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Applied and Environmental Microbiology, August 1998, p. 2875-2881, Vol. 64, No. 8
School of Microbiological, Immunological, and
Virological Sciences, The Medical School, University of Newcastle
upon Tyne, Newcastle upon Tyne, NE2 4HH, United Kingdom
Received 20 January 1998/Accepted 1 June 1998
AmyL, an extracellular The cell envelope of the
gram-positive bacterium Bacillus subtilis consists of a
single (cytoplasmic) membrane surrounded by a relatively thick cell
wall consisting of similar proportions of peptidoglycan and covalently
attached anionic polymers. The absence of an outer membrane means that
there is no equivalent of the membrane-enclosed periplasm found in
gram-negative bacteria. However, by virtue of its thickness and high
density of negative charge, the cell wall may perform some of the roles
of the periplasm in gram-positive bacteria.
The absence of an outer membrane in gram-positive bacteria also
simplifies the secretion pathway, and, consequently, B. subtilis and its close relatives have the potential to secrete
proteins directly into the growth medium, at concentrations in excess
of 5 grams per liter (4). Despite its extensive use in the
production of commercially important Bacillus enzymes (e.g.,
Although strains deficient in extracellular proteases have improved the
productivity of B. subtilis for the production of heterologous proteins, they have only partially overcome problems of
unexpectedly low yields. We and others have recently shown (22,
31) that significant amounts of secretory protein are degraded
within minutes of being synthesized. This degradation is observed even
for Bacillus proteins that are highly resistant to proteases
released into the culture medium, suggesting that a component of this
degradation is cell associated.
Margot and Karamata recently reported the identification of a
cell-wall-associated protease encoded by the wprA gene
(21). The primary product of this gene is a 96-kDa
polypeptide that is processed into two previously identified cell wall
proteins, namely, CWBP52 and CWBP23. The processing of the WprA
precursor during secretion accompanies the targeting of
CWBP52 and CWBP23 to the cell wall and is analagous to the processing
of another B. subtilis cell-wall-bound protein,
namely, WapA (5). The amino acid sequence of CWBP52
shows a high degree of similarity with serine proteases of the
subtilisin family, and phenylmethylsulfonile fluoride (PMSF)-sensitive
protease activity was detected in proteins extracted from the cell wall
of a wprA+ strain, but not one in which this
gene had been insertionally inactivated (21). In the absence
of homology to proteins in the databases, the N-terminal CWBP23 moiety
was presumed to function as a chaperone-like propeptide that is
proteolytically processed on the trans side of the membrane.
In this paper, we report on a potential role of products of
wprA in the integrity of secretory proteins during late
stages in the secretion pathway. We also discuss the potential of
wprA mutants to increase the productivity of B. subtilis for secretory proteins.
Bacterial strains, plasmids, and growth conditions.
The
bacterial strains and plasmids used in this study are listed in Table
1. In general, the bacterial strains were
grown in 2xYT medium (1.6% [wt/vol] tryptone, 1% [wt/vol] yeast
extract, 0.5% NaCl), which was supplemented as required with
chloramphenicol (6 µg/ml), erythromycin (1 µg/ml), lincomycin
(25 µg/ml), or ampicillin (100 µg/ml). Spizizen's minimal salts
(SMS) (29) with 1% (wt/vol) ribose as a
non-catabolite-repressing carbon source was used for pulse-chase
experiments.
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Influence of a Cell-Wall-Associated Protease on
Production of
-Amylase by Bacillus subtilis
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
-amylase from Bacillus
licheniformis, is resistant to extracellular proteases secreted
by Bacillus subtilis during growth. Nevertheless, when AmyL
is produced and secreted by B. subtilis, it is subject
to considerable cell-associated proteolysis. Cell-wall-bound proteins
CWBP52 and CWBP23 are the processed products of the B. subtilis wprA gene. Although no activity has been ascribed to
CWBP23, CWBP52 exhibits serine protease activity. Using a
strain encoding an inducible wprA gene, we show that a product of wprA, most likely CWBP52, is involved in the
