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Journal of Bacteriology, May 2000, p. 2909-2918, Vol. 182, No. 10
0021-9193/00/$04.00+0
Altered Stationary-Phase Response in a
Borrelia burgdorferi rpoS Mutant
Abdallah F.
Elias,1,*
James L.
Bono,1
James A.
Carroll,2
Philip
Stewart,1
Kit
Tilly,1 and
Patricia
Rosa1
Laboratory of Human Bacterial
Pathogenesis1 and Microscopy
Branch,2 Rocky Mountain Laboratories, National
Institute of Allergy and Infectious Diseases, National Institutes of
Health, Hamilton, Montana 59840
Received 22 November 1999/Accepted 23 February 2000
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ABSTRACT |
The homolog of the chromosomally encoded stationary-phase sigma
factor RpoS in Borrelia burgdorferi was
inactivated using gyrBr as a selectable marker.
Two-dimensional nonequilibrium pH gradient electrophoresis of
stationary-phase cell lysates identified at least 11 differences
between the protein profiles of the rpoS mutant and
wild-type organisms. Wild-type B. burgdorferi had a growth
phase-dependent resistance to 1 N NaCl, similar to the stationary-phase
response reported for other bacteria. The B. burgdorferi
rpoS mutant strain was less resistant to osmotic stress in
stationary phase than the isogenic rpoS wild-type organism. The results indicate that the B. burgdorferi rpoS homolog
influences protein composition and participates in
stationary-phase-dependent osmotic resistance. This rpoS
mutant will be useful for studying regulation of gene expression in
response to changing environmental conditions.
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INTRODUCTION |
Lyme disease is the most
common arthropod-borne disorder in the United States, with a variable
spectrum of clinical manifestations ranging from localized infection to
systemic disease (1, 11, 54, 55). Borrelia
burgdorferi, the spirochetal agent of Lyme disease, is normally
maintained in an enzootic cycle between wild mammals and
Ixodes ticks (30). In ticks and in mammals, the bacteria are present only in low numbers throughout most of the infectious cycle. However, periods of rapid growth occur in ticks after
blood engorgement (13, 43). Although little is known about
the growth kinetics of B. burgdorferi within the mammalian host, spirochetes appear to be present in considerably lower densities in chronically infected mice than in acutely infected animals (4). B. burgdorferi, similar to other bacterial
pathogens, undoubtedly has a repertoire of adaptive molecular responses
to environmental signals to assist survival within and successful transmission between its hosts (16, 35, 36). For example, in
vivo, differential synthesis of membrane proteins occurs during tick
transmission (3, 52) and mammalian infection (19, 41). Temperature, pH, and growth phase also have been shown to
modify the protein profile of cultivated B. burgdorferi
(7, 8, 12, 23, 37, 44, 52, 53, 56; J. G. Frye,
B. K. Kremer, T. R. Hoover, and F. C. Gherardini, Abstr.
99th Gen. Meet. Am. Soc. Microbiol. 1999, abstr. D/B-259, p. 259).
Despite this evidence for the presence of adaptive responses in
B. burgdorferi, the molecular mechanisms responsible for
regulation of gene expression in response to environmental changes are
unknown. This lack is due to the difficulty in studying the physiology of a fastidious organism and the limited availability of genetic tools
to manipulate B. burgdorferi.
An important mechanism involved in regulation of bacterial gene
expression in response to environmental signals is the use of
alternative sigma factors to alter RNA polymerase specificity (59). Three genes encoding sigma factor homologs are present in the genome of B. burgdorferi: rpoS
(
S), ntrA (54), and
rpoD (70). In Escherichia coli,
RpoS controls a regulon of more than 30 genes positively or negatively
regulated in response to starvation and transition to stationary phase
(15, 31). In the natural environment, B. burgdorferi and other bacteria often encounter nutrient
limitations, resulting in periods of negligible or absent growth.
E. coli and other bacteria respond to nutrient starvation by
entering a metabolic state referred to as stationary phase (25,
26, 42, 58), allowing them to survive environmental stresses such
as oxidative stress, heat, high salt, and near-UV radiation. The
stationary-phase response depends in part on the expression of the
sigma factor rpoS (22, 31). Several bacterial pathogens, including Salmonella (14, 29),
Yersinia enterocolitica (24), Vibrio
cholerae (60), and Legionella pneumophila
(20), have RpoS homologs with various roles. For example, in
Salmonella enterica serovar Typhimurium RpoS regulates
chromosomal and plasmid-encoded virulence genes, and the 50% lethal
dose in mice is 1,000-fold higher for a Salmonella serovar
Typhimurium rpoS mutant than for the wild-type strain
(14, 29).
