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INTRODUCTION |
The genes encoding the enzymes of
the tricarboxylic acid (TCA) branch of the Krebs cycle in
Bacillus subtilis, citrate synthase (CS), aconitase (ACN),
and isocitrate dehydrogenase (ICDH), have been isolated, and some
aspects of their regulation have been described (15, 16,
28). Genes for three CS isozymes have been found. The
citA and citZ genes encode minor and major
contributors, respectively, to total CS enzyme activity during the late
exponential growth phase in nutrient broth (DS) medium (27)
or during growth in a defined medium containing a poor carbon source.
The third CS is encoded by mmgD, a gene expressed during
sporulation but for which no function during development has been
demonstrated (1). ACN is encoded by citB, a gene
that is not linked to either citA or citZ
(10, 38). The third TCA branch enzyme, ICDH, is the product
of citC, the second gene of the citZCH operon
(25, 27). (The citH gene encodes malate
dehydrogenase, the enzyme that forms oxaloacetate, which is the
substrate for CS [25].) The citC gene is
transcribed both from the citZ operon promoter and from its
own promoter located within the C-terminal coding sequence of
citZ (28).
The Krebs cycle has three major metabolic functions: supplying
biosynthetic precursors (
-ketoglutarate, succinyl coenzyme A
[CoA], and oxaloacetate), generating energy, and creating reducing power when glycolysis is unable to fulfill the cell's needs. In accordance with these physiological roles, the specific activities of
CS and ACN in B. subtilis are reduced when glucose is
available and are more severely depressed when glucose and a source of
-ketoglutarate (such as glutamate or glutamine) are both supplied
(5, 12, 21, 22, 36). This regulation is exerted at the
transcriptional level (28, 39), and regulatory sites for
catabolite (glucose) repression have been identified in the
citB promoter region (15, 16). Mutations that
relieve catabolite repression of citB expression do not
significantly affect temporal regulation of citB in DS (sporulation) medium, suggesting that catabolite repression and temporal regulation are mediated by different mechanisms
(15).
In Escherichia coli, Krebs cycle enzyme activities are
affected both by the medium composition and by the level of oxygen in
the medium. During aerobic growth of E. coli in minimal
medium with acetate as the sole carbon source, Krebs cycle activity is at its highest and abundant energy is generated by the oxidation of
reduced coenzymes through the aerobic respiratory chain. Under anaerobic conditions, especially during fermentative growth, during which NADH cannot be reoxidized by the respiratory chain, Krebs cycle
activity is reduced to the minimum level needed to supply biosynthetic
pathways and is transformed from a cyclic pathway to two oppositely
oriented half-cycles. Synthesis of -ketoglutarate dehydrogenase is
repressed, and succinate dehydrogenase is replaced by fumarate
reductase (20, 41). Other Krebs cycle enzyme activities, including the TCA branch enzymes ACN and CS, are also reduced (17-19, 37, 43, 44). Expression of E. coli ACN
genes acnA (19) and acnB
(18) was shown to be subject to catabolite and anaerobic
repression. Furthermore, it was shown that catabolite repression of
acnA and acnB is mediated by cyclic AMP receptor protein (CRP) and that ArcA (24) functions as an anaerobic
repressor of acnA transcription (8, 19). ArcA
also functions as a repressor of the citrate synthase gene,
gltA, of E. coli under anaerobic as well as
aerobic conditions (37). Unlike the case for acn, a crp mutation does not significantly affect gltA
expression under almost any set of conditions tested (37).
The level of expression of E. coli icd, which encodes ICDH,
was also shown to be fivefold lower under anaerobic cell growth
conditions than under aerobic conditions. This negative control is
mediated by the arcA and the fnr gene products
(3).