posttranslocational stability of AmyL. A construct in which
wprA is not expressed exhibits an increased yield of
-amylase. The potential role of wprA in protein
secretion is discussed, together with implications for the use of
B. subtilis and related bacteria as hosts for the secretion of heterologous proteins.
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
-amylases and alkaline proteases), attempts to exploit B. subtilis for the production of heterologous proteins at high
concentrations have proved disappointing (8). One reason for
this failure is the production and release into the culture medium of
several extracellular proteases (24, 28, 37). Although
native Bacillus proteins are generally resistant to these
proteases, heterologous proteins are often rapidly degraded in their
presence. As a result, strains of B. subtilis that are multiply deficient in extracellular proteases have been developed (11, 37). The more developed of these strains have less than 1% of the proteolytic activity of the wild type (37). To
date, efforts have concentrated mainly on the proteases which reside in
a truly extracellular location, while those which remain cell associated have been largely overlooked.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
TABLE 1.
Bacterial strains and plasmids
-amylase from Bacillus licheniformis (AmyL) was expressed in B. subtilis during exponential phase
with a xylose-inducible promoter system developed by Novo Nordisk A/S
(9, 10, 31), and xylose (1% [wt/vol]) was included in the
growth medium to induce the synthesis of -amylase when required. To
avoid problems associated with plasmid instability (2, 7),
the xylose-inducible amyL cassette was integrated into the
chromosome of the -amylase (AmyE)-negative B. subtilis strain DN1885 by a Campbell-type recombination between
plasmid and chromosomally encoded xylR genes
(31).
Medium and reagents. The medium used in this study was purchased from Difco Laboratories Ltd. (East Molesley, United Kingdom). Other reagents were obtained from Sigma (Poole, United Kingdom).
Quantitation of -amylase activity.
Overnight cultures
were used to inoculate 20 ml of 2xYT-xylose broth, which was incubated
at 37°C with shaking. Samples were centrifuged (10,000 × g, 5 min, room temperature) to pellet the cells, and the
-amylase activity in the supernatant was quantified with a
scaled-down version of the Phadebas assay (Pharmacia Diagnostics, Uppsala, Sweden), according to the manufacturer's protocol. In all
cases, multiple samples were used for the Phadebas assay to calculate a
mean value for -amylase activity. One unit of -amylase activity
was defined as the amount of enzyme catalyzing the hydrolysis of 1 µmol of glycosidic linkage per min at 37°C.
Stability of AmyL in culture supernatants.
Cultures were
grown for 48 h in 20 ml of 2xYT-xylose broth to allow the
accumulation of -amylase and extracellular proteases in the
medium. The cells were removed by centrifugation (10,000 × g, 30 min, 4°C), and the supernatants were filtered
(0.45-µm-pore-size Acrodisc-32 filters; Gelman Sciences) to ensure
the complete removal of cellular material. Cell-free supernatants were
incubated at 4°C in the presence or absence of 10 mM EDTA, and
samples were removed at intervals for determinations of -amylase
activity and Western blotting.
DNA manipulations and PCR. Restriction enzymes and Pfu DNA polymerase were obtained from Promega. All DNA manipulations were carried out according to standard protocols (27). DNA fragments were purified from agarose gels with Qiaquick columns (Qiagen Limited, Dorking, United Kingdom), and plasmids were isolated from Escherichia coli with Qiatip-100 columns (Qiagen Limited). B. subtilis DN1885 was transformed with integration plasmids after the induction of natural competence (1).
A DNA fragment corresponding to the 5' end of the wprA gene was PCR amplified with oligonucleotide primers WPR-F (5'-GCGCGCGCGGATCCGGGATAACATGAAACGC-3') and WPR-R (5'-GCGCGCGCGGATCCCCATCCTCCGCTGTG-3'). These primers were designed with 5' extensions to introduce BamHI restriction sites into the ends of the PCR product to facilitate cloning.SDS-PAGE and Western blotting.
Sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was carried out
as described previously (17) with 10% (wt/vol) or 12.5%
(wt/vol) gels. For Western blotting, proteins were transferred from
SDS-PAGE gels (34) onto cellulose nitrate membranes
(0.4-µm pore size; Anderman Ltd., Kingston upon Thames, United
Kingdom). Bands corresponding to -amylase were detected with rabbit
anti-AmyL polyclonal antiserum and anti-rabbit-horseradish peroxidase
conjugate (Dako Immunochemicals A/S, Glostrup, Denmark).
Pulse-chase and immunoprecipitation.