Here, we begin a study to elucidate the role of RpoS in B. burgdorferi biology. As a first step, we inactivated the
rpoS locus by allelic exchange with
gyrBr, a mutated form of the B subunit of DNA
gyrase, as a selectable marker. Although this technique has been used
previously to inactivate several B. burgdorferi genes
located on a 26-kb circular plasmid (cp26) (5, 57),
rpoS is the first chromosomal gene to be inactivated in
B. burgdorferi. Stationary-phase cells of the isogenic B. burgdorferi rpoS mutant have an altered protein
composition compared with the rpoS wild-type organism and
are more sensitive to osmotic stress. These results indicate that RpoS
participates in the stationary-phase-related adaptive response.
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MATERIALS AND METHODS |
Bacterial strains.
The B. burgdorferi strains
used in this study are listed in Table 1.
Bacteria were grown at 35°C in liquid BSK-H medium (Sigma, St. Louis,
Mo.) supplemented with 6% rabbit serum (Sigma) (2) or in
solid BSK medium (45, 46). B31 (ATCC 35210) was originally isolated from a tick collected on Shelter Island, N.Y. (6). B31 clone A (B31-A) is a clone derived from culture-attenuated, noninfectious B31. B31 clone 4A (B31-4A) is a low-passage (P3) infectious clone derived from B31. Coumermycin A1-resistant
clones B31-A59 (A59), B31-A74 (A74), and B31-A29 (A29) were derived
from B31-A by transformation with the recombinant plasmid pAE30
(described below). This plasmid contains a copy of
gyrBr, the mutated B subunit of DNA gyrase from
B31-NGR (45), conferring resistance to coumermycin
A1, inserted in a 4.2-kb B. burgdorferi chromosomal DNA fragment.
Spirochetes were counted by dark-field microscopy with a
Petroff-Hausser counting chamber. The number of spirochetes was
determined
once or twice daily. Stationary phase was defined as the
period
of reduced bacterial growth after exponential growth. The onset
of stationary phase usually corresponds to a cell density of
approximately
10
8 spirochetes/ml.
Construction of the rpoS mutant.
Recombinant
plasmid pAE30 was constructed to inactivate the B. burgdorferi
rpoS gene. A 4.2-kb fragment encompassing the rpoS locus of B31-4A was amplified from chromosomal DNA by PCR (38, 49) with primers 2 and 9 (Table 2
and Fig. 1A). The PCR product was cloned
into pCR2.1 (Invitrogen, Carlsbad, Calif.), which contains an
ampicillin resistance gene. Ampicillin is a beta-lactam antibiotic and
is related to antimicrobial agents used to treat Lyme disease. Hence,
this drug resistance phenotype cannot be introduced into B. burgdorferi. Therefore, the rpoS-containing fragment
was recloned into pOK12, a 2.1-kb low-copy-number plasmid that contains
a kanamycin resistance gene. The gyrBr gene and
its putative promoter were amplified by PCR from B31-NGR chromosomal
DNA (Table 1) with primers 11 and 15 (Fig. 1B and Table 2) and cloned
into pCR2.1. The gyrBr gene was excised from
pCR2.1 by EcoRI digestion and inserted into the single
BbsI site of rpoS cloned in pOK12, which has ends compatible with EcoRI. The resulting plasmid (pAE30) was
confirmed to contain the
rpoS::gyrBr construct by
DNA sequencing with a 373A instrument (Applied Biosystems, Foster City,
Calif.) (Fig. 1B). Plasmid DNAs were purified from E. coli
with Qiagen purification kits (Qiagen, Chatsworth, Calif.). Restriction
endonucleases and T4 DNA ligase were obtained from New England Biolabs
(Beverly, Mass.). The sequence of the B. burgdorferi rpoS
locus was obtained from the web page of the Institute for Genomic
Research at http://www.tigr.org, where rpoS has accession number BB771.
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FIG. 1.
Schematic diagram of the B. burgdorferi
chromosomal rpoS gene and plasmid pAE30. (A) Location of
rpoS in a 6-kb chromosomal region. (B) Construct pAE30 used
for transformation of B. burgdorferi. The
gyrBr gene is inserted in the single
BbsI site of the rpoS locus. Solid arrows
indicate direction of gene transcription; open arrows represent primers
used in this study, and their numbers refer to the primers listed in
Table 2. R, EcoRI; B, BbsI; Ba, BamHI;
X, XbaI. Thick lines represent the pOK12 vector, and thin
lines represent the B. burgdorferi insert.
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Transformation of B. burgdorferi.
Transformation of
B31-A with pAE30 by electroporation was performed as described
previously (45, 51). Each transformation used 40 µg of DNA
in 5 µl of distilled water. After electroporation, the bacteria were
resuspended in 10 ml of liquid BSK-H and incubated overnight at 35°C.
