U.S. patent application number 10/479910 was filed with the patent office on 2004-12-09 for composition for detecting peptidoglycan, and diagnostic kit detecting peptidoglycan.
Invention is credited to Auh, Joong-Hyuck, Cho, Tae-Hoon, Joo, Chang-Hun, Kim, Hong-Lak, Kim, Hyun-Sic, Kim, Moon-Suk, Lee, Bok-Luel, Park, Bu-Soo, Park, Ji-Won, Park, Yeon-Sung, Song, Seung-Hwan, Yeo, Jeong-Mi, Yoon, Jong-Won.
Application Number | 20040248271 10/479910 |
Document ID | / |
Family ID | 26639131 |
Filed Date | 2004-12-09 |
United States Patent
Application |
20040248271 |
Kind Code |
A1 |
Park, Bu-Soo ; et
al. |
December 9, 2004 |
Composition for detecting peptidoglycan, and diagnostic kit
detecting peptidoglycan
Abstract
The present invention relates to a composition for selectively
detecting an extremely small amount of peptidoglycan in sample, a
preparation method of the composition, and a detection kit for
peptidoglycan. It is possible to quantify a small amount of
peptidoglycan contained in human blood, tissue, body fluid, water
or food, and to diagnose an infection of microorganism with
peptidoglycan as a component of cell wall using the composition and
the detection kit. In addition, the composition can be applied for
a diagnosis reagent of detecting an infection of Gram-positive
bacteria in animal or human being in advance, and thus, can be used
for the prevention or treatment of food poisonings and Bacterial
sepsis.
Inventors: |
Park, Bu-Soo; (Kwangju-city,
KR) ; Joo, Chang-Hun; (Taejeon-city, KR) ;
Kim, Moon-Suk; (Busan-city, KR) ; Song,
Seung-Hwan; (Seoul, KR) ; Yoon, Jong-Won;
(Taejeon-city, KR) ; Park, Yeon-Sung;
(Koyang-city, KR) ; Kim, Hong-Lak; (Taejeon-city,
KR) ; Auh, Joong-Hyuck; (Seoul, KR) ; Cho,
Tae-Hoon; (Suwon-city, KR) ; Lee, Bok-Luel;
(Busan-city, KR) ; Park, Ji-Won; (Busan-city,
KR) ; Yeo, Jeong-Mi; (Cheju-city, KR) ; Kim,
Hyun-Sic; (Busan-city, KR) |
Correspondence
Address: |
Avery N. Goldstein
Gifford, Krass, Groh, Sprinkle
Anderson & Citkowkowski
280 N. Old Woodward Avenue, Suite 400
Birmingham
MI
48009
US
|
Family ID: |
26639131 |
Appl. No.: |
10/479910 |
Filed: |
December 5, 2003 |
PCT Filed: |
June 7, 2002 |
PCT NO: |
PCT/KR02/01086 |
Current U.S.
Class: |
435/189 ;
424/538; 424/94.4 |
Current CPC
Class: |
G01N 33/56911 20130101;
C12Q 1/04 20130101; G01N 2333/43552 20130101; C12Q 1/26
20130101 |
Class at
Publication: |
435/189 ;
424/538; 424/094.4 |
International
Class: |
C12N 009/02; A61K
035/64 |
Foreign Application Data
Date |
Code |
Application Number |
Jun 8, 2001 |
KR |
2001/31890 |
Jun 7, 2002 |
KR |
2002/31856 |
Claims
1. A composition for detecting a peptidoglycan comprising extract
of insect body fluid which has a phenoloxidase activity on the
peptidoglycan without the addition of calcium.
2. The composition according to claim 1, wherein the extract of
insect body fluid is a plasma solution separated from insect body
fluid.
3. The composition according to claim 1, wherein the extract of
insect body fluid comprises a plasma solution and hemocyte lysate
of insect body fluid.
4. The composition according to claim 1, wherein the extract of
insect body fluid is derived from Galleria mellanella larvae.
5. The composition according to claim 2, wherein the extract of
insect body fluid is a fraction having a phenoloxidase activity on
peptidoglycan without the addition of calcium selected from
fractions which are prepared by treating plasma of insect body
fluid with solvent or buffer solution.
6. The composition according to claim 3, wherein the extract of
insect body fluid is a fraction having a phenoloxidase activity on
peptidoglycan without the addition of calcium selected from
fractions which are prepared by lysing hemocyte contained in insect
body fluid containing plasma and hemocyte, and treating with
solvent or buffer solution.
7. The composition according to claim 3, wherein the extract of
insect body fluid is a fraction having a phenoloxidase activity on
peptidoglycan without the addition of calcium selected from
fractions which are prepared by adding hemocyte lysate or
partially-purified hemocyte lysate to fractions obtained by
treating plasma of Galleria mellanella larvae with solvent or
buffer solution.
8. The composition according to claim 5, wherein the solvent or
buffer solution comprises a chelating agent in a sufficient amount
for chelating calcium ion existing in a sample and separation
process.
9. The composition according to claim 5, wherein the fraction is a
fraction prepared through column chromatography.
