We utilized primer extension analysis to demonstrate that the
divergently transcribed regB and senC-regA-hvrA
transcripts contain stable 5' ends 43 nucleotides apart within the
regB-senC intergenic region. DNA sequence analysis
indicates that this region contains two divergent promoters with
overlapping 
70 type 
35 and 10 promoter recognition
sequences. In vivo analysis of expression patterns of
regB::lacZ and
senC-regA-hvrA::lacZ reporter gene
fusions demonstrates that the regB and
senC-regA-hvrA transcripts are both negatively regulated by
the phosphorylated form of the global response regulator RegA. DNase I
protection assays with a constitutively active variant of RegA indicate
that RegA binds between regB and senC
overlapping 10 and 35 promoter recognition sequences. Two mutations
were also isolated in a regB-deficient background that
increased expression of the senC-regA-hvrA operon 10- and
5-fold, respectively. As a consequence of increased RegA expression,
these mutants exhibited elevated aerobic and anaerobic photosynthesis
(puf) gene expression, even in the absence of the sensor
kinase RegB. These results indicate that autoregulation by RegA is a
factor contributing to the maintenance of an optimal low level of RegA
expression that allows responsiveness to activation by phosphorylation.
 |
INTRODUCTION |
Two-component
phosphorylation-dependent regulatory systems exist in bacteria to allow
adaptation to changes in the environment (28, 29). Among
several species of alpha purple bacteria, there exists a highly
conserved two-component system comprised of the sensor kinase RegB and
the response regulator RegA (2, 3, 15). This regulatory pair
was first identified in the nonsulfur photosynthetic bacterium
Rhodobacter capsulatus, where it was shown to be required
for anaerobic induction of light-harvesting and reaction center
structural genes (2, 3, 17, 25, 37). Responding to
anaerobiosis, the histidine kinase RegB autophosphorylates itself at a
conserved histidine residue. The phosphoryl group is then transferred
to a highly conserved aspartate residue of the cognate response
regulator RegA (17, 25). Phosphorylated RegA (RegA~P) then
binds to the promoter region of the puf, puc, or
puh operon to exert gene activation (7, 11, 12).
Recent analyses of the RegB-RegA pair from several species indicate
that it is a global signal transduction system involved in the
anaerobic induction of many physiological processes. This includes the
synthesis of the light-harvesting, reaction center, and cytochrome
components of the bacterial photosystem and the assimilation of carbon
dioxide and nitrogen (4, 14, 15, 19, 22, 33, 41).
Analysis of regB and regA genes from R. capsulatus, Rhodobacter sphaeroides Rhodovulum
sulfidophilum, and Roseobacter denitrificans demonstrated that they are two genes of a highly conserved
"photosynthesis regulatory gene cluster" (8, 9, 23, 25).
In these species, regB is divergently transcribed from a
three-gene operon comprised of senC, regA, and
hvrA. Mutational analysis indicated that SenC is
involved in the formation of a functional cytochrome c
oxidase complex which is required for proper sensing of anaerobiosis by RegB (9), while HvrA appears to be a transcription factor
that facilitates RegA binding to DNA under dim-light growth conditions (8, 20).
As the function and mechanism of action of individual components are
being unraveled, it is becoming clear that components of the
photosynthesis regulatory gene cluster play important roles in
controlling anaerobic induction of numerous metabolic processes. Consequently, an investigation of the expression of the regB
and senC-regA-hvrA genes can provide important clues to the
control hierarchy of anaerobic gene expression in these species. In the present study, we determined the transcription initiation sites of the
regB and senC-regA-hvrA genes, which revealed the
presence of two divergent overlapping promoters. Reporter gene analyses with lacZ fusions to the regB and senC
promoters, as well as DNase I footprint analysis with RegA, indicated
that phosphorylated RegA negatively regulates regB and
senC-regA-hvrA transcription. Finally, two
regB-deleted strains bearing mutations in the overlapping promoter region were also characterized for a thorough understanding of
the functional significance of having low-level regulated expression of
these regulatory genes.
| |
MATERIALS AND METHODS |
Bacterial strains and growth conditions.
The parent strain
R. capsulatus SB1003 (46), the
regB-deficient strain SD01 (12), the
regA-deficient strain MS01 (37), and the two
promoter mutant strains SD01-M52 and SD01-M08 (as described in Results)
were grown at 34°C in PY salts medium or in RCV2/3PY (47).