Cultures were grown in
SMS-ribose-xylose to an optical density at 660 nm (OD660)
of approximately 0.8, at which stage the cells were in exponential
phase. Cells (15 ml) were pulse-labeled for 1 min with 10 µl of
L-[35S]methionine (561 kBq/µl; Amersham
International plc) as described previously (36). Following
dilution of the L-[35S]methionine with
unlabeled methionine (25 mg/ml), the proteins (cells plus growth
medium) were precipitated with ice-cold trichloroacetic acid (TCA; 10%
[wt/vol]). -Amylase was immunoprecipitated with anti-AmyL
antiserum. Proteins released into the culture medium were precipitated
with TCA after removal of the cells by filtration through
polyrinylidene difluoride filters (0.45-µm pore size; Whatman
Limited, Maidstone, United Kingdom). -Amylase was again recovered by
immunoprecipitation with anti-AmyL antiserum.
-amylase was determined by phosphorimaging (PhosphorImager; Molecular Dynamics) and were analyzed with ImageQuant software (version 3.22; Molecular Dynamics).
-Galactosidase assay.
Cultures (20 ml) were grown at
37°C in 2x YT broth. Samples were removed for the determination of
OD660 and -galactosidase activity, with the latter
expressed in Miller units as described previously (23).
Extraction of proteins from B. subtilis cell walls. Cultures (1 liter each) of B. subtilis KS408 and KS408 wprA::pMutin2 were grown for 15 h at 37°C in 2xYT-xylose broth with shaking. The cells were pelleted by centrifugation (11,000 × g, 4°C, 10 min) and washed twice with ice-cold 50 mM Tris-HCl (pH 7.5; 40 ml). The washed cells were resuspended in 40 ml of the same buffer, PMSF was added to a final concentration of 0.5 mM, and the cells were broken by passing the suspension three times through a French pressure cell (Aminco) at 4°C. Cell walls were sedimented by centrifugation (27,000 × g, 4°C, 30 min) and washed twice with Tris-HCl. The cell walls were then washed twice with ice-cold 100 mM NaCl (40 ml) to remove loosely associated proteins, followed by three further washes with Tris-HCl. Proteins were then extracted from cell walls by resuspension in 2× SDS-PAGE sample buffer and boiling for 5 min. The extracted proteins were analyzed by SDS-PAGE on 12.5% (wt/vol) gels with Coomassie blue staining.
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RESULTS |
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Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Stability of AmyL in spent culture medium.
During the
transition from exponential to stationary phase, B. subtilis secretes a battery of extracellular enzymes into the culture medium, including several proteases (24, 25).
Therefore, we determined the stability of mature AmyL in spent culture
medium following growth of B. subtilis KS408 to
stationary phase. In its native conformation, AmyL was stable in the
presence of cosecreted proteases over an incubation time of nearly
300 h, as indicated by only a slight reduction in -amylase
activity (Fig. 1A).
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) or presence
(
) of 10 mM EDTA; (B) Western blotting of AmyL in spent culture
medium at time intervals in the absence or presence of 10 mM EDTA.
-Amylases display a common requirement for Ca2+ ions
which are necessary for both enzymatic activity and structural
integrity. -Amylase preparations from which Ca2+ ions
have been removed become highly susceptible to proteolysis (19,
30, 35). When AmyL was incubated in spent culture medium in the
presence of the metal ion chelator EDTA, the enzyme became sensitive to
proteolysis, as indicated by a marked reduction in -amylase activity
with time (Fig. 1A). Western blotting confirmed that the loss of
-amylase activity in the presence of EDTA was due to proteolytic
degradation, rather than irreversible inactivation of enzyme activity,
since the amount of a cross-reacting band at 56 kDa (AmyL) decreases
with time and a number of major putative degradation products were
visualized (Fig. 1B). The data presented show the extent of proteolysis
at 4°C, since the rate of loss of activity at 37°C in the absence
of free Ca2+ ions was too rapid (>95% in 5 min) to be
determined with precision.
Construction of an inducible wprA gene. Despite its stability in the presence of extracellular proteases (Fig. 1), newly synthesized AmyL is subjected to substantial degradation (31). Since AmyL is stable in the growth medium, the protease(s) responsible for this degradation is likely to be cell associated and localized at the cytoplasmic membrane as lipoprotein with its activity on the trans side and/or immobilized in the matrix of the cell wall. In either case, the protease(s) would have access to secretory proteins emerging from the translocation complex. One such protease is CWBP52, a processed product of the wprA gene, that has been shown to be bound noncovalently to the cell wall (21).