10. The composition according to claim 9, wherein the column is
filed with a sugar resin or a vinyl resin.
11. A detection method of peptidoglycan comprising the steps of:
obtaining of sample from the test subject, adding a composition for
detecting peptidoglycan comprising extract of insect body fluid
which has a phenoloxidase activity on the peptidoglycan without the
addition of calcium to the sample, and measuring a phenoloxidase
activity.
12. The detection method according to claim 11, wherein the extract
of insect body fluid is a fraction having a phenoloxidase activity
on peptidoglycan without the addition of calcium selected from
fractions which are prepared by treating plasma of insect body
fluid with solvent or buffer solution.
13. The detection method according to claim 11, wherein the extract
of insect body fluid is a fraction having a phenoloxidase activity
on peptidoglycan without the addition of calcium selected from
fractions which are prepared by lysing hemocyte in insect body
fluid containing plasma and hemocyte, and treating with solvent or
buffer solution.
14. The detection method according to claim 11, wherein the extract
of insect body fluid is a fraction having a phenoloxidase activity
on peptidoglycan without the addition of calcium selected from
fractions which are prepared by adding hemocyte lysate or
partially-purified hemocyte lysate to fractions obtained by
treating plasma of Galleria mellonella larvae with solvent or
buffer solution.
15. A detection kit for peptidoglycan comprising the composition
for detecting a peptidoglycan comprising extract of insect body
fluid which has a phenoloxidase activity on the peptidoglycan
without the addition of calcium.
16. The detection kit according to claim 15, wherein the extract of
insect body fluid is a fraction having a phenoloxidase activity on
peptidoglycan without the addition of calcium selected from
fractions which are prepared by treating plasma of insect body
fluid with solvent or buffer solution.
17. The detection kit according to claim 15, wherein the extract of
insect body fluid is a fraction having a phenoloxidase activity on
peptidoglycan without the addition of calcium selected from
fractions which are prepared by lysing hemocyte in insect body
fluid containing plasma and hemocyte, and treating with solvent or
buffer solution.
18. The detection kit according to claim 15, wherein the extract of
insect body fluid is a fraction having a phenoloxidase activity on
peptidoglycan without the addition of calcium selected from
fractions which are obtained by adding hemocyte lysate or
partially-purified hemocyte lysate to fractions obtained by
treating plasma of Galleria mellonella larvae with solvent or
buffer solution.
Description
CROSS REFERENCE TO RELATED APPLICATION
[0001] This application claims priority to and the benefit of
Korean Application Nos. 10-2001-31890 and 10-2002-31856, filed on
Jun. 8, 2001 and Jun. 7, 2002 in the Korean Intellectual Property
Office, the entire disclosure of which are incorporated herein by
reference.
BACKGROUND OF THE INVENTION
[0002] (a) Field of the Invention
[0003] The present invention relates to a composition for detecting
peptidoglycan, and a diagnostic kit for peptidoglycan using the
same.
[0004] (b) Description of the Related Art
[0005] The infection of the pathogenic Gram-positive bacterium
constitutes a large portion of widely-spread bacterial infection in
hospitals. Food poisonings and bacterial sepsis caused by
Gram-positive bacterium are lethal diseases. A rapid detecting
system for Gram-positive bacteria in clinical samples such as
blood, tissue, and urine, and food is necessary. According to a
conventional technique, it takes a few days to detect the bacteria.
As foods contaminated with the bacteria will be distributed during
this detection period, additional consumers may be infected.
[0006] It is possible to detect Gram-positive bacteria living in
various types of samples in small amounts by detecting and
quantifying the peptidoglycan. The peptideglycan is a kind of
glycoprotein polymer constituting bacterial cell walls and contains
N-acetylmuramic acid or N-glycosylmuramic acid and D-amino acid in
outer cell wall of Gram-positive bacteria.
[0007] Accordingly, a detecting and measuring method of the
peptidoglycan can be applied for testing the safeness of the
medicine, detecting microorganism in food and water, and performing
diagnosis of infectious disease.
[0008] It is reported that a prophenoloxydase system of insect can
detect selectively a small amount of lipopolysaccharide (LPS),
peptidoglycan, and beta-1,3-glucan, in which zymogen-type
prophenoloxydase is converted to phenoloxidase in active form
through cascade reactions to amplify the signal more than 1,000
times. However, the prophenoloxydase system detects all components
including lipopolysaccharide, peptidoglycan, and beta-1,3-glucan.
Therefore, a system for selectively detecting any one of them is
necessary.
[0009] A prophenoloxidase, which exists in insect body with
complete metamorphosis, is activated to phenoloxidase through
cascade reaction on the beta-1,3-glucan or lipopolysacchride. The
prophenoloxidase reaction system consisting of a series of cascade
reaction steps can be easily activated to phenoloxidase system to
produce melanin by using catechol amines when it is exposed to
exterior factors such as a pathogenic microorganism and materials,
or interior factors derived from degranulation of interior
hemocyte, etc. Thus, it is difficult to extract the
prophenoloxidase system from the insect body (Ashida and yoshida,
(1988), Insect. Biochem. 18, 11-19).