Spectinomycin, kanamycin, and gentamicin were all used at a final
concentration of 5 µg/ml for the maintenance of plasmids and the
construction of stable recombinants in R. capsulatus.
Rifampin was used for counterselection of exconjugates at a final
concentration of 100 µg/ml. Highly oxygenated and anaerobic growth
conditions of R. capsulatus cultures were as described previously (37). Escherichia coli DH5
and
S17-1 (
pir) (38) were grown at 37°C in Luria broth
medium (35). Kanamycin, spectinomycin, and gentamicin were
added to the medium at 50, 50, and 10 µg/ml, respectively.
RNA extraction.
Total cellular RNA was isolated from
R. capsulatus cells grown photosynthetically in PY salts
medium. Cells from a 300-ml culture were collected after the culture
reached approximately 75 Klett units (25). Cell pellets were
treated for 20 min at room temperature with 500 µl of lysozyme at 4 mg/ml and then dispersed in 15 ml of a denaturing solution comprised of
4.2 M guanidium thiocyanate, 17 mM Na-N-lauroyl sarcosine,
25 mM Na-acetate, and 100 mM 
-mercaptoethanol at pH 5.5 in
diethylpyrocarbonate (DEPC)-treated H2O. Total RNA was
phenol-chloroform extracted once, precipitated at 4°C overnight with
0.6 volume of isopropanol, and then centrifuged at 17,000 × g for 15 min at 4°C. The crude RNA pellet was then resuspended in 4 ml of denaturing solution supplemented with 2 ml of a
5.7 M CsCl solution. RNA was then purified on a CsCl gradient by using
a swinging-bucket rotor at 30,000 × g overnight at
20°C. The pellet was then phenol-chloroform extracted, ethanol
precipitated, washed, and finally resuspended in 250 µl of
DEPC-treated H2O.
Primer extension.
Two primers,
5'-CCCATCGCAACAGGATCAATGTCCGC-3' and
5'-GCCGACATGTCGAATTCCGGCCGGTCG-3', were designed to anneal
the regB gene. Similarly, another two primers,
5'-GCGGCAAAGCGATCCGTCTCATGGG-3' and
5'-GAGATGCCCACCACGACGACGACGGC-3', were designed to anneal the senC gene. Labeling of the primers was carried at 37°C
for 1 h in a 10-µl total reaction volume containing 100 ng of
primer, 1× T4 kinase buffer (New England Biolabs), 10 U of T4
polynucleotide kinase (New England Biolabs), and 320 µCi of
[
-32P]ATP (specific activity of 7,000 Ci/mmol;
Amersham). Unincorporated label was separated on a Sephadex G-50
fine-nick spin column (Pharmacia) at 500 × g in
accordance with the manufacturer's instructions. Labeled primers were
then resuspended in 20 µl of DEPC-treated H2O. Annealing
reaction mixtures containing 16.2 µg of total RNA, 2.5 µl of
labeled primer, 10 mM Tris-acetate (pH 7.4), and 60 mM
NH4Cl in a 10-µl total volume were heated at 80°C for
10 min, cooled to the hybridization temperature of 50°C
(hybridization temperature = 29.3°C [0.41% G+C for primer]),
and further incubated at the same temperature for an additional 20 min.
The premixed extension reaction mixture was composed of 20 mM
Tris-acetate (pH 7.4), 20 mM Mg-acetate, 120 mM NH4Cl,
actinomycin D at 80 µg/ml, 50 mM dithiothreitol, 750 µM
deoxynucleotide triphosphate, and 12.25 U of avian myeloblastosis virus
reverse transcriptase (Boehringer Mannheim). Primer extension was
performed at 42°C for 1 h and then stopped with 80 µl of 0.3 M
Na-acetate (pH 6.0) and 250 µl of 100% ethanol. Reactions were
precipitated and resuspended in 10 µl of loading dye (10 mM NaOH, 10 mM EDTA, 0.05% bromophenol blue, and 0.05% xylene cyanol in
formamide). The sequencing ladders used were obtained as described by
the manufacture (thermo-Sequenase sequencing kit; Amersham Pharmacia
Biotech) using the same labeled primers. Reactions were heated at
80°C for 3 min and loaded onto a 6% urea denaturing polyacrylamide gel.
DNA sequencing.
