Regulation of hut enzymes and intracellular protease activities in Vibrio alginolyticus hut mutants

The production of alkaline protease, collagenase and histidine utilization (Hut) enzymes by Vibrio alginolyticus wild-type, hutH1 and hutU1 strains was investigated. Alkaline protease synthesis was stimulated by histidine and urocanic acid in the wild-type and hutU1 strains. The hutH1 mutant alkaline protease production was stimulated by urocanic acid and not by histidine. The Hut enzymes in the wild-type strain were coordinately induced by histidine. Urocanase and formimino-hydrolase were induced by histidine in the hutH1 mutant which lacked histidase and was not able to convert histidine to urocanic acid. Collagenase production in peptone medium was inhibited in the hut mutants. It is concluded that in V. alginolyticus urocanic acid regulates alkaline protease synthesis but that the Hut enzymes are induced by histidine. The involvement of the Hut genetic system in the regulation of alkaline protease and collagenase synthesis is discussed.     

Histidine ammonia-lyase from Streptomyces griseus.

Histidine ammonia-lyase (histidase; HutH) has been purified to homogeneity from Streptomyces griseus and the N-terminal amino acid (aa) sequence used to clone the histidase-encoding structural gene, hutH. The purified enzyme shows typical saturation kinetics and is inhibited competitively by D-histidine and histidinol phosphate. High concentrations of K.cyanide inactivate HutH unless the enzyme is protected by the substrate or histidinol phosphate. On the basis of the nucleotide sequence, the hutH structural gene would encode a protein of 53 kDa with an N terminus identical to that determined for the purified enzyme. Immediately upstream from hutH is a region that strongly resembles a class of Streptomyces promoters active during vegetative growth; however, there is no obvious ribosome-binding site adjacent to the hutH translation start codon. The deduced aa sequence of an upstream partial open reading frame shows no similarity with other proteins, including HutP of Bacillus subtilis and HutU of Pseudomonas putida. Promoter-probe analysis indicates that promoter activity maps within the DNA surrounding the hutH start codon. Pairwise comparisons of the primary structures of bacterial and mammalian histidases, together with the unique kinetic properties and gene organization, suggest that streptomycete histidase may represent a distinct family of histidases.     

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.     

Purification of histidase from Streptomyces griseus and nucleotide sequence of the hutH structural gene.

Histidine ammonia-lyase (histidase) was purified to homogeneity from vegetative mycelia of Streptomyces griseus. The enzyme was specific for L-histidine and showed no activity against the substrate analog, D-histidine. Histidinol phosphate was a potent competitive inhibitor. Histidase displayed saturation kinetics with no detectable sigmoidal response. Neither thiol reagents nor a variety of divalent cations had any effect on the activity of the purified enzyme. High concentrations of potassium cyanide inactivated histidase in the absence of its substrate or histidinol phosphate, suggesting that, as in other histidases, dehydroalanine plays an important role in catalysis. The N-terminal amino acid sequence of histidase was used to construct a mixed oligonucleotide probe to identify and clone the histidase structural gene, hutH, from genomic DNA of the wild-type strain of S. griseus. The cloned DNA restored the ability of a histidase structural gene mutant to grow on L-histidine as the sole nitrogen source. The deduced amino acid sequence of hutH shows significant relatedness with histidase from bacteria and a mammal as well as phenylalanine ammonia-lyase from plants and fungi.     

Characterization of a Snorhizobium meliloti ATP-binding cassette histidine transporter also involved in betaine and proline uptake

The symbiotic soil bacterium Sinorhizobium meliloti uses the compatible solutes glycine betaine and proline betaine for both protection against osmotic stress and, at low osmolarities, as an energy source. A PCR strategy based on conserved domains in components of the glycine betaine uptake systems from Escherichia coli (ProU) and Bacillus subtilis (OpuA and OpuC) allowed us to identify a highly homologous ATP-binding cassette (ABC) binding protein-dependent transporter in S. meliloti. This system was encoded by three genes (hutXWV) of an operon which also contained a fourth gene (hutH2) encoding a putative histidase, which is an enzyme involved in the first step of histidine catabolism. Site-directed mutagenesis of the gene encoding the periplasmic binding protein (hutX) and of the gene encoding the cytoplasmic ATPase (hutV) was done to study the substrate specificity of this transporter and its contribution in betaine uptake. These mutants showed a 50% reduction in high-affinity uptake of histidine, proline, and proline betaine and about a 30% reduction in low-affinity glycine betaine transport. When histidine was used as a nitrogen source, a 30% inhibition of growth was observed in hut mutants (hutX and hutH2). Expression analysis of the hut operon determined using a hutX-lacZ fusion revealed induction by histidine, but not by salt stress, suggesting this uptake system has a catabolic role rather than being involved in osmoprotection. To our knowledge, Hut is the first characterized histidine ABC transporter also involved in proline and betaine uptake.     

