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Journal of Bacteriology, November 2001, p. 6344-6354, Vol. 183, No. 21
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.21.6344-6354.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Interactive Control of Rhodobacter
capsulatus Redox-Balancing Systems during
Phototrophic Metabolism
Mary A.
Tichi and
F. Robert
Tabita*
Department of Microbiology and Plant
Molecular Biology/Biotechnology Program, The Ohio State University,
Columbus, Ohio 43210-1292
Received 9 March 2001/Accepted 9 August 2001
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ABSTRACT |
In nonsulfur purple bacteria, redox homeostasis is achieved by the
coordinate control of various oxidation-reduction balancing mechanisms
during phototrophic anaerobic respiration. In this study, the ability
of Rhodobacter capsulatus to maintain a
balanced intracellular oxidation-reduction potential was considered; in addition, interrelationships between the control of known
redox-balancing systems, the Calvin-Benson-Bassham, dinitrogenase and
dimethyl sulfoxide reductase systems, were probed in strains grown
under both photoheterotrophic and photoautotrophic growth conditions. By using cbbI (cbb form I
operon)-, cbbII-, nifH-, and
dorC-reporter gene fusions, it was demonstrated that
each redox-balancing system responds to specific metabolic
circumstances under phototrophic growth conditions. In specific mutant
strains of R. capsulatus, expression of
both the Calvin-Benson-Bassham and dinitrogenase systems was influenced
by dimethyl sulfoxide respiration. Under photoheterotrophic growth
conditions, coordinate control of redox-balancing systems was further
manifested in ribulose 1,5-bisphosphate carboxylase/oxygenase and
phosphoribulokinase deletion strains. These findings demonstrated the
existence of interactive control mechanisms that govern the diverse
means by which R. capsulatus maintains
redox poise during photoheterotrophic and photoautotrophic growth.
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INTRODUCTION |
Rhodobacter
capsulatus is a nonsulfur purple photosynthetic bacterium
that exhibits diverse respiratory abilities, allowing this organism to
grow under a variety of environmental conditions. Branched respiratory
electron transport pathways allow R. capsulatus to grow aerobically in the dark, either chemoautotrophically or chemoheterotrophically, by using O2 as the
terminal electron acceptor. Indeed, its high capacity for aerobic
chemoautotrophic growth distinguishes it from other well-studied
nonsulfur purple bacteria, such as R. sphaeroides
and Rhodospirillum rubrum (26). Like other organisms of this group, R. capsulatus can
also grow anaerobically in the light, either photoautotrophically or
photoheterotrophically, using cyclic photosynthetic electron transport
to generate a proton motive force. These organisms can grow
fermentatively as well. Due to such metabolic versatility,
R. capsulatus provides an excellent system with
which to gain insight into the control of redox homeostasis. Yet,
compared to the thorough and well-characterized redox control studies
of Escherichia coli (for a review, see reference
17 or 51 and references therein), knowledge
of the control of redox homeostasis in R. capsulatus is somewhat limited.
During phototrophic growth, various electron acceptors are employed, in
a hierarchical manner, to maintain a balanced redox state in
R. capsulatus (50). In the presence
of organic carbon under light anaerobic growth conditions
(photoheterotrophic growth), the redox-balancing mechanism(s) consists
primarily of the Calvin-Benson-Bassham (CBB) reductive pentose
phosphate pathway (CBB system). Under some growth conditions, the
dinitrogenase enzyme complex (dinitrogenase system), the dimethyl
sulfoxide (DMSO) reductase (DMSOR) system, or other systems yet to be
identified or implicated in redox control are employed. Specific
reactions of the CBB pathway allow CO2 to
function as a sink for excess reducing equivalents generated by the
metabolism of carbon substrates such as L-malate
and succinate. Thus, the predominant role of the CBB pathway during
photoheterotrophic growth is to balance the oxidation-reduction
potential of the cell (13, 24, 55). The capacity for
CO2-dependent growth under photoautotrophic
growth conditions is accomplished primarily by the CBB system, where
the chief role of the CBB pathway is to provide the cell with carbon
via the assimilation of CO2. The duality of roles
of the CBB system leads to an interplay between the maintenance of
redox poise and the control of carbon metabolism under
photoheterotrophic and photoautotrophic growth conditions. The
dinitrogenase system is synthesized in most phototrophs when the
organism is placed in an ammonia-free environment. This system enables
Rhodobacter to grow under conditions in which dinitrogen is
the sole source of nitrogen (N2-dependent
growth); i.e., the cells catalyze the reduction and assimilation of
atmospheric dinitrogen to ammonia, accompanied by the reduction of
protons to molecular hydrogen. The process of dinitrogen fixation
requires much reducing power and is an energy-intensive process
(5). Not only does the dinitrogenase system play a primary
role in nitrogen metabolism (23), but it has also been
shown to be involved in redox homeostasis in Rhodobacter and
Rhodospirillum rubrum (22, 50).