DNA fragments containing the 5' end of
regB and the full-length senC and regA
genes were amplified by PCR from the wild-type and putative mutant
chromosomes by using upstream and downstream primers
5'-CTCTAGAAATAG CCGTAAGCGCAATCAG-3' and
5'-CGGTACCTCCAGTGAGTGGTTTCATGG-3', respectively. DNA
sequencing was carried out by using several primers that annealed at
different sites of the PCR-amplified fragment using an ABI automatic
sequencing system (Perkin-Elmer).
Plasmid construction and mobilization.
The wild-type
senC-regA-hvrA promoter reporter plasmid pReg-operon and the
two promoter mutant reporter plasmids pReg-M52 and pReg-M08 were
constructed as follows. DNA fragments containing the regB
and senC-regA-hvrA promoter regions were PCR amplified from
the chromosomes of the wild-type and mutant strains by using primers
5'-GCGCCGCCAGGTGACCGACGACCG-3' and
5'-GCATGCACCGCCGATCTGCGCCGA-3', which contain
BstEII and SphI restriction sites (underlined), respectively. The PCR products were first cloned into the
BstEII and SphI sites of lacZ shuttle
vector pDC400 (21) and subsequently subcloned into the
BstEII and SstI sites of lacZ reporter
vector pZM400 as described previously (21). A
spectinomycin-resistant omega cassette (32) was then cloned
into the HindIII site that is located within the
kanamycin resistance gene in pZM400.
The regB reporter plasmid pRegB01 was constructed by the
procedure described above by using primers
5'-GGTTGCGCCGGTTACCGAGATCAG-3' and
5'-GGTTCGCATGCACATCGGCAGGTT-3' to amplify the
promoter region, which puts BstEII and SphI sites
(underlined) in the opposite orientation to the primers used for
construction of the regA promoter reporter vectors.
Promoter mutations were also cloned into suicide vectors and recombined
back into regB knockout strain SD01. For this analysis, DNA
fragments carrying the full-length senC gene were amplified from the mutant strain genomic DNA preparations by PCR using primers 5'-CTCTAGAAATAGCCGTAAGCGCAATCAG-3' and
5'-CGAGCTCATCGTCATCGACCAGAAGCAG-3', which
contain XbaI and SacI digestion sites
(underlined), respectively. The PCR products were subsequently cloned
into the integration plasmid pZJD3 (18), and the
resulting constructs were then backcrossed into strain SD01
harboring pufQ::lacZ
translational fusion reporter plasmid pCB532
(1) by
conjugation with plasmid-mobilizing strain S17-1 (pir)
(38). Transconjugates were isolated by restreaking several
times onto PY salts plates containing spectinomycin and gentamicin. The
resulting recombinants exhibited phenotypes (spectral analysis,
photosynthetic growth rates, and puf operon transcription rates) that were indistinguishable from those observed with the original isolates (data not shown).
Spectral analysis and -galactosidase activity.
In vivo
absorption spectra were obtained from crude intracytoplasmic membrane
preparations by sonicating cells grown either aerobically or
anaerobically that were harvested at 50 to 100 Klett units. Following
centrifugation at 10,000 × g for 5 min, the soluble
fraction was scanned from 400 to 900 nm with a Beckman DU-50 recording
spectrophotometer (47). -Galactosidase activities of
pufQ::lacZ fusion plasmid pCB532 in
wild-type strain SB1003 and mutant strains SD01, SD01-M52, and
SD01-M08, as well as the activities of pReg-operon, pRegB01, pReg-M52,
and pReg-M08 in strains SB1003, SD01, and MS01, were measured as
described previously (13).
Antibody production and Western blot analysis.
To obtain
polyclonal antibodies against RegA, E. coli-expressed
recombinant proteins (17) were excised from a sodium dodecyl sulfate-polyacrylamide gel electrophoresis gel and subsequently injected subcutaneously into a New Zealand White rabbit by Cocalico Biological, Inc. (Reamstown, Pa.). After initial inoculation, booster
injections were administrated in the second and the third weeks,
followed by a first test bleed in the fourth week. Additional booster
and test bleeds were performed on the 49th and 56th days, respectively.
