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Applied and Environmental Microbiology, August 2000, p. 3337-3343, Vol. 66, No. 8
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
A Novel Protein-Deamidating Enzyme from
Chryseobacterium proteolyticum sp. nov., a Newly Isolated
Bacterium from Soil
Shotaro
Yamaguchi* and
Masaaki
Yokoe
Gifu R & D Center, Amano Pharmaceutical Co.,
Ltd., Kagamigahara, Gifu 509-0108, Japan
Received 14 March 2000/Accepted 30 May 2000
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ABSTRACT |
A novel protein-deamidating enzyme, which has potential for
industrial applications, was purified from the culture supernatant of
Chryseobacterium proteolyticum strain 9670T
isolated from rice field soil in Tsukuba, Japan. The deamidating activities on carboxybenzoxy (Cbz)-Gln-Gly and caseins and protease activity were produced synchronously by the isolate. Both deamidating activities were eluted as identical peaks separated from several proteases by phenyl-Sepharose chromatography of the culture
supernatant. The enzyme catalyzed the deamidation of native caseins
with no protease and transglutaminase activities. Phenotypic
characterization and DNA analyses of the isolate were performed to
determine its taxonomy. Physiological and biochemical characteristics,
16S rRNA gene sequence analysis, and DNA-DNA relatedness data indicated that the isolate should be placed as a new species belonging to the
genus Chryseobacterium. The isolate showed no growth on
MacConkey agar and produced acid from sucrose. The levels of DNA-DNA
relatedness between the isolate and other related strains were less
than 17%. The name Chryseobacterium proteolyticum is
proposed for the new species; strain 9670 is the type strain (=FERM
P-17664).
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INTRODUCTION |
An enzyme catalyzing deamidation of
proteins has a great potential for industrial applications. Deamidation
of proteins can improve protein functionalities such as solubility,
emulsification, and foaming and gelation properties, which are desired
properties in some food proteins. Most plant proteins have poor
solubility and functionality under mild acidic conditions, which are
the pH ranges of most food systems, resulting in their limited use in
foods. Because the contents of glutamine residue in plant proteins are
generally high, deamidation of such proteins is one of the most
promising ways to expand their uses and to improve their functionalities. Many studies of the chemical (mild acid or alkaline treatment) or physical (dry heat treatment) deamidation of food proteins had reported and demonstrated the effectiveness of deamidation for improvement of protein functionalities (see reference
25 for review). To avoid unfavorable side effects
brought about by nonenzymatic treatments
for example, concomitant
peptide bond cleavage, off-flavor formation, and amino acid
racemizationenzymatic deamidations of proteins have been examined
(see reference 10 for review). Protease
(16), transglutaminase (23), and
peptidoglutaminase (9) were used for this purpose. None of
their primary reactions were deamidations, or the enzymic substrates
were peptides rather than proteins. Besides the improvement in protein
functionalities, protein-deamidating enzymes could be used for many
applications, including protein structure analysis.
In 1971, Kikuchi et al. (17) found an enzyme,
peptidoglutaminase, from Bacillus circulans that deamidates
the peptide-bound glutamines. This enzyme was not active on
high-molecular-weight peptides, i.e., proteins such as caseins, unless
the proteins were hydrolyzed to short peptides (17). In
plants, the possible presence of protein deamidase in germinating wheat
grains was reported, but the enzyme has not yet been fully purified and
characterized (31).
To obtain a protein-deamidating enzyme of microbial origin, we have
screened microorganisms from soils and successfully isolated a
bacterium that produces the target enzyme. The enzyme deamidated native
caseins without protease and transglutaminase activity. In the present
study, we report the discovery of a novel protein-deamidating enzyme
from a bacterium and the taxonomic determination of the isolate. The
latter led to the proposal of a new species within the genus of
Chryseobacterium.
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MATERIALS AND METHODS |
Bacterial strains.
