Institute of Medical Microbiology, University
of Zürich, CH-8028 Zürich,
Switzerland,1 and Institute of
Microbiology and Molecular Biology, Ernst-Moritz-Arndt University,
D-17487 Greifswald, Germany2
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INTRODUCTION |
Staphylococcus aureus is
a major human pathogen causing a wide spectrum of diseases and able to
survive under a variety of extreme conditions. In many bacteria,
alternative sigma factors have been shown to be important for survival
under extreme conditions by regulating the coordinate expression of
stress response genes triggered by environmental as well as
growth-dependent stimuli. As part of the RNA polymerase holoenzyme, the
sigma subunits are responsible for the binding of the catalytic core to
specific promoter regions and the initiation of transcription of
downstream genes. Thus, sigma factors provide an elegant mechanism in
eubacteria to ensure simultaneous transcription of a variety of
genetically unlinked genes, provided all these genes share the critical
promoter elements. The alternative sigma factor 
B of
Bacillus subtilis has been shown to control the
transcription of more than 100 genes in response to different stimuli
such as heat, ethanol, or salt stress; acid shock; or glucose, oxygen, or phosphate starvation (for reviews see references 23 and
46). In B. subtilis, B activity itself
is controlled posttranslationally by a multicomponent signal
transduction pathway comprising eight regulatory proteins which
with
the exception of Obg and RsbPare coexpressed with the sigma factor as
part of the same operon (3, 7, 24, 40, 44, 48, 50). One of
these proteins, RsbU, a positive regulator of B, is
essential for the activation of B during exponential
growth after environmental stress (45, 48, 50). RsbU
activity itself is controlled by the action of further Rsb proteins
encoded by the operon (1, 19, 50).
An operon encoding four proteins, sharing strong primary amino acid
similarity with RsbU, RsbV, RsbW, and B of B. subtilis, has been identified in S. aureus (27,
49). The putative S. aureus B was
shown to act as a sigma factor initiating the transcription of
sarC from the sar P3 promoter (17,
32). RsbW, on the other hand, was shown to be an anti-sigma
factor, regulating B activity posttranslationally
(32). B is activated upon heat shock in
S. aureus strain MA13 (20) and controls the
transcription of at least 30 genes encoding cytoplasmic proteins
(21). Although B was shown to be involved
in the heat and acid shock response of strain MA13, it had no apparent
function in strain 8325-4, either in the heat shock response,
starvation survival, or pathogenicity, in a mouse abscess model
(10, 20).
A phenotypic comparison of genetically distinct wild-type S. aureus strains and their 
rsbUVWsigB mutants revealed
the mutants to be almost unpigmented and to be unable to produce the
alkaline shock protein Asp23. Furthermore, the mutants showed increased alpha-hemolysin activity and were more susceptible to hydrogen peroxide
(28, 33). Remarkably, the 8325 derivative BB255 showed essentially the same phenotype as rsbUVWsigB mutants.
This phenomenon was traced back to an 11-bp deletion in the 5' part of
the rsbU gene of strain BB255, generating a stop codon
within a short distance downstream. This 11-bp deletion was also found
in the 8325 derivatives 8325-4 and RN4220 (20, 28).
In this study, we demonstrate that 8325 derivatives are unable to
produce the positive regulator RsbU. The lack of this protein results
in dramatic changes in B activity compared to that in
rsbU+ strains. cis complementation of
the 8325 derivative BB255 with the rsbU+ allele
from COL restored the B activity profile as well as the
B-dependent phenotypic properties to the levels seen in
the Newman strain.
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MATERIALS AND METHODS |
Bacterial strains, plasmids, and culture conditions.
The
bacterial strains and plasmids used in this study are listed in Table
1. S. aureus was routinely
grown in Luria-Bertani (LB) medium at 37°C and 200 rpm. Antibiotics
were used at the following concentrations: chloramphenicol, 30 µg
ml
1; erythromycin and tetracycline, 10 µg
ml1; ampicillin and kanamycin, 50 µg ml1.
General methods.
All DNA manipulations, basic molecular
methods, and handling of Escherichia coli were performed in
accordance with standard protocols (39). Genetic
manipulation of S. aureus was done as described earlier
(27). S. aureus carotenoids were extracted and
analyzed according to the methods of Marshall and Wilmoth (31) or Raisig and Sandmann (37). The general
transducing phage 80
was used for transductions. Preliminary
sequence data were obtained from The Institute for Genomic Research
(TIGR) through the website (http://www.tigr.org).
Northern blot analyses.
