Department of Microbiology and Immunology,
Medical College of Ohio, Toledo, Ohio, 43614,1
and Cell Biology and Metabolism Branch, National Institute of
Child Health and Human Development, National Institutes of Health,
Bethesda, Maryland 208922
DsrA is an 85-nucleotide, untranslated RNA that has multiple
regulatory activities at 30°C. These activities include the
translational regulation of RpoS and H-NS, global transcriptional
regulators in Escherichia coli. Hfq is an E. coli protein necessary for the in vitro and in vivo replication
of the RNA phage Q
. Hfq also plays a role in the degradation of
numerous RNA transcripts. Here we show that an hfq mutant
strain is defective for DsrA-mediated regulation of both
rpoS and hns. The defect in rpoS
expression can be partially overcome by overexpression of DsrA. Hfq
does not regulate the transcription of DsrA, and DsrA does not alter the accumulation of Hfq. However, in an hfq mutant,
chromosome-expressed DsrA was unstable (half-life of 1 min) and
truncated at the 3' end. When expressed from a multicopy plasmid, DsrA
was stable in both wild-type and hfq mutant strains, but it
had only partial activity in the hfq mutant strain.
Purified Hfq binds DsrA in vitro. These results suggest that Hfq acts
as a protein cofactor for the regulatory activities of DsrA by either
altering the structure of DsrA or forming an active RNA-protein complex.
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INTRODUCTION |
DsrA is a small untranslated RNA
that regulates expression of two global transcription factors, H-NS and
RpoS (Fig. 1). The DsrA secondary
structure is conserved and is predicted to form a three-stem-loop
structure (14). The three stem-loops correlate with
discrete regulatory activities of DsrA (Fig. 1). The first stem-loop is
involved in the anti-antisense regulation of translation of the
rpoS mRNA (14). Increased transcription of DsrA
at low temperatures leads to increased translation of rpoS
and, consequently, increased transcription of some RpoS-dependent genes
(27). The second stem-loop is necessary for the regulation
of hns translation (13, 14) and possibly its
activity (26). The third stem-loop apparently functions as
a factor-independent transcription terminator (14, 26).
Since many other RNAs require protein cofactors for activity, we looked
for proteins that might be necessary for the DsrA-mediated regulation.
A strong candidate cofactor was Hfq, an Escherichia coli
protein required for replication of the RNA genome of the Q phage
both in vivo and in vitro (7, 8, 23). Hfq functions by
destabilizing an RNA secondary structure on the 3' end of the positive
strand of Q (7, 8, 23). In addition, Hfq binds tightly
to Q RNA, poly(A) RNA (4, 8, 22), and OxyS RNA
(37). Hfq also targets several mRNAs for degradation,
possibly by increasing polyadenylation (10) or by
interfering with ribosome binding (36). Hfq is essential for the efficient translation of RpoS in E. coli
(17) and Salmonella enterica serovar
Typhimurium (3) and for the instability of the ompA,
miaA, mutS, and hfq mRNAs in E. coli
(32, 35). Hfq copurifies with H-NS, and overexpression or
mutations in Hfq can mask some H-NS
phenotypes
(24). In this paper, we show that Hfq is necessary for the
regulatory activity of DsrA and binds specifically to DsrA in vitro. In
addition, in the absence of Hfq, chromosome-expressed DsrA was
unstable, while plasmid-expressed DsrA remained stable.
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FIG. 1.
Model of DsrA-mediated regulation. DsrA has three
functional domains that correspond to three predicted stem-loops
(14, 27). Stem-loop 1 positively regulates RpoS
translation and the expression of RpoS-dependent genes. Stem-loop 2 decreases the translation of H-NS and also the ability of H-NS to
repress transcription of rcsA and other H-NS-repressed genes
(13, 26). RcsA activates transcription of the
cps genes involved in colonic acid capsule production
(29, 30). Stem-loop 3 functions as a factor-independent
transcription terminator (14).
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MATERIALS AND METHODS |
Bacterial strains and genetic techniques.
All strains used
in this paper were derivatives of E. coli K-12 strain
SG20250 (1), a derivative of MC4100, unless indicated otherwise. Transductions with P1vir were done as described previously (16). 
GN272 is equivalent to MPM5 (15)
and was a gift from D. Gentry. The
hfq-1::kan and
hfq-2::kan alleles are from strains TX2808 and TX2758, respectively (34). Transformations were
done either by electroporation (6) using a GenePulsar II
electroporator (Bio-Rad Laboratories, Richmond, Calif.) or by TSS
transformation (5).
