BamHI fragments between Top3 and polyA.sup.nos resulting
in the plasmids pTop3CDC2b and pTop3CDC2bDN respectively. The
expression cassettes Top3-CDC2bAt-polyA.sup.nos and
Top3-CDC2bAtDN-polyA.sup.nos were transferred as EcoRl(filled
in)-XbaI fragments of the above plasmids into the binary vector
pGSC1704 (Plant Genetic Systems N.V.) opened with SnaBI and XbaI.
The resulting binary plasmids pBinTop3CDC2b and pBinTop3CDC2bDN
were checked by NcoI-XbaI digestion and sequenced through the
region of the mutation. The binary plasmids were introduced in
Nicotiana tabacum cv Petit havana (SR1) plants by the leaf disc
protocol (Horsh,1985,Science,227,1229-1231). The level of
expression of CDC2b and CDC2bDN in the transgenic lines, 15 for
each transformation, was analysed by Western blotting as described
above. Of the total 12 lines expressing CDC2b and 13 lines
expressing CDC2bDN, two lines from each transformation with the
highest levels of expression were selected for further analysis.
The two wild-type lines are designated CDC2b-14 and CDC2b-23
whereas the two dominant negative mutant lines are coded CDC2bDN-1
and CDC2bDN-27 respectively. For the determination of kinase
activity associated with CDC2b in the transgenic plants, protein
extracts from 2 week old in vitro grown plants were prepared as
described above and protein complexes were immunoprecipitated from
200 .mu.g of the total protein with the use of an antibody
({fraction (1/200)}dilution) raised against the peptide
SAKTALDHPYFDSCDKSQF derived from CDC2bAt. The antibody had been
previously shown to specifically recognise also a CDC2bAt-like
kinase from tobacco. The histone H1 kinase activity in the
precipitated complexes was determined according to Magyar et al.
1993, Plant J.,4,151-161. It was found that overexpression of
CDC2bAt did not influence the kinase activity in a detectable way,
whereas overexpression of CDC2bDN resulted in a strong reduction of
the kinase activity, down to 20% of the control level. When the
roots of the transgenic plants were analysed by confocal
microscopy, the cells of the plants overexpessing CDC2bDN were
found to possess considerably enlarged nuclei, pointing to an
increase in the DNA content. The measurement of the nuclei in the
root tips produced the average size 49.5 .mu.m for the line
CDC2bDN-1 and 37.1 .mu.m for the line CDC2b-23 as compared to 35.2
.mu.m in the control. The DNA content in the transgenic plants was
further analysed by flow cytometry (Galbraith et al. 1991,
Plant.Physiol.,96,985-989). All the four "CDC2b-indicated" lines
analysed showed considerable increase in the nuclear DNA content in
the cotyledons compared to the wild-type SR1 control (see the
table).
1 COTYLEDONES DNA content 2C 4C 8C 16C SR1 (control) 93% 6% 0.42%
0.19% CDC2b-14 63% 34% 0.63% 2.50% CDC2b-23 62% 33% 2.70% 2.30%
CDC2b DN-1 70% 24% 3.60% 2.10% CDC2b DN-27 69% 27% 2.20% 1.60%
[0187] Both in the lines overexpressing CDC2b and the lines
expressing the dominant negative mutants of CDC2b, the number of
cells in the cotyledones with normal nuclear DNA content (2C)
decrease and the percentage of cells with increased nuclear DNA
content (from 4C up to 16C) significantly increases. This
demonstrates that modulated expression of CDC2b and/or expression
of dominant negative mutants of CDC2b clearly modulates the
endoreduplication in plants and plant cells. Similar results are
obtained in plant species different from tobacco.
Sequence CWU 1
1
* * * * *