Two strains, 9670T and 9671, isolated as described below were used. They were maintained on nutrient
agar at 4°C. Type strains of Chryseobacterium gleum JCM
2410T (ATCC 35910T), Chryseobacterium
indologenes IFO 14944T (ATCC 29897T),
Chryseobacterium balustinum IFO15053T (ATCC
33487T), Chryseobacterium meningosepticum IFO
12535T (ATCC 13253T), Empedobacter
brevis IFO 14943T (NCTC 11099T), and
Myroides odoratus IFO 14945T (ATCC
4651T) were used as reference strains for DNA-DNA
hybridization studies.
Isolation of strains.
Water suspensions of 320 soil samples,
collected from natural environments, such as grasslands, gardens, crop
fields, livestock farms, riversides, forests, and dumping grounds in
Tsukuba City, Japan, were inoculated into A medium consisting of 0.1%
carboxybenzoxy (Cbz)-Gln-Gly (Peptide Laboratory, Osaka, Japan), 0.5%
glucose, 0.02% KH2PO4, 0.02%
MgSO4 · 7H2O, 0.01% NaCl, 0.002%
CaCl2, 0.0002% FeSO4 · 7H2O, 0.0005% NaMO4 · 2H2O,
0.0005% NaWO4 · 4H2O, 0.0005% MnSO4 · 4H2O, and 0.01%
CuSO4 · 5H2O (pH 8.0, adjusted with 6N NaOH). The cultures were incubated aerobically at 30°C for 6 days. Fresh A medium was inoculated with a portion of the above cultures and
incubated at 30°C for 3 days. Bacterial and fungal strains were
isolated by plating or streaking a portion of the second culture onto
Luria-Bertani agar (Oxoid, Basingstoke, United Kingdom) for bacteria or
potato-dextrose agar (Difco Laboratories, Detroit, Mich.) for fungi.
Isolated strains were inoculated onto A medium containing 1.5% agar.
Strains grown on the plates were collected and then inoculated into B
medium consisting of 0.5% lactose, 1.0% peptone, 0.17%
Na2HPO4 · H2O, 0.025%
KH2PO4, 0.025% MgSO4 · 7H2O, and 0.005% FeSO4 · 7H2O (pH 7.2, adjusted with 6N NaOH). The cultures were
incubated aerobically at 30°C for a period of from 2 to 7 days.
Culture supernatants were subjected to enzyme assays. Two strains
showing higher protein-deamidating activity were selected and purified
by repeated streaking on the nutrient agar medium.
Enzyme assays.
For deamidating activity, 100 µl of
substrate solution containing 10 mM Cbz-Gln-Gly or 1.0% caseins
(Hammersten, Merk, Poole, United Kingdom), 175.6 mM sodium phosphate
buffer (pH 6.5), and 10 µl of enzyme solution were mixed and then
incubated at 37°C for 60 min. The reaction was stopped by the
addition of 100 µl of 12% trichloroacetic acid. For blank assays,
enzyme solution was added after addition of trichloroacetic acid. After
centrifugation at 18,000 × g for 5 min, released
ammonia in the supernatant was determined by an NADH-glutamate
dehydrogenase method (21) with an ammonia determination kit
according to the manufacturer's instructions (Boehringer-Mannheim/Roche Diagnostics, Lewes, United Kingdom). One
unit of enzyme was defined as the amount that released 1 µmol of
ammonia per min under the above conditions. Ammonia was also determined
by a phenol method for screening study. In this case, 10 µl of the
supernatant was mixed with 100 µl of 1.0% phenol-0.005% sodium
nitroprusside, and then 100 µl of 0.5% NaOH-0.6% NaOCl was added.
After 60 min, the A630 of the mixture was
measured. For protease activity, the A280 was
measured in the supernatant from the above deamidating activity assay
when casein was used as a substrate. One unit of protease activity was
defined as the amount that caused an increase of 1 optical density unit
at 280 nm (OD280) per 60 min under the above conditions.
Transglutaminase activity was assayed by a hydroxamate method according
to Folk and Chung (5).
Partial purification of protein-deamidating enzyme.