Photoheterotrophic growth with a poor nitrogen source such as glutamate
signals the cell to synthesize the dinitrogenase system (for a review,
see reference 25 and references therein). Under such
growth conditions, the excess reducing equivalents generated by the
oxidation of carbon substrates, such as malate, are consumed by the
reduction of protons and consequent evolution of molecular hydrogen by
a hydrogenase-like activity of the dinitrogenase system. This allows the cell to balance its intracellular redox potential
(20). Physiological studies have shown that a link between
carbon metabolism and nitrogen metabolism exists that is intimately
associated with the control of intracellular redox poise in
R. capsulatus (50), R. sphaeroides (22, 43), and R. rubrum (22). Specifically, in the absence of a
functional CBB system (achieved through the inactivation of genes
encoding key and unique enzymes of the CBB pathway), spontaneous
variants of strains with photoheterotrophic competency (PHC) and CBB
deficiency dissipate excess reducing equivalents as
H2 gas by derepressing the dinitrogenase system (22, 50). Respiration of the auxiliary oxidant DMSO or
trimethylamine-N-oxide (TMAO) through the DMSOR system has
also been shown to play an important role in the maintenance of redox
poise during phototrophic growth of R. capsulatus
(27, 44). Indeed, DMSO respiration allows growth of
CBB-deficient strains of R. sphaeroides
(11, 18, 19, 55) and R. capsulatus
(40, 50) under photoheterotrophic growth conditions in the
presence of a fixed nitrogen source. Thus, the reduction of DMSO or
TMAO serves as an additional mechanism by which to dissipate excess
reducing equivalents generated by carbon metabolism.
In this study, reporter-gene promoter fusions were employed to examine
the expression of the CBB, dinitrogenase, and DMSOR systems in response
to different environmental and metabolic signals. CBB-deficient strains
and a dinitrogenase-derepressing strain of R. capsulatus were used in these studies. Contributions of the
different redox systems to photoautotrophic carbon metabolism and the
interaction with nitrogen metabolism were explored, and the results of
these studies reflect on the overall control of redox homeostasis in
R. capsulatus.
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MATERIALS AND METHODS |
Bacterial strains and reporter gene fusion plasmids.
The
genotypes and phenotypes of the R. capsulatus
strains and reporter-gene fusion plasmids utilized in this study are
summarized in Tables 1 and
2. CBB-deficient strains SBI/II and SBP
and subsequent spontaneous variants derived from them, strains RCP and
SBP-PHC, respectively, were previously described, and their growth
potential in various media has been reported (37, 40, 50).
Strain SBI/II lacks form I and form II ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) due to the introduction, respectively, of a spectinomycin resistance cartridge in cbbL and a
kanamycin resistance cartridge in cbbM, while strain SBP
lacks phosphoribulokinase due to the introduction of the
-spectinomycin cassette into cbbP. In order to achieve
photoheterotrophic growth comparable to that of wild-type strain
SB1003, an exogenous electron acceptor, such as DMSO, must be provided
during photoheterotrophic growth with a fixed nitrogen source
(ammonia). R. capsulatus strains that have
acquired PHC in the absence of external electron acceptors like DMSO
and can use ammonia as a fixed nitrogen source include strains RCP and
SBP-PHC. Strain RCP (R. capsulatus
photoheterotrophically competent) is a spontaneous variant of strain
SBI/II that maintains the cbbLS cbbM phenotype,
while strain SBP-PHC is a spontaneous variant of strain SBP that
maintains the cbbP phenotype. The redox-balancing mechanism
that allows photoheterotrophic competency in the absence of a
functional CBB cycle remains to be established in strain RCP, while derepression of the dinitrogenase enzyme complex has been
shown to be essential to allow strain SBP-PHC to maintain photoheterotrophic competency (50).
Media and growth conditions.
E. coli
strain JM109 (57) containing reporter gene fusion plasmids
was grown aerobically on LB medium (1) at 37°C with appropriate antibiotic selection. Photoheterotrophic cultures of
R. capsulatus were grown anaerobically in
Ormerod's medium (36) supplemented with 0.4%
DL-malate, as required, and 1 µg of
thiamine/ml. The nitrogen source was provided as either 30 mM ammonia
or 6.8 mM L-glutamate. Photoheterotrophic and
photoautotrophic growth of all cultures was monitored by measuring the
optical density at 600 nm (OD660) of cultures
with a Beckman spectrophotometer. The concentrations of antibiotics
used for selection of the R. capsulatus strains
were as follows: rifampin, 50 µg/ml; kanamycin, 5 µg/ml;
spectinomycin, 10 µg/ml; tetracycline, 3 µg/ml for stock cultures
or 0.5 µg/ml for plasmid maintenance under phototrophic growth
conditions. For E. coli, the antibiotic
concentrations for plasmid maintenance were as follows: kanamycin, 20 µg/ml; tetracycline, 6 µg/ml. DMSO and TMAO were each utilized at a
concentration of 30 mM.