Analogous studies on the regulation of Krebs cycle enzymes in B. subtilis have not been reported, primarily because B. subtilis has long been regarded as a strict aerobe and is unable
to grow with acetate as the sole carbon source (23). The
recent discovery that B. subtilis grows anaerobically
(reviewed in reference 33) offers an opportunity to
examine how B. subtilis Krebs cycle enzymes are affected by
oxygen availability and what role, if any, they play in anaerobic
growth. In this paper, we show that the activities of Krebs cycle
enzymes of B. subtilis, particularly ACN, are depressed during anaerobic growth and that the dyad symmetry sequence located in
the citB promoter region, which was previously identified as the target for carbon catabolite repression (15, 16), is
needed for anaerobic repression of citB. The anaerobic
repression of citB and citZ was relieved in a
citB mutant, presumably due to accumulation of citrate,
which likely inactivates the repressor of citB.
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MATERIALS AND METHODS |
Bacterial strains.
All B. subtilis strains used
in this study (Table 1) are derivatives
of JH642. All lacZ fusions described here are
transcriptional fusions. lacZ fusions transcribed from
promoters of citB (ACN gene), citZ (CS gene), and
citC (ICDH gene) were constructed as follows. MAB100 and
MAB101 were constructed by transformation of JH642 with chromosomal DNA
from derivatives of strain SMY in which plasmid pAF23 or pAF24,
respectively, is integrated at the amyE locus. The plasmids
pAF23 and pAF24 contain a promoterless E. coli lacZ gene
fused to citB promoter sequences from positions 
84 to +36
and 67 to +36, respectively, relative to the transcription start site
(16). LAB2163, carrying a citZ-lacZ fusion, was
also constructed by transformation with SJB49 chromosomal DNA. SJB49 was previously constructed by integration of pCS46, a
citZ-lacZ fusion plasmid, at the citZ locus
(28). Two citZ-lacZ-carrying strains, LAB2164 and
LAB2851, with resDE and fnr mutations,
respectively, were constructed by transforming strain LAB2163 with
chromosomal DNA isolated from strain LAB2135 (for resDE) or
LAB2136 (for fnr). Strains MAB109 (citB-lacZ
resDE) and LAB2852 (citB-lacZ fnr) were constructed in
the same way, using MAB100 cells as the recipient. citB
mutants carrying citZ-lacZ (LAB2907) or
citB-lacZ (LAB2905) fusions were generated by transforming
MAB160 (citB::spc) (6) with
chromosomal DNA from LAB2163 or MAB100, respectively. Two citZAB mutants carrying citZ-lacZ (LAB2935) or
citB-lacZ (LAB2936) fusions were constructed by transforming
JCB61 (6) with pCS46 or chromosomal DNA from MAB100,
respectively. A citC-lacZ transcriptional fusion was
constructed in two steps. First, the 0.9-kb
PstI-SspI fragment from pCS34 (28),
which contains the citC promoter, was inserted into
PstI- and SmaI-cleaved pBluescript II SK() (Stratagene), creating plasmid pMMN325. Plasmid pMMN332 was constructed by inserting the EcoRI-BamHI fragment of pMMN325
into EcoRI- and BamHI-cleaved pTKlac
(30), a transcriptional fusion vector. pMMN332 was used to
transform ZB307A by homologous recombination at the SP
prophage
locus (46), and the phage lysate prepared from the
transformants was used to transduce ZB278. Strain MAB173, carrying
citC-lacZ, was constructed by transducing JH642 with the
lysate prepared from the ZB278 transductant. Strain LAB2962, carrying
the ccpA and ccpB mutations, was constructed by
transforming JH642 with chromosomal DNA obtained from strain ST125,
with selection for phleomycin resistance carried by Tn917
and spectinomycin resistance conferred by Tn10
(4). LAB2962 was transformed with MAB100 DNA or LAB2163 DNA
to generate ccpA ccpB double mutants carrying citB-lacZ (LAB2970) DNA or citZ-lacZ (LAB2971)
fusions, respectively. Two lacZ fusions containing
catabolite-responsive elements (cre), HUT924 and BGL2, were
obtained from L. Wray and S. Fisher (45). The HUT924
lacZ fusion contains the cre site of the
histidine utilization (hut) operon downstream of the
tms promoter (32). The BGL2 lacZ
fusion contains the promoter and the cre site of the
bglPH operon that encodes two enzymes involved in
-glucoside assimilation. Strains LAB2960 and LAB2961 were JH642
cells carrying the HUT924 and BGL2 fusions, respectively.