A
preculture of strain 9670T in B medium grown at 25°C
overnight was inoculated into the same medium at a 1.0% concentration of preculture. The culture was incubated at 25°C with reciprocal shaking at 145 rpm for 48 h for a culture profile study or 24 h for enzyme purification. The culture broth was centrifuged at 22,200 × g for 15 min at 4°C. After addition of 2 mM
EDTA, the supernatant was concentrated eightfold by ultrafiltration
with a hollow-fiber-type membrane (AIP1010, MW 6000 cut; Asahi Chemical Industry, Tokyo, Japan). After dialysis of the concentrate against 2.0 M NaCl in 10 mM sodium phosphate (pH 6.5), the dialysate was centrifuged at 2,200 × g for 10 min at 4°C and
filtered through a 0.45-µm-pore-diameter membrane in order to remove
the insoluble materials. The resultant filtrate was applied to a
phenyl-Sepharose High Performance Hiload 16/10 column (Amersham
Pharmacia Biotech, Uppsala, Sweden) preequilibrated with 2.0 M NaCl in
10 mM sodium phosphate buffer (pH 6.5). The column was washed with two
column volumes of 2.0 M NaCl in 10 mM sodium phosphate (pH 6.5), and absorbed proteins were eluted by an NaCl gradient from 2.0 to 0 M in 88 ml of 10 mM sodium phosphate buffer (pH 6.5). The elution was followed
with 10 mM sodium phosphate buffer (pH 6.5). The chromatography was
carried out with a fast-performance liquid chromatography (FPLC) system
(Amersham Pharmacia Biotech) with all flow rates at 1.0 ml/min.
SDS-PAGE.
Sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) was performed by the method of Laemmli
(20) using a 10 to 20% polyacrylamide gradient gel
(Multigel; Daiichi Pure Chemicals, Tokyo, Japan). Proteins were silver
stained with a kit from Wako Pure Chemicals, Osaka, Japan. Molecular
weight markers were obtained from Daiichi Pure Chemicals.
Determination of phenotypic characteristics.
Morphological
and cultural characteristics were observed on nutrient agar (Eiken,
Tokyo, Japan) and Trypto-Soy agar (Eiken). The pH range for growth was
determined in nutrient broth (Difco) filtered through a
0.45-µm-pore-diameter membrane after adjustment to various pHs with
HCl or NaOH. The cells grown on Trypto-Soy agar at 30°C were recorded
by scanning electron microscopy. Physiological and biochemical
characteristics were determined according to reference 1 and Yabuuchi et al. (35). Hydrolyses of
DNA, gelatin, and esculin were examined with DNA test agar (Difco),
heart infusion broth (Difco) containing 12% gelatin, and a medium
consisting of 1% Bacto Peptone (Difco), 0.5% NaCl, 0.05% ferric
citrate, and 0.1% esculin, respectively. Indole production was tested
by using 2% tryptone (Difco) broth and Kovacs reagent (7).
Urease activities, nitrate reduction, and malonate utilization were
examined by using Christensen urease test agar (Eiken), nutrient broth (Eiken) containing 0.1% potassium nitrate, and malonate-phenylalanine medium (Kyokuto, Tokyo, Japan), respectively. MacConkey agar was from
Eiken. Acid and gas formations from sugar were examined by using
ammonia salt-sugar medium [0.1%
(NH4)2HPO4, 0.02% KCl, 0.02% MgSO4 · 7H2O, 0.02% yeast extract,
1.5% agar, 0.002% bromcresol purple] and O-F basal medium (Difco)
containing 1% of each sugar. Flexirubin-type pigment was detected
according to the method of Yabuuchi et al. (35).
16S rRNA gene sequencing and analysis.
Isolation of genomic
DNA, PCR-mediated amplification of 16S rRNA gene, and purification and
sequencing of the PCR product were performed according to the method of
Shida et al. (28). Oligonucleotide primers
5'-CTGGGATCCATTTACTCGAGAGTTTGATCCTGGCTCAG-3' (5' end of the
16S rRNA gene) and 5'-GGTTCCCCTAAGCTTACCTTGTTACGACTTC-3' (3'
end of the 16S rRNA gene) were used for PCR amplification of the 16S
rRNA gene as described by Shida et al. (27). The amplified
16S gene was purified with a QIAquick spin PCR purification kit (Qiagen
GmbH, Hilden, Germany) and then used as a sequencing template. Seven
sequencing primers were used as described by Fox et al. (6).