[0010] Ashida et al. reported in Eur. J. Biochem, 188, 507-515
(1990) that bivalent ion plays an important role in activating
prophenoloxidase system by introducing a composition which
recognizes beta-1,3-glucan separated from mosquito larva, and
disclosing that prophenoloxidase system of insects requires Ca2+
for its activation.
[0011] A composition and method for detecting peptidoglycan was
disclosed in U.S. Pat. No. 4,970,152 where a protein reacting with
beta-1,3-glucan was removed from silkworm plasma to produce a
reagent for specifically detecting a peptidoglycan. However, the
addition of Ca2+ is required for activating a phenoloxidase system
on peptidoglycan. In other word, according to U.S. Pat. No.
4,970,152, inhibition of the phenoloxidase system activation by
adding Ca2+ is necessary when obtaining a phenoloxidase composition
from the insect body fluid and triggering a color reaction on the
peptidoglycan as a substrate with the composition.
[0012] Also, U.S. Pat. No. 5,747,277 disclosed a SLP reagent.
However, this reagent detected beta-1,3-glucan and peptidoglycan at
the same time; therefore, it did not show a specific reaction to
only peptidoglycan. As result, this reagent cannot be used for the
detection of only peptidoglycan.
SUMMARY OF THE INVENTION
[0013] Considering the shortcomings of the prior arts, the present
invention provides a composition for selectively detecting a
peptidoglycan.
[0014] This invention also provides a preparation method of the
composition for detecting peptidoglycan.
[0015] This invention further provides a method for selectively
detecting peptidoglycan using the composition.
[0016] This present invention further still provides a detection
kit for selectively detecting peptidoglycan using the
composition.
BRIEF DESCRIPTION OF THE DRAWINGS
[0017] The accompanying drawings, which are incorporated in and
constitute a part of the specification, illustrate an embodiment of
the invention, and, together with the description, serve to explain
the principles of the invention.
[0018] FIG. 1 is a graph showing a phenoloxidase activity on
beta-1,3-glucan or peptidoglycan with or without the addition of
Ca2+.
[0019] FIG. 2 is a graph showing a phenoloxidase activity of plasma
fraction B of Galleria mellonella larvae reacted with
lipopolysaccharide, beta-1,3-glucan, or peptidoglycan.
[0020] FIG. 3 is a graph showing a phenoloxidase activity of plasma
fraction B of Galleria mellonella larvae reacted with peptidoglycan
in various concentrations.
[0021] FIG. 4 is a graph showing phenoloxidase activities of plasma
fraction B of Galleria mellonella larvae, hemocyte lysate, and
mixture thereof reacted with beta-1,3-glucan, or peptidoglycan as a
substrate.
[0022] FIG. 5 is a graph showing phenoloxidase activity of solution
containing plasma fraction B with protein amount of 600 .mu.g, and
hemocyte lysate with protein amount of 200 .mu.g of Galleria
mellonella larvae which are reacted with peptidoglycan.
[0023] FIG. 6 is a graph showing a phenoloxidase activity of
solution containing plasma fraction B and hemocyte lysate of
Galleria mellonella larvae reacted with peptidoglycan in various
concentrations.
[0024] FIG. 7 is a standard curve showing a phenoloxidase activity
of solution containing plasma fraction B and hemocyte lysate of
Galleria mellonella larvae reacted with 20 ng/ml of
peptidoglycan.
[0025] FIG. 8 is a graph showing a phenoloxidase activity of
solution containing plasma fraction B and hemocyte lysate of
Galleria mellonella larvae reacted with lipopolysaccharide,
beta-1,3-glucan, or peptidoglycan as a substrate
DETAILED DESCRIPTION AND THE PREFERRED EMBODIMENTS
[0026] The present invention is directed to a composition for
detecting peptidoglycan in a sample, a preparation method of the
composition, and a detection kit for detecting peptidoglycan using
the same.
[0027] In the present invention, a phenoloxidase system is intended
to mean a system which is in Galleria mellonella larvae, and can be
activated and converted to phenoloxidase by peptidoglycan.
[0028] In the present invention, a phenoloxidase composition is
intended to mean a composition which comprises parts of
phenoloxidase system or whole phenoloxidase system, and has a
phenoloxidase activity on peptidoglycan.
[0029] In the present invention, a phenoloxidase system of Galleria
mellonella does not require Ca2+ for its activation. Moreover, the
addition of Ca2+ causes the suppression of the phenoloxidase
activity.
[0030] The present invention provides a composition for detecting a
peptidoglycan comprising extract of insect body fluid which has a
phenoloxidase activity on peptidoglycan without the addition of
Ca2+. The extract of insect body fluid can be a plasma solution
separated from insect body fluid. Compared with the composition
containing only the plasma solution, the composition that further
comprises hemocyte lysate in addition to the plasma solution allows
detection of peptidoglycan that is small. in number despite smaller
amount of plasma solution is used. Thus, the composition comprising
the plasma solution and hemocyte lysate is preferred.