To determine whether the products of the wprA gene are involved in the co- or posttranslocational degradation of AmyL, we constructed a strain of B. subtilis in which an intact copy of the gene was under the control of the isopropylthio--D-galactoside (IPTG)-inducible
Pspac promoter (38). The constructs were made with the pMutin2 integration vector (provided by S. D. Ehrlich [see Fig. 2]). A 357-bp DNA fragment corresponding to the 5' end of
the wprA gene was amplified by PCR from B. subtilis KS408 chromosomal DNA with oligonucleotide primers WPR-F
and WPR-R. This fragment was cloned into the unique BamHI
restriction site of pMutin2 with E. coli XL1-blue as the
host.
Recombinant plasmids were screened for the correct orientation of the
insert by PCR and then sequenced to verify the fidelity of the PCR and
cloning steps (data not shown). The resultant plasmid, pM2wprAFP, was used to transform B. subtilis
KS408 to produce strain KS408 wprA::pMutin2 selecting
for resistance to erythromycin and lincomycin. Since
pM2wprAFP does not have a functional B. subtilis origin of replication, transformants were selected in which the plasmid had integrated into the chromosome by a homologous single-crossover (Campbell-type) recombination between the
plasmid and chromosomal sequences of wprA (Fig.
2). The authenticity of the integrants
was confirmed by PCR (data not shown). Since the wprA gene
of KS408 wprA::pMutin2 is under the control of the
Pspac promoter, its expression can be controlled by the
presence or absence of IPTG. Additionally, a transcriptional fusion
(wprA
-lacZ) between the native wprA
promoter and lacZ was created to allow the expression of
wprA to be monitored via -galactosidase activity (Fig.
2).
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The influence of wprA on the yields of -amylase
released into the culture medium.
B. subtilis KS408 was
grown in 2xYT-xylose, and KS408 wprA::pMutin2 was
grown in the same medium in the absence or presence of 10 mM IPTG. The
strains grew at identical growth rates (Fig. 3), in agreement with previous
observations (21). However, when the yields of released
-amylase were compared, the strains differed markedly. In the
absence of IPTG (wprA uninduced), the yield of -amylase from KS408 wprA::pMutin2 started to
increase above that of KS408 during exponential phase and
continued to do so after transition to stationary phase. Approximately
13% more -amylase activity was detected in the supernatant
of KS408 wprA::pMutin2 at the start of stationary phase,
and this increased still further to 41% after 38 h (data not
shown).
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and -amylase from KS408
wprA::pMutin2 in the presence of IPTG
(wprA induced) was lower, and upon transition to stationary
phase the yield of -amylase was 95% of that of KS408. The presence
of IPTG had no effect on the yield of -amylase from strain KS408
(data not shown). These data demonstrate that expression of
wprA markedly influences the yield of released
-amylase.
Coupled pulse-chase and immunoprecipitation techniques were used to
investigate the secretion kinetics of AmyL in KS408 and KS408
wprA::pMutin2. Cultures were grown to exponential
phase (OD660, ~0.8) and pulse-chased with
L-[35S]methionine. Following
immunoprecipitation and subsequent SDS-PAGE, both the precursor and
mature forms of AmyL were visualized by autoradiography (Fig.
4A). In the case of KS408, the processing of the AmyL precursor to the mature form was rapid; in samples taken
immediately following the chase (0 min), only 27% of the total AmyL
(precursor plus mature) synthesized during the pulse was in the
precursor form (Fig. 4). Processing was completed by 5 min post-chase,
when all of the -amylase was in the mature form. The amount of
mature AmyL in the whole-culture sample (cells plus growth medium)
peaked at 1 min, after which it declined until it reached a constant
level of approximately 25% of the maximum detected, representing a
significant loss of newly synthesized -amylase during or shortly
after translocation across the cytoplasmic membrane.