For the heat shock experiments,
isolation of total RNA and analysis of transcription were performed as
described by Gertz et al. (20). The specific RNA probes
for sigB and crtM were prepared by in vitro
translation with T7 polymerase and the appropriate PCR fragments as the
template. The PCR fragments were generated by using chromosomal DNA of
S. aureus strain COL which was purified with the chromosomal
DNA isolation kit (Promega) according to the protocol of the
manufacturers and oligonucleotides SasigB+ (5'-AAATAATGGCGAAAGAGTCG-3') and SasigB(T7)
(5'-CTAATACGACTCACTATAGGGAGACATAATGGTCATCTTGTTGC-3') (corresponding to nucleotides 2669 to 2688 and 3228 to 3248, respectively, of GenBank accession no. Y07645) and SacrtM+
(5'-CAGAAGATCAAAGAAAGCG-3') and SacrtM(T7)
(5'-CTAATACGACTCACTATAGGGAGCCTGTCTCAACTTCGTCC-3') (nucleotides 317 to 335 and 985 to 1002, respectively, of
accession no. X73889). Nucleotides corresponding to the T7 promoter
consensus are underlined. The hybridizations specific for
asp23 were conducted with digoxigenin-labeled RNA as
described previously (20).
For all other Northern blot analyses, total RNA was isolated as
described by Cheung et al. (13). Eight micrograms of total RNA of each sample was electrophoresed through a 1.5% agarose-0.66 M
formaldehyde gel in morpholinepropanesulfonic acid (MOPS) running buffer (20 mM MOPS, 10 mM sodium acetate, 2 mM EDTA [pH 7]). RNA was
blotted onto a positively charged nylon membrane (Roche, Basel, Switzerland) with a vacuum blotter (Pharmacia, Uppsala, Sweden). The
intensities of the 23S and 16S rRNA bands stained with ethidium bromide
were verified to be equivalent in all the samples before transfer.
Labeling and hybridization were done by use of the digoxigenin labeling
and detection kits according to the manufacturer's instructions (Roche). The following specific primers were used to generate the
digoxigenin-labeled DNA probes by PCR labeling: Saasp23A+ (5'-ATGACTGTAGATAACAATAAAGC-3') and Saasp23A
(5'-TTGTAAACCTTGTCTTTCTTGG-3') (nucleotides 343 to 365 and
828 to 849, respectively, of accession no. S76213) and luc
int+ (5'-GGAGAGCAACTGCATAAGGC-3') and luc int
(5'-GGCGAAGAAGGAGAATAGG-3') (nucleotides 111 to 130 and 914 to 932, respectively, of accession no. U47122).
Construction of plasmid pPG11.
A 6.6-kb
PstI-EcoRI fragment of strain BB255, including
the whole sigB operon (27), was subcloned into
the MCS of pUC19. The plasmid obtained was digested with
MluI and BstXI, excising a 252-bp fragment from
the rsbU gene including the 11-bp deletion. The excised
fragment was replaced by the corresponding fragment of the
rsbU+ allele from COL. In a next step, a 1.6-kb
PCR fragment of the tetL gene of pAW8 was cloned into a
blunted Bsp119I site downstream of the sigB
operon (corresponding to positions 3545 to 3550 of the sigB
operon of strain 8325, accession no. Y07645). The resulting plasmid was
electroporated into S. aureus RN4220
rsbUVWsigB to promote a crossover upstream of
rsbU, and screening for double-crossover transformants
sensitive to erythromycin and resistant to tetracycline was carried out
(Fig. 1). In a last step, the engineered
chromosomal region of a positive transformant was transduced into
different 8325 derivatives.
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FIG. 1.
Genetic organization of the sigB operon. (A)
Schematic representation of the sigB operon of S. aureus strain NCTC8325. Open reading frames, putative promoters
( ), termination signals ( ), and restriction sites used for
construction of pPG11 are indicated. The 11-bp deletion within the
rsbU gene of strain 8325, resulting in a truncated open
reading frame for RsbU (solid area), is indicated by a triangle ( ).
(B) Schematic representation of the rsbU+
construct pPG11 and of the strategy for the integration of this
construct into the chromosome of S. aureus BB255. In plasmid
pPG11, a 252-bp MluI-BstXI restriction fragment
of the rsbU gene of strain COL including the 11 bp (shaded
area) replaces the corresponding fragment of the rsbU allele
from strain BB255 harboring the 11-bp deletion, leading to an open
reading frame that encodes a functional RsbU protein. A tetL
resistance gene was introduced as a selective marker downstream of the
proposed termination signal of the sigB operon, in order not
to disrupt the transcriptional control of this locus. Strain RN4220
rsbUVWsigB, in which the major part of the
sigB operon is replaced by an ermB resistance
cassette (28), was used for electroporation to promote a
double crossover of the modified sigB operon of the
introduced pPG11 suicide plasmid upstream of the rsbU gene
and downstream of the tetR gene. The chromosomal region of a
positive transformant was phage transduced into strain BB255 to obtain
strain GP268.
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Construction of plasmids
pECasp23P::luc+ and
pBTasp23P::luc+.