Conjugation techniques.
E. coli strain
JM107 (57), containing mobilizable helper plasmid pRK2013
(14), was used in triparental matings in order to
independently conjugate the respective reporter gene fusion plasmids
into recipient R. capsulatus strains. Donor and
recipient cultures were grown to a high turbidity (late log phase) in
peptone-yeast extract (PYE) medium (56) containing
appropriate antibiotics and washed three times with PYE medium prior to
mating in order to eliminate any interference from the presence of
antibiotics. Following conjugation, exconjugants were grown at 30°C
on PYE agar plates containing rifampin and tetracycline and (if
appropriate) spectinomycin and/or kanamycin as counterselective agents
against E. coli; tetracycline was provided for
plasmid maintenance.
Cell extracts and enzyme assays.
Culture samples (10 to 20 ml) were harvested in late log phase (OD660 = 0.9 to 1.2), washed in buffer (25 mM Tris-Cl, 1 mM EDTA [pH 8.0]), and
disrupted by sonication. The resultant cell debris was removed by
centrifugation at 18,000 × g for 15 min at 4°C.
-Galactosidase activity was measured as previously reported (40); the production of o-nitrophenol
(31) was continuously measured over a time period of 10 min by monitoring the increase in A405
on a Spectronic GENESYS 2 spectrophotometer. Specific activities were
calculated by using the change in steady-state A405 per minute and the extinction
coefficient for o-nitrophenol of 3.1 × 103 cm2/mmol
(54). Levels of activity were checked for cells taken at
different stages of growth, with no significant change in the enzyme
activity patterns noted. However, to ensure reproducibility of all
comparisons, all samples were taken from cultures at close to the same
OD660 and it was ensured that this never exceeded 1.2. Protein concentrations were determined by the Bio-Rad protein assay dye binding reagent (Bio-Rad Laboratories, Hercules, Calif.) using bovine serum albumin as the standard.
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RESULTS |
Interplay of the CBB, dinitrogenase, and DMSOR systems under
photoheterotrophic growth conditions.
Various systems are employed
by R. capsulatus to balance the intracellular
oxidation-reduction potential when the organism is exposed to specific
environmental conditions (Table 2). During photoheterotrophic growth on
carbon substrates such as L-malate, the CBB
system is expressed to allow CO2, produced as a
result of the oxidation of the organic substrate, to function as an
electron sink for the excess reducing equivalents generated during
metabolism. The dinitrogenase system, in conjunction with the CBB
cycle, serves as a redox-balancing tool during photoheterotrophic
growth with a poor nitrogen source (such as glutamate); growth with
ammonia represses the synthesis of this system. Furthermore, the DMSOR system contributes to redox poise under phototrophic growth conditions in the presence of the auxiliary oxidants DMSO and TMAO. No additional mechanism(s) employed to remove reducing equivalents is known. Specific
reporter gene promoter fusions were used to monitor the expression of
the CBB, dinitrogenase, and DMSOR systems in CBB-deficient strains
and photoheterotrophically competent CBB-deficient strains (which
included a dinitrogenase-derepressing strain) of R. capsulatus (Table 2). The responses of the selected
redox-balancing systems to different environmental and metabolic
signals under photoheterotrophic growth conditions were established by
using each of these strains.
The CBB system.
In R. capsulatus, form I
RubisCO is not synthesized during photoheterotrophic growth with malate
as the carbon source and ammonia as the nitrogen source (39,
48). However, form I RubisCO synthesis is observed during growth
with reduced carbon substrates, such as butyrate, or during
photoautotrophic (1.5% CO2-98.5%
H2) growth conditions (16, 39, 48).
Consistent with the established regulation of
cbbI (the cbb form I
operon), wild-type strain SB1003 did not exhibit
cbbI promoter activity under
photoheterotrophic growth conditions with ammonia as the fixed nitrogen
source in the absence or presence of the exogenous electron acceptor
DMSO (Fig. 1A). In addition, no
cbbI promoter activity was detected during
growth with glutamate (which also serves as an ancillary carbon source
to L-malate) in the absence or presence of DMSO (Fig. 1A). Thus, normal regulation of the
cbbI promoter was maintained in wild-type
strain SB1003 regardless of the nitrogen source (ammonia or glutamate)
or the presence or absence of an auxiliary oxidant (DMSO).