Selection for antibiotic resistance was performed on DS medium
(34) containing chloramphenicol (5 µg/ml), spectinomycin (75 µg/ml), tetracycline (12.5 µg/ml), phleomycin (5 µg/ml), or neomycin (5 µg/ml).
Measurement of -galactosidase activity.
For both aerobic
and anaerobic cultures, cells from fresh plates were used to inoculate
liquid medium to an optical density at 600 nm of 0.02. To compare
aerobic and anaerobic expression of various lacZ fusions in
the same medium, KNO3 was added to all cultures. Cells were
grown in DS medium (34) supplemented with 0.1% glucose,
0.2% KNO3, and 20 mM potassium phosphate buffer (pH 7.0).
For aerobic growth, the culture medium occupied about 10% of the
volume of the flask and was aerated by vigorous agitation. Anaerobic
conditions were achieved by filling tubes with cell suspensions,
flushing with N2 gas for 1 min, capping the tubes, and
incubating without shaking. After removal of each sample, N2 gas was used to flush O2 from the culture to
maintain anaerobic conditions. Assays of -galactosidase activity
were performed as described elsewhere (31).
Assays for CS, ACN, and ICDH activities.
B. subtilis
cells were grown in 100 ml (aerobic) or 500 ml (anaerobic) of DS medium
supplemented with 0.1% glucose, 0.2% KNO3, and 20 mM
potassium phosphate buffer (pH 7.0). Anaerobic cultures were grown in
bottles as described above. Cells were harvested by centrifugation
(12,000 × g for 5 min) about 1 h after the end of
the exponential growth phase, washed with buffer, and frozen on dry
ice. The buffer used to wash cells prior to the measurement of CS
activity contained 20 mM Tris-HCl (pH 8.0), 1 mM EDTA, and 20%
glycerol; that used for washing cells before measuring ACN activity
consisted of 20 mM Tris-20 mM citric acid (pH 7.35), 150 mM KCl, and
0.5 mM phenylmethylsulfonyl fluoride; and the buffer utilized prior to
measurement of ICDH activity contained 20 mM Tris-HCl (pH 7.5), 1 mM
trisodium citrate, 5 mM MnCl2, 5 mM -mercaptoethanol,
10% glycerol, and 0.5 mM phenylmethylsulfonyl fluoride. Cell pellets
were resuspended in the corresponding buffer prior to sonication (30-s
pulse, 3 to 5 min). Cell debris was removed by centrifugation (8 min at
10,000 × g and 4°C), and supernatants (crude extracts)
were used for measurement of enzyme activity. The activities of CS and
ICDH were assayed according to published procedures (14, 22,
27), and ACN activity was measured by a previously described
method (6, 10). Units of CS, ACN, and ICDH were expressed as
micromoles of CoA produced per minute per milligram of protein,
nanomoles of cis-aconitate produced per minute per milligram
of protein, and nanomoles of NADPH produced per minute per milligram of
protein, respectively. Protein concentrations were determined by the
Bio-Rad protein assay.
Immunoblotting analysis of CS, ACN, and ICDH.
Crude extracts
(50 µg for ACN and 10 µg for CS and ICDH) prepared as described
above were subjected to sodium dodecyl sulfate (SDS)-polyacrylamide
(8% for ACN and 12% for CS and ICDH) gel electrophoresis. Proteins
were transferred to an Immobilon P membrane and exposed either to
rabbit antibodies against CS or ICDH or to mouse antibodies against
ACN. Antigen-antibody reactions were detected by binding of the
appropriate anti-rabbit or anti-mouse immunoglobulin G coupled to
alkaline phosphatase and incubating with
5-bromo-4-chloro-3-indolylphosphate and nitroblue tetrazolium. The
antibody to CS was raised against the product of the citZ gene but shows some cross-reactivity with the product of the
citA gene (26).
Measurement of intracellular citrate concentration.