[0031] The composition comprising plasma solution of insect body
fluid and hemocyte lysate can be prepared by separating or without
separating the hemocyte. In other word, the composition comprising
plasma solution of insect body fluid and hemocyte lysate can be
prepared by separating the hemocyte from the body fluid, lysing the
hemocyte, and then adding the hemocyte lysate to the plasma
solution. Or, the hemocyte lysate or partially-purified hemocyte
lysate can be added to the partially purified plasma.
Alternatively, when the hemocyte contained in the body fluid is not
separated, the hemocyte can be broken down in part or as a whole to
produce the solution. For examples, the sonification or high-speed
centrifugation can be carried out on the body fluid or separated
hemocyte. Also, the plasma solution, hemocyte lysate, and their
mixture can be used in diluted form with addition of buffer
solution, or in concentrated form by conventional concentration
method. In the present invention, the hemocyte is intended to mean
precipitation which can be obtained by removing the plasma solution
from the insect body fluid. The hemocyte lysate can be a lysate
prepared by breaking-down the hemocyte with addition of solvent,
more preferably by obtaining supernatant form of the lysate.
[0032] In the composition for detecting peptidoglycan according to
the present invention, the extract of insect body fluid is
preferably derived from Galleria mellonella larvae. That is, the
composition comprises a part or whole of phenoloxidase system of
Galleria mellonella, e.g. prophenoloxidase system. Galleria
mellonella is short-lived with a life span of two months more or
less that is considerably shorter than most of other insects', and
has strong multiplication capability allowing easy large-scale
breeding means to yield a large amount of body fluid.
[0033] The plasma solution contained in insect body fluid can be
obtained by treating Galleria mellonella larvae with solvent or
buffer solution to produce factions, and by selecting the fraction
showing a phenoloxidase activity on peptidoglycan without addition
of Ca2+. Preferably, the solvent or buffer solution comprises
sufficient amount of chelating agent to chelate Ca2+ in a sample or
separation processes. More preferably, the fraction can be prepared
by column chromatography. For example, the column can be filled
with a sugar resin or vinyl resin as a carrier.
[0034] The composition for detecting peptidoglycan according to the
present invention can be used for detecting the infection with
Gram-positive bacteria, such as Staphylococcus, Streptococcus,
Pneumococcus, and Corynebacterium diphtheriae in an individual.
[0035] In another aspect of the present invention, the preparation
method of composition comprising extract of insect body fluid which
shows a phenoloxidase activity on peptidoglycan without the
addition of Ca2+. The preparation method of the present invention
comprises obtaining plasma solution from the body fluid of Galleria
mellonella larvae, treating the plasma with solvent or buffer
solution to produce fractions, and selecting the fraction showing a
phenoloxidase activity on peptidoglycan.
[0036] In the preparation method, it is preferable to use an
anticoagulant buffer solution for obtaining plasma from the body
fluid of Galleria mellonella larvae. The anticoagulant can be any
buffer solution capable of suppressing coagulation of body fluid,
and especially citric acid buffer solution is preferred. The
anticoagulating buffer solution further comprises an inhibitor
which can irreversibly inhibit a serine protease. The inhibitor of
serine protease can be any inhibitor which can irreversibly inhibit
serine protease, thereby obtaining phenoloxidase faction from the
body fluid of Galleria mellonella larvae. Preferably, the inhibitor
can include p-(aminginophenyl)-methanesulfonylfluoride(p-AP- MSF),
phenylmethanesulfonylfluoride(PMSF), and
diisopropylfluorophosphate(- DFP). The concentration of inhibitor
can be 0.2 mM or more. When obtaining the insect body fluid, the
chelating agent can be added to the anticoagulant for inhibiting
coagulation of cells, and preventing activation of phenoloxidase
system.
[0037] For example, a process of treating the plasma sample with
solvent or buffer solution in the preparation method can be carried
out by a column chromatography.
[0038] There is no limitation on solvent or buffer solution used in
the separation process. The anticoagulant can be used for obtaining
the plasma solution from the insect. Preferably, by adding the
chelating agent to the anticoagulant, a desirable phenoloxidase
composition can be obtained by inhibiting reactions associated with
protein coagulation.
[0039] The chelating agent which is sufficient for chelating
calcium ion contained in plasma sample and separation processes can
include any kind of known chelating agents without limitation, for
examples EDTA, EGTA, citric acid, etc. The chelating agent can be
used in various amounts, depending on the kind of subject insect,
and separation conditions such as the kind of column, and solvent.
A preferred amount of chelating agent can be a sufficient amount
for chelating Ca2+ contained in separating processes. Accordingly,
a person having an ordinary skill in the field can determine a
suitable amount of chelating agent without excess experimental
efforts.
[0040] For example, the treating process of plasma of Galleria
mellonella larvae with solvent or buffer solution can be carried
out by a column chromatography in which the plasma can be loaded on
column filled with resin, and eluted with solvent or buffer
solution like an anticoagulating buffer solution to produce
fractions. Only column chromatography provides a composition for
specifically detecting peptidoglycan without complicated
purification processes such as affinity chromatography.