-Galactosidase assays.
-Galactosidase activities of
the various lacZ fusions were assayed as described
previously (16). Cells were grown with shaking at 30°C
in Luria-Bertani (LB) medium supplemented with the appropriate
antibiotic. Total -galactosidase units were plotted against the
optical density of the culture at 600 nm (OD600). The
slopes of the linear regressions (differential rate of expression) were
used as the specific activities of the fusions. Regression fits had an
r2 of >0.95. Specific activities varied less
than 10% between experiments.
Plasmid construction.
To generate plasmid
pSP64-dsrA (pGSO122), a fragment carrying the T7 promoter
and the E. coli dsrA gene was amplified by PCR from K-12
genomic DNA using primers (5'-CTT GAA TTC TAA TAC GAC TCA CTA TAG
GGA ACA CAT CAG ATT TCC TGG and 5'-TAC AAG CTT AAA TCC CGA
CCC TGA GGG GGT). The DNA fragment was digested with
EcoRI and HindIII and cloned into the
corresponding sites of the pSP64 vector (Promega, Madison, Wis.). To
generate plasmid pT3-5S (pGSO123), a fragment carrying the T3 promoter
and the E. coli 5S gene was amplified by PCR from K-12
genomic DNA using primers 5'-GCC AAG CTC GAA ATT AAC CCT CAC TAA
AGG GTG CCT GGC GGC CGT AGC GCG and 5'-CCC CGG GTT TAA ATG
CCT GGC AGT TCC CTA CTC. The DNA fragment was cloned into pCR 2.1 vector according to the manufacturer's protocol (TA Cloning Kit;
Invitrogen, Carlsbad, Calif.) (K. M. Wassarman and G. Storz,
unpublished data). Plasmid pSP64-oxyS (pGSO100) was described
previously (37). The pBADHfq plasmid (pDDS400) was built
by directionally cloning a PCR-generated fragment of the hfq
gene into the EcoRI and PstI sites of the
arabinose-inducible vector pBAD24 (9) using the primers
5'-GGA ATT CAC CAT GGC TAA GGG GCA ATC T (hfq1) and
5'-AAC TGC AGT TAT TCG GTT TCT TCG CTG TCC (hfq2).
RNA purification, primer extension, and RNase protection
assays.
RNA was extracted from exponentially growing cells with
hot phenol using method II of Hinton (11). Primer
extension analysis was performed by the extension of the 5'-end
32P-labeled oligonucleotides 5'-GAC CCT GAG GGG GTC
GGG ATG (rcsA24) or 5'-AAA CTT GCT TAA GCA AGA AGC ACT TA
(dsrA25) following the method of Sambrook (19) with
the addition of 1.5 mM MgCl2 and using murine Moloney virus
reverse transcriptase (Life Technologies, Rockville, Md.).
Oligonucleotides were labeled using [
-32P]ATP (10 mCi/ml in aqueous solution) (Amersham, Arlington Heights, Ill.) and T4
polynucleotide kinase (Life Technologies) as described previously
(19). The RPA II kit (Ambion, Austin, Tex.) was used for
RNase protection assays, following the manufacturer's protocol. Antisense RNA probes were made using the MAXIscript T7 in vitro transcription kit (Ambion). The DNA template for the in vitro transcription reaction was a PCR product. The primers used were 5'-TAA TAC GAC TCA CTA TAG GGT CGT TGA ATG CAC AAT AAA A
(dsrA21, containing a T7 promoter) and 5'-TAT GGC GAA TAT
TTT CTT GTC AGC (dsrA20).
Gel electrophoresis and Western blotting.
Total cellular
extracts of E. coli were electrophoretically separated on
sodium dodecyl sulfate (SDS)-10% polyacrylamide gels or tris-tricine
SDS-16% polyacrylamide gels (20) and electroblotted (31) to a sheet of nitrocellulose or polyvinylidene
difluoride membrane. To verify equal protein loading in each lane, the
membrane was stained with Ponceau S (Sigma, St. Louis, Mo.) following
the manufacturer's protocol. The membrane was probed with rabbit
anti-Hfq or anti-RpoS polyclonal antisera. The antibody-antigen complex was visualized with goat anti-rabbit immunoglobin horseradish peroxidase-conjugated antibody (Pierce, Rockford, Ill.) and ECL reagent
kit (Pierce) following the manufacturer's protocol. The anti-Hfq
rabbit antibody was raised against a chemically synthesized 15-amino-acid peptide (SAQNTSAQQDSEETE) identical to the C'
terminus of the E. coli Hfq protein (Sigma-Genosys,
Woodlands, Tex.). The anti-RpoS antibody was a gift from R. Burgess.