A DNA fragment
carrying 1.1 kb of the asp23 gene, including its
B-dependent promoters, was generated by PCR with primers
Saasp23P+ (5'-GGGATCCTTTGAGTGAGGAGAAACC-3')
including a KpnI linker (underlined), and
Saasp23P
(5'-CTACAGCCATGGTAGATTCTCCTTTTAC-3') including
an NcoI linker (underlined). The PCR product was digested
with KpnI and NcoI and cloned in front of the
luciferase gene of plasmid pSP-luc+. The identity of the
construct was confirmed by sequence analysis and comparison to the
respective COL sequence of the TIGR database. The 2.7-kb
KpnI-EcoRI fragment, including the
asp23 promoter region fused to the luciferase coding region,
was then cloned into plasmids pEC1 and pBT, respectively. The plasmids obtained were electroporated into RN4220 and subsequently transduced into strains BB255, Newman, and GP268
(pECasp23P::luc+) and their respective
rsbUVWsigB mutants
(pBTasp23P::luc+) (Fig.
2C).
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FIG. 2.
Genetic organization of the asp23 operon of
S. aureus. (A) Schematic representation of the
asp23 operon of S. aureus based on a comparison
of the respective sequence region of strain COL, obtained from the
unfinished TIGR microbial database. The probes used for Northern blot
analyses, open reading frames, putative promoters, and the transcripts
detected are indicated. (B) Putative promoter sequences of the
asp23 locus. Nucleotides of the 35 and 10 regions of the
putative promoters of the asp23 locus which are identical to
the B-dependent promoter consensus of B. subtilis are boldfaced. Spacer regions between the 35 and 10
hexameric nucleotide sequences, and between the promoter sequence and
the proposed start codons of the closest open reading frames, are
indicated. (C) Schematic representation of the integration of
asp23P::luc+ fusion constructs into the
S. aureus chromosome by single crossover. For construction
of plasmids pECasp23P::luc+ and
pBTasp23P::luc+, and integration of the
constructs into the S. aureus chromosome, see Materials and
Methods.
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Construction of E. coli vectors for overexpression of
His-tagged RsbU, B, and Asp23.
A DNA fragment
carrying 999 bp of the rsbUCOL gene was
amplified by PCR using primers SarsbU1+ including an
NdeI linker (underlined) (5'-GGAGATATACATATGGAAGAATTTAAGCAAC-3'
[the start methionine shown in boldface type]) and
SarsbU1 including an XhoI linker (underlined)
(5'-GGTGGTGCTCATTTACTCTTTTTATAATC-3') (italics correspond to positions 785 to 772 and 1764 to 1782, respectively, in accession no. Y09929). The PCR product was cloned into
pET24b to obtain pETrsbUCOL. Similarly, the
sigB gene and the asp23 gene were amplified by PCR using, respectively, primer SasigB1+ including an
NdeI linker (underlined)
(5'-GGAGATATACATATGGCGAAAGAGTCGAAATCAGC-3') combined with primer SasigB1 including an
XhoI linker (underlined) (5'-GTGGTGCTCGAGTTGATGTGCTGCTTCTTG-3')
(italics correspond to positions 2674 to 2696 and 3424 to 3441, respectively, in accession no. Y07645) and primer Saasp2323+
(5'-GGAGATATACATATGACTGTAGATAACAATAAAGC-3') combined with primer Saasp23
(5'-GGTGGTGCTCGAGTTGTAAACCTTGTCTTTCTTGG-3') (italics correspond to positions 343 to 365 and 828 to 849, respectively in accession no. S76213). The PCR products were cloned
into pET24b to obtain pETsigB or pETasp23,
respectively. The junction regions and the introduced PCR products were
sequenced to ensure proper ligation and fidelity of the PCR. E. coli strain BL21(DE3) was transformed with the plasmids obtained.
Overexpression and purification of the His-tagged proteins were
performed using Ni-nitriloacetic acid (NTA) columns according to the
recommendations of the manufacturer (Qiagen, Basel, Switzerland). The
purified proteins were separated using sodium dodecyl sulfate-12%
polyacrylamide gel electrophoresis (SDS-12% PAGE), and bands
containing the protein were cut out of the gels. N-terminal sequencing
confirmed the identities of the desired proteins. The gel slices
containing the respective proteins were injected into rabbits to raise
anti-RsbU, anti-SigB, and anti-Asp23 polyclonal antibodies (BioScience,
Göttingen, Germany). The resulting antisera were purified against
the immobilized antigens.
Hydrogen peroxide experiments.
The MICs and minimal
bactericidal concentrations (MBCs) of hydrogen peroxide were determined
by broth microdilution using the National Committee for Clinical
Laboratory Standards protocol with serial dilutions of hydrogen
peroxide (2.2 M to 0.125 mM). Microtiter plates were incubated for 24 and 48 h at 37°C.
Luciferase assay.