The specificity of the antiserum was then tested by Western blot
analysis. For Western blot analysis, the wild type and various mutants
were grown anaerobically to 50 to 100 Klett units and collected by
centrifugation at 7,600 × g for 10 min. The cells were
washed once with washing buffer (20 mM Tris-HCl, 1 mM EDTA, 100 mM
NaCl, 0.2 mM phenylmethylsulfonium fluoride, pH 7.2), resuspended in
washing buffer, and then sonicated for 3 × 20 s. The crude
extracts were clarified by centrifugation at 12,000 × g for
10 min, and proteins in the supernatant were then separated by sodium
dodecyl sulfate-12% polyacrylamide gel electrophoresis. The proteins
were transferred onto a nitrocellulose membrane (Schleicher & Schuell),
using a Mini Trans-Blot electrophoretic transfer cell following
instructions of the manufacturer (Bio-Rad). The proteins were
subsequently detected using the ECL Western blotting analysis system as
indicated by the manufacture (Amersham Life Science). A transblotted
membrane was blocked with 5% nonfat dry milk in PBS-Tween (80 mM
Na2HPO4, 20 mM NaH2PO4,
100 mM NaCl, 0.1% Tween 20, pH 7.5) for 1 h at room temperature
and then incubated overnight at 4°C with polyclonal antibody against
RegA that was diluted at 1:8,000 in PBS-Tween. The membrane was then
washed with PBS-Tween and incubated for 1 h at room temperature
with a horseradish peroxidase-labeled anti-rabbit antibody diluted 1:10,000 in PBS-Tween. The membrane was then washed, and the
chemiluminescent antigen-antibody complexes were detected by exposure
to X-Omat AR film (Kodak).
DNase I footprint analysis.
Using chromosomal DNA from
wild-type R. capsulatus as a template, a PCR was performed
to generate a 210-bp DNA fragment containing the regB-senC
intergenic region by using primers 5'-CCGGACCCATTCCTGATGGCTC-3' and 5'-CTGCCGTGGCAGCCAGCGCGGC-3'. One of the primers
in the PCR mixture was 5' end labeled with T4 polynucleotide kinase and
[-32P]ATP prior to amplification as described for
primer extension analysis. The 32P-labeled promoter DNA
fragments were purified from 5% nondenaturing polyacrylamide gels by
electroelution. After precipitation and washing with ethanol, the DNA
fragments were resuspended in Tris-EDTA buffer containing 50 mM NaCl.
Footprint assays were initiated with a DNA probe and various amounts of
RegA* (RegA* was purified as described in reference 12) in footprint buffer containing 40 mM HEPES
(pH7.8), 8 mM Mg-acetate, 75 mM K-acetate, 2 mM CaCl2, 1.5 mM dithiothreitol, bovine serum albumin at 125 µg/ml, and 16%
glycerol in a total reaction volume of 20 µl. After 20 min of
incubation at room temperature, 2 µl of 0.5-µg/ml DNase I was added
to the reaction mixtures and digestion proceeded for 5 min at room
temperature before being quenched by the addition of 180 µl of stop
solution (0.33 M NH4-acetate, 55 mM EDTA, 14 µg of yeast
tRNA per ml). The reaction mixtures were then phenol-chloroform
extracted, ethanol precipitated, dried, and resuspended in 3 µl of
formamide loading dye. The amount of radioactivity in each sample was
determined by Cerenkov scintillation counting to ensure that equal
amounts of digested probe were loaded for electrophoresis. Reaction
samples were heated at 90°C for 10 min and electrophoresed through a
6% urea denaturing Long Ranger gel (FMC Bioproducts, Rockland, Maine).
A modified Maxam-and-Gilbert G+A chemical sequencing reaction was used
to determine positions of protected nucleotides relative to the
transcription start site (24).
| |
RESULTS |
Identification of transcription start sites.
Primer extension
analyses were undertaken with total cellular RNA isolated from
anaerobically grown wild-type R. capsulatus cells to map the
start sites of the regB and senC-regA-hvrA
transcripts. When 32P-labeled primers complementary to the
regB coding region were used, a stable 5' end was observed
at a G residue 98 nucleotides upstream of the regB start
codon (Fig. 1A). When labeled primers for
the senC transcript were used, a major 5'-end product was observed at an A residue located 16 nucleotides upstream of the senC start codon, as well as a minor end product at a C
residue located at nucleotide 17 (Fig. 1B). As shown in Fig.
2A, the major 5' ends are 43 nucleotides
apart within the regB-senC intergenic region. Inspection of
the DNA sequence between the transcription start sites revealed the
presence of two divergent promoters that each contain 10 and 35
elements similar to those of E. coli 70-type
promoter recognition sequences. These divergent promoters contain
overlapping 10 and 35 sequences (Fig. 2A).
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FIG. 1.