[0041] The resin used in the column chromatography can be sugars
such as monosaccharide or polysaccharide as a support, and
preferably includes sugar resins such as agarose or dextran, and
vinyl resin. For examples, Sephadex or Toyoperal can be used.
[0042] The composition of the present invention can be used for
specifically detecting peptidoglycan, and thus can be used for the
diagnosis of bacterial infection containing peptidoglycan in cell
walls.
[0043] Accordingly, the present invention provides a detection
method for the presence of peptidoglycan in a sample. The detection
method comprises obtaining sample from subject matter, adding a
composition showing a phenoloxidase activity on peptidoglycan in
the absence of Ca2+, and measuring the phenoloxidase activity of
the sample. The composition showing a phenoloxidase activity is
intended to include the composition for detecting peptidoglycan. In
an specific embodiment of the present invention, the plasma of
Galleria mellonella larvae can be recovered in the presence of
chelating agent with sufficient amount of chelating Ca2+ contained
in plasma sample and separating processes, and then, the plasma can
be treated with solvent which contains chelating agent in
sufficient amount of chelating Ca2+ contained in plasma sample and
separating process to produce fractions. A fraction having a
phenoloxidase activity on peptidoglycan can be selected by treating
the fractions in an absence of Ca2+ to produce the composition of
the present invention.
[0044] In the detection method of peptidoglycan according to the
present invention, the test subject can be those spread in the
surroundings, such as animals including human being and live
organisms. For example, the detection method includes a diagnosing
method for Gram-positive bacteria by obtaining blood from the test
subject and detecting peptidoglycan. In another example, it is
possible to diagnose the infection of bacteria containing
peptidoglycan in cell walls, such as Gram-positive bacteria by
obtaining water from the breeding field and detecting
peptidoglycan.
[0045] As desired, to improve the specificity of diagnosis for
bacterial infection, it is possible to remove lipopolysaccharide
from the test sample. For example, it is possible to remove
lipopolysaccharide by treating the test sample with agents capable
of specifically binding to or precipitating the lipopolysaccharide
such as polymyxin before diagnosing.
[0046] In the present invention, a conventional method or modified
method, which is known as a measuring method of phenoloxidase
activity, can be used in measuring the phenoloxidase activity. For
example, by using coloring reaction with
4-methylcatechol/4-hydroxyprolineethylester (4-MC/4-HP), or melanin
formation reaction with dopamine, the absorbance can be measured to
provide phenoloxidase activity as explained below. The presence of
peptidoglycan can be easily determined from the measurement of
phenoloxidase activity.
[0047] In addition, the present invention provides a diagnosis kit
for peptidoglycan. The diagnosis kit for peptidoglycan comprises
the composition which has a phenoloxidase activity on peptidoglycan
in the absence of Ca2+. In the specific embodiment, the composition
can be a composition which shows a phenoloxidase activity on
peptidoglycan in the absence of Ca2+. Preferably, the composition
can be prepared by recovering plasma of Galleria mellonella larvae
in the presence of chelating agent with sufficient amount of
chelating Ca2+ contained in plasma sample and separating process,
treating the plasma with solvent which contains chelating agent
with sufficient amount of chelating Ca2+ contained in plasma sample
and separating process to produce fractions, and selecting a
fraction having the phenoloxidase activity on peptidoglycan by
treating the fractions without the addition of Ca2+.
[0048] The following examples are intended to further illustrate
the present invention. However, these examples are shown only for
better understanding of the present invention without limiting its
scope.
EXAMPLE 1
Preparation of Plasma and Hemocyte from Galleria mellonella
Larva
[0049] Larvae among Galleria mellonella larva that are about
2.5.about.3 cm in length were selected and anesthetized on ice for
10-30 minutes. Then, anticoagulant buffer solution (pH 4.6) and 0.2
mM of p-APMSF (Wako Co. Japan) was injected to the second node from
the head with 5 ml of syringe having 23G needle. The 4-5 drops of
body fluid was obtained by halfway slicing the second node from
tail, injecting buffer solution with syringe. The anticoagulant
buffer solution contains 15 mM of NaCl, 30 mM of trisodium citrate,
26 mM of citric acid, and 20 mM of EDTA.
[0050] 50 ml of body fluid was centrifuged at 4.degree. C.,
371.times.g, for 20 minutes to produce supernatant referred as
"plasma", and precipitates referred as "hemocyte".
EXAMPLE 2
Preparation of Plasma Solution
[0051] 2-1: Pretreatment of Extracted Plasma Solution
[0052] The plasma solution was treated with an ultra-filtration kit
(membrane cut off. 3000) to obtain up to about 2 ml of concentrated
plasma solution. In a condition where up to 5 mM of calcium is
added to the concentrated solution or no calcium is as to the
concentration solution, the phenoloxidase activity of resulting
concentrated solutions were measured, and showed in FIG. 1 as
follows:
[0053] 1: plasma solution,
[0054] 2: plasma solution+1 .mu.g lipopolysaccharide (LPS),
[0055] 3: plasma solution+1 .mu.g beta-1.3-glucan (BG),
[0056] 4: plasma solution+1 .mu.g peptidoglycan(PG),
[0057] 5: plasma solution+Ca2+,
[0058] 6: plasma solution+1 .mu.g LPS+Ca2+,
[0059] 7: plasma solution+1 .mu.g BG+Ca2+,
[0060] 8: plasma solution+1 .mu.g PG+Ca2+.