Cloning and expression of rat histidase. Homology to two bacterial histidases and four phenylalanine ammonia-lyases

Histidase (histidine ammonia-lyase, EC 4.3.1.3) catalyzes the deamination of histidine to urocanic acid. Apart from phenylalanine ammonia-lyase, which is not expressed in animals, histidase is the only enzyme known to have a dehydroalanine residue in its active site. The amino site precursor and the mechanism of formation of dehydroalanine are not known. As an initial step to determining the precursor of dehydroalanine in histidase, we have isolated a functional cDNA clone for histidase from a rat liver cDNA library using an affinity-purified antiserum. The 2.2-kilobase cDNA has a 1,971-base pair open reading frame coding for a 657-amino acid polypeptide with a predicted molecular mass of 72,165 Da. The cDNA has a rare polyadenylation signal (AAUACA) that appears to inefficiently direct polyadenylation in transfected COS monkey kidney cells. Conversion of this sequence to the consensus polyadenylation signal (AAUAAA) resulted in increased levels of stable mRNA. COS cells transfected with a histidase expression vector produce active histidase. The formation of active histidase in cells that have no endogenous histidase activity suggests either that the requisite modifying enzyme is present in these cells or that the dehydroalanine residue forms by an autocatalytic mechanism. Rat histidase was found to have 41 and 43% amino acid identity to Pseudomonas putida and Bacillus subtilis histidases, respectively. Phenylalanine ammonia-lyases from parsley, kidney bean, and two yeast strains were also found to have approximately 20% amino acid identity to rat histidase. On the basis of the similarity of function of histidase and phenylalanine ammonia-lyase, dehydroalanine at the active sites, and the sequence conservation over a large evolutionary distance (mammals, bacteria, yeast, and plants), we propose that the genes for histidase and phenylalanine ammonia-lyase have diverged from a common ancestral gene, of which the most conserved regions are likely to be involved in catalysis or dehydroalanine formation.     

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.     

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.     

Formation and operation of the histidine-degrading pathway in Pseudomonas aeruginosa

Histidine ammonia lyase (histidase), urocanase, and the capacity to degrade formiminoglutamate, which are respectively involved in steps I, II, and IV in the catabolism of histidine, were induced during growth of Pseudomonas aeruginosa on histidine or urocanate, and were formed gratuitously in the presence of dihydro-urocanate. Urocanase-deficient bacteria formed enzymes I and IV constitutively; presumably they accumulate enough urocanate from the breakdown of endogenous histidine to induce formation of the pathway. Urocanate did not satisfy the histidine requirement of a histidine auxotroph, indicating that it probably acted as an inducer without being converted to histidine. The results imply that urocanate is the physiological inducer of the histidine-degrading enzymes in P. aeruginosa. Enzymes of the pathway were extremely sensitive to catabolite repression; enzymes I and II, but not IV, were coordinately repressed. Our results suggest a specific involvement of nitrogenous metabolites in the repression. Mutant bacteria with altered sensitivity to repression were obtained. The molecular weight of partially purified histidase was estimated at 210,000 by sucrose gradient centrifugation. Its K(m) for histidine was 2 x 10(-3)m in tris(hydroxymethyl)aminomethane chloride buffer. Sigmoid saturation curves were obtained in pyrophosphate buffer, indicating that the enzyme might have multiple binding sites for histidine. Under certain conditions, histidase appeared to be partially inactive in vivo. These findings suggest that some sort of allosteric interaction involving histidase may play a role in governing the operation of the pathway of histidine catabolism.     

Molecular cloning of chicken hepatic histidase and the regulation of histidase mRNA expression by dietary protein

Chicken hepatic histidase activity varies with dietary protein consumption, but the mechanisms responsible for this alteration in activity are unclear. In the present research, the complete coding sequence and deduced amino acid sequence for chicken histidase was determined from clones isolated from a chicken liver cDNA library. The deduced amino acid sequence of chicken histidase has greater than 85% identity with the amino acid sequences of rat, mouse, and human histidase. In a series of four experiments, broiler chicks were allowed free access for 1.5, 3, 6, or 24 h to a low (13 g/100 g diet), basal (22 g/100 g diet) and high (40 g/100 g diet) protein diet. In the final experiment 5, chicks were allowed free access for 24 h to the basal, high protein diet or the basal diet supplemented with three different levels of l-histidine (0.22 g/100 g diet, 0.43 g/100 g diet or 0.86 g/100 g diet). There were no differences in the expression of the mRNA for histidase at 1.5 h, but at 3 h, histidase mRNA expression was significantly (P < .05) greater in chicks fed the high protein diet compared to chicks fed the low protein diet. At 6 and 24 h, histidase mRNA expression was significantly enhanced in chicks fed the high protein diet, and significantly reduced in chicks fed the low protein diet, compared with chicks fed the basal diet. Histidase mRNA expression was not altered by supplementing the basal diet with histidine. The results suggest that previously observed alterations in the activity of histidase, which were correlated to dietary protein intake, are mediated by rapid changes in the mRNA expression of this enzyme, and are not necessarily related to dietary histidine intake.     