The sequence determined was compared with 16S rRNA gene sequences
obtained from the EMBL, GenBank, and DDBJ databases. Multiple alignment
of sequences, calculation of nucleotide substitution rates
(Knuc values) (18), construction of a
neighbor-joining phylogenetic tree (26), and a bootstrap
analysis with 1,000 replicates for evaluation of phylogenetic tree
topology (4) were performed with the CLUSTAL W version 1.5 program (30).
DNA base composition and DNA-DNA hybridization.
The G + C content of the DNA was determined by the method of Tamaoka and
Komagata (29). Levels of DNA-DNA relatedness were determined
fluorometrically by the method of Esaki et al. (3) with
photobiotin-labeled DNA probes and microplates.
Nucleotide sequence accession number.
The nucleotide
sequence data of the 16S rRNA gene of strain 9670T have
been deposited in the DDBJ, EMBL, and GenBank nucleotide sequence
databases under accession no. AB039830.
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RESULTS |
Isolation of bacterial strains.
Repeated liquid cultures and
subsequent plate culture using Cbz-Gln-Gly as the sole nitrogen source
were used to enrich for protein-deamidating enzyme producers from
soils. From 320 soil samples, 150 bacteria and 294 fungi were isolated
and examined for protein-deamidating enzyme productivity in their
culture supernatants. Among positive isolates, two bacteria showed
significantly higher activities of deamidation of both Z-Gln-Gly and
caseins. These isolates, designated as strains 9670T and
9671, originated from soils of a rice field and the bank of a brook,
respectively, and were used for the following studies.
Culture profile of the isolates.
Figure
1 shows the culture profile of strain
9670T. A similar profile was obtained for strain 9671. At
the late exponential growth phase (16-h culture), deamidating
activities on both Cbz-Gln-Gly and caseins began to be produced
significantly and simultaneously. Protease activity was also produced,
accompanied by the deamidating activities. The pH of the culture broth
began to rise at the same time with increasing ammonia produced, which
might be released from peptone contained in the medium by the
deamidating activities. Maximum deamidating activities were observed at
24 h of culture with 0.258 U/ml on Cbz-Gln-Gly and 0.228 U/ml on
caseins. The enzyme productivities of strain 9671 were lower than those
of strain 9670T by ca. 30%.
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FIG. 1.
Culture profile of strain 9670T. Culture
conditions were described in Materials and Methods. Cell growth (×) in
liquid culture was monitored by measuring the OD660.
Ammonia ( ) was determined by the NADH-glutamate dehydrogenase
method. Deamidating activities were determined on Cbz-Gln-Gly ( ) and
casein ( ). Protease activity ( ) was also determined.
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Partial purification of the protein-deamidating enzyme.
Although ammonia-releasing activity from caseins was observed in the
culture supernatants of the isolate, it was necessary to confirm
whether the enzyme deamidated high-molecular-weight peptides, i.e.,
proteins, or merely deamidated short peptides produced by the protease
activity. For this purpose, we tried to purify the deamidating activity
from the culture supernatant of strain 9670T. After trials
of several kinds of chromatography and conditions, including
ion-exchange chromatography, gel filtration, and chromatofocusing, it
was found that hydrophobic chromatography on a phenyl-Sepharose column
successfully resulted in the separation of deamidating activities from
protease activities. The ultrafiltration and dialysis procedure
described in Materials and Methods had also contributed to the removal
of most of the protease activity (ca. 98%). At around 0.2 M NaCl in
its gradient (elution volume of 113 ml), both deamidating activities on
caseins and Cbz-Gln-Gly were eluted as identical peaks separated from
several protease peaks (Fig. 2). A minor
peak of deamidating activities was observed in the unabsorbed fraction
(elution volume of 25 ml) with crossover by protease peaks. The main
fraction for the deamidating enzyme at an elution volume of 113 ml was
used in the following study. Protease activity in this fraction was
less than the level of the minimal detection limit (<0.003 U/ml).