[0061] The plasma solution was used to measure phenoloxidase
activities in 1 .mu.g of LPS, peptidoglycan, and beta-1,3-glucan.
From the result, the plasma solution of the present invention
showed a low phenoloxidase activity on lipopolysaccharide (2nd
rod), and a strong phenoloxidase activity on beta-1,3-glucan (3rd
rod) and peptidoglycan (4th rod). Also, the system of Galleria
mellonella larva can be activated in the absence of Ca2+. In fact,
it is found that this system is inhibited by the addition of
Ca2+.
[0062] 2-2: Purification of a Fraction Specifically Recognizing
Peptidoglycan
[0063] 1.0.times.45 of column filed with Sephadex G-100 resin was
equalized with anticoagulant buffer solution (pH 5.0). The
concentrated sample (500 mg of protein) was loaded on the equalized
column, and then, was eluted with anticoagulant at a rate of 3.0
ml/test tube, and the eluted solution was taken to produce 3 ml of
1 to 30 fractions.
[0064] Depending on the separation pattern of the proteins, the
fractions were divided into Group A (fractions 1.about.6), Group B
(fractions 7.about.10), and Group C (fractions 11.about.16). The
groups B and C were concentrated with ultra-filtration Kit to be
similar concentration of Group A. Before loading, the phenoloxidase
activity of the sample, Groups A, B, and C on .beta.-1,3-glucan,
peptidoglycan, and lipopolysaccharide were measured and showed in
FIG. 2 as follows:
[0065] 1: Plasma solution,
[0066] 2: Plasma solution+1 ug of liposaccharide(LPS).
[0067] 3: Plasma solution+1 .mu.g of beta-1,3-glucan(BG),
[0068] 4: Plasma solution+1 .mu.g of peptidoglycan(PG),
[0069] 5: Group A,
[0070] 6: Group A+1 .mu.g LPS,
[0071] 7: Group A+1 .mu.g BG,
[0072] 8: Group A+1 .mu.g of PG,
[0073] 9: Group B,
[0074] 10: Group B+1 .mu.g of LPS,
[0075] 11: Group B+1 .mu.g of BG,
[0076] 12: Group B+1 .mu.g of PG,
[0077] 13: Group C,
[0078] 14: Group C+1 .mu.g of LPS,
[0079] 15: Group C+1 .mu.g of BG,
[0080] 16: Group C+1 .mu.g of PG.
[0081] Group B showed a phenoloxidase activity on only the
peptidoglycan.
EXAMPLE 3
Phenoloxidase Activity of Plasma Fractions
[0082] The group B showed a phenoloxidase activity specifically for
peptidoglycan. This example was to test a sensitivity of Group B on
peptidoglycan.
[0083] Firstly, a peptidoglyean solution was made by suspending 1
mg of water-insoluble peptidoglycan (Fluka Co.) in 20 mM TRIS
solution (pH 8.0). 100 .mu.l of the suspension was added to 900
.mu.l of TRIS solution, and then was treated with sonification for
a few seconds. 10 .mu.l of the resultant solution was used to
measure the phenoloxidase activity.
[0084] To measure the phenoloxidase activity, modified Pye's
spectrophotometer method was used with 4-methtylcatechol and
4-hydroxyproline ethyl ester as a substrate. 1 .mu.g/10 .mu.l of
peptidoglycan suspension in TIRS buffer (pH 8.0) was mixed with 30
.mu.l of sample (600 ug of protein amount), and then, incubated at
30.degree. C., for 5 minutes. As a negative control, only 10 .mu.l
of 20 mM TRIS buffer solution(pH 8.0) was added. The protein amount
in the sample was determined by measuring an absorbance at 280 nm
of wavelength, and meant the protein amount in total which were
contained in the sample prepared according the above method. Then,
442 .mu.l of 20 mM TRIS buffer (pH 8.0) was poured to test tube,
added by 4-MC and 4-HP to be 1 mM, and 2 mM, respectively, and
adjusted to 500 .mu.l of volume. The resultant was incubated at
30.degree. C. for 20 minutes. Then, 100 .mu.l of solution was taken
from test tube, diluted with 100 .mu.l of anticolagulant (pH 4.6),
and then true phenoloxidase activity was determined by measuring an
absorbance of 2 times-diluted phenoloxidase activity at 520 nm of
wavelength with spectrophotometer, and multiplying the absorbance
with dilution times.
[0085] When measuring the phenoloxidase activity under the
condition of calcium addition, 20 mM of TRIS buffer solution (pH
8.0) added by 5.65 mM of CaCl.sub.2 was used for determining the
phenoloxidase activity according to the substantially same method
as explained above.