Bacterial cells were harvested by
centrifugation (at 11,000 × g for 1 min. at room
temperature), and the cell pellet was resuspended in phosphate-buffered
saline (PBS) (137 mM NaCl, 2.7 mM KCl, 4.3 mM
Na2HPO4, 1.4 mM KH2PO4
[pH 7.3]) to an optical density at 600 nm (OD600) of 10 and snap-frozen in liquid nitrogen. Luciferase activity was determined
by rapidly mixing PBS-resuspended cells (10 µl) with an equal volume
of luciferase assay reagent (Promega, Madison, Wis.). Luminescence was
measured on a Turner Designs TD-20/20 Luminometer (Promega) for a
period of 10 s with a delay of 2 s.
UV-stress experiments.
Bacterial cells were diluted to
McFarland 0.5 and streaked out on LB agar plates. After plating, cells
were immediately exposed to far-UV light (254 nm) or near-UV light (312 nm) for different time periods, using a Stratalinker (Stratagene, La
Jolla, Calif.) as the light source. The bacteria were then incubated
for 24 h at 37°C.
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RESULTS |
Occurrence of RsbU and B in different S. aureus strains.
The rsbU gene in S. aureus strain COL encodes a 323-amino-acid open reading frame,
while a deletion in the 5' region of rsbU in strain 8325 generates a premature stop codon, giving rise to an open reading frame
of only 74 amino acids. The same deletion was found in all 8325 derivatives tested (BB255, 8325-4, RN4220, RN6390, and BB270)
(20, 28). Western blot analyses using antigen-purified polyclonal antibodies revealed the presence of RsbU in the clinical isolates COL and Newman but not in the 8325 derivatives (Fig. 3B), while B was
detectable in all strains analyzed except BB255
rsbUVWsigB (Fig. 3C).
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FIG. 3.
Western blot analyses of different S. aureus
strains. Cytoplasmic protein fractions (10 µg/lane) of different
S. aureus overnight cultures, grown in LB medium at 37°C
and 200 rpm, were separated using SDS-10% PAGE and blotted onto
nitrocellulose. The blotted proteins were either stained with amido
black (A) or subjected to Western blot analyses using antigen-purified
anti-RsbU antibodies (B), anti-SigB antibodies (C), or anti-Asp23
antibodies (D). The broad-range molecular size marker (Gibco-BRL) was
used. Relevant protein signals are indicated.
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Fifteen independent clinical isolates of S. aureus, selected
at the University Hospital of Zürich in 1999, were tested for the
presence of the deletion in rsbU by PCR using
oligonucleotides flanking the deletion site (28). None of
the clinical isolates tested had such a deletion. The presence of RsbU
in all clinical isolates was demonstrated by Western blot analysis
(data not shown). These results indicated (i) the general presence of
RsbU in clinical isolates and (ii) that 8325 derivatives are unable to
produce the potential B activator RsbU. Furthermore,
they excluded the possibility that an RsbU protein, truncated at its N
terminus, is translated by use of a cryptic start codon downstream of
the deletion. Strain 8325 derivatives are therefore natural
rsbU mutants.
Complementation of strain BB255 with
rsbUCOL.
The finding that 8325 derivatives
are devoid of RsbU and the fact that most studies on B
have been conducted with these strains prompted us to investigate the
effects of RsbU on the phenotype of S. aureus in the 8325 isogenic background by replacing the truncated rsbU gene of
BB255 with the intact rsbU+ allele from strain
COL. For this purpose, we constructed the suicide plasmid pPG11,
harboring a 6.6-kb chromosomal region including the sigB
operon of strain BB255 and the rsbU gene of strain COL. In
order not to disrupt the transcriptional integrity of the
sigB operon, the tetL gene was inserted as a
selective marker downstream of the operon (Fig. 1). To promote
crossover events upstream of the rsbU region, we used RN4220
rsbUVWsigB mutants for electroporation and selected for
transformants that were resistant to tetracycline but sensitive to
erythromycin, the selective marker that replaced the sigB
operon in the RN4220 derivative (28). Transformants possessing these resistance characteristics should have undergone a
double crossover, thereby replacing the rsbUVWsigB
deletion region through the sigB operon including the
rsbU gene from COL (Fig. 1B). The corresponding chromosomal
region of such a transformant was then transduced into 8325 derivatives
to obtain the respective tetracycline-resistant
rsbU+ derivatives. Transductants were analyzed
by Southern hybridization for correct integration and loss of the
suicide vector (data not shown). Strain GP268 was thus generated and
characterized (see below). As a final proof for correct construction,
the chromosomal region of the sigB operon was further phage
transduced from GP268 into the natural rsbU+
strain Newman. The phenotypes of the resulting transductants, harboring
the chromosomal region of the sigB operon of GP268, and that
of the Newman strain were found to be identical (data not shown),
confirming that all manipulations had occurred as intended.
Growth of S. aureus strains.