Analysis by SDS-PAGE indicated this fraction contained a main protein
band of 20 kDa with several minor protein bands.
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FIG. 2.
Phenyl-Sepharose chromatography of the culture
supernatant of strain 9670T. Eluted proteins ( ) were
monitored by the OD280. Both deamidating activities on
Cbz-Gln-Gly () and casein () were determined by the phenol method
and expressed as the OD630. Protease activity () was
also determined.
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Evidence of protein-deamidating enzyme.
To confirm that the
enzyme can deamidate high-molecular-weight proteins, caseins were
incubated with the above enzyme fraction for 16.5 h at 37°C, and
the products were subjected to SDS-PAGE. As shown in Fig.
3, casein treated with the deamidating
enzyme fraction was scarcely degraded (lane 4), compared to the control casein treated without enzyme (lane 2), whereas casein was completely hydrolyzed by the culture supernatant which contains proteolytic activities besides the deamidating activity (lane 3). Ammonia released
in these reaction mixtures was also determined and found to be at
concentrations of 7.12, 0.02, and 8.04 mM in the reaction mixture with
the deamidating enzyme, control casein mixture, and the reaction
mixture with the culture supernatant, respectively. Provided an average
molar content of amido-containing amino acid residues, Gln and Asn, in
caseins of 26.8 mol/mol of protein and assuming an average molecular
weight of casein of 23,261, which were calculated based on the numbers
of both amino acids in four casein components (
S1-,
S2-, 
-, and 
-caseins) and the relative content of
each component in the casein preparation (34), the deamidation degree (millimolar ammonia released/millimolar total amido
content in the substrate casein] × 100) was estimated as 62.0% for
the reaction product by the deamidating enzyme fraction. These results
imply that the casein treated by the deamidating enzyme fraction was
deamidated in a high-molecular-weight state, not in a small-peptide
state (i.e., not after degradation). It can be concluded, therefore,
that the deamidating enzyme fractionated from the culture supernatant
of strain 9670T can deamidate high-molecular-weight
proteins (caseins).
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FIG. 3.
SDS-PAGE of the caseins treated by the
protein-deamidating enzyme fraction. Reaction conditions were the same
as those in the casein-deamidating activity assay described in
Materials and Methods, except for the reaction time (16.5 h). Lanes: 1, molecular mass markers; 2, control casein incubated with water (without
enzyme); 3, reaction product treated by the culture supernatant; 4, reaction product treated by the protein-deamidating enzyme fraction.
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Slow migrations of protein bands in the casein treated with the
deamidating enzyme fraction were observed (Fig.
3, lane 4
as compared
to lane 2). Such slow migration on SDS-PAGE was reported
for chemically
deamidated gluten (
2). This phenomenon might
be considered
to be caused by the increased negative charge in
the deamidated
protein, which should decrease the affinity between
the protein and the
negatively charged SDS molecule due to an
electrostatic repulsion and
then decrease the total negative charge
of the protein-SDS
complex.
The deamidating enzyme fraction had no transglutaminase activity, as
measured by hydroxamate formation between Cbz-Gln-Gly
and
hydroxylamine, which is a common characteristic of transglutaminase.
Furthermore, no formation of higher-molecular-weight, cross-linking
products was observed in the reaction products of caseins by the
deamidating enzyme fraction, as judged by SDS-PAGE (Fig.
3, lane
4 compared to lane 2). Casein is one of the best substrates for
transglutaminase-catalyzed protein cross-linking, and the cross-linked
products of casein can be easily detected by SDS-PAGE. The deamidating
enzyme from strain 9670
T therefore could be distinguished
from
transglutaminase.
Phenotypic characteristics.
Strains 9670T and 9671 showed the same morphological and physiological characteristics. They
were rod-shaped, nonmotile, and nonsporing. Gram staining was negative.
The cells were 0.4 to 0.5 µm wide and 0.8 to 2.0 µm long (Fig.
