Regulation of histidine catabolism by succinate in Pseudomonas putida

The regulation of the histidine-degrading pathway is known to involve induction and repression. Our studies have shown that succinate may control the histidine-degrading pathway by sequential negative feedback inhibition. Succinate inhibited urocanase, and urocanate in turn inhibited histidase. Crude preparations of the two enzymes were made from Pseudomonas putida grown on l-histidine. Succinate was a competitive inhibitor of urocanase (K(i), 1.8 mm). Lactate, pyruvate, alpha-ketoglutarate, and glutamate did not inhibit urocanase. Urocanate inhibited histidase competitively (K(i), 0.13 mm). A multienzyme system (histidine to glutamate), when incubated with histidine and succinate, exhibited the combined effect. Succinate caused the level of accumulated urocanate to increase and indirectly blocked histidine disappearance. Growth of cells on urocanate as a nitrogen source was inhibited by 1% succinate. Succinate may play a physiological role in the biological regulation of histidine metabolism.     

Histidine utilization by Alcaligenes eutrophus: Regulation of histidase formation under heterotrophic conditions of growth

Histidine supported good growth of Alcaligenes eutrophus strain H 16 as a nitrogen source, but only poor growth as a carbon and energy source. The facultative chemolithoautotrophic bacterium was also able to utilize urocanic acid, the first intermediate of histidine catabolism. The products of histidine degradation were ammonium, formate and glutamate. Three enzymes of the pathway, histidase, urocanase and formiminoglutamate hydrolase, were present in histidine-grown cells. Two types of spontaneous mutants, derived from the wild type, were characterized by an increased growth rate on histidine. One of these types was found to produce histidase constitutively and at a higher activity compared with the parental strain. The second type of mutant had apparently gained an improved histidine uptake system, which is supposed to be growth rate-limiting in the wild type. From the physiological studies the conclusion was drawn that the control of histidine-degrading enzymes is based on induction by urocanate and catabolite repression by carbon sources supporting fast growth, such as succinate or pyruvate. Ammonium was found not to affect catabolite repression, however, we obtained evidence that histidine uptake is subject to a nitrogen control.Abbreviation CTAB hexadecyltrimethylammonium bromide     

The effect of nitrogen limitation on catabolite repression of amidase, histidase and urocanase in Pseudomonas aeruginosa.

In Pseudomonas aeruginosa, the synthesis of histidase, urocanase and amidase is severly repressed when succinate is added to a culture growing in pyruvate + ammonium salts medium. When growth is nitrogen-limited, catabolite repression by succinate of histidase and urocanase synthesis does not occur but succinate repression of amidase synthesis persists. Amidase synthesis is not regulated in the same way as histidase synthesis by the availability of other nitrogen compounds for growth. Growth of P. aeruginosa strain PACI in succinate + histidine media is nitrogen-limited since this strain is defective in a histidine transport system. When methyl-ammonium chloride is added to succinate + histidine media, growth inhibition occurs. Mutants isolated from succinate + histidine + methylammonium chloride plates were found to be resistant to catabolite repression by succinate even in ammonium salts media. It is suggested that the hut genes of P. aeruginosa may be regulated in the same way as in Klebsiella aerogenes, by induction by urocanate and activation by either the cyclic AMP-dependent activator protein or by glutamine synthetase.     

Induction of Histidine-Degrading Enzymes in Pseudomonas aeruginosa

Urocanate but not histidine was able to induce formation of histidine-degrading enzymes in a histidine ammonia-lyase-deficient mutant of Pseudomonas aeruginosa. The results, in conjunction with others reported previously, indicate that urocanate, the first intermediate, is the physiological inducer of the pathway.     

