Effect of aeration and sodium on the metabolism of citrate by Klebsiella aerogenes.

Anaerobic growth of Klebsiella aerogenes NCDO 711 (NCTC 418) on citrate was dependent on the presence of Na+ in the medium, and fermentation of citrate was mediated via the fermentation pathway enzymes, citrate lyase and a Na+-dependent oxalacetate decarboxylase. This confirms the previous findings on strain NCTC 418. Growth under aerobic conditions was independent of Na+. The mean generation time for cells grown aerobically on either Na+ or K+ citrate medium was about 60 min, with a molar growth yield of about 40 g (dry weight) of cells per mol of citrate utilized. Citrate was apparently metabolized aerobically in both the Na+ and K+ citrate cells via the citric acid cycle, since cell extracts contained alpha-ketoglutarate dehydrogenase but not the citrate fermentation enzymes. The presence of theother enzymes of the citric acid cycle in K. aerogenes was shown in earlier studies. Under aerated conditions (no detectable oxygen tension in the culture), growth was faster on the Na+ citrate medium (mean generation time, 85 min) than on the K+ citrate medium (mean generation time, 120 min). Both cultures grew slower than under aerobic conditions, presumably because of oxygen limitation. Despite the faster growth rate, the molar growth yield of the aerated Na+ citrate culture was one-half that observed for the aerated K+ citrate culture. Citrate was metabolized via the citric acid cycle in cells grown in the K+ citrate medium under aerated conditions since alpha-ketoglutarate dehydrogenase, but not the fermentation enzymes, was detected in extracts prepared from these cells. Metabolism of citrate in the Na+ citrate medium under aerated conditions occurred via both the fermentation pathway (approximately 75 percent) and the citric acid cycle (about 25 percent), as evidenced by (i) the presence of the fermentation enzymes and alpha-ketoglutarate dehydrogenase in extracts of cells grown under these conditions, (ii) a molar growth yield which was intermediate between that obtained for anaerobic and aerated K+ citrate cultures, and (iii) the excretion of acetate, which also occurred in anaerobic cultures but not in aerated K+ citrate or aerobic cultures.     

Citrate Metabolism in Aerobacter cloacae

Growth of Aerobacter cloacae on citrate either anaerobically or aerobically did not require and was not stimulated by the presence of Na(+) in the medium. Citrate was metabolized anaerobically via the fermentation pathway as evidenced by the (i) presence of oxalacetate decarboxylase, (ii) induction of citrate lyase, and (iii) repression of alpha-ketoglutarate dehydrogenase under anaerobic conditions. Thus, although all the other enzymes of the citric acid cycle were present in anaerobic cells, this pathway was not available for the metabolism of citrate. Citrate was metabolized aerobically via the citric acid cycle, since (i) citrate lyase but not oxalacetate decarboxylase was repressed and (ii) alpha-ketoglutarate dehydrogenase was induced under these conditions. The presence of Na(+) in the medium did not lead to a repression of alpha-ketoglutarate dehydrogenase as in the case of Aerobacter aerogenes. The oxalacetate decarboxylase was a soluble, constitutive enzyme, not activated by Na(+) nor inhibited by avidin. It was slightly inhibited by ethylenediaminetetraacetate but was not stimulated by Mg(2+) or Mn(2+). Thus, this enzyme differed markedly in its properties from the same enzyme found in citrate-grown A. aerogenes.     

Role of sodium in determining alternate pathways of aerobic citrate catabolism in Aerobacter aerogenes

In contrast to the absolute Na(+) requirement for anaerobic growth of Aerobacter aerogenes on citrate as sole carbon source, aerobic growth of this microorganism did not require the presence of Na(+). However, Na(+) (optimal concentration, 10 mm) did increase the maximal amount of aerobic growth by 60%, even though it did not change the rate of growth. This increase in growth was specifically affected by Na(+), which could not be replaced by K(+), NH(4) (+), Li(+), Rb(+), or Cs(+). Enzyme profiles were determined in A. aerogenes cells grown aerobically on citrate in media of varying cationic composition. Cells grown in Na(+)-free medium possessed all the enzymes of the citric acid cycle including alpha-ketoglutarate dehydrogenase, which is repressed by anaerobic conditions of growth. The enzymes of the anaerobic citrate fermentation pathway, citritase and oxalacetate decarboxylase, were also present in these cells, but this pathway of citrate catabolism was effectively blocked by the absence of Na(+), which is essential for the activation of the oxalacetate decarboxylase step. Thus, in Na(+)-free medium, aerobic citrate catabolism proceeded solely via the citric acid cycle. Addition of 10 mm Na(+) to the aerobic citrate medium resulted in the activation of oxalacetate decarboxylase and the repression of alpha-ketoglutarate dehydrogenase, thereby diverting citrate catabolism from the (aerobic) citric acid cycle mechanism to the fermentation mechanism characteristic of anaerobic growth. The further addition of 2% potassium acetate to the medium caused repression of citritase and derepression of alpha-ketoglutarate dehydrogenase, switching citrate catabolism back into the citric acid cycle.     