Additionally, strains SBP and SBP-PHC exhibited wild-type regulation of
the cbbI promoter for all of the
photoheterotrophic growth conditions tested (Fig. 1A). By contrast,
strains SBI/II and RCP showed definitive
cbbI promoter activity during
photoheterotrophic growth (Fig. 1A). cbbI
promoter activity was observed in strain SBI/II with either ammonia or
glutamate as the nitrogen source in the presence of DMSO or in the
absence of DMSO when glutamate was used as the nitrogen source. Strain
RCP exhibited cbbI promoter activity only
during growth with ammonia as the nitrogen source in the absence of
DMSO (Fig. 1A). Interestingly, strain SBI/II exhibited threefold higher
cbbI promoter activity during
photoheterotrophic growth in the presence of glutamate when
supplemented with DMSO (Fig. 1A); strain SBI/II does not grow in the
absence of DMSO with ammonia as the nitrogen source due to the lack of
an expressed redox-balancing mechanism (40, 50).
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FIG. 1.
cbbI::lacZ
(A) and cbbII::lacZ
(B) promoter activities during photoheterotrophic growth of
R. capsulatus CBB-deficient strains.
-Galactosidase activities were determined in three or four
independent cultures assayed in duplicate. NG indicates no growth under
photoheterotrophic growth conditions with ammonia as the nitrogen
source in the absence of DMSO.
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In contrast to
cbbI,
cbbII was expressed under all growth
conditions that require the CBB system (
39,
40); for
photoheterotrophic
conditions with
L-malate as
the carbon source, the primary role
of CO
2
fixation via the CBB cycle (using only
cbbII) is to maintain
the redox poise of
the cell. Wild-type strain SB1003 exhibited
cbbII promoter activity under
photoheterotrophic growth conditions
with either ammonia or glutamate
as the nitrogen source, in the
absence or presence DMSO (Fig.
1B).
Strain SBI/II, however, exhibited
a 10-fold induction of
cbbII promoter activity when cultures were
supplemented with DMSO while retaining wild-type control during
growth
in the absence of DMSO (Fig.
1B). Strain RCP expressed
low basal levels
of
cbbII promoter activity under all of the
photoheterotrophic
growth conditions tested (Fig.
1B). Similar to
strain RCP (Fig.
1B), additional PHC strains that were derived from
RubisCO-deficient
strain SBI/II (M. A. Tichi and F. R. Tabita, unpublished data)
were also shown to exhibit basal, uninduced
levels of
cbbII expression
under the four
growth conditions depicted in Fig.
2B.
Thus, upon
developing photoheterotrophic competency, RubisCO-deficient
strains
such as strain RCP regained the normal low basal levels of
cbbII promoter activity during
photoheterotrophic growth; however, the
absolute promoter activity
levels were, for unknown reasons, considerably
reduced and were similar
to those observed with
cbbRII strains
(
53). Strains SBP and SBP-PHC exhibit comparable wild-type
(strain
SB1003) control of
cbbII promoter
activity during photoheterotrophic
growth in the presence of ammonia,
although somewhat less activity
was observed with malate-glutamate-DMSO
(Fig.
1B). Among all of
the CBB-deficient strains, it appears from
these results that
only strain SBI/II showed substantial activation of
both
cbbI and
cbbII promoter activities in the presence
of DMSO. Apparently,
basic regulatory mechanisms are altered in this
strain.
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FIG. 2.
nifH::lacZ
promoter activity during photoheterotrophic growth of R.
capsulatus with either ammonia or glutamate as the
nitrogen source. -Galactosidase activities were determined in four
or five independent cultures assayed in duplicate. NG indicates no
growth under photoheterotrophic growth conditions with ammonia as the
nitrogen source in the absence of an ancillary electron acceptor
(DMSO).
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The dinitrogenase system.
Previous studies indicated that the
conventional molybdenum dinitrogenase system of R. capsulatus (encoded by the nifHDK genes) provides
a sufficient compensatory electron sink in the absence of an
operational CBB pathway under photoheterotrophic growth conditions with
glutamate as the nitrogen source. Redox poise is also accomplished in
the presence of ammonia in PHC strains of R. capsulatus. Under these conditions, the organism derepresses the synthesis of an active and unmodified dinitrogenase enzyme complex
(50). Consistent with this regulatory scheme, strain SBP-PHC exhibited nifH promoter activity when grown
photoheterotrophically in the presence of ammonia, while the wild-type
strain and additional CBB-deficient strains repressed nifH
promoter activity (Fig. 2). Also consistent with previous findings
(50), the nifH promoter activity of strain
SBP-PHC was decreased 13.4-fold and 2.8-fold under DMSO-supplemented
growth conditions when either ammonia or glutamate, respectively, was
used as the nitrogen source; nifH promoter activity of
parent strain SBP was hardly affected by the addition of DMSO under
growth conditions permissive for dinitrogenase expression (Fig. 2).