[0086] 30 .mu.l of Group B solution prepared according to Example 2
(600 .mu.g of protein amount) was used to determine the
phenoloxidase activity depending on the various concentration of
water-soluble peptidoglycan without the addition of Ca2+ or with
the addition of Ca2+. The result was shown in FIG. 3 as
follows:
[0087] 1: Group B,
[0088] 2: Group B+3 ng of peptidoglycan (PG),
[0089] 3: Group B+5 ng of PG,
[0090] 4: Group B+10 ng of PG,
[0091] 5: Group B+20 ng of PG,
[0092] 6: Group B+30 ng of PG.
[0093] It was confirmed that Group B solution could quantify the
peptidoglycan up to 3 ng/ml of concentration.
EXAMPLE 4
Hemocyte Lysate of Galleria mellonella Larvae
[0094] The hemocytes separated from body fluid as disclosed in
Example 1 were added by 50 mM of TIRS buffer (pH 6.5) including 1
mM EDTA as much as half of the volume of hemocyte treated with
sonification for 2 minutes, and then, centrifuged at 4.degree. C.,
3,586.times.g for 20 minutes to produce the supernatant, as called
"Primary sample." The precipitate removed from the supernatant was
added by TIRS buffer as much as half of the volume of hemocyte, and
centrifuged one more time to produce the supernatant, referred as
"Second sample." The primary and second samples referred as
"hemocyte lysate" were kept in a refrigerator at -80.degree. C. for
the following use.
EXAMPLE 5
Phenoloxidase Activity and Specificity of Hemocyte Lysate on
Peptidoglycan
[0095] To determine whether the hemocyte lysate can react with
peptidoglycan specifically, the phenoloxidase activity of hemocyte
lysate was determined for its activity on beta-1,3-glucan and
peptidoglycan, which is shown in FIG. 4. The following solutions
were used for this example:
[0096] 1: Plasma fraction B solution of Example 2(Protein amount:
200 .mu.g),
[0097] 2: plasma fraction B solution (200 .mu.g)+beta-1,3-glucan(1
.mu.g),
[0098] 3: plasma fraction B solution (200 .mu.g)+peptidoglycan(1
.mu.g),
[0099] 4: hemocyte lysate (protein amount: 100 .mu.g),
[0100] 5: hemocyte lysate (100 .mu.g)+beta-1,3-glucan (1
.mu.g),
[0101] 6: hemocyte lysate (100 .mu.g)+peptidoglycan (1 .mu.g),
[0102] 7: plasma fraction B solution (200 .mu.g)+hemocyte lysate
(100 .mu.g),
[0103] 8: plasma fraction B solution (200 .mu.g)+hemocyte lysate
(100 .mu.g)+beta-1,3-glucan (1 .mu.g)
[0104] 9: plasma fraction B solution (200 .mu.g)+hemocyte lysate
(100 g)+peptidoglycan(1 .mu.g))
[0105] As a result, when the plasma fraction B solution of Example
2 including anticoagulant (protein amount: 200 .mu.g) was added by
1 .mu.g of beta-1,3-glucan and 1 .mu.g of peptidoglycan,
respectively(2.sup.nd, and 3.sup.rd rods of FIG. 4), the
phenoloxidase activity was not detected. Also, when the hemocyte
lysate solution (protein amount: 100 .mu.g) was added by 1 .mu.g of
beta-1,3-glucan and 1 .mu.g of peptidoglycan, respectively
(5.sup.th, and 6.sup.th rods of FIG. 4), the phenoloxidase activity
was not detected. However, when plasma fraction B solution (protein
amount: 200 .mu.g) was added by 100 .mu.g of hemocyte lysate and 1
.mu.g of peptidoglycan 9.sup.th rod), the increase in the
phenoloxidase activity was detected. However, when plasma fraction
B solution (protein amount: 200 .mu.g) was added by 100 .mu.g of
hemocyte lysate and 1 .mu.g of beta-1,3-glucan (10.sup.th rod), the
phenoloxidase activity was not detected.
[0106] Accordingly, the mixture of plasma fraction B solution and
hemocyte lysate specifically recognized peptidoglycan and showed
phenoloxidase activity. In addition, compared with only the plasma
fraction B solution, the mixture showed the phenoloxidase activity
despite of using a smaller amount of plasma fraction B solution.
Thus, it is possible to detect peptidoglycan with a smaller amount
of plasma fraction by adding the hemocyte lysate to the plasma
fraction.
EXAMPLE 6
Effect of Hemocyte Lysate on Phenoloxidase Activity
[0107] After reaction with 30 .mu.l of each solution of Plasma
fraction B solution of Example 2 (protein amount: 600 .mu.g),
plasma fraction B solution (protein amount: 600
.mu.g)+peptidoglycan (1 .mu.g), plasma fraction B solution (protein
amount: 600 .mu.g)+hemocyte lysate (protein amount: 100 .mu.g),
plasma fraction B solution (protein amount: 600 .mu.g)+hemocyte
lysate (protein amount: 100 .mu.g)+peptidoglycan (1 .mu.g) for 15
minutes, the phenoloxidase activities of the solutions were
determined according to Example 3.