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-amylase synthesized during the pulse was released into the
supernatant in an intact form was in agreement with previous data
(31). An indication of the proportion of AmyL that
remains cell associated at each time point can be obtained by
subtracting the amount of released AmyL from that observed in
whole culture samples. Figure 5 shows
that following an initial increase, mature AmyL is degraded and by
approximately 7 min post-chase no AmyL remains in a
cell-associated form. These data suggest that the observed
degradation of AmyL occurs during or shortly after translocation
across the membrane and in a cell-associated location.
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Transcriptional activity of the wprA gene.
The
transcriptional activity of the native wprA promoter in
strain KS408 wprA::pMutin2 was monitored by measuring
-galactosidase activity expressed from the transcriptionally fused
lacZ gene (Fig. 2). During exponential growth and on
transition to stationary phase, the -galactosidase activity was
relatively constant at approximately 40 Miller
units/OD660 unit (Fig.
6), confirming previous reports
that wprA is expressed during exponential growth (21). However, following transition to stationary
phase, -galactosidase activity increased, reaching a peak of
75 Miller units/OD660 unit after ~28 h (data not shown).
Since -galactosidase is relatively unstable in B. subtilis (unpublished observations), the maintenance of this level
of activity in stationary phase is likely to reflect de novo protein
synthesis. The presence of IPTG in the growth medium had no effect on
the -galactosidase activity of KS408 wprA::pMutin2,
and the amount of activity detected in strain KS408 was negligible
(Fig. 6).
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Analysis of cell wall-bound proteins. Proteins were extracted from the cell walls of B. subtilis KS408 and KS408 wprA::pMutin2 and analyzed by SDS-PAGE (Fig. 7). A prominent band corresponding in size to that of the CWBP52 serine protease (52 kDa) was observed in protein extracts from the wall of KS408 (Fig. 7, lane 1). This protein was absent from the wall extracts of KS408 wprA::pMutin2 (Fig. 7, lane 2).
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Two previously identified cell-wall-bound proteins of B. subtilis, CWBP23 and CWBP52, have recently been identified as the processed products of the wprA gene (21). Although CWBP52 was identified as a wall-associated serine protease, its role in cell growth and physiology was not defined, since its absence has no discernible effect on growth rate, cell morphology, sporulation, or motility.
When the B. licheniformis -amylase, AmyL, is
secreted from B. subtilis, it is subjected to
considerable cell-associated proteolytic degradation (31).
This proteolysis results in only a proportion of the newly
synthesized -amylase being released into the culture medium. Our
data reveal a time window between translocation and release into
the growth medium during which AmyL is susceptible to proteolytic
degradation since, once released, it is stable for prolonged
periods. This observation prompted us to investigate the influence of
CWBP52, a product of the wprA gene, on the yield of released
AmyL.
We constructed a mutant in which the expression of wprA was controlled by IPTG. In the absence of induction, the amount of AmyL released into the culture medium increased significantly compared with the wild type. Conversely, when wprA was induced, the yield of AmyL was reduced. These data point to a role of the wprA gene product(s) in the stability of AmyL. Pulse-chase studies showed that AmyL was subjected to cell-associated proteolysis and that the extent of this degradation was reduced in the absence of the wprA gene products.
To be competent for translocation, secretory proteins are prevented from folding into their native conformations in the cytosol by, for example, the action of cytoplasmic molecular chaperones (26). During or shortly after translocation, secretory proteins fold into their native conformations on the trans side of the cytoplasmic membrane and in B. subtilis this process appears to be assisted by the putative extracytoplasmic chaperone, PrsA (14, 15). Secretory proteins such as AmyL, when partially or fully unfolded, are susceptible to proteolytic degradation, and the rate at which the fully folded state is reached determines the extent of degradation (31). Our data suggest that the CWBP52 serine protease, by virtue of its cellular location, is able to degrade a significant proportion of newly translocated AmyL before it is able to achieve its fully folded, and therefore protease-resistant, conformation. However, we cannot rule out the possibility that the effect(s) of the wprA gene product(s) on AmyL is indirect, for example via its activity on a protein such as PrsA.
Furthermore, it is possible that expression of wprA from the inducible promoter (possibly to a level above that of the native promoter) resulted in limited obstruction of the secretion apparatus by WprA, leading to the induction of other cellular proteases which could in turn contribute to the degradation of AmyL. However, this is unlikely since expression of wapA, encoding an unrelated cell-wall-associated protein, using the pMutin2 system, did not have a significant effect on the yield of released AmyL (data not shown).