Gel mobility shift assays.
The RNAs used for the mobility
shift assays were obtained as follows. The pSP64-dsrA and pSP64-oxyS
plasmid DNAs were linearized by digestion with HindIII,
and the DsrA and OxyS RNAs were generated by in vitro transcription
with T7 RNA polymerase (Life Technologies). The pGEM-5S plasmid DNA was
linearized by digestion with DraI, and the 5S rRNA was
generated by in vitro transcription with T3 RNA polymerase (Life
Technologies). The transcripts were radioactively labeled at the 3' end
with [-32P]pCp (Amersham Pharmacia Biotech,
Piscataway, N.J.) and T4 RNA ligase (Boehringer Mannheim Biochemicals,
Indianapolis, Ind.). Full-length transcripts were purified on a 6%
polyacrylamide-7 M urea gel and eluted in elution buffer (20 mM
Tris-HCl [pH 7.5], 0.5 M sodium acetate, 10 mM EDTA, 1% SDS) at
65°C for 1 h, followed by ethanol precipitation. The RNA
concentration was determined by measuring the OD260 of
unlabeled transcripts exposed to the same treatment.
The gel mobility shift assays were performed as follows. End-labeled
DsrA or 5S transcript (0.2 pmol) and nonspecific competitor yeast RNA
(100 ng), without or with the indicated amounts of purified Hfq protein
(A. Zhang and G. Storz, personal communication), were incubated in a
10-µl reaction mixture in RNA binding buffer (10 mM Tris-HCl [pH
8.0], 50 mM NaCl, 50 mM KCl, 10 mM MgCl2) for 10 min at
37°C. The samples were then mixed with 2 µl of loading dye (50%
glycerol, 0.1% bromophenol blue, 0.1% xylene cyanol), analyzed on a
6% polyacrylamide gel in 0.5× TBE (Tris-borate-EDTA) buffer at 200 V
for 1.5 h, and subjected to autoradiography. The competition
reactions were performed as described above with purified Hfq protein
(3 pmol), end-labeled DsrA transcript (0.2 pmol), and yeast RNA (100 ng) in the absence or presence of the indicated amounts of unlabeled
DsrA, OxyS, or 5S transcript.
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RESULTS |
Hfq is important for DsrA-mediated regulation of RpoS.
Since
both DsrA and Hfq regulate the translation of the alternative sigma
factor RpoS (3, 17, 27), we explored their possible
interactions by testing the ability of DsrA to function in an
Hfq host. Two hfq mutations were transduced
into our strains. hfq-1, an hfq null allele, and
hfq-2, an insertion in the 3' end of hfq that
produces functional Hfq protein and controls for polar effects on
downstream genes (34), were used.
Three lacZ fusions were used as assays for DsrA activity
(Table 1). An RpoS::LacZ
translational fusion (27), an
rcsA90::lacZ transcriptional fusion (an
indicator of the anti-H-NS activity [26]), and a
cps-2::lacZ transcriptional fusion (an
indicator of RcsA expression [28]) were used. Consistent
with previous results (2, 3, 17), expression of the
RpoS::LacZ translational fusion was decreased 5-fold in a
dsrA mutant (11 U for dsrA1 compared to 50 U for
wild type) and 19-fold in the hfq-1 mutant (2.5 U for
hfq-1 compared to 48 U for the control hfq-2).
When DsrA was overproduced, the RpoS::LacZ fusion was
expressed at 12-fold-higher levels (610 U) than in cells containing
vector alone (50 U). Plasmid-expressed DsrA remained fully functional
in a dsrA1 mutant.
In the absence of Hfq, overexpression of DsrA increased
RpoS::LacZ expression 8-fold (2.5 U compared to 20 U), but
this level of expression was 30-fold down from what is seen in the
wild-type strain (50 and 610 Units). This suggested that DsrA
stimulates RpoS translation in the absence of Hfq but at a reduced
level. Since the dsrA mutant reduced activity to 11 U while
the hfq-1 mutation alone reduced activity to 2.5 U, not all
Hfq-dependent stimulation of RpoS::LacZ was DsrA dependent.
This could be due either to the pleiotropic nature of the
hfq mutation (34) or the existence of another
small RNA that affected RpoS translation (N. Majdalani, J. Murrow, S. Chen, K. Stjohn, and S. Gottesman, Abstr. 99th Gen. Meet. Am. Soc.
Microbiol. 1999, abstr. H-109, p. 350, 1999).