Even though strain RCP exhibited a 2.5-fold decrease in nifH
promoter activity compared to wild-type strain SB1003, the promoter
activities observed during malate-glutamate growth for both strains
were not appreciably altered by the addition of DMSO (Fig. 2).
nifH promoter activity increased 2.5-fold in strain SBI/II
during photoheterotrophic growth with glutamate supplemented with DMSO
compared to that in wild-type strain SB1003.
The DMSOR system.
Excess reductant generated by photosynthetic
electron transport is transferred via the ubiquinone pool to the
periplasmic terminal electron acceptor DMSOR during phototrophic growth
in the presence of DMSO or TMAO (27-29). Thus, DMSO
respiration via the DMSOR system (encoded by the genes
dorCDA) contributes to the maintenance of redox homeostasis.
Accordingly, dorC promoter activity was examined in
wild-type strain SB1003 and the CBB-deficient strains of R. capsulatus in order to assess dor expression
during photoheterotrophic growth. During growth in the presence of
DMSO, dorC promoter activity was induced in all
R. capsulatus strains regardless of the supplied
nitrogen source (Fig. 3). Compared to
wild-type strain SB1003, strain SBI/II exhibited enhanced
dorC promoter activity (4.1 to 4.9-fold) during
photoheterotrophic growth with DMSO when either glutamate or ammonia,
respectively, was used as the nitrogen source (Fig. 3). These results
were consistent with the enhanced cbbI,
cbbII, and nifH promoter
activities obtained in strain SBI/II under DMSO-supplemented growth
conditions.
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FIG. 3.
dorC::lacZ
promoter activity of R. capsulatus under
photoheterotrophic growth conditions with or without DMSO.
-Galactosidase activities were determined in four or five
independent cultures assayed in duplicate. NG indicates no growth in
the absence of DMSO under conditions with ammonia as the nitrogen
source.
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PHC and coordinate regulation of redox poise and carbon
metabolism.
The first indication that the PHC phenotype and the
control of cbb expression might be linked in R. capsulatus came from studies with strain RCP, where low
basal levels of cbbII promoter activity were obtained under all of the photoheterotrophic growth conditions tested. In addition, unlike all of the other strains, including the
wild type, strain RCP expressed cbbI
promoter activity only during growth with ammonia in the absence of
DMSO (a condition under which the PHC phenotype is obligatory for
growth) (Fig. 1A and B).
The hierarchical use of electron acceptors and control mechanisms
involved in phototrophic redox homeostasis in
R. capsulatus differs from the situation found in
R. sphaeroides and
R. rubrum (
50). Specifically, coordinate control of the DMSOR and
dinitrogenase
systems in PHC strains appears to be unique to
R. capsulatus.
The development of a PHC phenotype
and the control of
cbb expression
also differed in
R. capsulatus and
R. sphaeroides. This was particularly
evident when heterologous
expression experiments were performed
with an
R. sphaeroides translational
cbbI::
lacZ promoter
fusion
vector to examine the effect of the PHC phenotype on
R. sphaeroides cbb promoter activities
in the
R. capsulatus wild-type and PHC
strain
backgrounds (Table
3). Plasmid pVKD1
contains, in addition
to the
cbbI promoter
of
R. sphaeroides, the upstream and divergently
transcribed
R. sphaeroides cbbR gene
(
6,
7). Endogenous
R. capsulatus
CbbR proteins do not recognize
R. sphaeroides
cbb promoters; thus, transcription of this
cbbI promoter in the
R. capsulatus background is dependent on its cognate CbbR
protein.
It is clear that the
R. capsulatus
cbbI promoter is not expressed
in
photoheterotophically grown wild-type
R. capsulatus (Fig.
1A).
However, when an
R. sphaeroides cbbR-cbbI
promoter plasmid (pVKD1)
was used,
-galactosidase activity was
obtained under all of the
photoheterotrophic growth conditions tested
in an
R. capsulatus strain RCP background and
very low, but demonstrable, basal levels
of activity were detected in
wild-type
R. capsulatus (Table
3).
R. sphaeroides cbbI promoter
activity in
R. capsulatus strain
RCP was highest
when the PHC growth phenotype was obligatory (malate-ammonia
medium)
and decreased up to fourfold as additional redox-balancing
systems were
used by the organism (Table
3), i.e., when glutamate
was used as a
nitrogen source (and the dinitrogenase system was
synthesized) or when
DMSO was added to cultures (when the DMSOR
system was synthesized). The
high level of
cbbI expression obtained
in a
malate-ammonia medium is very similar to what occurs when
R. capsulatus cbbI expression is
monitored in strain RCP (Fig.