The degradation of l-histidine, imidazolyl-l-lactate and imidazolylpropionate by Pseudomonas testosteroni

1. Imidazol-5-ylpropionate and imidazol-5-yl-lactate are degraded by Pseudomonas testosteroni via inducible pathways. 2. Growth on either compound as the sole source of carbon results in the induction of the enzymes for histidine catabolism. 3. The pathway of histidine degradation in this organism, a non-fluorescent Pseudomonad, is shown to be the same as that operating in Pseudomonas fluorescens and Pseudomonas putida. It consists of the successive formation of urocanate, imidazol-4-on-5-ylpropionate, N-formimino-l-glutamate, N-formyl-l-glutamate and glutamate. 4. Whole cells of P. testosteroni accumulate urocanate in the reaction mixture when incubated with imidazolylpropionate, but only after an adaptive lag period which is removed by previous growth on imidazolylpropionate as the source of carbon. 5. Imidazolyl-lactate is oxidized to imidazolylpyruvate, which then gives rise to histidine by specific transamination with l-glutamate. 6. Cells grown on histidine, urocanate or imidazolylpropionate are also able to degrade imidazolyllactate. 7. Mutants lacking urocanase are unable to grow on imidazolylpropionate, imidazolyl-lactate, histidine or urocanate. One with impaired histidase activity cannot utilize histidine or imidazolyl-lactate, but grows normally on imidazolylpropionate or urocanate. A mutant unable to grow on imidazolylpropionate is indistinguishable from the wild-type with respect to growth on histidine, imidazolyl-lactate or urocanate. 8. Thus it is established that imidazolyl-lactate is metabolized via histidine whereas imidazolylpropionate enters the histidine degradation pathway after conversion into urocanate.     

Cascading regulation of histidase activity in Streptomyces griseus.

Mutants of Streptomyces griseus unable to utilize histidine as the sole nitrogen source have been isolated and characterized. Using a mutant defective in the production of histidase, we have demonstrated that urocanate functions as the inducer of the histidine utilization system. Another mutant produced histidase that was locked in an inactive form but could be activated by treatment with an extract from the wild-type strain or the histidase-negative strain. This mutant was deficient in the activity of a protein of Mr ca. 90,000 to 100,000 that is required for the activation of histidase. Histidase was synthesized constitutively but was maintained in an inactive form until after histidine or urocanate was added to the medium. At least four components were implicated in the activation of histidase: histidase, the activation protein, urocanate, and a phosphatase that is apparently inactive in cells grown without inducer. The functions of the last three factors could be supplanted in vitro by incubation of histidase with snake venom phosphodiesterase or 5' nucleotidase. The results suggest that histidine utilization by S. griseus is controlled posttranslationally by an activation cascade that involves at least two regulatory proteins.     

L-histidine utilization in Aspergillus nidulans.

Histidase activity rather than uptake of L-histidine is the limiting factor for the utilization of histidine as the sole nitrogen source for Aspergillus nidulans. Histidine cannot act as the sole carbon source, and evidence is presented indicating that this is attributable to an inability to convert histidine to L-glutamate in vivo. It has been shown that this fungus lacks an active urocanase enzyme and that histidine is quantitatively converted to urocanate, which accumulates in the extracellular medium. The use of histidine as a nitrogen source is regulated by nitrogen metabolite repression control of histidase synthesis. In addition, evidence for a requirement for a carbon source for histidase synthesis and for a minor form of control by nitrate is presented. The activity of the histidase enzyme is inhibited by micromolar concentrations of the product urocanate and by physiological levels of L-glutamate and L-glutamine.     

The control of the enzymes degrading histidine and related imidazolyl derivatives in Pseudomonas testosteroni

1. The induction of the enzymes for the degradation of l-histidine, imidazolylpropionate and imidazolyl-l-lactate in Pseudomonas testosteroni was investigated. 2. The activities of histidine ammonia-lyase, histidine-2-oxoglutarate aminotransferase and urocanase are consistent with these enzymes being subject to co-ordinate control under most growth conditions. However, a further regulatory mechanism may be superimposed for histidase alone under conditions where degradation of histidine must take place for growth to occur. 3. Experiments with a urocanase(-) mutant show that urocanate is an inducer for the enzymes given above and also for N-formiminoglutamate hydrolyase and N-formylglutamate hydrolase. 4. N-Formiminoglutamate hydrolase and N-formylglutamate hydrolase are also induced by their substrates, and it is suggested that these two enzymes may be different gene products from those expressed in the presence of urocanate. 5. Induction of the enzyme system for the oxidation of imidazolylpropionate is dependent on exposure of cells to this compound.     