Different
S. aureus strains and their respective
rsbUVWsigB mutants were analyzed for their
stationary-phase cell densities, measured as the
OD600. The wild-type strains COL and Newman were found to
reach significantly higher OD600 values than their
respective rsbUVWsigB mutants, while strain
BB255 reached a cell density that was indistinguishable from that of
its rsbUVWsigB mutant (Table
2). In contrast, the
rsbU+ derivative GP268 reached a cell density
that was clearly higher than that of the corresponding strain BB255 or
the respective rsbUVWsigB mutant. The ratio between the
cell densities of GP268 and BB255 was comparable to those found for the
other two rsbU+ strains and their
rsbUVWsigB mutants.
Increased H2O2 tolerance conferred by
RsbU.
Kullik et al. (28) reported the MBC of
H2O2 to be four times higher than the MIC in
strains COL and Newman, whereas for their rsbUVWsigB
mutants as well as for BB255, the MICs and MBCs were found to be
identical. Consistent with the data for the
rsbU+ strain Newman, we demonstrate here that
the MBC of H2O2 for GP268 is four times higher
than the MIC (Table 3).
Alpha-hemolysin activity is negatively correlated to
B activity.
It has been shown previously that
rsbUVWsigB mutants possess higher alpha-hemolysin
activities than their respective wild-type mutants (15,
33). Alpha-hemolysin activities were analyzed here by examining
the lysed zones around spotted colonies grown on horse blood agar (Fig.
4). The rsbUVWsigB
mutants as well as strain BB255 produced clearly visible zones of
hemolysis. In contrast, the rsbU+ strains Newman
and GP268 showed almost no lytic zones. The lytic zones of BB255 and
its respective rsbUVWsigB mutant were indistinguishable.
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FIG. 4.
Alpha-hemolysin activities of different S. aureus strains. Cells of different S. aureus strains (3 µl of McFarland 0.5 dilutions) were spotted on horse blood agar
plates and incubated for 24 h at 37°C. The resulting colonies
were scanned and analyzed for their surrounding lytic zones.
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Production of Asp23.
The alkaline shock protein Asp23, a
169-amino-acid polypeptide of still unknown function, is known to be
highly inducible in S. aureus strains 912 and MA13 by a pH
upshift to pH 10 (20, 29). It was, however, neither
detectable nor inducible in strain 8325-4 (20). Asp23 was
found to be highly abundant in the cytoplasmic fraction of
stationary-phase protein extracts of strains COL and Newman, while it
was missing in their respective rsbUVWsigB mutants as
well as in the 8325 derivatives (20, 28). A
B-dependent promoter motif has been proposed (20,
28) and recently confirmed (32) upstream of the
asp23 open reading frame. Northern blot analysis suggested
asp23 expression to be highly dependent on the alternative
stress sigma factor B (20). Here we present
further evidence for asp23 being under the sole control of
B in S. aureus.
Kuroda et al. (29) reported 0.7- and 1.5-kb
asp23 transcripts. Our Northern blot experiments
demonstrated that sequences hybridizing to the asp23 probes
can be detected on three different RNAs, including a 3.3-kb transcript
that was not previously detected. This longer RNA includes an open
reading frame with strong homology to OpuD of B. subtilis.
Transcription of the asp23 locus (Fig. 5) was analyzed by use of three different
DNA probes (as indicated in Fig. 2A; data for probe 2 and 3 not shown).
The 0.7- and 1.5-kb transcripts were found to be highly abundant, and
all three transcripts were heat inducible in strains Newman and GP268,
while they were only weakly expressed and not heat inducible in strain
BB255 and were not detectable at all in the rsbUVWsigB
mutants of BB255 and Newman (Fig. 5 and 8A). Western blot analysis with
anti-Asp23 antibodies confirmed that Asp23 was highly abundant in
strains COL, Newman, and GP268, less abundant in strain BB255, and
undetectable in the rsbUVWsigB mutant (Fig. 3D).
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FIG. 5.
Northern blot analyses of the asp23 operon.
(A) Growth curves of the S. aureus strains investigated.
Solid squares, BB255; solid circles, IK181 (BB255
rsbUVWsigB); solid triangles, GP268 (BB255
rsbU+); open squares, MB33 (BB255
asp23P::luc+); open circles, MB90
(BB255 rsbUVWsigB asp23P::luc+);
open triangles, MB49 (BB255 rsbU+
asp23P::luc+). Time points of sampling
are indicated. (B) Total RNAs (8 µg/lane) of S. aureus
strains BB255 (lanes 1 to 3), IK181 (BB255 rsbUVWsigB)
(lanes 7 to 9), GP268 (BB255 rsbU+) (lanes 13 to
15), MB33 (BB255 asp23P::luc+) (lanes 4 to 6), MB90 (BB255 rsbUVWsigB
asp23P::luc+) (lanes 10 to 12), and MB49
(BB255 rsbU+
asp23P::luc+) (lanes 16 to 18),
obtained from cells grown in LB medium at 37°C and harvested 1 h
(lanes 1, 4, 7, 10, 13, and 16), 3 h (lanes 2, 5, 8, 11, 14, and
17), and 5 h (lanes 3, 6, 9, 12, 15, and 18) after inoculation of
the medium with log-phase cells, were blotted onto a positively charged
nylon membrane and subjected to Northern blot analysis. The blotted
membranes were hybridized using a digoxigenin-labeled DNA probe
specific for asp23 (for construction, see Materials and
Methods). The RNA molecular size marker I (Roche) was used. Positions
of the 16S and 23S rRNAs are indicated by diamonds ( ) on the left,
and relevant transcript signals are indicated on the right.