Wild-type and mutant cells were cultured anaerobically in DS medium
supplemented with 0.1% glucose, 0.2% KNO3, and 20 mM
potassium phosphate buffer (pH 7.0). Cells from 25-ml cultures were
collected by centrifugation (10,000 × g for 5 min) and
washed with 0.1 M Tris-HCl (pH 8.0). The cell pellet was resuspended in
0.5 ml of 1 M perchloric acid and kept in an ice bath for 30 min. The
supernatant fluid was recovered by centrifugation and neutralized with
0.25 ml of a 0.75 M potassium carbonate solution. The mixture was
placed on ice for 15 min and centrifuged. The supernatant fluid was
used for measurement of citrate with a kit obtained from Boehringer Mannheim. The principle of the assay is as follows: citrate is converted to oxaloacetate and acetate by citrate lyase, coupled to
reduction of oxaloacetate to malate by malate dehydrogenase and
concomitant oxidation of NADH. The oxidation of NADH is measured as the
reduction in absorbance at 340 nm. The protein concentration in the
extract was determined by the Bio-Rad protein assay.
| |
RESULTS |
The levels of expression of Krebs cycle enzymes were lower under
anaerobic conditions than under aerobic conditions.
Since carbon
and electron flow as well as energy generation are altered by a shift
between aerobiosis and anaerobiosis, expression of the Krebs cycle
enzyme genes could be regulated in response to oxygen availability. The
recent finding that B. subtilis grows anaerobically prompted
us to examine how expression of genes specifying Krebs cycle enzymes in
B. subtilis is regulated in response to an anaerobic
environment. The activities of CS, ACN, and ICDH in cells grown
anaerobically were 10, 3, and 54%, respectively, of those measured in
cells of aerobic cultures (Table 2). To determine if the depressed activity of each of these Krebs cycle enzymes was caused by enzyme inhibition or a reduced level of enzyme
protein, equal amounts of crude protein extracts of aerobic and
anaerobic cultures were applied to SDS-polyacrylamide gels and the
Krebs cycle proteins were detected by immunoblotting (Fig. 1). Coomassie blue staining of the gel
showed that some cellular proteins are predominantly or exclusively
detected in either the anaerobic or aerobic cultures (Fig. 1A). When
anti-ACN antibody was used, the crude extract from the aerobic cultures
gave a strong band at the expected position corresponding to ACN, but
the band was barely detectable in the extract prepared from the
anaerobic cultures (Fig. 1B). Densitometric scanning showed that the
intensity of the ACN band in the anaerobic culture was 3% of that of
the aerobic one. CS and ICDH proteins were detectable in both the aerobic and anaerobic cultures, but the intensity of the band of CS
from the anaerobic cultures was 45% of that of the aerobic cultures
(Fig. 1C), and the intensity of ICDH from the anaerobically grown cells
was 53% of that of the aerobic ones (Fig. 1D). The levels of ACN and
ICDH proteins corresponded well to the enzyme activity determinations
(Table 2), indicating that the low specific activities detected in
anaerobic cultures were mainly due to reduced amounts of the protein
products. CS behaved differently; the enzyme activity under anaerobic
conditions was 10% of that observed in the aerobic cultures, but the
amount of protein was reduced only twofold by anaerobiosis, suggesting
that CS activity may also be controlled by the oxygen level.
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Fig. 1.
(A) SDS-polyacrylamide gel electrophoresis analysis of
proteins from B. subtilis. Cell lysates were prepared as
described in Materials and Methods from cells grown until
T1 in DS medium supplemented with 0.1% glucose,
0.2% KNO3, and 20 mM phosphate buffer (pH 7.0) under
aerobic (lane 2) and anaerobic (lane 3) conditions. Lane 1, molecular
size markers. (B to D) Immunoblot analysis of the cell lysates, using
anti-ACN (B), anti-CS (C), or anti-ICDH (D) immunoglobulin G as the
primary antibody as described in Materials and Methods.
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Anaerobic reduction of the Krebs cycle enzyme level is exerted at
the transcriptional level.