Tn1000-mediated insertion mutagenesis of the histidine utilization (hut) gene cluster from Klebsiella aerogenes: genetic analysis of hut and unusual target specificity of Tn1000.

The histidine utilization (hut) genes from Klebsiella aerogenes were cloned in both orientations into the HindIII site of plasmid pBR325, and the two resulting plasmids, pCB120 and pCB121, were subjected to mutagenesis with Tn1000. The insertion sites of Tn1000 into pCB121 were evenly distributed throughout the plasmid, but the insertion sites into pCB120 were not. There was a large excess of Tn1000 insertions in the "plus" or gamma delta orientation in a small, ca. 3.5-kilobase region of the plasmid. Genetic analysis of the Tn1000 insertions in pCB120 and pCB121 showed that the hutUH genes form an operon transcribed from hutU and that the hutC gene (encoding the hut-specific repressor) is independently transcribed from its own promoter. The hutIG cluster appears not to form an operon. Curiously, insertions in hutI gave two different phenotypes in complementation tests against hutG504, suggesting either that hutI contains two functionally distinct domains or that there may be another undefined locus within the hut cluster. The set of Tn1000 insertions allowed an assignment of the gene boundaries within the hut cluster, and minicell analysis of the polypeptides expressed from plasmids carrying insertions in the hut genes showed that the hutI, hutG, hutU, and hutH genes encode polypeptides of 43, 33, 57, and 54 kilodaltons, respectively.     

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.     

Molecular cloning of the nahG gene encoding salicylate hydroxylase from Pseudomonas fluorescens

A gene encoding the salicylate hydroxylase was cloned from the genomic DNA of Pseudomonas fluorescens SME11. The DNA fragment containing the nahG gene for the salicylate hydroxylase was mapped with restriction endonucleases and sequenced. The DNA fragment contained an ORF of 1,305 bp encoding a polypeptide of 434 amino acid residues. The nucleotide and amino acid sequences of the salicylate hydroxylase revealed several conserved regions with those of the enzyme encoded in P. putida PpG7: The homology of the nucleotide sequence is 83% and that of amino acid sequence is 72%. We found large conserved regions of the amino acid sequence at FAD and NADH binding regions. The FAD binding site is located at the amino terminal region and a lysine residue functions as a NADH-binding site.     

Genetic control of the histidine dissimilatory pathway in Pseudomonas putida

Summary In P. putida the first four enzymes involved in the dissimilation of histidine are induced by the first intermediate of the pathway, urocanic acid. The genes specifying these enzymes, hutH, hutU, hutF and (probably) hutI appear to be clustered on the chromosome between pcaE and pcaA (genes involved in p-hydroxybenzoic acid catabolism). Two mutants which produce the histidine-dissimilitory enzymes constitutively have been isolated. They appear to carry mutations in a regulatory locus, which maps in the same region as the structural genes of the pathway.     

Characterization of a gene involved in histidine biosynthesis in Halobacterium (Haloferax) volcanii: isolation and rapid mapping by transformation of an auxotroph with cosmid DNA.

Techniques for the transformation of halophilic archaebacteria have been developed recently and hold much promise for the characterization of these organisms at the molecular level. In order to understand genome organization and gene regulation in halobacteria, we have begun the characterization of genes involved in amino acid biosynthesis in Halobacterium (Haloferax) volcanii. These studies are facilitated by the many auxotrophic mutants of H. volcanii that have been isolated. In this project we demonstrate that cosmid DNA prepared from Escherichia coli can be used to transform an H. volcanii histidine auxotroph to prototrophy. A set of cosmid clones covering most of the genome of H. volcanii was used to isolate the gene which is defective in H. volcanii WR256. Subcloning identified a 1.6-kilobase region responsible for transformation. DNA sequence analysis of this region revealed an open reading frame encoding a putative protein 361 amino acids in length. A search of the DNA and protein data bases revealed that this open reading frame encodes histidinol-phosphate aminotransferase (EC 2.6.1.9), the sequence of which is also known for E. coli, Bacillus subtilis, and Saccharomyces cerevisiae.