The transformed bacteria were plated in solid BSK with 0.5 µg of
coumermycin A1 per ml. Plating efficiency was determined to
be between 50 and 70%, as assessed by growth on solid BSK without
antibiotics. The transformation frequency (2 × 10
5)
was calculated as the ratio of coumermycin-resistant CFU relative to
the total number of CFU in the transformed cultures.
Screening of B. burgdorferi transformants by
PCR.
Coumermycin-resistant colonies were screened for allelic
exchange at the rpoS locus by PCR. Individual colonies
picked with sterile toothpicks were added to tubes containing a 20-µl
PCR mix, and oligonucleotides 5 and 8 (Table 2 and Fig. 1A) were used
to amplify a fragment that spanned the rpoS gene. Reaction conditions were 94°C for 1 min and then 30 cycles with 94°C for 30 s, 55°C for 45 s, and 68°C for 3 min in a GeneAmp 9600 DNA Thermal Cycler (Perkin-Elmer, Norwalk, Conn.) with 96-well PCR plates. E. coli colonies that contained plasmid pAE30 or a
pOK12 derivative with a 6-kb rpoS-spanning fragment were
used as positive controls. PCR products were separated by agarose gel
electrophoresis and visualized by ethidium bromide staining. To obtain
clonal mutants, individual colonies were aspirated with a sterile
Pasteur pipette and grown in 5 ml of liquid BSK containing coumermycin A1 (0.5 µg/ml). Appropriate dilutions of cultures were
replated in solid BSK-H with coumermycin A1 (0.5 µg/ml),
and individual colonies were picked, grown up, and subjected to PCR and
Southern blot analysis to confirm insertion of
gyrBr within rpoS (see below).
SspI digestion of the PCR-amplified gyrB
locus from potential transformants.
To determine the proportion of
Cour colonies that were "true" transformants, i.e.,
that had a copy of the B31-NGR gyrBr in their
chromosome, the gyrB locus in 42 randomly chosen
Cour colonies was amplified by PCR with primers 11 and 13 (Table 2 and Fig. 1B) and digested with SspI. The
gyrBr from B31-NGR contains one SspI
site, which is due to a dinucleotide change in codon 133 (45; D. S. Samuels, unpublished data) and is
not present in gyrBr of spontaneous mutants. The
PCR products from 38 of the 42 colonies were cut by SspI,
indicating that approximately 90% of the Cour colonies
were transformants and 10% were spontaneous resistance mutants.
Southern blot analysis.
B. burgdorferi total genomic
DNA was isolated, digested with restriction endonucleases, and
separated by pulsed-field gel electrophoresis in a 0.8% (wt/vol)
agarose gel under field inversion conditions (47) with a
PPI-200 programmable power inverter (MJ Research, Watertown, Mass.).
Bidirectional transfer to Biotrans nylon membranes (ICN, Irvine,
Calif.), DNA hybridization with radiolabeled probes, and visualization
by autoradiography were performed as described previously
(47).
Northern blot analysis.
Total borrelial RNA from
stationary-phase cultures grown in liquid BSK-H was extracted with the
ULTRASPECII RNA Isolation System (Biotecx, Houston, Tex.) according to
the manufacturer's instructions. After denaturation with glyoxal and
dimethyl sulfoxide, 10 µg of total RNA was electrophoresed in a 1%
(wt/vol) agarose gel in 10 mM sodium phosphate buffer, pH 7.0 (50). RNA transfer to nylon membranes (MSI, Westboro,
Mass.), hybridization with radiolabeled probes, and visualization by
autoradiography were performed as previously described (5).
Protein analysis.
B. burgdorferi was grown in liquid
BSK-H to stationary phase and harvested by centrifugation
(6,000 × g, 10 min, 4°C). For sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (27), cells were
washed twice in 100 mM sodium chloride-20 mM
N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid, pH 7.3 (HEPES buffer), and lysed by a previously described protocol (9). Protein concentrations were determined by a
modified Lowry protein assay (33). Equivalent amounts of
cell lysates were solubilized by boiling in Laemmli sample buffer for 5 min (50) and separated through 12.5% polyacrylamide gels in
a Hoefer SE600 gel apparatus (Hoefer Scientific, San Francisco,
Calif.). For two-dimensional nonequilibrium pH gradient electrophoresis (2D-NEPHGE), stationary-phase cultures were harvested and washed as
described above. Pellets were solubilized directly in NEPHGE sample
buffer (9 M urea, 4% NP-40, 2% 
-mercaptoethanol, 2% ampholytes in
distilled H2O) for 2 h at room temperature, followed
by ultracentrifugation at 100,000 × g for 1 h at
room temperature. A total of 108 cells were loaded onto
10-cm tube gels, and 2D-NEPHGE was performed as previously described
(9, 40). Preblended ampholytes (pH 3.5 to 9.5) were
purchased from Pharmacia Biotech (Piscataway, N.J.). Proteins were
visualized by staining with Coomassie R250 or by silver stain with the
Silver Stain Plus kit (Bio-Rad, Hercules, Calif.). Integrated density
values were measured with an Alphaimager 2000 digital imaging system
(Alpha Innotech Corporation, San Leandro, Calif.).