Sequence analysis of the hutH gene encoding histidine ammonia-lyase in Pseudomonas putida.

The complete nucleotide sequence of the hutH gene, encoding histidine ammonia-lyase (histidase), in Pseudomonas putida ATCC 12633 has been determined from the appropriate portions of the hut region that had been cloned into Escherichia coli. The resulting DNA sequence revealed an open reading frame of 1,530 base pairs, corresponding to a protein subunit of approximate molecular weight 53,600, in the location previously identified for the histidase gene by Tn1000 mutagenesis. Translation began at a GTG codon, but direct protein sequencing revealed that the initiating amino acid was removed posttranslationally to provide an N-terminal threonine; 11 additional residues completely agreed with the predicted amino acid sequence. This sequence excluded the possibility that a dehydroalanine unit, the postulated coenzyme for histidase, is attached at the N terminus of histidase subunits. Comparison of the P. putida histidase gene sequence with that of a Bacillus subtilis region encoding histidase revealed 42% identity at the protein level. Although the hutU (urocanase) and hutH (histidase) genes are induced by urocanate and normally are transcribed as a unit beginning with hutU, analysis of the region immediately upstream of the histidase gene revealed a potential weak promoter that may possibly be used to maintain a basal level of histidase for the generation of inducer (urocanate) when histidine levels are elevated.     

Effect of growth rate on histidine catabolism and histidase synthesis in Aerobacter aerogenes

A study was made of how the catabolism of a carbon and energy source is affected by the biosynthetic demands of growing bacterial cells. Cultures of Aerobacter aerogenes in l-histidine medium were grown in a chemostat at rates determined by the supply of either sulfate or a required amino acid, l-arginine. It was discovered that the rate at which these cells grow under a biosynthetic restriction determines both the rate and the pattern of histidine degradation. (i) Histidine catabolism is partially coupled to the growth rate. This coupling is achieved by catabolite repression of histidase (histidine ammonia lyase; EC 4.3.1.3.), and also by a slightly decreased in vivo function of this enzyme at low growth rates. (ii) The looseness of the coupling results in a direct relationship between growth rate and growth yield, and possibly is correlated with an altered pattern of carbon flow from histidine. (iii) Sudden decreases in growth rate cause total repression of histidase synthesis for substantial periods of time. (iv) Sudden release of biosynthetic restriction leads rapidly to an increase in the functioning of the cells' complement of histidase, an increase in the rate of synthesis of this enzyme, and an increase in the growth yield from histidine.     

Cyclic adenosine 3',5'-monophosphate levels in Pseudomonas putida and Pseudomonas aeruginosa during induction and carbon catabolite repression of histidase synthesis.

Inducibility of histidase (histidine ammonia-lyase, EC 4.3.1.3) in Pseudomonas putida and Pseudomonas aeruginosa was observed to be strongly affected by succinate-provoked catabolite repression, but this did not occur as a consequence of reduced intracellular cyclic adenosine 3',5'-monophosphate levels, and repression could not be alleviated by exogenously added cyclic adenosine 3,'5'-monophosphate. Milder repression of histidase by lactate was also not reversed by the addition of cyclic adenosine 3',5'-monophosphate. These results, along with data showing intracellular cyclic adenosine 3',5'-monophosphate levels remained essentially constant during growth on such diverse carbon sources as histidine, acetamide, glucose, and succinate, indicated that catabolite repression of histidase synthesis by efficient carbon sources was not mediated through variations in internal cyclic adenosine 3,'5'-monophosphate.     

Activation of the Bacillus subtilis hut operon at the onset of stationary growth phase in nutrient sporulation medium results primarily from the relief of amino acid repression of histidine transport.