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The abundance of asp23 transcripts and their sole dependence
on B makes the asp23 promoter(s) an ideal
candidate for studying B activity in S. aureus. We therefore fused the promoter region of asp23
to the firefly luciferase gene (luc+) and integrated the
construct into the chromosome (Fig. 2C). Except for the missing 3.3-kb
transcript due to the chromosomal integration of
asp23P::luc+, transcription was found
to be similar to that of the original chromosomal region as
demonstrated by Northern blotting (Fig. 5). The B
activity determined indirectly by the use of the luciferase reporter system confirmed that B was almost inactive in strain
BB255, while in strain GP268 the B activity profile was
comparable to that found in strain Newman (Fig.
6). The B activity
profiles of the above five strains were confirmed by the use of further
luciferase fusions to the promoter of csb7, another
B-controlled gene (21). While luciferase
activities derived from csb7P::luc+
strains were found to be 10-fold lower compared to the
asp23P::luc+ data, relative intensities
in the different strains were essentially identical (data not shown).
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FIG. 6.
B activity during growth of S. aureus. The expression of
asp23P::luc+ during growth of S. aureus strain BB255 (A) and strain Newman (B), grown in LB medium
at 37°C, is shown. Bacterial growth was measured as the
OD600 (solid symbols). B transcriptional
activity was determined by measuring the luciferase activity of Luc+
(open symbols), the product of the luc+ reporter gene fused
to the B-dependent promoters of asp23
(asp23p). (A) Squares, S. aureus strain MB33
(BB255 asp23P::luc+); circles, strain
MB90 (BB255 rsbUVWsigB
asp23P::luc+); triangles, strain MB49 (BB255
rsbU+
asp23P::luc+). (B) Squares, S. aureus strain MB32 (Newman
asp23P::luc+); circles, strain MB69
(Newman rsbUVWsigB asp23P::luc+).
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Pigmentation.
A characteristic feature of many S. aureus strains is the increase in pigmentation, with cells turning
bright orange from pale yellow when incubated for 48 h at 37°C.
This phenomenon has also been observed in COL, Newman, and MA13 but did
not occur in 8325 derivatives, which kept their pale-yellow
pigmentation even after 96 h of incubation at 37°C. Although
pigment production by S. aureus has been described as a
rather unstable characteristic (47), it has clearly been
demonstrated by Kullik et al. (28) that the orange
pigmentation of S. aureus is influenced by B.
They showed that sigB deletion mutants of strains COL and
Newman were unable to produce the orange pigment, while a
sigB-complemented strain of the 8325 derivative BB255 did.
Corroborating these findings, we observed that GP268, the BB255
derivative complemented with rsbU+, accumulated
staphyloxanthin, the orange end product of S. aureus carotenoid biosynthesis (31), as its major
stationary-phase pigment after 48 h of growth (data not shown). In
contrast, BB255 produced only trace amounts of the staphyloxanthin
precursors 4,4'-diapophytoene (colorless) and 4,4'-diaponeurosporene
(yellow), the products of the diapophytoene synthase (CrtM) and
diapophytoene desaturase (CrtN), respectively (37, 47).
Consistent with its increased pigmentation, GP268 was found to be more
tolerant to UV radiation, especially to near-UV light (312 nm), than
its unpigmented donor, BB255 (Fig. 7). In
the 8325-4 background, the tolerance to UV light was even more
pronounced. GP269, the rsbU-complemented 8325-4 derivative,
was significantly more tolerant to UV light than its donor (Fig. 7).
The differences in UV tolerance observed between the BB255 and the
8325-4 strains are probably due to the fact that the BB255 strains, in
contrast to 8325-4 strains (34), still harbor temperate
bacteriophages which are known to be excised by UV radiation
(41). The marked differences in near-UV-light tolerance
between the rsbU+ strains and their unpigmented
relatives (Fig. 7B), as opposed to the marginal differences in
far-UV-light tolerance (Fig. 7A), reflect the findings of Tuveson et
al. (43). These authors, using different light qualities,
investigated the UV-protective capacity of pigmentation in an E. coli strain that was transformed with the carotenoid biosynthesis
cluster of Erwinia herbicola. They showed that carotenoids
protected the transformed E. coli strain against high
fluences of near-UV light (320 to 400 nm) but not against far-UV light
(200 to 300 nm).
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|
FIG. 7.
UV tolerances of different S. aureus strains.