Osmotic shock assay.
Borrelia cultures were inoculated at an
initial concentration of 105 organisms/ml and grown in
BSK-H medium. Starting at a density of 107 bacteria per ml,
which corresponds to mid-log phase, daily aliquots were divided into
two equal portions that contained identical numbers of bacteria. An
appropriate amount of 5 N NaCl was added to one aliquot to increase the
osmolarity by 1 M, whereas the corresponding control aliquot received
an identical volume of fresh BSK. At 10, 40, and 100 min after addition
of NaCl, 200 µl of each mixture was centrifuged at 5,000 × g for 5 min at 4°C, and the pellets were resuspended in 0.6 to 1 ml of HEPES buffer. Spirochetes were then assayed for viability
with the LIVE/DEAD BacLight bacterial viability kit
(Molecular Probes, Wilsonville, Oreg.) according to the manufacturer's
instructions. Viable bacteria with intact membranes stain fluorescent
green, whereas dead bacteria with damaged membranes stain fluorescent
red. The stained cells were counted with a Petroff-Hausser chamber
under fluorescence microscopy (Zeiss, Jena, Germany). The limits of
detection with this technique were between 5 × 104
and 1 × 105 cells/ml. In independent experiments, the
total numbers of bacteria prior to NaCl exposure varied between 5 × 107 and 9 × 107/ml in log-phase
cultures and 1 × 108 and 3 × 108/ml
in stationary-phase cultures. The percentage of survivors was
calculated as the number of live (green-fluorescent) bacteria in the
aliquot exposed to 1 N NaCl divided by the number of live bacteria in
the control aliquot, multiplied by 100.
In preliminary experiments, we tested the effect of centrifugation and
resuspension in buffer on the viability of untreated
log- and
stationary-phase cultures and the effectiveness of the
washing step in
removing free nucleic acids that might result
in variation in staining.
Centrifugation and washing in various
buffers did not alter cell
viability (data not shown). Likewise,
the addition of up to 25 µg of
purified plasmid DNA did not have
an effect on the staining character
(data not
shown).
To confirm that the
BacLight stain accurately reflects
spirochetal viability, growth endpoint determinations were performed
with a microdilution assay. A log-phase B31-A culture was counted,
divided into two aliquots, and treated as described above for
40 min.
After resuspension in HEPES buffer, the bacterial suspensions
were
diluted 1:10 with fresh BSK-H into a microtiter plate well
to a final
volume of 260 µl, corresponding to 3.5 × 10
5
bacteria prior to treatment. Duplicate twofold serial dilutions
were
then performed. The microtiter plates were sealed with a
gas-permeable
sealing membrane (Breathe Easy; Diversified Biotech,
Boston, Mass.) and
incubated at 35°C in a humidified environment
with 1%
CO
2. The number of spirochetes surviving treatment with
1 N
NaCl was determined from the dilution at which no bacterial
growth was
observed (growth endpoint) as determined by lack of
color change of the
medium (
48) and detectable spirochetes.
After incubation for
25 days, no further color change of the medium
was observed, and each
well was examined by dark-field microscopy
for the presence of
spirochetes.
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RESULTS |
Construction of a B. burgdorferi rpoS mutant.
The
plasmid pAE30 used for disruption of the B. burgdorferi rpoS
gene contains a 4-kb fragment of borrelial chromosomal DNA with
gyrBr inserted into the rpoS locus in
the reverse orientation (Fig. 1B). This disrupts rpoS in the
first quarter of the gene and leaves approximately 2 kb of flanking
sequence on either side of gyrBr to mediate
allelic exchange. Clone B31-A was transformed with pAE30 DNA by
electroporation. Seven mutants with an
rpoS::gyrBr genotype were
identified by PCR screening of 576 Cour colonies with
primers that flank the gyrBr insertion within
rpoS (5 and 8, Table 2
and Fig. 2). An estimated 90% of the
Cour colonies were transformants, as determined by
SspI digestion of the gyrB gene (see Materials
and Methods), whereas 10% resulted from spontaneous resistance
mutations. Hence, an estimated 1.4% of the transformants were
rpoS mutants.
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FIG. 2.