Primer extension (PE) analyses to determine the start
sites of the regB (A) and senC-regA-hvrA
transcripts (B). The G, A, T, and C ladders are as indicated. Primer
extension products are indicated by asterisks, and transcription
initiation sites are indicated by arrows.
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FIG. 2.
(A) Characteristics of the divergent overlapping
regB and senC-regA-hvrA operon promoters. The
transcription start sites of the regB and
senC-regA-hvrA genes are indicated by arrows, with
translation start sites of the regB and senC
genes also indicated. The 35 and 10 regions are indicated by lines,
and the RegA protection regions on both strands are depicted as white
letters on a black background. The hypersensitive sites are indicated
by asterisks. (B) Comparison of the wild-type and mutant
senC-regA-hvrA promoters with the consensus sequence of
E. coli 70-type promoters. The R. capsulatus 35 and 10 regions are in capital letters. The
most-conserved nucleotides are represented by large uppercase letters,
the less-conserved nucleotides are represented by smaller uppercase
letters, and the least-conserved nucleotides for E. coli
70 are represented by lowercase letters, with
conservation between E. coli and B. capsulatus
promoters highlighted by lines. The numbers below the white-on-black
letters indicate the sites of promoter mutations in strains SD01-M52
and SD01-M08.
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The regB and senC-regA-hvrA transcripts are
negatively regulated by RegA~P in vivo.
Many transcription
factors, including some response regulators, are either positively or
negatively autoregulated (6, 10, 16, 26, 27, 34, 36, 39, 40,
42-45). To determine if the RegA protein influences the activity
of its own promoter and possibly the regB promoter, we
assayed the transcription of the regB gene and the
senC-regA-hvrA operon with lacZ transcriptional fusions. By using regB promoter reporter plasmid pRegB01, we
reproducibly observed a twofold reduction in -galactosidase activity
when the wild-type strain was grown under anaerobic versus aerobic conditions (Fig. 3A, left). This
reduction was caused by phosphorylated RegA, since constitutively high
levels of expression were observed in regB-disrupted strain
SD01, as well as in regA-disrupted strain MS01.
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FIG. 3.
-Galactosidase activity measurements of wild-type and
mutant promoter expression. (A) Activity of the regB
reporter plasmid pRegB01 (left) and the wild-type senC
reporter plasmid pReg-operon (right) in wild-type (SB1003),
regB mutant (SD01), and regA-disrupted (MS01)
cells. A plus or minus sign indicates growth in the presence or absence
of oxygen. (B) Activities of promoter mutant vectors pReg-M52 (left)
and pRegM08 (right) harbored in the same strains as in panel A. Units
of activity are micromoles of ONPG
(o-nitrophenyl--D-galactopyranoside)
hydrolyzed per minute per milligram of protein. The results shown are
averages of at least three independent assays.
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When using the senC-regA-hvrA promoter probe plasmid
pReg-operon, we observed a similar pattern of expression, namely, a
twofold reduction of activity in anaerobically grown wild-type cells
and no effect of oxygen on regB- or
regA-disrupted cells (Fig. 3A, right). Thus, both promoters
are repressed by phosphorylated RegA.
RegA binds to the regB and senC-regA-hvrA
promoters in vitro.
We next addressed the question of whether the
negative autoregulation observed with RegA in vivo is a direct
consequence of binding of RegA to the overlapping regB gene
and senC-regA-hvrA operon promoters. For this analysis, we
performed DNase I nuclease protection assays on the overlapping
promoter regions by using purified RegA*, which is a previously
described variant of RegA that exhibits constitutive
(phosphorylation-independent) DNA binding activities in vivo and in
vitro (12). As demonstrated by the protection patterns in
Fig. 4A and B, RegA* binds to a region that spans the overlapping 10 and 35 promoter regions. Relative to
the major start site of the senC-regA-hvrA transcript, RegA* protects a region stretching from 15 to 30 on the bottom strand and
a region stretching from 3 to 24 on the top strand. There are also
hypersensitive sites located on the top strand at position 22 and on
the bottom strand at position 31 (Fig. 2A). Since the regB
promoter overlaps the senC-regA-hvrA promoter, protection of
this promoter relative to its transcription start site is from 14 to
29 on the top strand and from 20 to 41 on the bottom strand (Fig.
2A). The RegA* protection pattern suggests that RegA~P directly
represses the activity of these divergent overlapping promoters.
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FIG. 4.