McFarland 0.5 dilutions of different S. aureus strains were
streaked out onto LB agar plates and exposed to far-UV light (254 nm)
(A) or near-UV light (312 nm) (B) for different time periods. After
light exposure, plates were incubated for 24 h at 37°C.
|
|
The observation that strain BB255 did not efficiently accumulate the
staphyloxanthin precursors 4,4'-diapophytoene and
4,4'-diaponeurosporene argues for an influence of B on
carotenoid biosynthesis, either on gene products governing the
formation of 4,4'-diaponeurosporene or 4,4'-diapophytoene or on a prior
synthetic step. Consistent with this assumption that formation of
4,4'-diapophytoene may be affected, we could detect an influence of
B on the transcription of crtMN by Northern
blot analysis (Fig. 8B). Both the
transcript levels of GP268 compared with those of BB255 and the heat
inducibility of the detected transcripts argue for a B
dependence of crtMN. However, B dependence of
crtMN alone is not sufficient to explain the inability of
BB255 to produce staphyloxanthin, as overproduction of
crtMN under the control of a xylose-inducible promoter
resulted, after 24 h of growth, in a strong accumulation of
4,4'-diaponeurosporene, which was not further converted to
staphyloxanthin even after 96 h of growth. Overproduction of
crtMN in the rsbU+ strain Newman
resulted in an equal accumulation of 4,4'-diaponeurosporene after
24 h of growth, but in contrast to the situation in BB255, almost
all the 4,4'-diaponeurosporene was converted to staphyloxanthin after
96 h of growth (data not shown). Thus, B is likely
to control more than one of the intermediate steps of carotenoid
biosynthesis in S. aureus.
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FIG. 8.
Heat shock induction of B-dependent
transcripts in S. aureus. Total RNA was isolated from
S. aureus GP268 (BB255 rsbU+) (lanes
1 to 7) and S. aureus BB255 (lanes 9 to 15) grown at 37°C
(lanes 1, 2, 9, and 10) and 1 min (lanes 3 and 11), 3 min (lanes 4 and
12), 6 min (lanes 5 and 13), 9 min (lanes 6 and 14), and 12 min (lanes
7 and 15) after shifting the cultures to 48°C. The RNAs (15 µg/lane) were blotted onto positively charged nylon membranes and
subjected to Northern blot analyses. The blotted membranes were
hybridized using digoxigenin-labeled RNA probes specific for
asp23 (A), crtM (B), and sigB (C) (for
construction see Materials and Methods). A digoxigenin-labeled RNA size
marker (lane 8) (Roche) was used as a standard. Relevant transcript
signals are given on the left.
|
|
Induction of B-dependent transcripts after heat
shock.
In B. subtilis, B directs
transcription of its own gene when activated through a variety of
stress stimuli (4, 7, 8, 22, 45, 50). Transcription starts
within the sigB operon upstream of the rsbV gene.
A similar situation has been proposed for S. aureus, as a
promoter sequence highly similar to the B consensus of
B. subtilis is found upstream of the rsbV gene
(27, 49). Transcription from this promoter would lead to
an mRNA of approximately 1.6 kb. In agreement with this prediction,
Gertz et al. (20) detected a 1.6-kb transcript that was
heat inducible in strain MA13 but was not detectable in strain 8325-4. Here we demonstrate that BB255 cells expressed the 1.6-kb transcript
when complemented with rsbU (Fig. 8) and that the transcript
was heat inducible as in MA13 (20). In addition to
sigB and asp23, we found transcription of
crtM to be heat inducible and dependent on B
(Fig. 8). The time course of transcript induction after heat stress
resembled that of the 1.6-kb sigB transcripts in strain MA13
(20), with a maximum induction within the first 3 to 6 min
and a decrease thereafter to or below the uninduced level after 12 min.
| |
DISCUSSION |
In the gram-positive bacterium B. subtilis, RsbU has
been shown to be essential for activation of B in
response to different environmental stress stimuli such as heat shock,
salt stress, or ethanol stress (45, 48, 50). A similar
function has been proposed for the RsbU homologue of S. aureus (27, 49). In this study, we clearly
demonstrate that RsbU of S. aureus is indeed an essential
factor for B activity, as strains lacking this protein
were unable to render activity from this sigma factor (Fig. 6).
Furthermore, the lack of RsbU in 8325 derivatives resulted in
phenotypes comparable to those of rsbUVWsigB mutants of
rsbU+ strains such as COL or Newman
(28). Complementation of strain BB255 with the
rsbU+ allele from COL resulted in the
rsbU+ derivative GP268. This strain exhibited a
B activity profile comparable to that of the
rsbU+ wild-type strain Newman (Fig. 6) and
restored the B-dependent phenotypic traits to the levels
seen in Newman. Overexpression of RsbU in BB255 altered the phenotype
to that found for GP268, while overexpression in the corresponding
rsbUVWsigB mutant had no apparent influence, suggesting
that RsbU acts primarily through B (unpublished data).