Agarose gel of Cour transformants screened
by PCR for insertion of gyrBr in the chromosomal
rpoS gene. The rpoS gene from individual B. burgdorferi colonies was amplified by PCR with primers 5 and 8 (Table 2 and Fig. 1A). The asterisk indicates the position of the
mutant PCR fragment containing gyrBr. The
additional wild-type PCR product was not present in clonal mutants
(Fig. 3). Controls: 1 and 2, E. coli colonies containing
plasmid pAE30 and a pOK12 derivative with an rpoS-flanking
fragment, respectively; 3, blank spot on transformation plate; 4, reagent blank. The positions of DNA size standards are indicated on the
left.
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The mutant colonies were picked from solid medium for growth in liquid
BSK-H with coumermycin A
1 (0.5 µg/ml) and replated
on
solid BSK to ensure clonality. The homozygous
rpoS::
gyrBr genotype of
individual clones was confirmed by PCR with primers
5 and 8. The
additional wild-type PCR product present in the initial
screen (Fig.
2)
was not present in clonal mutants. Two
rpoS mutants
(A74 and
A29) and A59, a Cou
r transformant with a wild-type
rpoS locus in which allelic exchange
had occurred at the
gyrB locus, were chosen for subsequent
analyses.
Confirmation of the structure of the mutant rpoS
gene.
To confirm that the rpoS mutants were the result
of allelic exchange at the chromosomal rpoS locus, we
amplified chromosomal sequences flanking the cloned 4-kb fragment from
pAE30 with primers 1 and 10 (Table 2 and Fig. 1A), in combination with
internal gyrB primers 12 and 14 (Table 2 and Fig. 1B). The
PCR results were only compatible with allelic exchange occurring at the
rpoS locus (Fig. 3).
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FIG. 3.
Confirmation of gyrBr insertion
in the rpoS chromosomal locus by PCR. Genomic DNA from
B. burgdorferi clones B31-A (rpoS wild type) and
transformant A74
(rpoS::gyrBr) and pAE30
plasmid DNA were amplified by PCR with the primer sets indicated above
the lanes, analyzed by agarose gel electrophoresis, and visualized with
ethidium bromide. Primer numbers refer to Table 2 and Fig. 1. The
positions of DNA size standards are indicated on the left.
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Southern blot analysis provided further evidence for the presence of
gyrBr within the
rpoS locus (Fig.
4). Hybridization with a probe specific
for
rpoS resulted in restriction patterns consistent with
the
presence of a single
rpoS gene and the integration of
gyrBr into the
rpoS locus (Fig.
4A
and C). Similarly, a probe specific
for
gyrBr
identified additional bands in A74
(
rpoS::
gyrBr) compared to
A59 (
rpoS+ wild type) due to the presence of two
gyrBr copies in the chromosome (Fig.
4B and C).
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FIG. 4.
Southern blot analysis of Cour
transformants. Total borrelial DNA of the Cour
rpoS wild-type A59 and the rpoS mutant A74 was
digested with restriction endonucleases BglII,
XbaI, and BamHI. (A) Hybridization with an
rpoS probe (generated with primers 6 and 7 [Table 2 and
Fig. 1A]). (B) Hybridization with a probe specific for gyrB
(generated with primers 11 and 13 [Table 2 and Fig. 1B]). A59,
Cour rpoS wild-type strain; A74,
rpoS::gyrBr. DNA source,
restriction enzyme, and probe are indicated above the lanes. DNA size
standards are indicated on the left. (C) Relevant BglII,
XbaI, and BamHI restriction sites at the
chromosomal loci for gyrB (upper line) and rpoS
(lower line). The rpoS gene of rpoS mutant A74
was disrupted by the insertion of gyrBr into the
BbsI site. A size bar (1.1 kb) is indicated. Hatch marks
indicate discontinuity to distal restriction sites.
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Transcriptional analysis.
To study rpoS
transcription, we performed Northern blot analysis of total borrelial
RNA from stationary-phase cultures of B31-4A and B31-A. The 798-bp
rpoS gene is located between nucleotides 812442 and 813239 on the minus strand of the B. burgdorferi chromosome (18). The gene is flanked upstream by flgI,
encoding a flagellar P-ring protein homolog, and downstream by an
879-bp open reading frame that lacks homology with genes of known
function (BB770, Fig. 1A) (18). The 454-bp intergenic region
between flgI and rpoS does not contain a sequence
with more than 60% identity to a consensus 70 promoter
(determined with the program MacTargsearch). A 54-bp sequence which
lacks apparent rho-independent terminators lies between the
3' end of rpoS and the start codon of BB770.
A specific
rpoS transcript of approximately 1 kb was
identified in B31-A and B31-4A, a size that matches the predicted
length
of a transcript encompassing only the
rpoS gene (Fig.
5A). In
contrast, no detectable
rpoS transcript was observed in the
rpoS mutant
A74 (Fig.