Previous work demonstrated that the expression of the
RpoS::LacZ translational fusion correlated with the amount of
RpoS protein when DsrA was expressed from the chromosome (14,
27). To ensure that pDsrA was affecting translation of the
wild-type rpoS gene, RpoS protein levels were assayed
by SDS-polyacrylamide gel electrophoresis and Western
blotting. RpoS protein levels are increased during exponential growth
at 30°C in LB broth when DsrA is expressed from a plasmid (Fig.
2). Expression of DsrA from a plasmid in the hfq-1 mutant had only a minor effect on the amount of
RpoS (Fig. 2).
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FIG. 2.
Western blot analysis of RpoS levels in hfq-1
mutant and DsrA-overexpressing strains. Cells were grown at 30°C in
LB broth to OD600 of 0.5. Total cellular extracts of the
strains were electrophoretically separated on a SDS-10%
polyacrylamide gel, and electroblotted to a polyvinylidene difluoride
membrane. The membrane was probed with rabbit anti-RpoS polyclonal
antisera and visualized as described in Materials and Methods. Lanes 1 and 2 contain wild-type cells with either vector (pACYC184) or pDsrA.
Lanes 3 and 4 contain isogenic hfq-1 mutants with either
vector (pACYC184) or pDsrA. Since long exposures were used to visualize
RpoS in the hfq mutant strains, lanes 1 and 2 are beyond the
linear range of the Western blot. The position of RpoS is indicated.
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Hfq is important for DsrA-mediated regulation of H-NS.
Plasmid-expressed DsrA increased expression of genes normally repressed
by H-NS, including rcsA, proU, and papA
(26). DsrA has no effect on these H-NS-regulated genes in
an hns mutant strain (26). Activation of these
genes by DsrA therefore is indirect and is mediated through down
regulation of H-NS repression (Fig. 1) (26).
To monitor the anti-H-NS regulatory activity of DsrA, we assayed the
rscA90::lacZ and
cps-2::lacZ transcriptional fusions (Table 1). RcsA is an unstable positive regulator of colonic acid
capsule expression (30). In an hns mutant host
(or when DsrA is expressed from a plasmid in an
hns+ host), rcsA transcription was
increased, leading to activation of the colonic acid capsule synthesis
genes (cps) and a mucoid colony phenotype (26).
Activity of the rcsA90::lacZ fusion
correlated with expression of RcsA and is therefore a good indicator of
rcsA transcription (26). Expression of
cps-2::lacZ is a sensitive indicator of
the amount of wild-type RcsA (28). Both fusions are on a
lambda phage integrated into the chromosome at the lambda att site in otherwise isogenic hosts (26, 28).
Expression of rcsA90::lacZ and
cps-2::lacZ was stimulated by DsrA when
the RNA was expressed from a multicopy plasmid (Table 1). The
hfq-1 mutation interfered with DsrA-dependent stimulation of
rcsA90::lacZ (12 U for hfq-1
compared to 90 U for hfq-2) and cps-2::lacZ (15 U for hfq-1
compared to 90 U for wild type). In addition, the colony phenotypes of
DsrA-overexpressing strains were no longer mucoid in the
hfq-1 mutant strain (Table 1). Thus, Hfq is required for
most of the anti-H-NS activity of DsrA. Since some residual DsrA
activity was noticed in the hfq-1 mutant strain after 2 days
of incubation on MacConkey lactose indicator plates (data not
shown), DsrA can function to repress H-NS in the absence of Hfq, albeit
at a much reduced level.
Regulated expression of Hfq can complement the hfq-1
mutation but does not increase expression of RpoS::LacZ or
rcsA::lacZ in the absence of
DsrA.
Overexpression of hfq from a multicopy plasmid
complements the hfq-1 mutation and confers other phenotypes
(34). To confirm that the hfq-1 mutation was
responsible for the loss of DsrA activity, we constructed a plasmid
that expressed hfq under control of the araBAD
promoter (9). At subsaturating concentrations of arabinose (<1 mM), the araBAD promoter demonstrates different levels
of gene expression within individual cells within a population
(25). Thus, we determined the optimal concentration of
arabinose which complemented the hfq-1 defect in
RpoS::LacZ expression. An arabinose concentration of 150 µM
restored 80% of the expression of the RpoS::LacZ fusion in
an hfq-1 mutant and 100% of the
rcsA::lacZ fusion in an
hfq-1 mutant containing pDsrA (data not shown). Less complementation was seen with higher or lower concentrations of arabinose. Since this observation agrees with work done by others using
a similar araBADHfq construct and assaying RpoS expression (2), 150 µM arabinose was used in the experiments below.