This poses the question as to why B. subtilis possesses a cell-wall-associated protease that limits the yield of secretory proteins. Protein secretion is an essential cellular process for bacteria, and blockages of the secretion apparatus have potentially lethal consequences (13, 18). One role for a cell-associated protease such as CWBP52 could be to authenticate secreted proteins and to clear slowly folding or misfolded proteins from the vicinity of the translocation complex. It may also be important that highly expressed secretory proteins do not attach inappropriately to the cell wall, restricting the activity of cell wall-active proteins or the passage of other molecules into or out of the cell.
It is likely that native B. subtilis secretory proteins have coevolved with the secretion apparatus to avoid potentially undesirable activities of cell-associated proteases such as CWBP52. AmyL itself is not native to B. subtilis, and the extent of its observed degradation (~75% of the total synthesized during the pulse) may reflect this fact. Certain chimeric secretory proteins expressed in E. coli are also subject to proteolysis at a late stage in the secretion process (6), and a periplasmic protease, DegP, has been shown to be involved in degradation of abnormal periplasmic proteins in this organism (32, 33). Therefore, it appears that mechanisms operate in both E. coli and B. subtilis to ensure the fidelity of the secretion process, although in the latter case such proteases would need to be anchored in the cell wall or the membrane as a consequence of the different cell envelope architecture.
We were not able to determine the individual roles of CWBP52 and CWBP23 in the degradation of AmyL. However, previous data suggests that the serine protease activity can be solely attributed to CWBP52 (21). CWBP23 shows some sequence homology to eukaryotic protease modulators, and it is possible that this protein regulates the activity of CWBP52 in a manner analogous to the modifier protein (LytD) of the B. subtilis N-acetylmuramoyl-L-alanine amidase (LytC) (12, 16, 20).
In summary, this study has identified one role for the products of the
B. subtilis wprA gene. Proteolysis of AmyL was still observed in cells not induced for wprA, suggesting either
that there was a small amount of wprA expression from the
Pspac promoter under noninducing conditions or that other,
not yet identified proteases are also involved. However, a null
wprA mutant produces -amylase at a level comparable to
that for the inducible wprA strain in the absence of
induction (data not shown), suggesting that the level of proteolysis
observed is not due to readthrough but to another protease. Although
the cellular location of CWPB52 and CWBP23 is within the wall cylinder,
it is reasonable to assume that integral membrane or membrane-linked
proteases could have similar effects on secretory proteins and
contribute to lower yields of released protein. These data have
important implications for the use of B. subtilis and
other members of the genus as hosts for the secretion of native and
nonnative Bacillus proteins. Cell-associated and truly
extracellular proteases contribute to low yields of secretory proteins,
and, for the reasons discussed above, nonnative proteins would be
expected to be affected to a greater extent than native proteins
which have coevolved with the Bacillus secretion apparatus.
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ACKNOWLEDGMENTS |
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This work was supported by the European Commission under the Biotechnology Programme (contract numbers BIO2-CT93-0524 and BIO4-CT96-0097) and was carried out within the framework of the European Bacillus Secretion Group.
We thank S. D. Ehrlich for pMutin2, S. J. Foster for the cell-wall-bound protein extraction protocol, and Novo Nordisk A/S for AmyL antiserum.
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FOOTNOTES |
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* Corresponding author. Mailing address: School of Microbiological, Immunological, and Virological Sciences, The Medical School, University of Newcastle upon Tyne, Framlington Place, Newcastle upon Tyne, NE2 4HH, United Kingdom. Phone: 44 191 222 7708. Fax: 44 191 222 7736. E-mail: colin.harwood{at}ncl.ac.uk.
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REFERENCES |
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Abstract
Introduction
Materials & Methods
Results
Discussion
References
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| 1. | Bron, S. 1990. Plasmids, p. 146-147. In C. R. Harwood, and S. M. Cutting (ed.), Molecular biological methods for Bacillus. John Wiley & Sons, Chichester, United Kingdom. |
| 2. | Bron, S., and E. Luxen. 1985. Segregational instability of pUB110-derived recombinant plasmids in Bacillus subtilis. Plasmid 14:235-244[Medline]. |
| 3. |
Diderichsen, B.,
U. Wedsted,
L. Hedegaard,
B. R. Jensen, and C. Sjöholm.
1990.