Enzymatic analysis of the requirement for sodium in aerobic growth of Salmonella typhimurium on citrate

Na(+) was required for the aerobic growth of Salmonella typhimurium on citrate, but not on l-malate, glucose, or glycerol. The maximal growth rate and the maximal total growth occurred with 6 to 7 mm Na(+). Na(+) could not be replaced by K(+), NH(4) (+), Li(+), Rb(+), or Cs(+). Sonically treated extracts of citrate-grown cells contained the enzymes of the citrate fermentation pathway (citritase and oxalacetate decarboxylase) and all of the enzymes of the citric acid cycle. Thus, two separate routes of citrate catabolism appeared to be operational in the cells. Two discrete oxalacetate (OAA) decarboxylases were also demonstrated. One was of the "classic" type, being activated by Mn(++) and inhibited by ethylenediaminetetracetate (EDTA). It was present in the cell sap. The second decarboxylase closely resembled the Na(+)-activated OAA decarboxylase of citrate-grown Aerobacter aerogenes, whose growth also requires, or is increased, by Na(+). This decarboxylase was EDTA-insensitive, specifically activated by Na(+) and inhibited by avidin, and it had a high affinity for OAA. It was induced by growth on citrate, but not l-malate or glycerol. It is suggested that the Na(+) requirement for growth reflects the need to activate this OAA decarboxylase as a component of the citrate fermentation pathway and that citrate catabolism via the citric acid cycle, which should be independent of Na(+), is somehow dependent upon the activity of the Na(+)-activated enzyme.     

Inhibiton of isocitrate dehydrogenase and isocitrate lyase from Acinetobacter calcoaceticus by acids of the citrate and glyoxylate cycle]

Acinetobacter calcoaceticus contains two forms of NADP+-dependent isocitrate dehydrogenases differing, among others, by their molecular weights and regulatory properties. The regulation of the high-molecular form of isocitrate dehydrogenase and of isocitrate lyase by organic acids, either belonging or related to the citrate and glyoxalate cycle, is investigated. While alpha-ketoglutarate and oxalacetate competitively inhibit the isocitrate dehydrogenase against Ds-isocitrate, glyoxylate and pyruvate were found to increase Vmax and to lower the KM value for Ds-isocitrate and NADP+. Simultaneous addition of oxalacetate and glyoxylate (not, however, addition of the nonenzymatically formed condensation product of both compound) nullified the activation of isocitrate dehydrogenase by glyoxylate, and potentiates the inhibitory effect of oxalacetate. Alpha-ketoglutarate, succinate, and phosphoenolpyruvate inhibit the isocitrate lyase in a noncompetitive fashion against DS-isocitrate; L-malate, oxalacetate and glyoxylate inhibit competitively. The intermediates of the citrate and glyoxylate cycle afford additive inhibition of the isocitrate lyase. The importance of organic acids of the citrate and glyoxylate cycle and of phosphoenolpyruvate for the regulation of the citrate and glyoxylate cycle at the level of isocitrate dehydrogenase and isocitrate lyase is discussed.     