During growth of Bacillus subtilis in nutrient sporulation medium containing histidine (DSM-His medium), the expression of histidase, the first enzyme in the histidine-degradative pathway (hut), is derepressed 40- to 200-fold at the onset of stationary phase. To identify the gene products responsible for this regulation, histidase expression was examined in various hut regulatory mutants as well as in mutants defective in stationary-phase gene regulation. Histidase expression during growth in DSM-His medium was significantly altered only in a strain containing the hutC1 mutation. The hutC1 mutation allows the hut operon to be expressed in the absence of its inducer, histidine. During logarithmic growth in DSM-His medium, histidase levels were 25-fold higher in the HutC mutant than in wild-type cells. Moreover, histidase expression in the HutC mutant increased only four- to eightfold after the end of exponential growth in DSM-His medium. This suggests that histidine transport is reduced in wild-type cells during exponential growth in DSM-His medium and that this reduction is largely responsible for the repression of hut expression in cells growing logarithmically in this medium. Indeed, the rate of histidine uptake in DSM-His medium was fourfold lower in exponentially growing cells than in stationary-phase cells. The observation that the degradation of histidine is inhibited when B. subtilis is growing rapidly in medium containing a mixture of amino acids suggests that a hierarchy of amino acid utilization may be present in this bacterium.     

Histidine metabolism in experimental protein malnutrition in rats

1. The activities of the enzymes histidase, urocanase and histidine-pyruvate transaminase were studied in rats under conditions of protein malnutrition. Urocanase and histidase activities in liver were markedly lowered in experimental protein malnutrition, but the activity of histidine-pyruvate transaminase was unaffected. There is a metabolic control in vivo of the enzymes involved in the catabolism of histidine. 2. Significant changes in the urinary excretion of histidine, composition of liver and serum were apparent in the protein-malnourished rat. 3. The changes in the activities of the enzymes and other parameters were of a reversible nature and dependent on the nature of the dietary protein. 4. The significance of these findings is discussed in relation to abnormal histidine metabolism in kwashiorkor.     

In vivo synthesis of histidine by a cloned histidine ammonia-lyase in Escherichia coli

Histidine ammonia-lyase catalyzes the first step in histidine catabolism, the deamination of histidine to urocanate and ammonia. In vitro experiments have shown that histidine ammonia-lyase also can catalyze the reverse (amination) reaction, histidine synthesis, relatively efficiently under extreme reaction conditions (4 M NH4OH, pH 10). An Escherichia coli hisB deletion strain was transformed with a pBR322 derivative plasmid (pCB101) containing the entire Klebsiella aerogenes histidine utilization (hut) operon to determine whether the catabolic histidine ammonia-lyase could function biosynthetically in vivo to satisfy the histidine auxotrophy. Although the initial construct did not grow on media containing urocanate and ammonia as a source of histidine, spontaneous mutants possessing this ability were isolated. Four mutants characterized grew at doubling times of 4 h compared with 1 h when histidine was present, suggesting that histidine synthesis, although unequivocally present, remained growth limiting. Each mutant contained a plasmid-encoded mutation which eliminated urocanase activity, the second enzyme in the Hut catabolic pathway. This genetic block led to the accumulation of high intracellular levels of urocanate, which was subsequently converted to histidine via histidine ammonia-lyase, thus satisfying the histidine auxotrophic requirement.     

Histidine degradation enzymes in rat liver: Induction by high protein intake

Summary High protein dietary content stimulates urea formation in ureotelic animals but does not exert almost any effect on ammonia production from L-amino acids in vitro. L-histidine and L-threonine are the only amino acids which are most actively deaminated by ureotelic animals fed on a high protein diet.All the steps of L-histidine metabolism have been studied: it has been found that both the histidine transaminase pathway and the histidase pathway are stimulated. Glutamic acid is also a product of histidine catabolism through the histidase pathway, but its catabolism is unaffected by the dietary protein content. These data suggest the existence of independent mechanism controlling the catabolism of the two amino acids.     

Effects of anaerobiosis and nitrate on the expression of succinate dehydrogenase and enzymes associated with nitrogen metabolism in Klebsiella pneumoniae

We have shown that the low histidase activity found in anaerobic, nitrogen-limited cultures of Klebsiella pneumoniae is due to repression of the right-hand hut operon. In addition, we have examined the effects of NO3- on the aerobic and anaerobic expression of catabolite- and NH4+-repressible enzymes in this organism. NO3- permitted anaerobic growth of K. pneumoniae in minimal medium containing histidine as the sole carbon source, and histidase and succinate dehydrogenase were derepressed during anaerobic growth in histidine/NO3- medium. Use of sucrose rather than histidine as the carbon source reversed the effects of NO3- and repressed histidase and succinate dehydrogenase activities. Anaerobic growth in sucrose/NO3- medium also uncoupled the expression of urease and glutamine synthetase.     