1A), suggesting that the basic
environment in
R. capsulatus RCP
is responsible
for regulating CbbR-dependent transcription, no
matter whether
transcription is directed by the
R. sphaeroides or
R. capsulatus CbbR protein and the cognate
cbbI promoter. The
fact that very low
levels of
R. sphaeroides CbbR-dependent
cbbI promoter activity was observed in a
wild-type
R. capsulatus environment
is compatible
with the finding that
R. capsulatus
CbbR-dependent
cbbI promoter activity was
not even detected under these growth
conditions. Perhaps the low-level
expression of the
R. sphaeroides cbbI promoter, compared to the
R. capsulatus cbbI
promoter, was
due to the presence of the unique upstream activator
region in
the promoter-distal region of the
R. sphaeroides cbbI promoter
(
6,
7).
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TABLE 3.
Promoter activity using an R. sphaeroides
cbbI::lacZ promoter fusion in
R. capsulatus wild-type strain SB1003 and strain RCP under
photoheterotrophic growth conditions
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Integrative control of the DMSOR redox-balancing system with
photoautotrophic carbon metabolism.
To assess the integration of
the DMSOR and CBB systems with photoautotrophic metabolism,
dorC and cbb promoter activities were examined in
wild-type strain SB1003. dorC promoter activity in wild-type
strain SB1003 was not significantly altered under photoautotrophic
(CO2-H2) growth conditions
when cultures were supplemented with DMSO in the presence of ammonia or
glutamate (Table 4). Likewise,
cbbII promoter activity in wild-type strain SB1003 was not significantly changed when the exogenous electron acceptor DMSO was added under photoautotrophic growth conditions, no
matter whether ammonia or glutamate was used as the nitrogen source
(Table 4). These results were analogous to
cbbII promoter activities obtained for
wild-type strain SB1003 during photoheterotrophic growth with malate,
where the addition of DMSO did not affect activity (Fig. 1B). In
wild-type strain SB1003, cbbI promoter activity, however, decreased sixfold during photoautotrophic growth in
the presence of DMSO compared to growth in the absence of DMSO (Table
4). These data suggested that the presence of DMSO has a selective
effect on expression of the cbbI promoter
in R. capsulatus during photoautotrophic growth.
No cbbI promoter activity was observed in
the wild-type strain under photoautotrophic growth conditions when
glutamate was added as a potential carbon and nitrogen source in the
absence or presence of DMSO (Table 4). It is apparent from these
results that the DMSOR and cbbI systems are
reciprocally regulated under photoautotrophic conditions, suggesting
that electron flow through the DMSOR system negatively impacts
cbbI expression.
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TABLE 4.
Levels of CBB and DMSOR promoter systems in wild-type
strain SB1003 during photoautotrophic growth in the presence or absence
of DMSO with ammonia G glutamate as the nitrogen source
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To confirm that the control of the
cbbII
system is independent of controls on the DMSOR system, an experiment
was designed
to take advantage of the fact that the DMSOR system
catalyzes
both DMSO and TMAO respiration; despite this,
dorC
promoter activity
decreases during photoheterotrophic growth when TMAO
is used as
an exogenous electron acceptor instead of DMSO
(
47). Using either
DMSO or TMAO as the electron acceptor
for the DMSOR system did
not significantly affect
cbbII promoter expression in either
wild-type
strain SB1003 or strain SBI/II under photoheterotrophic
growth
conditions (Fig.
4A and B). In
addition, strain SBI/II maintained
up-regulated expression of the
cbbII system in the presence of
either TMAO
or DMSO. By contrast, however, the addition of TMAO
to
photoheterotrophic cultures of strains SB1003 and SBI/II resulted
in a
three- to fivefold decrease in
dorC promoter activity
compared
to the activities obtained in the presence of DMSO (Fig.
4B).
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FIG. 4.
cbbII::lacZ
(A) and dorC::lacZ (B) promoter
activities in wild-type R. capsulatus
strain SB1003 and strain SBI/II during photoheterotrophic growth with
either DMSO or TMAO as the supplied exogenous electron acceptor in the
presence of either ammonia or glutamate as the nitrogen source.
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DISCUSSION |
Nonsulfur purple bacteria couple their ability to assimilate
carbon dioxide and dinitrogen to photosynthetic energy generation and
the production of required reducing equivalents (15).