4). They were aerobic and positive for
oxidase and catalase, producing an insoluble yellow or orange pigment,
which turned red with 3% KOH and returned to orange by neutralization,
indicating a flexirubin type of pigment.
Phenotypic characterization of the isolates indicated that they were
included in the genus
Chryseobacterium, which belongs
to the
family
Flavobacteriaceae. Differential characteristics
were
reported among seven genera of
Flavobacteriaceae, including
the genera
Chryseobacterium,
Flavobacterium,
Empedobacter,
Weeksella,
Bergeyella,
Riemerella (
33), and
Myroides
(
32). Except for
the acid-forming property from sucrose, all
other properties of
the isolates matched those of
Chryseobacterium. In the genus
Chryseobacterium,
six species (
C. gleum,
C. indologenes,
C. balustinum,
C. indoltheticum,
C. meningosepticum, and
C. scophthalmum) are recognized at
present.
Besides acid formation from sucrose, the new isolates were
distinguished
from these six existing species: acid formation from
mannitol
and growth on MacConkey agar for
C. gleum; malonate
utilization
for
C. indologenes, G+C content, acid formation
from mannitol,
growth at 36 to 37°C, and growth on MacConkey agar for
C. balustinum;
G+C content, acid formation from mannitol,
and growth on MacConkey
agar for
C. indoltheticum; growth on
MacConkey agar for
C. meningosepticum;
and acid formation
from glucose and mannitol, growth at 36 to
37°C, urease activity, and
indole production for
C. scophthalmum (Table
1). These results indicated that the new
isolates should
be placed as a new species in the genus
Chryseobacterium.
16S rRNA gene sequence and phylogenetic analysis.
The
determined 16S rRNA sequence of strain 9670T showed higher
similarities to those of a group consisting of several
Chryseobacterium strains with 96.0, 95.9, 95.1, and 94.9%
similarity to C. gleum, C. indologenes, C. balustinum, and C. indoltheticum, respectively. A
recent published sequence of the 16S rRNA gene from
Chryseobacterium sp. (22) showed 95.1%
similarity to that of the strain 9670T. A second group
consisted of Riemerella anatipestifer, Bergerella zoohelicom, and C. meningosepticum, with 92.2 to 93.5%
similarities. Other related strains, such as Weeksella
virosa, Empedobacter brevis, Flavobacterium
aquatile, and Myroides odoratus, had 83.6 to 87.1%
similarities. A phylogenetic tree constructed by the neighbor-joining
method showed that strain 9670T exists as an independent
branch within the above-mentioned group having higher sequence
similarities (Fig. 5). The bootstrap
analysis resulted in relatively high values of more than 75% for all
of the branches within this group.
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FIG. 5.
Phylogenetic position of strain 9670T within
the genus Chryseobacterium and the allied bacteria. The
branching pattern was generated by the neighbor-joining method. The
accession numbers of the 16S rRNA nucleotide sequences used are
indicated in parentheses. The 16S rRNA sequence of
Chryseobacterium sp. was obtained from reference
22. The number at each branch indicates the
bootstrap values. Bar, 0.02 nucleotide substitutions per site.
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DNA base composition and DNA-DNA hybridization.
The G+C
content of strains 9670T and 9671 was 37.1 mol%. The
levels of DNA-DNA relatedness were estimated by using these two strains, four type strains from Chryseobacterium (C. balustinum, C. gleum, C. indologenes, and
C. meningosepticum), and two other related type strains
(Empedobacter brevis and Myroides odoratus) (Table 2). The DNA-DNA relatedness value
between strains 9670T and 9671 was 94%. Low values (14 to
17%) of relatedness were observed between the new isolates and three
strains, C. gleum, C. indologenes, and C. balustinum, which showed higher similarities in 16S rRNA gene
sequences to strain 9760T. The values for strain
9670T to three other strains, C. meningosepticum, E. brevis, and F. odoratus,
were only 8 or 7, 4 and 3%, respectively. A relatively higher value
(31%) in this analysis was observed between C. gleum and
C. indologenes. All of these results supported the
phylogenetic tree illustrated from 16S rRNA gene sequence analysis
(Fig. 5).