In an hfq-1 mutant, DsrA-mediated regulation of
RpoS::LacZ was restored when Hfq was expressed from the plasmid in
rich media at 30°C with 150 µM arabinose (Fig.
3). In contrast, increased expression of
Hfq in a dsrA1 strain only slightly increased expression of
the RpoS::LacZ fusion (Fig. 3). This suggested that both DsrA and Hfq are necessary for the optimal expression of RpoS at low temperatures.
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FIG. 3.
DsrA and Hfq are both needed for regulation of
RpoS::LacZ at 30°C. Cultures of the various strains grown
overnight were diluted 1:100 in LB broth. Cultures were grown at
30°C, and samples were taken at various times during logarithmic
growth (0.2 > OD600 < 1.0). Total
-galactosidase units were plotted against the OD600 of
the culture. The slopes of the curves between OD values of 0.2 and 1.0 (approximately log phase) were used as the specific activities of the
fusions. Slopes had an r2 of >0.95. Specific
activities varied less than 10% between experiments. All activities
are in relation to that of the wild-type RpoS::LacZ strain
during logarithmic growth (100%) (gray bars). Black bars represent the
addition of 150 µM arabinose. pBADHfq expresses recombinant Hfq under
control of the araBAD promoter. The vector is the
araBAD promoter vector pBAD24. pDsrA has DsrA cloned into
pACYC184 under control of its own promoter. The presence of
hfq-1 and dsrA1 mutations in isogenic strains is
indicated. The inset above the bar graph is a Western blot of those
strains using anti-Hfq antibody. Lanes 1 to 3 of the gel correspond to
the strains and conditions immediately below the inset. Note the
induction of Hfq after the addition of arabinose.
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In an hfq-1 mutant expressing wild-type dsrA from
the chromosome, induction of the plasmid hfq gene did not
affect the expression of an
rcsA90::lacZ fusion (Fig.
4) or a
cps-2::lacZ fusion (data not shown) and
did not make cells mucoid (an indicator of cps gene
expression). Induction of the plasmid hfq gene in wild-type cells also did not affect rcsA or capsule production (data
not shown). Hfq is therefore apparently not limiting under these
conditions. When both pDsrA and pBADHfq are present in an
hfq-1 mutant, induction of hfq increased
rcsA90::lacZ expression about fivefold
(Fig. 4). No increase in rcsA90::lacZ
expression was seen following arabinose induction of a strain carrying
pDsrA and paraBAD (data not shown). All of Hfq's effects on
rcsA and cps expression require pDsrA. In the
absence of arabinose, Hfq was detected from the pBADHfq plasmid (Fig.
3) but was not sufficient to complement the tested phenotypes.
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FIG. 4.
Hfq is necessary for DsrA-mediated regulation of
rcsA::lacZ, but Hfq does not regulate
rcsA::lacZ alone. Cultures of the various strains
grown overnight were diluted 1:100 in LB broth. Cultures were grown at
30°C, and samples were taken at various times during logarithmic
growth (0.2 > OD600 < 1.0). Total
-galactosidase units were plotted against the OD600 of
the culture. The slopes of the curves between OD values of 0.2 and 1.0 (approximately log phase) were used as the specific activities of the
fusions. Slopes had an r2 of >0.95. Specific
activities varied less than 10% between experiments. All activities
are in relation to a wild-type
rcsA90::lacZ strain containing pDsrA
(100%) (gray bars). Black bars represent the addition of 150 µM
arabinose. pBADHfq expresses recombinant Hfq under control of the
araBAD promoter. pDsrA has DsrA cloned into pACYC184 under
control of its own promoter. The presence of the hfq-1
mutation in an isogenic wild-type strain is indicated.
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Hfq is necessary for the stability of chromosome-expressed
DsrA.
Hfq affects the accumulation of ompA, miaA, hfq,
and other mRNAs (32, 33, 35). We therefore determined the
amount and stability of chromosome-expressed DsrA RNA by both a RNase
protection assay and a primer extension assay (see Fig. 6). In
wild-type cells, chromosome-expressed DsrA was less stable than
plasmid-expressed DsrA with a half-life between 6 and 30 min (Fig.
5B, 6B, and
7). The lower value was calculated from
the primer extension assay (Fig. 6B). The higher value was calculated
from the RNase protection assay (Fig. 5B). The differences in the
half-lives calculated by the two assays were consistent between
experiments using the same RNA samples. Accurate calculation of the
stability of chromosome-expressed DsrA was difficult, since the amount
of DsrA increased after the addition of rifampin in the RNase
protection experiments, peaking after ~10 min (Fig. 5B). This
increase was not seen in the primer extension assays (Fig. 6B).