5A). No distinct transcript for BB770 was identified
in
B31-A, B31-4A, and A74 with a probe specific for this gene
(data not
shown). The
rpoS blots were reprobed with an internal
flaB probe, and the results confirmed that equivalent
amounts
of RNA were analyzed for all three strains (Fig.
5B).
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FIG. 5.
Northern blot analysis of the B. burgdorferi
rpoS transcript. Total borrelial RNA from stationary-phase
cultures was extracted and transferred to nylon membranes. (A)
Hybridization with a probe specific for rpoS (PCR fragment
amplified with primers 6 and 7 [Table 2 and Fig. 1A]). The arrow
indicates the rpoS transcript. (B) Rehybridization with a
flaB probe (PCR fragment amplified with primers 16 and 17 [Table 2]) after decay of the rpoS probe confirmed the
presence of equivalent amounts of RNA in all three lanes. RNA sources
are indicated above the lanes. RNA size standards are indicated on the
left.
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Growth phase-dependent resistance of wild-type B. burgdorferi to osmotic stress.
RpoS participates in
stationary-phase-mediated resistance to environmental stresses in many
bacteria (17, 22, 34). Next, we tested whether growth phase
affects the ability of wild-type B. burgdorferi to survive
treatment with a high salt concentration. A representative experiment
in which resistance to high salt was determined for clone B31-A with a
wild-type rpoS allele is shown in Fig.
6. With an initial inoculum of
105 bacteria/ml, stationary phase was reached after 4 days
and the number of viable bacteria remained constant through day 7. Log-phase and stationary-phase organisms were exposed to 1 N NaCl for
10, 40, and 100 min, and the number of viable spirochetes was
determined. Greater than 90% of the log-phase bacteria were dead after
the 10-min exposure, and no viable bacteria were detected by
microscopic examination after 100 min (Fig. 6B). Between days 4 and 7, greater than 90% of the bacteria survived 1 N NaCl for 10 min, but
only 30% were viable after 100 min (Fig. 6B). However, on day 7 the majority of spirochetes remained viable after 100 min of exposure to 1 N NaCl (Fig. 6B). The distinct patterns of osmotic resistance in log
phase and early and late stationary phase were confirmed by repetition
of the experiment five times. In all experiments less than 0.2% (0.005 to 0.14%) of log-phase spirochetes survived 70 to 100 min of exposure
to 1 N NaCl. Survival of bacteria in late stationary phase varied
between 74 and 105% after 10 to 100 min in 1 N NaCl.
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FIG. 6.
Growth phase-dependent resistance of rpoS
wild-type B31-A to 1 N NaCl. (A) Growth curve of B31-A. (B) Survival of
B31-A grown for 3 to 7 days in 1 N NaCl. The number of viable
spirochetes was determined at the indicated times before and after
addition of NaCl.
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To determine the ability of the LIVE/DEAD
BacLight bacterial
viability kit to accurately reflect cell viability, we compared
data
from this assay with the results of a growth endpoint determination
obtained with a microdilution assay (Fig.
7). In the microdilution
assay, the
growth endpoint of B31-A log-phase bacteria was determined
at a
dilution corresponding to 1.3 spirochetes (Fig.
7B). After
40 min of
exposure to 1 N NaCl, the growth endpoint occurred at
a dilution
corresponding to 87 spirochetes in the untreated control
culture (Fig.
7B). Thus, exposure of a log-phase culture to 1
N NaCl for 40 min
resulted in greater than 90% reduction in the
number of viable
organisms, as assessed by limiting dilution.
This value is comparable
to the results obtained with the LIVE/DEAD
BacLight
bacterial viability kit (Fig.
6 and
8).
These results
also demonstrate a good correlation between the LIVE/DEAD
BacLight
bacterial viability kit and the growth endpoint
determination
by limiting dilution with respect to absolute numbers of
viable
bacteria.
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FIG. 7.
Susceptibility of rpoS wild-type B31-A to 1 N
NaCl. (A) Live/dead stain with the LIVE/DEAD BacLight
bacterial viability kit of a B31-A log-phase culture without and 40 min
after addition of 1 N NaCl. (B) Susceptibility of B31-A to 1 N NaCl
determined with a microdilution assay. Successive wells represent
twofold dilutions. Row I, after 40 min of exposure to 1 N NaCl. Row II,
control culture not exposed to NaCl. The first well of the control
received an initial inoculum of 3.5 × 105 bacteria
(row II, asterisk). An equivalent inoculum was treated with 1 N NaCl
for 40 min prior to addition to the first well (row I). Solid arrow,
growth endpoint of the untreated control culture, corresponding to a
calculated number of 1.3 spirochetes in the initial inoculum; open
arrow, growth endpoint of the NaCl-exposed culture. A >90% reduction
in viability was calculated as the inverse of the ratio of the number
of viable spirochetes as assessed by growth endpoint following salt
treatment relative to the untreated control culture.