The observations that B is produced by 8325 derivatives
(Fig. 3C) and that BB255 was phenotypically indistinguishable from its
sigB derivative under the conditions that we tested indicate
that although B is detectable in 8325 derivatives, it
cannot be activated to relevant levels due to the absence of RsbU in
this genetic background. However, the presence of detectable amounts of
Asp23 and B activity at a low level in BB255 suggests
that RsbU is not the sole determinant of B activity in
S. aureus. Significant amounts of Asp23 were detectable in
the 8325 isogenic background only in BB255, which harbors at least four
prophages, and not in any of the 8325-4 derivatives (i.e., 8325-4, RN4220, and RN6390), which have been cured from the respective
prophages, implying that the loss of the prophages from 8325 may
influence such residual RsbU-independent B activity.
The finding that 8325 derivatives are almost unable to activate
B is of particular interest, as 8325 derivatives are the
laboratory strains most frequently used in S. aureus
research. Most studies on starvation survival, pathogenicity, and the
regulation of the two global regulators agr (accessory gene
regulator) and sar (staphylococcal accessory gene regulator)
and, in particular, the influence of B in these
processes, have been carried out in this genetic background (2,
6, 10, 11, 12, 14, 15, 16, 17, 30, 42). The observed lack of
B activity in the 8325 isogenic background revives the
question if, and to what extent, B is involved in these
processes. The findings in rsbU+ strains such as
COL, Newman, and GP268 of the inducibility of transcription of
B-dependent genes, of staphyloxanthin accumulation, of
reduced susceptibility to hydrogen peroxide (Table 2), and of higher cell densities in overnight cultures compared to those for their respective rsbUVWsigB mutants (Table 3) argue for an
influence of B on the survival capacity of S. aureus.
B has been shown to be a major player in the general
stress response of B. subtilis, by controlling the
transcription of more than 100 genes under a variety of stress
conditions (23, 46). So far, more than 30 genes in
S. aureus have been determined to be controlled by
B (21). These proteins are likely to be
involved in the general stress response of S. aureus. In
addition, pigmentation of S. aureus by the carotenoid
staphyloxanthin, the biosynthesis of which is clearly influenced by
B, is also likely to be a protective measure against
various environmental stress factors, such as UV radiation (Fig. 7) or
free radicals. As biological antioxidants, carotenoid pigments have
been shown to protect many bacteria against the harmful effects of
light, in particular against high fluences of near-UV light (320 to 400 nm). They act as scavengers of reactive molecules that are generated within cells and that can induce oxidative damage, e.g., singlet molecular oxygen (1O2) (36, 43).
Thus, pigmented S. aureus cells are very likely to survive
longer periods of daylight exposure than their unpigmented relatives.
The lower susceptibility of rsbU+ strains to
hydrogen peroxide may also be due to the pigmentation, as carotenoids
have been shown to protect efficiently against oxygen radicals
(36). Alternatively, the increased resistance of
rsbU+ strains to hydrogen peroxide may be due to
a B-dependent transcriptional control of enzymes
directly involved in the degradation of reactive oxygen species, such
as catalase or superoxide dismutase. Transcriptional control of the
katA gene, coding for the sole catalase thus far identified
in S. aureus, however, was found to be independent of
B in Northern blot analysis (data not shown).
Notwithstanding, the higher tolerance of rsbU+
strains to hydrogen peroxide is likely to provide considerable benefit
for S. aureus strains invading a host, enabling them to tolerate higher concentrations of oxygen radicals that are produced by
the host defense system (38).
We note that rsbU mutants were unable to accumulate the
pigment staphyloxanthin, even after 72 h of growth. This finding
indicates thatunlike the situation in B. subtilisB is inactive even during the
stationary-growth phase, provided that RsbU is absent. Since all
analyzed clinical isolates of S. aureus were found to be
rsbU+, we consider it important to reinvestigate
these processes. Most importantly, the regulation of the two global
regulators agr and sar will have to be studied in
a genetic background representative for the majority of clinical
isolates. Preliminary data suggest a strong impact of B
on sar expression in rsbU+ strains
(M. Bischoff, unpublished data). Strain GP268, which has
B activity, provides the possibility of studying these
processes in the well-characterized 8325 isogenic background.
We thank B. Berger-Bächi, A. Schaller, and M. Hecker for
critical reading of, and comments on, the manuscript. We are very grateful to A. Wada for providing plasmid pAW8 and to A. Raisig for
HPLC analysis of carotenoids. Preliminary sequence data were obtained
from The Institute for Genomic Research (TIGR) through the website at
http://www.tigr.org. Sequencing of S. aureus COL was
accomplished with support from National Institute of Allergy and
Infectious Diseases (NIAID) and the Merck Genome Research Institute (MGRI).
This work was supported by Swiss National Science Foundation grant NF
31-46762.96 to F. H. Kayser.
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B Activity Depends on RsbU in
Staphylococcus aureus
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Abstract
Introduction