Effect of molecular hydrogen on histidine utilization by Alcaligenes eutrophus

The effect of molecular hydrogen on heterotrophic metabolism of the facultative chemolithoautotrophic bacterium Alcaligenes eutrophus strain H 16 was representatively investigated on histidine utilization. The presence of hydrogen in a histidine or urocanate-containing medium had two effects (i) growth of the cells was inhibited, and (ii) formation of histidase was repressed. Both effects were relieved by supplying the cells with exogenous carbon dioxide. Studies on mutants defective in chemolithoautotrophic metabolism revealed that growth inhibition by hydrogen was exclusively mediated by the catalytic function of the soluble hydrogenase. Mutants containing only particulate hydrogenase activity did not exhibit growth inhibition. Repression of histidase formation, however, was mediated by the catalytic activity of the soluble as well as the particulate hydrogenase. Unexpectedly, mutants defective in autotrophic carbon dioxide fixation but unaffected in hydrogen oxidation showed an inhibition of growth by hydrogen but no repression of histidase synthesis. Mutants which formed histidase constitutively were still sensitive to repression in the presence of hydrogen. The results indicate that repression of enzyme synthesis by hydrogen is dependent on the function of both, the hydrogen-oxidizing and the carbon dioxide-fixing system. It is concluded that the hydrogen effect is a transient regulatory mechanism and only relevant for unbalanced conditions of growth.     

Enzyme induction and repression in Arthrobacter crystallopoietes

Summary Catabolic effects which exert control over the inducible synthesis of three enzymes in Arthrobacter crystallopoietes involve at least three different mechanisms: interference with inducer transport, severe catabolite repression, and transient repression. The rate of histidase induction by histidine is reduced by incubation of the cells with succinate or glucose. The maximum effect of succinate, 67% reduction in histidase production, occurs only after 100 min of incubation with succinate. At least 3h of incubation are required for the maximum effect of glucose (31% reduction in enzyme induction). Both succinate and glucose inhibit histidine transport. Cyclic adenosine 3,5-monophosphate (cyclic AMP), at 10^-7 M, slightly stimulates the induction of histidase in cultures both with or without succinate. No conditions were found in which cyclic AMP abolishes the effect of succinate. Induction of l-serine dehydratase by glycine is severely and permanently repressed by glucose and to a lesser extent by citrate. Glucose does not affect glycine uptake. Succinate, fumarate, and aspartate, which are all better substrates than glucose or citrate for growth of A. crystallopoietes, have no effect on l-serine dehydratase induction. Induction and repression of l-serine dehydratase are not affected by cyclic AMP. Synthesis of isocitrate lyase after addition of acetate is unaffected by glucose but is severely repressed by succinate or fumarate. Aspartate and glutamate cause a transient repression of enzyme synthesis after which synthesis proceeds at the control rate. The ability to transport acetate is inducible. Development of this capacity in the presence of acetate is not affected by succinate or glutamate. Cyclic AMP has no effect on enzyme production or repression. A. crystallopoietes takes up radioactive cyclic AMP and has at least one of the enzymes of cyclic AMP metabolism, adenyl cyclase.     

Pyrimidine catabolism in Pseudomonas aeruginosa

Pyrimidine catabolism in Pseudomonas aeruginosa was investigated. It was found that the pyrimidine bases uracil and thymidine as well as their respective reductive catabolic products could be utilized as sole sources of nitrogen. Reductive degradation of the pyrimidine bases was noted. The reductive catabolic pathway enzymes dihydropyrimidine dehydrogenase, dihydropyrimidinase and N-carbamoyl-beta-alanine amidohydrolase were all detected in minimal medium grown cells. Induction of pyrimidine catabolism by uracil was observed in this pseudomonad. Pyrimidine degradation in P. aeruginosa was not subject to catabolite repression.