Requirement for sodium in the anaerobic growth of Aerobacter aerogenes on citrate

Anaerobic growth of Aerobacter aerogenes on citrate as a carbon source required the presence of Na(+). The growth rate increased with increasing Na(+) concentration and was optimal at 0.10 m Na(+). The requirement was specific for Na(+), which could not be replaced by K(+), NH(4) (+), Li(+), Rb(+), or Cs(+). K(+) was required for growth in the presence of Na(+), the optimal K(+) concentration being 0.15 mm. Enzyme profiles were determined on cells grown in three different media: (i) intermediate Na(+), high K(+) concentration, (ii) high Na(+), high K(+) concentration, and (c) high Na(+), low K(+) concentration. All cells contained the enzymes of the citrate fermentation pathway, namely, citritase and the Na(+)-requiring oxalacetate (OAA) decarboxylase. All of the enzymes of the citric acid cycle were present, except alpha-ketoglutarate dehydrogenase which could not be detected. The incomplete citric acid cycle was, in effect, converted into two biosynthetic pathways leading to glutamate and succinate, respectively. The specific activities of citritase and OAA decarboxylase were lowest in medium (i), and under these conditions the activity of OAA decarboxylase appeared to be limited in vivo by the availability of Na(+). Failure of A. aerogenes to grow anaerobically on citrate in the absence of Na(+) can be explained at the enzymatic level by the Na(+) requirement of the OAA decarboxylase step of the citrate fermentation pathway and by the absence of an alternate pathway of citrate catabolism.     

Glucose/citrate cometabolism in Lactococcus lactis subsp. lactis biovar diacetylactis with impaired alpha-acetolactate decarboxylase

The pyruvate metabolism of a Lactococcus lactis subsp. lactis biovar diacetylactis mutant deficient in alpha-acetolactate decarboxylase and its wild-type strain was studied during batch cultivations. A chemically defined medium was used containing glucose as carbon- and energy-source. The alpha-acetolactate decarboxylase deficiency had no effect on the specific growth rate. Addition of citrate was found to increase the specific growth rate of both strains under aerobic and anaerobic conditions. The product formation was monitored throughout the cultivations. The carbon- and redox-balances were within the accuracy of the experimental data. When citrate was added, alpha-acetolactate, diacetyl, and acetoin were formed, and aeration was shown to have a positive effect on the formation of these metabolites. By omitting lipoic acid (required for a functional pyruvate dehydrogenase complex) from the growth medium, a similar stimulatory effect on alpha-acetolactate, diacetyl, and acetoin formation was observed under aerobic conditions. The strain with impaired alpha-acetolactate decarboxylase activity accumulated alpha-acetolactate which resulted in an increased diacetyl formation compared to the wild-type strain, under aerobic and anaerobic conditions.     

Utilization of Oxalacetate by Acinetobacter calcoaceticus: Evidence for Coupling Between Malic Enzyme and Malic Dehydrogenase

Growth of Acinetobacter calcoaceticus strain BD413 in malate-mineral medium resulted in the excretion of large quantities of oxalacetate. Malate was virtually depleted by the time the cell density reached 60% of its final value; most of the remaining growth took place at the expense of oxalacetate. Experiments in which oxalacetate was used as the initial substrate showed that pyruvate was not utilized until most of the oxalacetate disappeared. The generation time for growth on malate or oxalacetate was approximately 40 min; the generation time for growth on pyruvate was 62 min, which implies that pyruvate transport may be rate limiting. Oxalacetate and pyruvate, however, supported approximately the same growth yield. These observations suggested that the first step in the utilization of oxalacetate as an energy source consisted of an enzymatic decarboxylation of the keto acid to pyruvate and CO(2). Three enzyme reactions that carry out this decarboxylation have been detected in extracts of A. calcoaceticus. The first, which functioned maximally at pH 4.8, was attributable to the oxalacetate decarboxylase activity of oxidized diphosphopyridine nucleotide-malic enzyme. The second and third, which functioned in the neutral pH range, resulted from coupling of oxidized diphosphopyridine nucleotide-malic enzyme to reduced diphosphopyridine nucleotide-dependent malic dehydrogenase, and oxidized triphosphopyridine nucleotide-malic enzyme to a reduced triphosphopyridine nucleotide-dependent malic dehydrogenase. The efficiency of these coupled reactions was high enough so that the overall reaction could be physiologically significant.     

Effect of growth conditions on the activation and inactivation of citrate lyase of Rhodopseudomonas gelatinosa.

Cells of Rhodopseudomonas gelatinosa growing with citrate anaerobically in the light contained citrate lyase only in the acetylated, enzymatically active form of this enzyme. After exhaustion of citrate in the culture medium citrate lyase was deacetylated to yield the inactive sulfhydryl (HS) enzyme. Acetylation of HS-citrate lyase required light, anaerobic conditions and the availability of citrate as substrate. The acetylation reaction already in progress stopped immediately when the culture was placed in the dark. Deacetylation of citrate lyase occurred anaerobically in the light when citrate was exhausted and under aerobic conditions in the presence or absence of citrate. In cells of R. gelatinosa fermenting citrate in the dark neither the acetylating enzyme nor the deacetylating enzyme was active.     