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DISCUSSION |
Protein-deamidating activity was found in the culture supernatant
of a newly isolated bacterium, strain 9670T. Both
Cbz-Gln-Gly- and casein-deamidating activities and protease activity
were produced synchronously during the course of culture. The
deamidating enzyme was separated from proteases by phenyl-Sepharose chromatography. Native caseins were not degraded by the enzyme, while
more than 60% of amido groups in caseins were estimated to be
deamidated, indicating that the enzyme can deamidate
high-molecular-weight peptides (i.e., proteins) in the native state.
The enzyme from strain 9670T is the first
protein-deamidating enzyme of microbial origin. From the industrial
point of view, the microbial protein-deamidating enzyme has great
significance, because it opens the way to mass production of such an
enzyme, which will find many applications.
Two peptidoglutaminases that catalyze the deamidation of peptide-bound
glutamine residues have been found in Bacillus circulans: peptidoglutaminase I (EC 3.5.1.43), which deamidates the
-carboxyamido group of C-terminal glutamine residue; and
peptidoglutaminase II (EC 3.5.1.44), which deamidates the
-carboxyamido groups of N-terminal and internal glutaminyl residues.
Both enzymes, however, cannot deamidate caseins unless the caseins are
prehydrolyzed (17). Gill et al. (8) reported that
peptidoglutaminases are not active against caseins and whey proteins
even after denaturation and are only active against glutaminyl residues
in peptides with a molecular weight below 5,000. Hamada (9)
reported slight enhancements of peptidoglutaminase-catalyzed protein
deamidation using heat- and/or alkaline-treated proteins, but the
degrees of deamidation were very low (0.8 to 3.0% for caseins)
compared to those for the preparations treated by the combinations with proteolysis (ca. 38%).
Transglutaminase (EC 2.3.2.13) is an enzyme with a wide distribution
ranging from mammals to microorganisms. The enzyme catalyzes the acyl
transfer reaction in which the -carboxyamido groups of glutaminyl
residue in proteins or peptides are the acyl donor. A variety of
amines, including lysyl residues of proteins, can act as acyl
acceptors. When lysyl residues of protein act as acyl acceptors,
cross-linked products with higher molecular weights are formed through
intermolecular isopeptide bonding. In the absence of amines in the
reaction system, water can act as an acyl acceptor, resulting in the
deamidation of glutaminyl residues in proteins. The protein-deamidating
enzyme from strain 9670T was distinguished from
transglutaminase, because no transglutaminase activities were detected
based on the lack of hydroxyamate formation and lack of cross-linked
product formation from caseins.
The physiological role of the protein-deamidating enzyme produced by
the microorganism is unknown. In germinating seeds in plants,
deamidations of storage proteins preceeding their proteolytic degradation were observed, and the possible involvement of a
protein-deamidating enzyme in this process has been pointed out
(31). Observed simultaneous expressions of the
protein-deamidating enzyme and proteases into a culture medium by
strain 9670T (Fig. 1) may suggest the involvement of a
protein-deamidating enzyme in the degradation process of proteins to be
utilized as energy or nutritional sources in cooperation with
proteases. It was reported that proteins isolated from germinated seed,
which were deamidated and conformationally changed, had an increased susceptibility to proteolytic digestion (19).
Two strains, 9670T and 9671, were isolated from soils in
natural environments of the Tsukuba area, Japan, as producers of the protein-deamidating enzyme. Phenotypic characterization, 16S rRNA sequencing, and DNA-DNA hybridization studies indicated the isolates belonged to a new species in the genus Chryseobacterium. The
genus Chryseobacterium is an emended one for some strains
originally isolated as "Flavobacterium-like bacteria."