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FIG. 8.
Comparison of rpoS wild-type (wt) B31-A and
rpoS mutant A74 in their resistance to 1 N NaCl. Spirochetes
were grown for 3, 5, and 7 days in liquid culture. At days 3, 5, and 7, the number of viable spirochetes was determined without (0 min) and 10, 40, and 100 min after addition of NaCl. The percent survivors
represents the number of viable spirochetes in salt-treated cultures
relative to that in comparable sham controls. Error bars indicate the
standard error obtained from three independent countings.
|
|
Survival of the isogenic rpoS mutant under high-salt
conditions.
Our results indicate that osmotic resistance in
wild-type B31-A is growth phase dependent and increases during
stationary phase. To assess the role of RpoS in resistance to osmotic
stress, we compared the survival of B31-A and the rpoS
mutant A74 after addition of 1 N NaCl to the medium. Wild-type and
mutant bacteria in log phase died shortly after NaCl was added (Fig. 8,
day 3). However, in early stationary phase, the rpoS mutant
was more susceptible to 1 N NaCl than wild-type B31-A (Fig. 8, day 5).
Although both the wild-type and mutant organisms were more resistant to
prolonged osmotic shock in late stationary phase, survival was
decreased by more than 50% in the rpoS mutant relative to
B31-A (Fig. 8, day 7). These results indicate that RpoS participates in
growth phase-dependent osmotic resistance in B. burgdorferi.
Due to the limited set of genetic methods for
B. burgdorferi, we were not able to use genetic complementation to
confirm that
the observed phenotype of A74 was due to inactivation of
rpoS.
However, we tested another
rpoS mutant
(A29, Table
1) for osmotic
resistance and obtained comparable results
(data not shown). The
Cou
r rpoS wild-type A59
(Table
1) showed a growth phase-dependent
survival in high-salt medium
similar to that of B31-A (data not
shown). Therefore, it is unlikely
that the presence of the altered
B subunit of the DNA gyrase in
rpoS mutants A74 and A29 accounted
for their increased
susceptibility to osmotic
stress.
Protein analysis of the rpoS wild-type and mutant
strains.
2D-NEPHGE (9, 39) was used to assess
differences in protein composition between rpoS mutant A74
and isogenic rpoS wild-type A59. Representative
silver-stained 2D gels containing protein lysates from 108
spirochetes grown to stationary phase are shown in Fig.
9. Two independent cultures of each clone
were analyzed, and 11 protein spots with three- to eightfold
differences in abundance, as determined by densitometry, were
repeatedly detected (Fig. 9). The lysates from rpoS
wild-type strain A59 had five protein spots that were either absent or
markedly decreased in the lysates from rpoS mutant strain
A74 (Fig. 9, spot numbers 7, 8, 9, 10, and 11). In contrast, six
protein spots were present in the lysates from rpoS mutant A74 that were either absent from or markedly decreased in lysates from
rpoS wild-type A59 (Fig. 9, spot numbers 1, 2, 3, 4, 5, and 6). The levels of OspA, OspD (39), and flagellin (FlaB) were not significantly different in the isogenic strains (Fig. 9).
View larger version (53K):
[in this window]
[in a new window]
|
FIG. 9.
Silver-stained gels of total borrelial lysates from
stationary-phase cultures separated by 2D-NEPHGE. (A) A59
(rpoS wild type). (B) A74 (rpoS mutant). Acidic
end is on the left. Protein spots that differ more than threefold in
abundance as determined by densitometry are indicated by arrows. The
numbers indicate corresponding protein spots. Protein size standards
are indicated on the left of each panel. The locations of OspA, OspD,
and flagellin (FlaB) are indicated by an arrow. Flagellin does not
stain with silver but is easily detectable with Coomassie blue staining
(data not shown).
|
|
| |
DISCUSSION |
Borrelia burgdorferi survives within and is
transmitted between two very different host environments, the tick
vector and the mammalian host. In many bacteria, alternative sigma
factors regulate gene expression in response to environmental
conditions. The genome of B. burgdorferi contains two genes
encoding homologs of alternative sigma factors, rpoS and
ntrA, but nothing is known about their function. Here we
describe the site-directed inactivation of rpoS in B. burgdorferi and the characterization of the rpoS mutant.