To determine if the reduction in Krebs
cycle enzyme levels observed in the experiment described above was the
result of transcriptional control, expression of lacZ
fusions transcribed from the citZ, citB, or
citC promoter was examined. Previous studies showed that citZ-lacZ (28) and citB-lacZ
(9) fusions were repressed during early exponential growth
in DS medium and reached a peak of expression when cultures enter the
end of exponential phase. In this study, B. subtilis cells
were grown in DS medium supplemented with 0.1% glucose, 0.2%
KNO3, and 20 mM phosphate buffer (pH 7.0) to support anaerobic growth. A low concentration of glucose was chosen for supplementation of the medium so that anaerobic growth would be enhanced but catabolite repression of Krebs cycle gene transcription would be minimized. In this medium, the aerobically grown cells had
patterns and levels of citZ- and citB-lacZ
expression similar to those of cells grown in unsupplemented DS medium,
as previously shown (Fig. 2). This
confirmed that 0.1% glucose does not cause catabolite repression of
the Krebs cycle enzymes. The maximum level of anaerobic citZ
expression was threefold lower than that observed in an aerobic
culture, while maximum anaerobic expression of citB-lacZ
reached only 10% of the maximum aerobic expression. In contrast, the
level of citC-lacZ expression was higher during anaerobic
growth than during aerobic growth (Fig.
3). The citC gene is known to
be transcribed from the upstream citZ promoter as well as
from its own promoter (28). Therefore, threefold repression
of the citZ promoter and twofold induction of transcription from the citC promoter under anaerobic conditions could
explain the overall 50% reduction of ICDH activity during anaerobic
growth shown in Table 2. Among the three enzymes, synthesis of ACN was the most severely repressed, as judged by enzyme activity, immunoblot analysis, and lacZ fusion expression.
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Fig. 2.
Expression of citZ-lacZ and
citB-lacZ fusions in wild-type, resDE, and
fnr strains. Cells of wild-type (LAB2163), resDE
(LAB2164), and fnr (LAB2851) strains carrying
citZ-lacZ fusions and cells of wild-type (MAB100),
resDE (MAB109), and fnr (LAB2852) strains
carrying citB-lacZ fusions were grown in DS medium
supplemented with 0.1% glucose, 0.2% KNO3, and 20 mM
phosphate buffer (pH 7.0) under aerobic (open circles) and anaerobic
(closed circles) conditions. Time zero is the end of exponential
growth. -gal. act., -galactosidase activity (in Miller units).
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Fig. 3.
Expression of a citC-lacZ fusion in a
wild-type strain. Cells of strain MAB173 were grown as described in the
legend to Fig. 2 under aerobic (open circles) and anaerobic (closed
circles) conditions. -gal. act., -galactosidase activity (in
Miller units).
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Anaerobic repression of Krebs cycle enzymes is not mediated by
either CcpA or CcpB.
Although the concentration of glucose used
for the cultures described above does not cause catabolite repression
of Krebs cycle enzymes during aerobiosis, it is possible that this
amount of glucose is sufficient to result in catabolite repression
under anaerobic conditions. To examine this possibility, we tested
whether other carbon catabolite-controlled genes are repressed during anaerobic growth under the culture conditions used for the expression of Krebs cycle enzymes. Two lacZ fusions used for this
purpose are under the control of carbon catabolite repression mediated by a trans-acting factor, catabolite control protein A
(CcpA), and cis-acting cre sequences. The HUT924
lacZ fusion contains the tms promoter and the
cre site of the hut operon. The BGL2 lacZ fusion contains both the promoter and the
cre site of the bglPH operon (45).
Figure 4 shows that the expression of
these lacZ fusions was not repressed (but instead increased)
during anaerobic growth compared to aerobic growth. This result
indicates that the repression of citZ and citB
under anaerobic conditions is not caused by glucose but rather by
oxygen limitation. It also shows that CcpA is not responsible for the
anaerobic repression of Krebs cycle enzymes. A recent study identified
a novel transcription factor, CcpB, which is involved in catabolite
repression in B. subtilis (4). It was
demonstrated that CcpA alone functioned in catabolite repression during
growth in liquid medium with high agitation but that both CcpA and CcpB
functioned when cells were grown on solid medium or in liquid medium
with little agitation, conditions under which the oxygen level could be
reduced. A possible role for CcpB (and CcpA) in the anaerobic
repression of the citZ and citB genes was
examined. As shown in Fig. 5,
citZ and citB were still anaerobically repressed
in the absence of CcpA and CcpB, indicating that CcpA and CcpB do not
have any significant role in the anaerobic repression of
citZ and citB.