DNase I footprint analysis of RegA* protection in the
regB and senC-regA-hvrA promoter region. (A)
Footprint analysis of the top strand. (B) Footprint analysis of the
bottom strand. G+A indicates Maxam-and-Gilbert chemical cleavage
patterns. Lanes 2 to 6 are DNase I digestions of binding reaction
mixtures containing increasing amounts (in micrograms) of purified
RegA*. The binding reaction mixture in lane 7 contains no RegA*. The
thick lines delineate regions protected by RegA*, and the asterisks
indicate hypersensitive sites. The transcription start sites of
regB and senC-regA-hvrA are also indicated.
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Characterization of promoter mutants.
We next addressed the
functional significance of having low-level regulated expression of
RegA through the characterization of strains containing point mutations
in the overlapping-promoter region. In a previous study
(12), we described a genetic screen for the isolation of
mutants that exhibit constitutively high-level photosystem synthesis in
the absence of the sensor kinase RegB. Two of the 14 isolates were
shown to contain point mutations in regA which rendered the
response regulator active for initiation of transcription even in the
absence of phosphorylation by RegB (7, 12). The remaining 12 "RegB bypass" isolates contained undefined mutations outside of
regA. In this study, we further characterized the RegB
bypass mutants by performing DNA sequence analysis of the regions
flanking regA. The results of this sequence analysis
indicated that 10 of the 12 newly sequenced RegB bypass mutants
contained base pair substitutions in the intergenic promoter region
that drive expression of the senC-regA-hvrA transcript. Among these promoter mutants, eight contained the same T
C transition mutation at position 33 and the other two strains contained the same
CT transition mutation at position 17 relative to the start of the
senC-regA-hvrA operon transcript (Fig. 2B). Strain SD01-M52, which contains a TC mutation at 33, and strain SD01-M08, which contains a CT mutation at 17, were chosen for further analysis.
Previous in vitro footprint assays indicated that unphosphorylated RegA
could bind to the puc promoter with 16-fold lower affinity
than phosphorylated RegA (7). It is therefore possible that
these putative promoter mutations bypass the requirement for RegB by
increasing the intracellular amount of RegA to a level that will allow
promoter binding and subsequent activation of photosynthesis gene
expression in the absence of phosphorylation. To test whether the
intergenic point mutations indeed affect the transcription of the
senC-regA-hvrA operon, we constructed promoter probe vectors
by using the same PCR primers, cloning techniques, and vectors
described above for the wild-type senC-regA-hvrA operon promoter reporter vector pReg-operon. The only difference was the use
of SD01-M52 or SD01-M08 chromosomal DNA as the template for PCR
amplification, which resulted in the construction of mutant promoter
reporter vectors pReg-M52 and pReg-M08, respectively. When the
-galactosidase values obtained with these promoter mutants (Fig. 3B)
were compared to -galactosidase values obtained with the wild-type
promoter vector pReg-operon (Fig. 3A, right), we observed that pReg-M52
and pReg-08 had 10- and 5-fold increases in promoter activity,
respectively. These promoter mutations were still repressed by
phosphorylated RegA, as evidenced by the observation that the
activities of both pReg-M52 and pReg-M08 were significantly lower under
anaerobic growth conditions than under aerobic conditions in wild-type
strain SB1003. This conclusion was confirmed by the fact that a
constitutively high level of -galactosidase activity was observed in
regB and regA mutant strains SD01 and MS01,
respectively, when they were grown under aerobic or anaerobic
conditions (Fig. 3B).
We also directly assayed for RegA protein levels in vivo by performing
Western blot analysis on extracts derived from anaerobically grown
cells with RegA-specific polyclonal antibodies. As shown in Fig.
5, regB-disrupted strain SD01
exhibited an amount of RegA slightly elevated over that observed with
the wild-type strain SB1003. This confirmed the -galactosidase
results described above, which indicated that transcription of
senC-regA-hvrA was repressed by phosphorylated RegA. The
level of RegA was even higher in SD01-M52 and SD01-M08 cells. This is
congruent with the -galactosidase-based promoter reporter probe
results discussed above, which show significantly higher expression for
pReg-M52 and pReg-08, which contain the promoter mutations (Fig. 3B),
than for the wild-type promoter vector pReg-operon (Fig. 3A).
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FIG. 5.