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FIG. 5.
RNase protection assay of DsrA stability in an
hfq-1 strain. Cells were grown at 30°C in LB broth to an
OD600 of 0.5 and treated with rifampin to block new
transcription. Samples were taken at the indicated times, and RNA was
extracted. DsrA was detected using a RNase protection assay and
DsrA-specific probe. The minus sign in panel B indicates that the RNA
was isolated from a dsrA deletion mutant. (A) DsrA expressed
from the chromosome and the plasmid pDDS164. (B) DsrA expressed only
from the chromosome. The positions of full-length, processed,
read-through, and unstable DsrA transcripts are indicated. Processed
DsrA transcripts were also seen when DsrA was expressed from the
plasmid but are not shown. Note that in lane 1, no DsrA is detected in
RNA isolated from a DsrA deletion strain.
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FIG. 6.
Primer extension assay of DsrA stability in an
hfq-1 strain. Cells were grown at 30°C in LB broth to an
OD600 of 0.5 and treated with rifampin to block new
transcription. Samples were taken at the indicated times, and RNA was
extracted. DsrA was detected using a primer extension assay and
DsrA-specific primers. Lanes marked with a minus sign contain RNA
isolated from a dsrA deletion mutant. (A) DsrA expressed
from a plasmid and the chromosome. (B) DsrA expressed only from the
chromosome. Note that the chromosome- and plasmid-expressed
dsrA genes have the same transcription start site. Only the
chromosome-expressed DsrA has a decreased half-life in the
Hfq host.
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FIG. 7.
DsrA half-life in wild-type and Hfq
strains. DsrA amounts from a RNase protection assay were quantitated on
a Storm 840 phosphorimager. Dashed lines are chromosome-expressed DsrA.
Solid lines are plasmid-expressed DsrA. The numbers in parentheses are
half-lives calculated from the curve fit equations. Hfq
is an isogenic strain containing the
hfq-1::kan mutation.
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In the hfq-1 strain, chromosome-expressed DsrA was
dramatically less stable than in the wild type, with a half-life of <1 min in both the RNase and primer extension assays (Fig. 6B, 7B, and 8).
In addition, the DsrA transcript was significantly shorter in the
hfq-1 strain than in the wild type (Fig. 5B). This
difference in size was not detected in primer extension experiments
(data not shown), suggesting a truncation in the 3' end of the DsrA transcript.
Hfq does not affect the transcription or stability of
plasmid-expressed DsrA.
The amount and stability of the
plasmid-expressed DsrA were also determined. The pDsrA plasmid has
dsrA under control of its own promoter with the same
transcription start site as chromosome-expressed DsrA (Fig. 6)
(26). Two sets of DsrA transcripts were detected with the
RNase protection assay in wild-type cells (Fig. 5B). Based on the
results with molecular weight markers, the larger transcripts
corresponded to the three-stem-loop DsrA RNA. The second,
faster-migrating set of transcripts was also detected with primer
extension assays (data not shown). The size was consistent with the
absence of the first stem-loop of DsrA (responsible for RpoS regulation
[14]) and the 5' half of the second stem-loop (responsible for H-NS regulation [13]). Although this
shorter transcript is stable, it is not known whether it has any
regulatory activities.
When grown in rich media at 30°C, the amount of plasmid-expressed
DsrA was equal in the hfq-1 and wild-type strains in both the RNase protection assay (Fig. 5A, lanes 1 and 6) and primer extension assay (Fig. 6A, lanes 1 and 7). In addition, the expression of a dsrA::lacZ fusion is unchanged in
a wild-type strain compared to an isogenic hfq-1 mutant
(specific activities of 51 ± 4 and 46 ± 5 U, respectively).
Thus, Hfq does not regulate dsrA transcription.
The multiple bands seen in both assays are consistent with multiple
transcription start sites (26).
The half-life of plasmid-expressed DsrA, assessed by measuring DsrA
levels at various times after inhibiting transcription with rifampin,
was >30 min for both hfq+ and hfq-1
strains (Fig. 5A, 6A, and 7). This agrees with previous results showing
that DsrA is stable (14). A 60% decrease in the stability
of plasmid-expressed DsrA in an hfq mutant was observed during very long (up to 3 h) experiments (Fig. 7). This is
unlikely to be physiologically significant, because both half-lives are still well above the 20-min doubling time of exponentially growing E. coli grown in rich media.