[0108] The phenoloxidase activity was measured on the solution
which was substantially the same as the above solutions except that
the plasma fraction B solution of Example 2 (protein amount: 200
.mu.g) was added by anticoagulant. The result was shown in FIG.
5:
[0109] 1: Plasma fraction B solution (600 .mu.g),
[0110] 2: Plasma fraction B solution (600 .mu.g)+peptidoglycan (1
.mu.g),
[0111] 3: Plasma fraction B solution (600 .mu.g)+hemocyte lysate
(100 .mu.g),
[0112] 4: Plasma fraction B solution (600 .mu.g)+hemocyte lysate
(100 .mu.g)+peptidoglycan (1 .mu.g),
[0113] 5: Plasma fraction B solution (200 .mu.g),
[0114] 6: Plasma fraction B solution (200 .mu.g)+peptidoglycan(1
.mu.g),
[0115] 7: Plasma fraction B solution (200 .mu.g)+hemocyte lysate
(100 .mu.g),
[0116] 8: Plasma fraction B solution (200 .mu.g)+hemocyte lysate
(100 .mu.g)+peptidoglycan (1 .mu.g).
[0117] As a result, while the fraction B solution with protein
amount of 600 .mu.g showed strong phenoloxidase activity on
peptidoglycan (2.sup.rd rod), the fraction B solution with protein
amount of 200 .mu.g showed low phenoloxidase activity on
peptidoglycan (6.sup.th rod). Accordingly, the addition of the
hemocyte lysate (protein amount: 100 .mu.g) to plasma fraction B
solutions increased the phenoloxidase activity. Both the solutions
with protein amount of 600 .mu.g and 200 .mu.g had higher
phenoloxidase activity (4.sup.th and 8.sup.th rods). Accordingly,
it was found that a component contained in hemocyte lysate
activated the phenoloxidase specifically.
EXAMPLE 7
Phenoloxidase Activity of a Composition Comprising Plasma Fraction
B Solution and Hemocyte Lysate
[0118] 30 .mu.l of the solution (protein amount of fraction B: 200
.mu.g, protein amount of hemocyte lysate: 100 .mu.g) containing the
plasma fraction B solution added by anticoagulant buffer solution
(200 .mu.g of protein amount of plasma fraction B) of Example 2,
and the hemocyte lysate prepared in Example 4 was tested for the
phenoloxidase activity on the various concentrations of
peptidoglycan. In order to obtain the standard curve, the
phenoloxidase activity was determined according to the
substantially same method as explained above except that the
concentration of peptidoglycan was 2, 5, 10, or 20 ng/ml.
[0119] 2 ng/ml, 20 ng/ml and 200 ng/ml of the peptidoglycan
solutions were prepared according to the substantially same method
of Example 3, treated with 4-MC/4-HP coloring reaction at
30.degree. C. for 1 hour, and then absorbance at 520 nm was
measured. The result of the experiment was shown in FIG. 6, and the
standard curve was shown in FIG. 7. As shown in FIG. 7, the
correlation constant between the peptidoglycan concentration and
the phenoloxidase activity was 0.98, thereby allowing detection of
even small amount of peptidoglycan.
EXAMPLE 8
Specificity on Peptidoglycan
[0120] To determine whether the plasma fraction B solution of
Example 2 (protein amount: 200 .mu.g) and hemocyte lysate (protein
amount: 100 .mu.g) have a specificity on peptidoglycan, the
phenoloxidase activities on lipopolysaccharide and beta-1,3-glucan
were measured on 30 .mu.l of the plasma fraction B solution of
Example 2 (protein amount: 200 .mu.g) and hemocyte lysate (protein
amount: 100 .mu.g), respectively. 2 ng/ml, 20 ng/ml, and 200 ng/ml
of the substrate solutions containing beta-1,3-glucan were prepared
by suspending beta-1,3-glucan in 20 mM TRIS buffer solution (pH
7.6). 2 ng/ml, 20 ng/ml, and 200 ng/ml of the substrate solutions
containing lipopolysaccharide (LPS) were prepared by suspending
lipopolysaccharide (Sigma Co.) in 20 mM TRIS buffer solution (pH
7.6), and then sonificating for 2-3 minutes. The phenoloxidase
activities were determined using the beta-1,3-glucan solution and
the LPS solution as a substrate according to the method of Example
3. This result was then compared with the experiment where 20 ng/ml
of peptidoglycan and was shown in FIG. 8.
[0121] As a result, 200 ng/ml of LPS and beta-1,3-glucan solution
did not show any phenoloxidase activity despite the reaction time
is increased. Thus, it was found that the phenoloxidase composition
of the present invention could be used for specific detection of
peptidoglycan.
[0122] The present invention makes it possible to quantify even a
small amount of peptidoglycan contained in human blood, tissue,
body fluid, water or food, and to diagnose infection of
microorganism having peptidoglycan as a component of cell wall. In
addition, the composition can be used as a diagnosis reagent for
detecting an infection of Gram-positive bacteria in animal or human
being in advance. Therefore, the composition can be used for
prevention or treatment of food poisoning and Bacterial sepsis.
* * * * *