Western blot analysis of crude extracts from strains
SB1003, SD01, SD01-M52, and SD01-M08 grown anaerobically. Purified RegA
protein (15 ng) was used as a positive control in the first lane, and
20 µg of total cellular protein was added to the other lanes.
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Increased expression of the senC-regA-hvrA operon leads
to elevated photosynthesis gene expression.
Spectral and
puf operon expression analyses were also performed on
strains SD01-M52 and SD01-M08 to address the consequence of elevating
senC-regA-hvrA operon expression for the synthesis of the
photosystem. Spectral analysis demonstrated that both wild-type strain
SB1003 and regB-disrupted strain SD01 exhibit characteristic low levels of photopigment synthesis when grown aerobically (Fig. 6A). This is contrasted by a significant
increase in pigment levels in aerobically grown SD01-M52 and SD01-M08
cells. As expected, when wild-type strain SB1003 was grown
anaerobically, the photopigment levels significantly increased while
the regB-disrupted strain SD01 exhibited a lower level of
photopigment synthesis as a consequence of the absence of the sensor
kinase (Fig. 6B). However, spectral analysis of anaerobically grown
SD01-M52 and SD01-M08 cells exhibited significantly higher levels of
pigment synthesis than observed with parent strain SD01, with SD01-M52
synthesizing slightly more photopigments than SD01-M08 (Fig. 6B).
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FIG. 6.
Spectral analysis of crude membrane fractions from
cultures grown aerobically (A) or anaerobically (B). SB1003 is the
wild-type strain, SD01 is the regB knockout strain, and
SD01-M52 and SD01-M08 are mutant strains harboring mutations in the
promoter region of the senC-regA-hvrA operon. Each scan was
performed on the same cell mass, as determined by spectral analysis at
660 nm.
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To examine whether the elevated photosystem synthesis observed by
spectral analysis is due to the direct effect of RegA on photosynthesis
gene expression, measurement of puf operon expression was
also undertaken by using the reporter plasmid pCB532 in wild-type and mutant strains. As shown in Fig. 7,
the -galactosidase activity levels obtained from the puf
reporter plasmid harbored in strains SB1003 and SD01 grown aerobically
were essentially the same as reported before, with more than 20-fold
anaerobic induction in the wild-type strain and no significant
induction in the regB-disrupted strain (25).
However, the -galactosidase activities in strains SD01-M52 and
SD01-M08 were constitutively high, with strain SD01-M52 showing a
slightly higher level of expression than SD01-M08. These results are in
good agreement with the regulation pattern shown by spectral analysis.
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FIG. 7.
-Galactosidase activity measurement of
puf::lacZ reporter gene plasmid
pCB532 in strains SB1003, SD01, SD01-M52, and SD01-M08 (see the
legend to Fig. 6 for strain genotypes). Cells were grown either
aerobically (open bars) or anaerobically (solid bars), and
-galactosidase activities were then measured as described in the
legend to Fig. 3.
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| |
DISCUSSION |
Divergent promoters for the regB and
senC-regA-hvrA operons overlap with promoter activities
repressed by RegA~P.
Prior to this study, there was no
investigation of the expression pattern of a photosynthesis regulatory
gene from a photosynthetic prokaryote. In order to obtain a better
understanding of the RegB-RegA signal transduction pathway, we have
characterized the promoters and expression patterns of the
regB gene and the senC-regA-hvrA operon. Mapping
of transcriptional start sites of the divergently transcribed
regB gene and the senC-regA-hvrA operon indicates that the major transcripts are separated by 43 nucleotides delineating two superimposed divergent promoters. These promoters are probably transcribed by an E. coli 70-RNA polymerase
holoenzyme, as indicated by the similarity of the 35 and 10 regions
to the 70 consensus sequence (Fig. 2A and B, upper).
Divergent overlapping promoters have been described in many other
systems, where they presumably provide some advantage in coregulating
transcripts by a common signal. The binding of a regulatory protein to
a region that contains overlapping promoters can either activate or
repress transcription in both directions or activate transcription in one direction and repress it in the other direction (5, 30, 31,
43). For example, in E. coli K-12, the ilvY
and ilvC genes, whose products are involved in
isoleucine-valine biosynthesis, are also divergently transcribed from
overlapping promoters. The regulator IlvY negatively autoregulates its
own expression 2-fold while activating ilvC expression
15-fold (43). In the case of RegA, we observed that
phosphorylated RegA negatively influences the transcriptional activity
of both regB and senC-regA-hvrA transcripts by
approximately twofold. The repressing activity of RegA~P is presumably mediated by steric interference with RNA polymerase binding
to the promoters, since our footprint results indicate that the
RegA~P binding site overlaps the regB and
senC-regA-hvrA promoter recognition sequences.