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Fig. 4.
Expression of tms-hut cre-lacZ and
bglPH-lacZ fusions. Cells of LAB2960 (tms-hut
cre-lacZ) and LAB2961 (bglPH-lacZ) were grown as
described in the legend to Fig. 2 under aerobic (open circles) and
anaerobic (closed circles) conditions. -gal. act., -galactosidase
activity (in Miller units).
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Fig. 5.
Effect of ccpA and ccpB mutations
on expression of citZ-lacZ and citB-lacZ fusions.
Cells of strains LAB2971 (ccpA ccpB citZ-lacZ) and LAB2970
(ccpA ccpB citB-lacZ) were grown as described in the legend
to Fig. 2 under aerobic (open circles) and anaerobic (closed circles)
conditions. -gal. act., -galactosidase activity (in Miller
units).
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ResDE and FNR are not involved in anaerobic repression of Krebs
cycle enzymes.
Since the ResDE two-component regulatory signal
transduction pathway (35, 42) and Fnr (7) are
known to regulate gene expression in B. subtilis in response
to oxygen limitation, we examined the effect of resDE and
fnr mutations on citZ and citB expression. In either the resDE or fnr mutant,
expression of citZ-lacZ was reduced by 40 to 50% during
both aerobic and anaerobic growth (Fig. 2). However, the anaerobic
repression ratio of citZ expression in the mutant strains
was almost identical to that in the wild-type strain. The expression of
citB-lacZ under aerobic and anaerobic conditions was not
affected by either the resDE or fnr mutation, although the resDE mutation resulted in a slight but
reproducible increase in citB expression during exponential
growth (Fig. 2). These results indicate that the known global anaerobic
regulators in B. subtilis, ResDE and Fnr, are not
responsible for anaerobic repression of citB and
citZ.
A regulatory site in the citB promoter involved in
carbon catabolite repression is also important for anaerobic
repression.
Among the genes for the Krebs cycle enzymes, only the
promoter region of the citB gene has been analyzed in
detail. The dyad symmetry sequence centered at position 66 relative
to the transcription start site has been shown to be required for
catabolite repression (15, 16). To determine if the dyad
symmetry sequence mutation that relieves catabolite repression
(15, 16) also affects citB expression under
anaerobic conditions, we measured -galactosidase activity driven
from a mutant promoter (citBp24), which lacks the left arm
of the dyad symmetry element (16). Figure
6 shows that MAB101 cells carrying the
citBp24 promoter exhibited a level of lacZ
expression under anaerobic conditions that was equal to that observed
under aerobic conditions, indicating that the dyad symmetry element
involved in catabolite repression is also critical for anaerobic
repression of citB.
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Fig. 6.
Expression of lacZ from a mutant
citB promoter. Cells of wild-type strain MAB101 were grown
as described in the legend to Fig. 2 under aerobic (open circles) and
anaerobic (closed circles) conditions. -gal. act., -galactosidase
activity (in Miller units).
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Accumulation of citrate relieves anaerobic repression of
citZ and citB.
How are the citZ and
citB genes coordinately regulated by the oxygen level? One
possibility is that a common repressor is responsible for the
regulation of both genes. The other possibility is that the primary
effect of anaerobiosis is to reduce CS activity, resulting in a
decrease in the intracellular citrate concentration, leading to
low-level citB expression. (Catabolite repression of the
citB gene is known to be alleviated by accumulation of
citrate [6, 15, 36]). The two possibilities are not
mutually exclusive. In attempts to determine if citrate deficiency
caused the anaerobic repression, expression of citB in
strain MAB100 which was grown in the presence of added citrate (5 and
10 mM) was measured. If a low citrate level in the anaerobically grown
cells was the cause of the reduced citB expression, addition
of citrate to the culture medium might lead to a higher level of
citB expression. The results showed that exogenous citrate
had no significant effect on either aerobic or anaerobic
citB expression (data not shown), indicating either that
anaerobic repression of the citB gene is not caused by a low
intracellular citrate concentration or that citrate transport is
repressed under anaerobic conditions.