However, knowledge of how various redox-balancing systems interact and contribute to successful photoheterotrophic or photoautotrophic metabolism is limited. In the present study, the expression of three
important redox-balancing mechanisms, the CBB, dinitrogenase, and DMSOR
systems, was shown to be either coordinately regulated or influenced by
the presence of one system or the other. This is necessary to ensure
balance in the use of reducing equivalents generated by phototrophic
metabolism (Fig. 5). The control of anaerobic respiratory pathway gene expression in R. capsulatus is comparable to the situation in E. coli, where there is also coordinate and integrative control
over the redox-balancing systems (for a review, see reference
17 and references therein). However, in the present study,
evidence for linkage in the control of key redox-balancing systems
(i.e., those important for CO2 fixation, nitrogen
fixation, and DMSO respiration) is presented for the first time in both
the photoheterotrophic and photoautotrophic growth modes.
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FIG. 5.
Mechanisms involved in adaptation of the efficiency of
energy conservation to intracellular requirements under
photoautotrophic (A) and photoheterotrophic (B) growth conditions.
Cyclic photosynthetic electron transport and the specific
redox-balancing mechanisms of the CBB, DMSOR, and nitrogenase systems
contribute to redox homeostasis in R.
capsulatus. NADH generated by the oxidation of carbon
substrates or reverse electron flow via complex I is dissipated by the
CBB system (A and B) and perhaps the nitrogenase system (B). Flux of
reductant from the ubiquinone pool is transduced to the DMSOR system
under phototrophic growth conditions (A and B). The dotted line
indicates the influence of DMSO reduction on specific redox-balancing
mechanisms under phototrophic environmental conditions (A and B).
|
|
The interplay between the dual roles (maintenance of redox poise and
carbon metabolism) of the CBB system has been shown to correlate with
the expression of the DMSOR system. The integration of the CBB system
and the DMSOR system in phototrophic metabolism is not unprecedented.
Phototrophic growth on highly reduced substrates such as butyrate and
propionate is known to depend upon the addition of exogenous
CO2 as an electron acceptor (52).
Under these conditions, the CBB system is obligately required for
growth (11, 12, 39). An auxiliary oxidant, DMSO or TMAO,
can substitute for CO2 under these phototrophic
growth conditions (44). Moreover, during phototrophic
growth on less-reduced carbon substrates (e.g., L-malate), the DMSOR system can also replace the need for a
functional CBB system in R. capsulatus (40,
50). The results of the present investigation indicated that
cbbI of the CBB system of R. capsulatus was responsive to activation of the DMSOR system
under photoautotrophic growth conditions, while
cbbII was unaffected by the DMSOR system under either photoheterotrophic or photoautotrophic growth conditions. By contrast, RubisCO-deficient strain SBI/II exhibited a different response in that both cbbI and
cbbII promoter activities were raised to
photoautotrophic (1.5% CO2-98.5%
H2) wild-type levels under photoheterotrophic
growth conditions in the presence of DMSO. In fact, all of the redox
systems, as exemplified by the respective promoter fusions, were
up-regulated in strain SBI/II.
In Rhodobacter, redox homeostasis is achieved through the
interplay of cyclic photosynthetic electron transport and specific redox-balancing mechanisms of anaerobic metabolism during phototrophic growth (30). It has been suggested that the electron
acceptors involved in photosynthetic metabolism function as a sink for
excess reducing equivalents or prevent the overreduction of the cyclic electron transport system. This interaction between redox poise and
electron transport occurs at the level of the ubiquinone pool (13; Fig. 5). Respiratory electron flow to the DMSOR
system has been shown to branch from cyclic electron transport at the level of the ubiquinone pool (27, 28); thus, activation of the DMSOR system under phototrophic growth conditions may siphon reductant from the ubiquinone pool. Studies of the related organism R. sphaeroides indicated that flux from the
ubiquinone pool is transduced through a pathway involving
cbb3-type cytochrome c oxidase,
while a signal involved in the flow of reductant is conveyed to the
PrrBA (RegBA) signal transduction pathway (33-35). In
R. capsulatus, the two-component signal
transduction system RegBA (PrrBA) has been shown to be involved in the
regulation of operons important for photosynthetic gene expression
(46), CO2 fixation (53), and nitrogen fixation and H2
oxidation (8, 50). Indeed, the current model suggests that
the RegBA system responds to the overall intracellular redox state
(22, 49), although more-detailed studies are required to
elucidate the specific redox-sensing mechanisms that influence the Reg
system of R. capsulatus (4, 8).
Under photoautotrophic growth conditions in R. capsulatus, the RegBA global regulatory system was shown to
be involved in activation of cbbI promoter
expression, as well as maximal expression of the
cbbII promoter (53). It is
possible that by activating the DMSOR system, which alters the
oxidation-reduction potential of the ubiquinone pool, a redox signal is
transmitted to a regulatory system that, in turn, controls the
expression of key operons involved in phototrophic metabolism. In
R. capsulatus, the RegBA system plays more of a
critical role in regulating cbbI since this
operon is up-regulated only during photoautotrophic metabolism while cbbII is expressed under a variety of
conditions. This could explain the sensitivity of
cbbI to activation of the DMSOR system
under photoautotrophic growth conditions. Alternatively, additional, unknown factors that have been postulated to be involved in expression of the CBB system in R. sphaeroides (6,
7) and R. capsulatus (53)
could play a critical role in transmitting a redox signal to control
key operons involved in redox homeostasis.