Mutation of the oxaloacetate decarboxylase gene of Lactococcus lactis subsp. lactis impairs the growth during citrate metabolism

Aims:  Citrate metabolism generates metabolic energy through the generation of a membrane potential and a pH gradient. The purpose of this work was to study the influence of oxaloacetate decarboxylase in citrate metabolism and intracellular pH maintenance in relation to acidic conditions.
Methods and Results:  A Lactococcus lactis oxaloacetate decarboxylase mutant [ILCitM (pFL3)] was constructed by double homologous recombination. During culture with citrate, and whatever the initial pH, the growth rate of the mutant was lower. In addition, the production of diacetyl and acetoin was altered in the mutant strain. However, our results indicated no relationship with a change in the maintenance of intracellular pH. Experiments performed on resting cells clearly showed that oxaloacetate accumulated temporarily in the supernatant of the mutant. This accumulation could be involved in the perturbations observed during citrate metabolism, as the addition of oxaloacetate in M17 medium inhibited the growth of L. lactis .
Conclusions:  The mutation of oxaloacetate decarboxylase perturbed citrate metabolism and reduced the benefits of its utilization during growth under acidic conditions.
Significance and impact of the study:  This study allows a better understanding of citrate metabolism and the role of oxaloacetate decarboxylase in the tolerance of lactic acid bacteria to acidic conditions.     

Cloning and expression of Klebsiella pneumoniae genes coding for citrate transport and fermentation.

Three Escherichia coli clones (DH1/Cit1, DH1/Cit2 and DH1/Cit3) capable of utilizing citrate as a sole carbon source were isolated from a cosmid bank of Klebsiella pneumoniae wild-type DNA. Two of these clones (DH1/Cit1 and DH1/Cit2) only grew aerobically on citrate minimal medium, the third clone (DH1/Cit3) could also be cultured under fermentative conditions. The aerobic as well as the anaerobic generation times of the three clones were from 4.5 to 7 h. Whereas clone DH1/Cit3 showed a pronounced lag phase on citrate when the cells were pre-grown in medium without citrate, clone DH1/Cit1 immediately started growth, while with clone DH1/Cit2 a short lag phase could be observed upon transfer to citrate minimal medium. Restriction analyses of the three plasmids showed that no common fragments had been cloned. The length of the inserts were 13 and 6 kb for the aerobic Cit+ clones and 27 kb (10 kb) for the anaerobic one. Cultures of the anaerobic Cit+ clone were analyzed by immunoblotting techniques and shown to contain oxaloacetate decarboxylase, which confers citrate utilization under anaerobic conditions to K. pneumoniae. Enzyme assays demonstrated the active state of this biotin-containing membrane protein. The specific activity in vesicle preparations from the E. coli clone was 30% of the wild-type K. pneumoniae vesicles. Citrate acts as an inducer of enzyme protein synthesis in the E. coli clone as it does in K. pneumoniae.     

Net citrate production by isolated prostate epithelial cells

The net production of citrate from exogenous substrates by rat ventral prostate was investigated. The preparation of isolated prostate epithelial cells was described. These cells were capable of oxidizing pyruvate (5 mmol/l) as a source of acetyl coenzyme A. The addition of aspartate + alpha-ketoglutarate (5 mmol/l) in the presence of pyruvate resulted in significant net production of citrate and excess oxalacetate. In the presence of aspartate and glutamate, the cells were capable of producing citrate without excessive oxalacetate production. Neither glucose alone nor glucose plus pyruvate resulted in net citrate production. The results demonstrated that aspartate could serve as a 4-carbon source of oxalacetate for citrate synthesis. Furthermore, the results indicate the intramitochondrial operation of a glutamate-aspartate-citrate pathway involving mitochondrial aspartate aminotransferase and glutamic dehydrogenase activities in prostate epithelial cells.     

Energy-dependent inactivation of citrate lyase in Enterobacter aerogenes.