The RNase protection assay detected DsrA transcription terminator
read-through products from the plasmid-expressed DsrA (Fig. 5A). In
both the hfq+ and hfq-1 strains,
these transcripts were unstable with a half-life of ~2 min (Fig. 5A).
Hfq binds DsrA in vitro.
The loss of stability of
chromosomally expressed DsrA in an hfq-1 mutant coupled with
our genetic data suggested a direct interaction between DsrA and Hfq.
To examine Hfq binding to DsrA, 0.2 pmol of end-labeled DsrA RNA was
incubated with purified Hfq protein and examined by a gel mobility
shift assay (Fig. 8). Incubation with 3 pmol of Hfq led to complete
retardation of DsrA in the presence of 100 ng of yeast tRNA (Fig.
8A). Hfq binding to the control 5S rRNA
was less efficient, requiring 10 pmol of Hfq for complete retardation
(Fig. 8A). Multiple complexes were observed for both DsrA and 5S RNAs,
possibly due to different multimeric forms of the Hfq protein binding
to the RNAs.
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FIG. 8.
Gel mobility shift analysis of DsrA binding to Hfq. (A)
3'-end -32P-labeled transcript (0.2 pmol) of DsrA or 5S
RNA and nonspecific competitor yeast RNA (100 ng) were incubated
without (lanes 1 and 5) or with the indicated amounts of Hfq protein
(lanes 2 to 4 and 6 to 8). (B) 3'-end -32P-labeled DsrA
(0.2 pmol) and yeast RNA (100 ng) were incubated with purified Hfq
protein (3 pmol). Unlabeled transcript of DsrA (lanes 2 and 3), OxyS
(lanes 5 and 6), or 5S (lanes 8 and 9) were added as competitors.
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|
OxyS RNA binds to Hfq in vitro and in vivo (37). To test
the strength and specificity of the DsrA-Hfq complex, the labeled DsrA
RNA and Hfq protein were incubated in the presence of excess unlabeled
DsrA, OxyS, or 5S RNA (Fig. 9B). The DsrA
binding to Hfq was competed by fivefold molar excess unlabeled DsrA.
Between 5- and 25-fold more OxyS RNA was necessary to get a comparable competition. This suggests that Hfq binds more tightly to DsrA than
OxyS. 5S rRNA was a poor competitor, requiring more than 25-fold molar
excess to partially compete with the DsrA-Hfq interaction (Fig. 9B).
These results are indicative of a specific interaction between DsrA and
Hfq that is approximately equal in strength to the OxyS-Hfq
interaction.
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FIG. 9.
Model of Hfq's role in DsrA-mediated regulation. When
initially synthesized, DsrA folds into active and inactive forms. Hfq
binds to DsrA molecules, unfolds them, and allows them to refold into
active forms and inactive forms. Active DsrA forms regulatory complexes
with its targets and leaves the cycle. Alternatively, Hfq and DsrA
could form an RNA-protein complex that is active for the regulation of
rpoS and hns (lower box). These models are not
mutually exclusive.
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DISCUSSION |
The untranslated RNA DsrA regulates at least two global regulatory
networks by affecting mRNA translational efficiency of the global
transcription factors RpoS and H-NS (13, 14). In this
paper, we show that DsrA-mediated regulation of RpoS and H-NS was
absent or severely reduced in an hfq-1 mutant (Table 1). Hfq
is not required for DsrA synthesis, and overexpression of Hfq does not
complement a dsrA1 mutation. In addition, plasmid-expressed DsrA accumulated in an hfq-1 mutant but was only weakly
active for regulation. A direct interaction between DsrA and Hfq was detected in vitro using a gel mobility shift assay. This binding was
specific and was approximately equal to the binding of Hfq to another
regulatory RNA, OxyS, which was shown to bind Hfq in vivo
(37). Since both OxyS and DsrA could compete with each other for binding to Hfq in vitro, it is likely that DsrA also binds to
Hfq in vivo. This observation is consistent with a model that OxyS
binding to Hfq may compete with the binding of other RNAs
(37). According to this model, overexpression of OxyS
could decrease RpoS translation in an Hfq-dependent manner by competing with DsrA.
How do Hfq and DsrA affect gene expression?
Our data are
consistent with two models that explain the necessity for both DsrA and
Hfq to obtain maximal translation of RpoS at low temperatures (Fig. 9).