During photoheterotrophic metabolism, redox poise is also achieved by
the coordinate integration of the DMSOR and CBB systems, as well as the
dinitrogenase system. Indeed, in the absence of an operational CBB
system, spontaneous variants of R. capsulatus derepress the dinitrogenase system, resulting in photoheterotrophic competency (50). Dinitrogenase-catalyzed proton reduction
and the consequent evolution of H2 gas are
important for maintenance of redox poise in R. capsulatus (20). The current study monitored the interplay between the CBB and dinitrogenase systems, as well as the
DMSOR system, in CBB-deficient and PHC strains of R. capsulatus. Although the specific regulatory mechanism(s)
involved in the derepression of dinitrogenase in PHC mutant strains of
R. capsulatus remains to be established, it
should be noted that the PrrBA (RegBA) two-component regulatory system
is involved in the maintenance of the PHC phenotype of an R. sphaeroides dinitrogenase-derepressing strain
(22). Additionally, the Reg system was shown to be
involved in the control of nitrogen fixation in wild-type R. capsulatus (8) and Bradyrhizobium
japonicum (3).
The specific integration of redox mechanisms with the derepression of
the dinitrogenase system in R. capsulatus differs
from the situation in R. sphaeroides
(50). For example, activation of the DMSOR system under
photoheterotrophic growth conditions diminishes nif
expression in a dinitrogenase-derepressing strain of R. capsulatus while exhibiting no effect in R. sphaeroides (22, 42). We have also observed
differences in R. sphaeroides and R. capsulatus cbbI promoter
expression in an R. capsulatus PHC strain
background. This could be due to differences in general redox response
between cbbIs of the two organisms, the
differential effects of specific metabolic signals on the cognate CbbR
proteins, or a combination of both possibilities. With different
ecological niches in aquatic ecosystems (41), it is not
unexpected that R. capsulatus and R. sphaeroides differentially regulate processes involved in
the control of redox homeostasis in response to the environmental
milieu. An indication of this possibility was previously suggested by
the demonstration of differences in the roles of the global regulatory
systems of FnrL (47, 59, 60) and RegBA (PrrBA) (2,
9, 10, 32, 46) during phototrophic growth in R. sphaeroides and R. capsulatus.
A question that must be addressed concerns the potential role and
coordinate control of specific metabolic signals with redox homeostasis
in response to environmental factors. In R. sphaeroides (7) and Rhodopseudomonas
palustris, whose genomic sequence was recently completed
(http://www.jgi.doe.gov/tempweb/JGImicrobial/html/index.html), it
is apparent that a single cbbR gene controls the
transcription of the two major cbb operons. A separate
upstream and divergently transcribed cbbR gene, however,
controls each cbb operon in R. capsulatus (38, 39, 53). LysR-type
transcriptional regulators, such as CbbR, generally utilize a
metabolite or coinducer produced by the pathway they regulate
(45). Clearly, the current study has demonstrated that a
complex interrelationship of specific redox-balancing systems exists in
R. capsulatus and probably other nonsulfur purple
bacteria. Since activation of the DMSOR system affects control of the
CBB system under photoautotrophic environmental conditions and in some
instances may also cause up-regulation of promoter sequences important
for redox balancing under photoheterotrophic growth conditions, it is
important to determine if these observed regulatory events are
coordinated with the appearance of and subsequent interaction with a
specific metabolic signal metabolite(s). Perhaps strain SBI/II can be
effectively used in such investigations since there is dramatic
up-regulation of operons important for redox control in this strain.
Continued studies of the nature of the signal(s) that influences both
CbbR and the more global redox-sensing pathways required for
photoheterotrophic and photoautotrophic growth are warranted.
| |
ACKNOWLEDGMENTS |
We thank A. Shaw and A. G. McEwan for the R.
capsulatus translational
dorC-lacZ plasmid. We also thank A. G. McEwan and Janet Gibson for helpful advice and insightful
discussions concerning this work and Janet Gibson for helpful editing.
This work was supported by NIH grant GM45404 from the U.S. Public
Health Service.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, The Ohio State University, 484 West 12th Ave., Columbus, OH 43210-1292. Phone: (614) 292-4297. Fax: (614) 292-6337. E-mail: tabita.1{at}osu.edu.
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Journal of Bacteriology, November 2001, p. 6344-6354, Vol. 183, No. 21
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.21.6344-6354.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