In 1994, Vandamme et al. (33) proposed that six strains
(F. gleum, F. indologenes, F. balustinum, F. indoltheticum, F. meningosepticum, and F. scophthalmum) should be given a
new separate status based on the previously reported phenotypic and
chemotaxonomic features as well as rRNA cluster analysis, and they
coined a new name, Chryseobacterium, for these strains. The
well-characterized species C. gleum (11) was
selected as the type species of this genus. They pointed out that
C. meningosepticum, well known as a pathogenic strain, had the most aberrant features within this genus. In this study, we recognized the newly isolated strains should be placed in the genus
Chryseobacterium based on the results from both phenotypic and DNA analyses (DNA-DNA hybridization and 16S rRNA sequencing). DNA
analyses also indicated that the isolates were closely related to a
group of Chryseobacterium species, except for C. meningosepticum.
The strains belonging to Chryseobacterium have been isolated
from various ecosystems, such as water, soils, fish, marine
environments, and clinical specimens. Many bacteria isolated from food
environments, such as milk and butter (15), were recently
recognized as members of the genus Chryseobacterium
(12, 13). More recently, an isolate from fish was determined
as a strain belonging to the genus by 16S rRNA analysis
(22). The isolates we studied here were from soils of a rice
field and the bank of a brook in Japan. These recent reports suggest a
wide distribution of Chryseobacterium strains in various
natural environments, although early studies of the taxonomy of
"Flavobacterium-like bacteria," some of which are
presently placed in Chryseobacterium, had been mainly
focused on clinical strains. The new isolates reported here produced
highly proteolytic activities. This characteristic was also mentioned for some Chryseobacterium strains (originally isolated as
flavobacteria) from dairy foods (14).
We propose a new species with the name Chryseobacterium
proteolyticum sp. nov. Strain 9670 was designated the type strain of Chryseobacterium proteolyticum. A description of the new
species is given below.
Description of Chryseobacterium proteolyticum sp. nov.
Chryseobacterium proteolyticum (pro.te.o.ly'ti.cum. Gr. n.
proteo; Gr. adj. lyticus, dissolving; M.L. neut.
adj. proteolyticum, protein dissolving, proteolytic). Cells
are gram-negative, nonsporeforming, and nonmotile rods (0.4 to 0.5 by
0.8 to 2.0 µm). Circular, orange or light-pinkish cream colonies are
formed on nutrient agar at 30°C for 2 days. Yellow or orange
insoluble, flexirubin-type pigment is produced. The organism shows
growth at 37°C but not at 42°C. The pH range for growth is from 5 to 9 and that for optimal growth is 6 to 8. Growth occurs aerobically,
not anaerobically. No growth is observed on MacConkey agar. Catalase
and cytochrome oxidase reactions are positive, but urease negative. The
organism is positive for indole production, weakly positive for
H2S formation, but negative for malonate utilization,
nitrate reduction, denitrification, 3-ketolactose formation, and the
Voges-Proskauer test. Lysine decarboxylase, arginine dihydrase,
ornithine decarboxylase, and phenylalanine deaminase are negative.
Hydrolyses of esculin, Tween 80, starch, tyrosine, casein, gelatin,
DNA, and o-nitrophenyl--D-galactopyranoside are positive. The organism produces acid from L-arabinose,
D-glucose, maltose, sucrose, trehalose, and soluble starch;
produces acid weakly from glycerol and mannitol; and does not produce
acid from adonitol, cellobiose, ethanol, inositol, inulin, lactose,
raffinose, rhamnose, or salicin. The G + C content of the DNA
is 37.1 mol% (determined by high-performance liquid chromatography).
Strains 9670T and 9671 were obtained from soil samples from
Tsukuba, Ibaraki, Japan. The type strain, 9670, has been deposited in
the Patent Microorganism Depository, National Institute of Bioscience
and Human Technology (Tsukuba, Japan), as strain FERM P-17664. The strain will be made available for research.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute of
Food Research, Norwich Research Park, Colney, Norwich NR4 7UA, United Kingdom. Phone: 44-1603-255000. Fax: 44-1603-507723. E-mail:
LDV01447{at}nifty.ne.jp.
| |
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Applied and Environmental Microbiology, August 2000, p. 3337-3343, Vol. 66, No. 8
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Abstract
Introduction