We then took an alternative approach to examine the effect of citrate
on anaerobic expression of citZ and citB. It was
shown that aerobic cultures of a citB null mutant
accumulated a high level of citrate in the medium and also contained a
twofold-higher intracellular concentration of citrate than do wild-type
cells (6). Extracts from anaerobic cultures of MAB160 cells
also contained a higher citrate concentration than did wild-type
extracts (Table 3), and an almost
10-fold-higher citrate accumulation was observed in the citB
mutant at 2 h after the end of exponential growth compared to the
wild type at the same growth stage. To examine further the effect of
citrate on anaerobic citZ and citB expression, we
measured citZ- and citB-lacZ activities in the citB mutant. As seen in Fig.
7, aerobic citZ and
citB expression was threefold higher in the citB
mutant than in the wild-type strain, and anaerobic repression of
citZ and citB was lost in the mutant. This result
strongly suggests that accumulation of citrate can overcome the
anaerobic repression of citZ and citB but does
not eliminate the possibility that ACN itself is involved in the
regulation.
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Fig. 7.
Expression of citZ-lacZ and
citB-lacZ fusions in citB and citZAB
mutants. citB strains carrying citZ-lacZ
(LAB2907) and citB-lacZ (LAB2905) fusions and
citZAB strains carrying citZ-lacZ (LAB2935) and
citB-lacZ (LAB2936) fusions were grown as described in the
legend to Fig. 2 under aerobic (open circles) and anaerobic (closed
circles) conditions. Also shown are endogenous -galactosidase
activities (-gal. act.) of JH642, which carries no lacZ
fusion, during aerobic (open circles) and anaerobic (closed circles)
growth.
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To determine which possibility is more probable, citZ- and
citB-lacZ fusions were introduced into a triple mutant
(JCB61) lacking ACN and both CS isozymes, encoded by citZ
and citA. Mutations in citZ and citA
abolished the citrate accumulation observed in the citB
mutant, as shown in Table 3. If derepression of citB and
citZ by the citB mutation were caused by
accumulation of citrate, the level of expression of these genes in the
triple mutant would be decreased. Figure 7 shows that the level of
aerobic citZ expression in the triple mutant was two- to
threefold lower than that in the citB single mutant but was
comparable to the level in the wild type. Anaerobic citZ
expression was more severely repressed in the triple mutant than in the
wild-type strain, indicating that citrate deficiency causes anaerobic
citZ repression. The effect of the citZAB
mutations on anaerobic citB repression was difficult to
assess since the level of citB expression in the triple
mutant was highly reduced (although it was slightly higher than the
endogenous -galactosidase activity, as shown in Fig. 7) even under
aerobic conditions, which is in agreement with the previous observation
that citrate is a prerequisite for citB expression (9,
28). This result demonstrates that hyperaccumulation of citrate
in the citB mutant is responsible for derepression of
citZ and citB under anaerobic conditions and
hence suggests that the anaerobic repression of the genes is mainly due
to a citrate deficiency in anaerobically grown cells.