Enterobacter aerogenes was grown in continous culture with ammonia as the growth-limiting substrate, and changes in citrate lyase and citrate synthase activities were monitored after growth shifts from anaerobic growth on citrate to aerobic growth on citrate, aerobic growth on glucose, anaerobic growth on glucose, and anaerobic growth on glucose plus nitrate. Citrate lyase was inactivated during aerobic growth on glucose and during anaerobic growth with glucose plus nitrate. Inactivation did not occur during anaerobic growth on glucose, and as a result of the simultaneous presence of citrate lyase and citrate synthase, growth difficulties were observed. Citrate lyase inactivation consisted of deacetylation of the enzyme. The corresponding deacetylase could not be demonstrated in cell extracts, and it is concluded that, as in a number of other inactivations, electron transport to oxygen or nitrate was required for inactivation.     

Molybdenum cofactor negative mutants of Escherichia coli use citrate anaerobically

Anaerobically, Escherichia coli cannot grow using either glycerol or citrate as sole carbon and energy source. However, it has been reported that a mixture of glycerol and citrate will support growth. We have found that wild-type strains of E. coli K-12 do not grow on glycerol plus citrate anaerobically. However, growth eventually occurs due to the frequent appearance of mutants. We found that such Cit+ mutants were defective in anaerobic respiration with nitrate or trimethylamine-N-oxide and were chlorate resistant (i.e. molybdenum cofactor deficient). Conversely, well characterized mutants in any of chlA, B, D, E, G and N were also able to use citrate anaerobically. No anaerobic growth differences between wild type and chl mutants were observed either with fermentable sugars or with glycerol plus fumarate or glycerol plus tartrate. Citrate lyase was induced anaerobically by citrate and repressed by glucose in both wild type strains and chl mutants. Furthermore, levels of citrate lyase, fumarate reductase, malate dehydrogenase, fumarase and alcohol dehydrogenase were similar in both types of strains under anaerobic conditions. It is conceivable that a functioning molybdenum cofactor prevents use of citrate by keeping citrate lyase in the inactive form.     

Synthesis of citrate from phosphoenolpyruvate and acetylcarnitine by mitochondria from rabbit, pigeon and rat liver: Implications for lipogenesis

Rabbit, pigeon and rat liver mitochondria convert exogenous phosphoenolpyruvate and acetylcarnitine to citrate at rates of 14, 74 and 8 nmol/15 min/mg protein. Citrate formation is dependent on exogenous HCO3, is increased consistently by exogenous nucleotides (GDP, IDP, GTP, ADP, ATP) and inhibited strongly by 3-mercaptopicolinate and 1,2,3-benzenetricar☐ylate. Citrate is not made from pyruvate alone or combined with acetylcarnitine. Pigeon and rat liver mitochondria make large amounts of citrate from exogenous succinate, suggesting the presence of an endogenous source of acetyl units or a means of converting oxalacetate to acetyl units. Citrate synthesis from succinate by pigeon and rabbit mitochondria is increased significantly by exogenous acetylcarnitine. Pigeon and rat liver contain 80 and 15 times, respectively, more ATP:citrate lyase activity than does rabbit liver. Data suggest that mitochondrial phosphoenolpyruvate car☐ykinasein vivo could convert glycolysis-derived phosphoenolpyruvate to oxalacetate that, with acetyl CoA, could form citrate for export to support cytosolic lipogenesis as an activator of acetyl CoA car☐ylase, a carbon source via ATP:citrate lyase and NADPH via NADP: malate dehydrogenase or NADP: isocitrate dehydrogenase.     

Formation and dissimilation of oxalacetate and pyruvate Pseudomonas citronellolis grown on noncarbohydrate substrates.

Metabolism of lactate as a carbon source by Pseudomonas citronellolis occurred via a nicotinamide adenine dinucleotide (NAD)-independent L-lactate dehydrogenase, which was present in cells grown on DL-lactate but was not present in cells grown on acetate, aspartate, citrate, glucose, glutamate, or malate. The cells also possessed a constitutive, NAD-independent malate dehydrogenase instead of the conventional NAD-dependent malate dehydrogenase instead of the conventional NAD-dependent enzyme in the tricarboxylic acid cycle. Both enzymes were particulate and used dichlorophenolindo-phenol or oxygen as an electron acceptor. In acetate-grown cells, the activity of pyruvate dehydrogenase and NAD phosphate-linked malate enzyme decreased, cells grown on glucose or lactate. This was consistent with the need to maintain a supply of oxalacetate for metabolism of acetate via the tricarboxylic acid cycle. Changes in enzyme activities suggest that gluconeogenesis from noncarbohydrate carbon sources occurs via the malate enzyme (when oxalacetate decarboxylase is inhibited) or a combination of the NAD-independent malate dehydrogenase and oxalacetate decarboxylase.     