Cloning of aldB, which encodes -acetolactate decarboxylase, an exoenzyme from Bacillus brevis.
J. Bacteriol.
172:4315-4321 |
| 4. | Ferrari, E., A. S. Jarnagin, and B. F. Schmidt. 1993. Commercial production of extracellular enzymes, p. 917-937. In A. L. Sonenshein, J. A. Hoch, and R. Losick (ed.), Bacillus subtilis and other gram-positive bacteria: biochemistry, physiology, and molecular genetics. American Society for Microbiology, Washington, D.C. |
| 5. | Foster, S. J. 1993. Molecular analysis of three major wall-associated proteins of Bacillus subtilis 168: evidence for processing of the product of a gene encoding a 258 kDa precursor two-domain ligand-binding protein. Mol. Microbiol. 8:299-310[Medline]. |
| 6. |
Gentz, R.,
Y. Kuys,
C. Zwieb,
D. Taatjes,
H. Taatjes,
W. Bannwarth,
D. Stueber, and I. Ibrahimi.
1988.
Association of degradation and secretion of three chimeric polypeptides in Escherichia coli.
J. Bacteriol.
170:2212-2220 |
| 7. | Gryczan, T. J. 1982. Molecular cloning in Bacillus subtilis, p. 307-329. In D. Dubnau (ed.), The molecular biology of the bacilli. Academic Press Inc., New York, N.Y. |
| 8. | Harwood, C. R. 1992. Bacillus subtilis and its relatives: molecular biological and industrial workhorses. Tibtech. 10:247-256. |
| 9. | Hastrup, S. 1988. Analysis of the B. subtilis xylose regulon, p. 79-84. In A. T. Ganesan, and J. A. Hoch (ed.), Genetics and biotechnology of bacilli, vol. 2. Academic Press, Inc., New York, N.Y. |
| 10. | Hastrup, S., and M. F. Jacobs. 1990. Lethal phenotype conferred by xylose-induced overproduction of an apr-lacZ fusion protein, p. 33-41. In A. T. Ganesan, and J. A. Hoch (ed.), Genetics and biotechnology of bacilli, vol. 3. Academic Press, Inc., New York, N.Y. |
| 11. | He, X., S. R. Bruckner, and R. H. Doi. 1991. The protease genes of Bacillus subtilis. Res. Microbiol. 142:797-803[Medline]. |
| 12. |
Herbold, D. R., and L. Glaser.
1975.
Interaction of N-acetylmuramic acid L-alanine amidase with cell wall polymers.
J. Biol. Chem.
250:7231-7238 |
| 13. | Ito, K., and J. Beckwith. 1981. Protein localization in Escherichia coli: is there a common step in the secretion of periplasmic and outer-membrane proteins? Cell 24:707-717[Medline]. |
| 14. | Kontinen, V. P., P. Saris, and M. Sarvas. 1991. A gene (prsA) of Bacillus subtilis involved in a novel, late stage of protein export. Mol. Microbiol. 5:1273-1283[Medline]. |
| 15. | Kontinen, V. P., and M. Sarvas. 1993. The PrsA lipoprotein is essential for protein secretion in Bacillus subtilis and sets a limit for high level secretion. Mol. Microbiol. 8:727-737[Medline]. |
| 16. |
Kuroda, A., and J. Sekiguchi.
1991.
Molecular cloning and sequencing of a major Bacillus subtilis autolysin gene.
J. Bacteriol.
173:7304-7312 |
| 17. | Laemmli, U. K. 1970. Cleavage of structural protein during the assembly of the head of bacteriophage T4. Nature 227:680-685[Medline]. |
| 18. |
Lee, C.,
P. Li,
H. Inouye,
E. R. Brickman, and J. Beckwith.
1989.
Genetic studies on the inability of -galactosidase to be translocated across the Escherichia coli cytoplasmic membrane.
J. Bacteriol.
171:4609-4616 |
| 19. |
Machius, M.,
G. Weigand, and R. Huber.
1995.
Crystal structure of calcium-depleted Bacillus licheniformis -amylase at 2.2Å resolution.