A few additional two-component response regulators have also been
demonstrated to be autoregulated either positively or negatively (6, 16, 34, 36, 39, 42, 44, 45). Among them, a situation
similar to that described here for RegA was also observed for the
response regulator FlbD in Caulobacter crescentus, which is
encoded by the last gene in the fliF operon (6, 34,
45). Phosphorylation of FlbD by the sensor kinase FlbE is known
to be required for the activation of numerous level III and IV
flagellar genes, as well as negative autoregulation of the
fliF operon.
Maintaining RegA at an appropriate level of expression is
functionally important.
We also isolated and characterized two
senC-regA-hvrA promoter mutants in a regB
deletion background that significantly affect the expression of
photosynthesis genes that are controlled by RegA~P. Promoter
expression analysis indicates that point mutations at positions 33
and 17, relative to the major startsite of the senC-regA-hvrA transcript, resulted in 10- and 5-fold
increases in senC-regA-hvrA promoter activity, respectively.
Inspection of the DNA sequence indicates that the T-to-C mutation at
33 creates a perfect match to the 35 region of the canonical
E. coli 70 consensus sequence (Fig. 2B,
middle). The C-to-T mutation at 17 also results in a better fit to
the 10 region of the E. coli 70 consensus
sequence (Fig. 2B, bottom). It should also be noted that the mutation
at 17 is well within the region of DNA that is protected by RegA from
DNase I digestion, whereas the mutation at position 33 is located
just at the boundary of protection (Fig. 2A). However, neither mutation
appears to significantly affect RegA~P binding, as evidenced by the
observation that both mutant promoters are anaerobically repressed in
vivo by RegA~P (Fig. 3B). Furthermore, in vitro footprint analysis
indicates that the affinity of RegA* binding to mutant DNA templates is similar to that observed with wild-type promoter templates (data not
shown). Thus, the increase in promoter activity observed in these
mutants may be a result of better promoter binding, or open complex
formation, by the RNA polymerase holoenzyme containing a E. coli 70-type factor rather than due to a reduction
in the repressing activity of RegA~P.
The promoter mutations in strains SD01-M52 and SD01-M08 result in much
more photosystem synthesis and puf operon expression than
observed with regB-deficient parent strain SD01. This
indicates that unphosphorylated RegA activates gene expression in vivo
in these strains. Recent footprint analysis has indicated that
unphosphorylated RegA exhibits specific binding to the puc
operon promoter region with an affinity 16-fold lower than that of
phosphorylated RegA (7). Since RegA expression appears to be
elevated 5- or 10-fold as a consequence of the promoter mutations, it
is reasonable to presume that the RegA concentration has risen in the
mutant strains to a level that promotes DNA binding, and subsequent
activation of photosynthesis gene expression, in the absence of
phosphorylation. Thus, low-level expression of RegA appears to be
necessary to promote phosphorylation-dependent activation of target
gene expression.
RegA~P has multiple regulatory roles.
Combining the results
of the present study and previous studies (2, 3, 7, 12, 17, 25,
37), the RegB-RegA regulon in R. capsulatus can now be
depicted as diagrammed in Fig. 8.
At the top of the hierarchy, RegA~P functions as a transcriptional repressor of regB and senC-regA-hvrA expression.
Below that, RegA~P functions as a transcription activator for the
puf, puc, and puh operons, which code
for the light-harvesting and reaction center apoproteins, as well as an
activator of several nonphotosynthesis genes, such as those involved in
CO2 assimilation, nitrogen fixation, and cytochrome
c2 expression (4, 7, 12, 14, 15, 19, 22,
33, 41). This study, as well as continued analysis of the
RegB-RegA regulon in R. capsulatus and in other species,
should provide better understanding of how this regulator controls the expression of these diverse metabolic processes.
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FIG. 8.
Activation and repression by the RegA-RegB regulon.
Negative and positive regulation of the regulatory gene cluster and
photosynthesis genes by RegA~P is depicted.
|
|
This study was supported by research grant GM40941 (to C.E.B.) from the
National Institutes of Health.
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Abstract
Introduction
Present address: Department of Physiology, University of Michigan
Medical School, Ann Arbor, MI 48109-0622.