By using 2D gel electrophoresis of stationary-phase spirochetes, we
identified 11 proteins that differed at least threefold in abundance in
the rpoS mutant compared with the rpoS wild-type strain. Interestingly, 6 of the 11 proteins were made in higher amounts
by the rpoS mutant than by the isogenic wild-type organism. In E. coli, RpoS mainly acts as a positive regulator of a
group of genes expressed in stationary-phase cells (21, 22),
and only a small number of genes have been reported to be negatively regulated (15). In contrast, our results suggest that the
borrelial RpoS participates in both up- and downregulation of gene
expression. The natural environment and life cycle of B. burgdorferi differ greatly from those of members of the
Enterobacteria, for which the role of RpoS has been studied
most extensively (21, 22, 28, 31). Therefore, we anticipate
that many genes regulated by RpoS in B. burgdorferi will
have functions and expression patterns distinct from those of E. coli and related enteric organisms. Synthesis of most proteins,
including OspA, OspD, and flagellin (FlaB), was not significantly
altered in the rpoS mutant relative to the rpoS
wild type, suggesting that either 70 or
54 is responsible for transcription of the respective genes.
The designation of BB771 as an RpoS homolog is based on sequence
similarity with RpoS of other bacteria. The most closely related RpoS
homolog is found in Pseudomonas aeruginosa (34% identity and 58% similarity using the BLASTP program, National Center for Biotechnology Information) (18). Preliminary results
indicate that the B. burgdorferi rpoS gene partially
complements a Shigella flexneri rpoS mutant in an acid
resistance assay (data not shown). Similar to E. coli,
B. burgdorferi wild-type organisms had an increased osmotic
resistance in the stationary phase relative to the exponential growth
phase, and our results indicate that the borrelial RpoS homolog
participates in this stationary-phase response. This is consistent with
the previous demonstration of RpoS induction in stationary-phase
spirochetes (Frye et al., Abstr. 99th Gen. Meet. Am. Soc. Microbiol.
1999). However, RpoS is not solely responsible for these changes, since
the osmotic resistance of the rpoS mutant also increased
during stationary phase, although to a lesser extent. Growth
phase-related factors, such as pH change of the BSK medium, could
influence osmotic resistance independently of RpoS. RpoS in B. burgdorferi is not required for resistance to oxidative stress,
because survival of rpoS mutant organisms exposed to 15 mM
hydrogen peroxide in stationary phase was unaltered compared with the
isogenic rpoS wild-type strain (data not shown). We note
that in Legionella pneumophila, RpoS does not
participate in stationary-phase-dependent resistance to environmental
factors such as oxidative stress but is required for growth within the protozoan host Acanthamoeba castellanii (20).
Further characterization of the rpoS mutant will provide
information about how B. burgdorferi adapts to variable
environmental conditions. Identification of the 11 proteins
differentially made by rpoS wild-type and mutant spirochetes
will address which B. burgdorferi genes are regulated by
RpoS, either directly or indirectly. In this regard, several borrelial
proteins have previously been shown to be differentially regulated in
log phase versus stationary phase (23, 44; Frye et
al., Abstr. 99th Gen. Meet. Am. Soc. Microbiol. 1999), but their
dependence upon RpoS expression has not been investigated.
Osmotolerance requires de novo protein synthesis (25), and
some of the proteins made in greater abundance in the rpoS
wild-type than in the rpoS mutant could be responsible for
the higher osmotic resistance. For example, proX,
proW, and proV on the chromosome of B. burgdorferi encode an ABC transporter for osmoprotectants such as
proline and betaine (ProU). In E. coli, ProU participates in
osmoregulation and is regulated by RpoS (32).
RpoS is important for the survival of Salmonella serovar
Typhimurium and L. pneumophila in their hosts and regulates
virulence genes in Salmonella (14, 20, 29) and
V. cholerae (60). Inactivation of rpoS
in a low-passage, infectious B. burgdorferi strain will
enable us to directly test the function of RpoS in the infectious cycle
of this important pathogen.
| |
ACKNOWLEDGMENTS |
We thank J. Battisti, B. J. Hinnebusch, J. M. Musser,
and T. G. Schwan for critical review of the manuscript; K. Matteson for assistance in manuscript preparation; G. Hettrick and R. Evans for artwork and photography; and J. Frye, F. Gherardini, and T. Hoover for helpful discussions.
| |
ADDENDUM IN PROOF |
While this article was in press, Knight et al. reported the
disruption of the gac gene located on the chromosome
of B. burgdorferi (S. W. Knight, B. J. Kimmel, C. H. Eggers, and D. S. Samuels, J. Bacteriol. 182:2048-2051, 2000).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Rocky Mountain
Laboratories, Laboratory of Human Bacterial Pathogenesis, National
Institute of Allergy and Infectious Diseases, National Institutes of
Health, 903 South 4th Street, Hamilton, MT 59840. Phone: (406)
363-9301. Fax: (406) 363-9204. E-mail:
aelias{at}niaid.nih.gov.
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Abstract
Introduction