| |
DISCUSSION |
Expression of genes encoding enzymes of the TCA cycle branch of
the Krebs cycle enzymes was previously shown to be subject to at least
two different modes of transcriptional regulation, catabolite
repression and temporal regulation in DS medium. Although the three
Krebs cycle enzymes studied here are necessary to generate -ketoglutarate, the regulation of the first two enzymes (CS and ACN)
is somewhat different from that of ICDH. Both CS and ACN are partially
repressed in cells grown in a glucose minimal medium, and the addition
of glutamate to this medium leads to a severe reduction of the levels
of these enzymes (12, 21, 22), whereas the synthesis of ICDH
is not significantly altered in the presence of glucose and glutamate
(22). These results suggest that CS and ACN, but not ICDH,
are coordinately regulated, which may be due in part to the fact that
citrate is an inducer of ACN (36) and that citB
expression is severely repressed in a strain that lacks CS activity
(9, 28). Citrate synthesis is not a prerequisite for
citB expression driven from a catabolite
repression-insensitive promoter (15), supporting the earlier
hypothesis that a repressor for citB is activated by
-ketoglutarate and antagonized by citrate (36). In fact,
there is an inverse correlation between ACN activity and the
intracellular concentration of -ketoglutarate (11). In
-ketoglutarate dehydrogenase (citK) mutants, in which the -ketoglutarate concentration is high, the level of ACN is low (2, 13, 40) and citB expression (9) is
repressed. Furthermore, both ACN and CS activities were shown to be
derepressed in a strain carrying multiple copies of a DNA fragment with
a dyad symmetry sequence in the citB regulatory region, the
target sequence for catabolite repression, probably due to titration of
a negative regulator(s) (16). This indicates the presence of
a regulatory loop in which CS activity is required for inactivation of
the repressor that functions in catabolite repression of both
citZ and citB. A gel mobility shift assay showed
that a protein(s) binds to the dyad symmetry sequence in the
citB promoter region (15). Since citZ
does not appear to have citB-like operator sites in its
regulatory region (28), it is not known how citZ is regulated by the repressor.
As reported herein, the B. subtilis Krebs cycle enzyme genes
are also controlled in response to anaerobic growth conditions. Again,
citZ and citB are more susceptible to anaerobic
repression than is citC. The anaerobic regulation of the
citB and citZ genes was shown to be exerted
independently of ResDE and Fnr, two control systems known to function
in anaerobic gene regulation in B. subtilis. Anaerobic
repression of citB can be overcome in two ways: by deletion of the cis-acting sequence in the citB promoter,
the target for the catabolite repression, and by mutation of the
citB gene, which results in derepression of citZ
as well. The effect of the citB mutation on anaerobic
citZ and citB expression was shown to be caused
by accumulation of citrate, which also partially overcomes catabolite
repression. Taken together, these results suggest that anaerobic
regulation and catabolite repression of citB and
citZ might be controlled by the same mechanism. It is not
likely that the catabolite repression is mediated by catabolite control
proteins CcpA and CcpB, because these regulators have no effect on the anaerobic repression of citZ and citB. A
signal(s) generated by anaerobiosis or by the presence of excess
glucose and glutamate probably leads to reduced citZ
expression (and/or decreased CS activity) by a mechanism which remains
to be elucidated. Reduced levels of citrate due to low CS activity
further repress citZ as well as citB, the latter
being the target of the repressor which binds to the dyad symmetry
sequence of the citB promoter region. Citrate may interact
directly with the putative repressor or may inactivate the repressor by
chelating divalent cations essential for repressor activity. Chelation
of divalent cations by accumulated citrate was also suggested to cause
the early block of sporulation in the citB mutant, possibly
because divalent cations are necessary for the activity of the Spo0A
phosphorelay (6). Whether the repressor also controls
citZ expression by interacting with the citZ
regulatory region is unknown at present. A study involving the
isolation of the gene encoding the repressor (29) is in
progress, and the identification of this gene will likely shed light on
the mechanism of the catabolite and anaerobic regulation of
citB and citZ.
We thank S. Jin, D. Blaydon, D. Acheson, and K. Matsuno for
antibodies to Krebs cycle enzymes. We also thank B. Belitsky, J. Craig,
and K. Matsuno for helpful discussions and advice. We are grateful to
S. Chauvaux and M. H. Saier for a ccpA ccpB mutant and
to S. H. Fisher and L. V. Wray for tms-hut
cre-lacZ and bglPH-lacZ fusions. M.M.N. thanks the
individuals in the Department of Molecular Biology and Microbiology at
Tufts University School of Medicine for their warm hospitality and help
during her sabbatical stay.
This work was supported by research grants from the National Science
Foundation to M.M.N. (MCB-9722885) and from the National Institutes of
Health (U.S. Public Health Service) to P.Z. (GM45898) and to A.L.S.
(GM36718).
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Abstract
Introduction
E-dependent operon subject to catabolite repression during sporulation in Bacillus subtilis.
J. Bacteriol.
178,
4778-4786