Substrate channeling of oxalacetate in solid-state complexes of malate dehydrogenase and citrate synthase

Current evidence suggests that mitochondrial matrix enzymes exist in solid-state, multienzyme complexes in vivo. Addition of polyethylene glycol to a solution containing malate dehydrogenase and citrate synthase generates such a solid-state, enzyme complex in vitro at enzyme concentrations permitting kinetic measurements. Suspensions of the isolated, solid-state, hetero-complex of these enzymes were used to study the coupled reactions of citrate synthesis from malate, NAD, and CoASAc. The particles appear to be about 1 microgram in diameter. Considering the ratio of enzyme to oxalacetate molecules in or at the surface of the solid-state particles, one would expect oxalacetate to be converted to citrate within a few molecular distances of the site of oxalacetate generation. This model of "substrate channeling" (or alternatively a direct transfer of oxalacetate between enzymes) is supported by experiments with excess aspartate aminotransferase and glutamate added to the solution phase to give a reaction competing with the synthase for bulk phase oxalacetate. Quantities of aminotransferase that reduce the citrate reaction rate with soluble dehydrogenase and synthase by 90% do not significantly affect rates with comparable amounts of the dehydrogenase-synthase complex. We suggest that similar substrate channeling can occur in vivo and discuss the possible advantages provided thereby.     

Role of glutamate dehydrogenase reaction in the control of citrate pool in yeast

• 1.1. Role of NADP-glutamate dehydrogenase in the depletion of citrate was analyzed using permeabilized yeast cells.
• 2.2. Citrate was converted to 2-oxoglutarate, which was then metabolized to glutamate by NADP-glutamate dehydrogenase in the presence of ammonium ion.
• 3.3. Formation of 2-oxoglutarate plus glutamate was in good agreement with the concentration of citrate decreased. Glutamate formation can be a good indicator of the depletion of citrate, because 70% of the citrate decreased was converted to glutamate.
• 4.4. Glycolytic activity was closely correlated with the decrease in citrate under the in situ conditions.
• 5.5. NADP-glutamate dehydrogenase increased in anaerobically grown yeast cells.
• 6.6. An effective depletion of citrate by increased synthesis of NADP-glutamate dehydrogenase can explain the lowered mechanism of citrate causing glycolytic stimulation under the anaerobic growth conditions of yeast.

     

Anaerobic citrate metabolism and its regulation in enterobacteria

Several species of enterobacteria are able to utilize citrate as carbon and energy source. Under oxic conditions in the presence of a functional tricarboxylic acid cycle, growth on this compound solely depends on an appropriate transport system. During anaerobiosis, when 2-oxoglutarate dehydrogenase is repressed, some species such as Klebsiella pneumoniae and Salmonella typhimurium, but not Escherichia coli, are capable of growth on citrate by a Na⁺-dependent pathway forming acetate, formate, and CO₂ as products. During the last decade, several novel features associated with this type of fermentation have been discovered in K. pneumoniae. The biotin protein oxaloacetate decarboxylase, one of the key enzymes of the pathway besides citrate lyase, is a Na⁺ pump. Recently it has been shown that the proton required for the decarboxylation of carboxybiotin is taken up from the side to which Na⁺ ions are pumped, and a membrane-embedded aspartate residue that is probably involved both in Na⁺ and in H⁺ transport was identified. The Na⁺ gradient established by oxaloacetate decarboxylase drives citrate uptake via CitS, a homodimeric carrier protein with a simultaneous-type reaction mechanism, and NADH formation by reversed electron transfer involving formate dehydrogenase, quinone, and a Na⁺-dependent NADH:quinone oxidoreductase. All enzymes specifically required for citrate fermentation are induced under anoxic conditions in the presence of citrate and Na⁺ ions. The corresponding genes form a cluster on the chromosome and are organized as two divergently transcribed operons. Their co-ordinate expression is dependent on a two-component system consisting of the sensor kinase CitA and the response regulator CitB. The citAB genes are part of the cluster and are positively autoregulated. In addition to CitA/CitB, the cAMP receptor protein (Crp) is involved in the regulation of the citrate fermentation enzymes, subjecting them to catabolite repression. Received: 25 September 1996 / Accepted: 18 November 1996