J. Mol. Biol.
246:545-559[Medline].
|
| 20. | Margot, P., and D. Karamata. 1992. Identification of the structural genes for N-acetylmuramoyl-L-alanine amidase and its modifier in Bacillus subtilis 168: inactivation of these genes by insertional mutagenesis has no effect on growth or cell separation. Mol. Gen. Genet. 232:359-366[Medline]. |
| 21. |
Margot, P., and D. Karamata.
1996.
The wprA gene of Bacillus subtilis 168, expressed during exponential growth, encodes a cell-wall-associated protease.
Microbiology
142:3437-3444 |
| 22. | Meens, J., M. Herbort, M. Klein, and R. Freudl. 1997. Use of the pre-pro part of the Staphylococcus hyicus lipase as carrier for the secretion of Escherichia coli outer membrane protein A (OmpA) prevents proteolytic degradation of OmpA by cell-associated protease(s) in two different gram-positive bacteria. Appl. Environ. Microbiol. 63:2814-2820[Abstract]. |
| 23. | Miller, J. H. 1972. Experiments in molecular genetics. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y. |
| 24. | Pero, J., and A. Sloma. 1993. Proteases, p. 939-952. In A. L. Sonenshein, J. A. Hoch, and R. Losick (ed.), Bacillus subtilis and other gram-positive bacteria: biochemistry, physiology, and molecular genetics. American Society for Microbiology, Washington, D.C. |
| 25. |
Priest, F.G.
1977.
Extracellular enzyme synthesis in the genus Bacillus.
Bacteriol. Rev.
41:711-753 |
| 26. |
Pugsley, A.
1993.
The complete general secretory pathway in gram-negative bacteria.
Microbiol. Rev.
57:50-108 |
| 27. | Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y. |
| 28. |
Simonen, M., and I. Palva.
1993.
Protein secretion in Bacillus species.
Microbiol. Rev.
57:109-137 |
| 29. |
Spizizen, J.
1958.
Transformation of biochemically deficient strains of Bacillus subtilis by deoxyribonucleate.
Proc. Natl. Acad. Sci. USA
44:1072-1078 |
| 30. |
Stein, E. A., and E. H. Fischer.
1958.
The resistance of -amylases to proteolytic attack.
J. Biol. Chem.
232:867-879 |
| 31. |
Stephenson, K.
1996.
Construction and use of chimeric -amylases to study protein secretion in Bacillus subtilis Ph.D. thesis.
University of Newcastle upon Tyne, Newcastle upon Tyne, United Kingdom.
|
| 32. |
Strauch, K. L., and J. Beckwith.
1988.
An Escherichia coli mutation preventing degradation of abnormal periplasmic proteins.
Proc. Natl. Acad. Sci. USA
85:1576-1580 |
| 33. |
Strauch, K. L.,
K. Johnson, and J. Beckwith.
1989.
Characterization of degP, a gene required for proteolysis in the cell envelope and essential for growth of Escherichia coli at high temperature.
J. Bacteriol.
171:2689-2696 |
| 34. |
Towbin, H.,
T. Staehelin, and J. Gordon.
1979.
Electrophoretic transfer of proteins from polyacrylamide gels to nitrocellulose sheets: procedure and some applications.
Proc. Natl. Acad. Sci. USA
76:4350-4354 |
| 35. |
Vallee, B. L.,
E. A. Stein,
W. N. Sumerwell, and E. H. Fischer.
1959.
Metal content of -amylases of various origins.
J. Biol. Chem.
234:2901-2905 |
| 36. | van Dijl, J. M., A. de Jong, H. Smith, S. Bron, and G. Venema. 1991. Signal peptidase I overproduction results in increased efficiencies of export and maturation of hybrid secretory proteins in Escherichia coli. Mol. Gen. Genet. 227:40-48[Medline]. |
| 37. |
Wu, X.,
W. Lee,
L. Tran, and S. L. Wong.
1991.
Engineering a Bacillus subtilis expression-secretion system with a strain deficient in six extracellular proteases.
J. Bacteriol.
173:4952-4958 |
| 38. | Yansura, D. G., and D. J. Henner. 1984. Development of an inducible promoter for controlled expression in Bacillus subtilis, p. 249-263. In A. T. Ganesan, and J. A. Hoch (ed.), Genetics and biochemistry of bacilli, vol. 1. Academic Press, Orlando, Fla. |
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