First, DsrA and Hfq could form a complex that binds to the RpoS mRNA
leader, destabilizing the putative 5' translation inhibitory stem-loop
structure (2). In this case, the function of Hfq might be
to bind to DsrA and unfold the first stem-loop, which is necessary for
the regulation of RpoS translation (14). The role of Hfq
might be analogous to Rop, in which two phenylalanines intercalate into
the stem and facilitate a secondary RNA hybridizing (18).
The unfolded DsrA-Hfq complex could then hybridize to the RpoS mRNA
leader, preventing the formation of the translational inhibitory RNA
secondary structure (2). It is interesting to note that
among the Hfq proteins from 11 gram-negative and 1 gram-positive
bacteria, there are two absolutely conserved phenylalanines at
positions 39 and 42 (data not shown).
A second possibility is that DsrA and Hfq transiently interact, and Hfq
functions as an RNA chaperone that is necessary for the proper folding
of DsrA into an active conformation. A similar activity was proposed
for Hfq interactions with mutS, miaA, hfq, Q phage
(21, 32) and ompA (35) mRNAs as
well as StpA stimulation of RNA self-splicing (38). In the
case of Q, the binding of Hfq is thought to denature an RNA
secondary structure at the 3' end of the positive strand, allowing the
Q replicase to synthesize negative strands (21).
We have shown that plasmid-expressed DsrA increased RpoS and Cps
expression in an hfq-1 host, albeit only modestly; thus, Hfq
is not essential for the regulatory activity of DsrA. With the Hfq
chaperone model, a small portion of DsrA might be expected to
spontaneously fold into an active conformation in the absence of Hfq.
This necessity, but not absolute requirement, for Hfq was also seen
with Q replication (21). Conversely, an
hfq-1 mutant clearly has regulatory effects on RpoS and
other genes that are independent of DsrA (Table 1 and reference
34). In addition, since RpoS expression is not regulated
by DsrA at 37°C (27) but is regulated by Hfq, it is
possible that Hfq can directly affect the formation of the RpoS mRNA 5'
translational inhibitor. At lower temperatures, the secondary structure
of the RpoS mRNA 5' untranslated region is likely to be more stable and
Hfq alone might not be able to "melt-out" the structure. DsrA's
function might then be to decrease the stability of the RpoS leader by binding to it and forming a stable alternative structure (2, 3). Alternatively, there may be other factors (RNAs) that
interact with Hfq at higher temperatures to modulate RpoS translation
(Majdalani et al., Abstr. 99th Gen. Meet. Am. Soc. Microbiol. 1999).
Interactions similar to those postulated for RpoS could also explain
the DsrA-mediated regulation of H-NS translation and H-NS-regulated
genes (13, 26).
Hfq and DsrA stability.
Hfq had a dramatic effect on DsrA
stability when DsrA was expressed from the chromosome. In the wild-type
strain, chromosome-expressed DsrA had a half-life of 6 to 30 min
depending on the assay. In contrast, in the hfq-1 strain,
chromosome-expressed DsrA was very unstable with a half-life of ~1
min in both assays. A degradation product was detected; its presence
suggested that DsrA was truncated at the 3' end in the hfq-1
mutant. This sensitivity to degradation in the absence of Hfq is
opposite to what was seen with the ompA, miaA, mutS, and
hfq mRNAs which are stabilized in an hfq mutant (32, 35).
As previously shown (14) and confirmed in this paper,
plasmid-expressed DsrA was very stable in wild-type cells with a
half-life of 60 min. What was surprising was that in the absence of
Hfq, plasmid-expressed DsrA remained stable with a half-life of 36 min.
This difference might be strain specific, since plasmid-expressed DsrA
does not accumulate in some hfq mutant backgrounds
(12). One possibility is that factors necessary for the
degradation of DsrA are found only within the nucleoid. One prediction
of this model is that DsrA would remain unstable in an hfq-1
mutant even when overexpressed from the chromosome by an inducible promoter.
Whether Hfq acts transiently, by altering the structure of DsrA or by
forming an active RNA-protein complex within the cell, it will be
interesting to discover how Hfq functions to enhance the interaction of
DsrA with its targets. The availability of an in vitro model of
DsrA-Hfq binding will allow us to study this interaction in more detail.
We thank S. Gottesman, S. Garges, N. Majdalani, G. Storz, and R. Blumenthal for helpful comments and G. Beyer for technical assistance.
We also thank M. Winkler for the hfq mutant strains and R. Lease and M. Belfort for unpublished data.
This research was supported in part by grants from NIH (GM56448), The
American Cancer Society-Ohio Division, and the Ohio Board of Regents
Research Challenge II.
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Abstract
Introduction
Present address: Bio-Rad Laboratories, Life Science Group,
Hercules, CA 94547.
