Fasting-induced changes in ECL cell gene expression.

Gastric enterochromaffin-like (ECL) cells release histamine in response to food because of elevation of gastrin and neural release of pituitary adenylate cyclase-activating peptide (PACAP). Acid secretion is at a basal level in the absence of food but is rapidly stimulated with feeding. Rats fasted for 24 h showed a significant decrease of mucosal histamine despite steady-state expression of the histamine-synthesizing enzyme histidine decarboxylase (HDC). Comparative transcriptomal analysis using gene expression oligonucleotide microarrays of 95% pure ECL cells from fed and 24-h fasted rats, thereby eliminating mRNA contamination from other gastric mucosal cell types, identified significantly increased gene expression of the enzymes histidase and urocanase catabolizing the HDC substrate L-histidine but significantly decreased expression of the cellular L-histidine uptake transporter SN2 and of the vesicular monoamine transporter 2 (VMAT-2) responsible for histamine uptake into secretory vesicles. This was confirmed by reverse transcriptase-quantitative polymerase chain reaction of gastric fundic mucosal samples from fed and 24-h fasted rats. The decrease of VMAT-2 gene expression was also shown by a decrease in VMAT-2 protein content in protein extracts from fed and 24-h fasted rats compared with equal amounts of HDC protein and Na-K-ATPase alpha(1)-subunit protein content. These results indicate that rat gastric ECL cells regulate their histamine content during 24-h fasting not by a change in HDC gene or protein expression but by regulation of substrate concentration for HDC and a decreased histamine secretory pool.

The amino-terminal 100 residues of the nitrogen assimilation control protein (NAC) encode all known properties of NAC from Klebsiella aerogenes and Escherichia coli.

The nitrogen assimilation control protein (NAC) from Klebsiella aerogenes or Escherichia coli (NACK or NACE, respectively) is a transcriptional regulator that is both necessary and sufficient to activate transcription of the histidine utilization (hut) operon and to repress transcription of the glutamate dehydrogenase (gdh) operon in K. aerogenes. Truncated NAC polypeptides, generated by the introduction of stop codons within the nac open reading frame, were tested for the ability to activate hut and repress gdh in vivo. Most of the NACK and NACE fragments with 100 or more amino acids (wild-type NACK and NACE both have 305 amino acids) were functional in activating hut and repressing gdh expression in vivo. Full-length NACK and NACE were isolated as chimeric proteins with the maltose-binding protein (MBP). NACK and NACE released from such chimeras were able to activate hut transcription in a purified system in vitro, as were NACK129 and NACE100 (a NACK fragment of 129 amino acids and a NACE fragment of 100 amino acids) released from comparable chimeras. A set of NACE and NACK fragments carrying nickel-binding histidine tags (his6) at their C termini were also generated. All such constructs derived from NACE were insoluble, as was NACE itself. Of the his6-tagged constructs derived from NACK, NACK100 was inactive, but NACK120 was active. Several NAC fragments were tested for dimerization. NACK120-his6 and NACK100-his6 were dimers in solution. MBP-NACK and MBP-NACK129 were monomers in solution but dimerized when the MBP was released by cleavage with factor Xa. MBP-NACE was readily cleaved by factor Xa, but the resulting NACE was also degraded by the protease. However, MBP-NACE-his6 was completely resistant to cleavage by factor Xa, suggesting an interaction between the C and N termini of this protein.

Regulation of histidase gene expression by glucagon, hydrocortisone and protein-free/high carbohydrate diet in the rat.

The effect of glucagon and hydrocortisone was investigated to understand the mechanism of induction of hepatic histidase gene. In this study, glucagon (0.6 mg/100 g body wt/d) was injected to rats fed 10% casein diet. After 3 h of the last injection, histidase activity and amount of enzyme were induced by 3 fold and histidase mRNA concentration by 6 fold. Injection of hydrocortisone (2 mg/100 g body wt/d) increased 100% histidase activity and mRNA concentration and by 150% the amount of enzyme after 3 h of the last injection. These results indicate that glucagon is a better inductor of histidase gene expression than hydrocortisone. Another purpose of the study was to evaluate if a protein-free/high carbohydrate diet could reverse the induction of Hal expression produced by a high protein diet. Hal activity, amount of enzyme and mRNA concentration was repressed by 68, 88 and 95% respectively by a protein-free/high carbohydrate diet. Injection of glucagon reversed partially the effect of a high carbohydrate diet, however, injection of hydrocortisone under the concentration used in these experiments did not reverse the effect of a high carbohydrate diet. These results support the evidence that hepatic histidase gene expression is probably regulated transcriptionally by hormones.

The nac (nitrogen assimilation control) gene from Escherichia coli.

The nitrogen assimilation control gene, nac, was detected in Escherichia coli but not in Salmonella typhimurium by Southern blotting, using a probe from the Klebsiella aerogenes nac (nacK) gene. The E. coli nac gene (nacE) was isolated from a cosmid clone by complementation of a nac mutation in K. aerogenes. nacE was fully functional in this complementation assay. DNA sequence analysis showed considerable divergence between nacE and nacK, with a predicted amino acid sequence identity of only 79% and most of the divergence in the C-terminal half of the protein sequence. The total predicted size of NAC(E) is 305 amino acids, the same as for NAC(K). A null mutation, nac-28, was generated by reverse genetics. Mutants bearing nac-28 have a variety of phenotypes related to nitrogen metabolism, including slower growth on cytosine, faster growth on arginine, and suppression of the failure of an Ntr-constitutive mutant to grow with serine as sole nitrogen source. In addition to a loss of nitrogen regulation of histidase formation, nac-28 mutants also showed a loss of a weak repression of glutamate dehydrogenase formation. This repression was unexpected because it is balanced by a NAC-independent activation of glutamate dehydrogenase formation during nitrogen-limited growth. Attempts to purify NAC(E) by using methods established for NAC(K) failed, and NAC(E) appears to be degraded with a half-life at 30 degrees C as short as 15 min during inhibition of protein synthesis.

Molecular cloning and structural characterization of the human histidase gene (HAL).

Histidase (EC 4.3.1.3) is a cytosolic enzyme that catalyzes the nonoxidative deamination of histidine to urocanic acid. Histidinemia, resulting from reduced histidase activity as reported in Cambridge stock his/his mice and in humans, is the most frequent inborn metabolic error in Japan. The histidase chromosomal gene (HAL) was isolated from a lambda EMBL-3 human genomic library using the human histidase cDNA as a probe. Restriction mapping and Southern blot analysis of the isolated clones reveal a single-copy gene spanning approximately 25 kb and consisting of 21 exons. Exon 1 encodes only 5' untranslated sequence of liver histidase mRNA, with protein coding beginning in exon 2. A rarely observed 5' GC, similar to that reported in the human P-450 (SCC) gene, is present in intron 20. All other splicing junctions adhere to the canonical GT/AG rule. A TATA box sequence is located 25 bp upstream of the liver histidase transcription initiation site determined by S1 nuclease protection analysis. Several liver- and epidermis-specific transcription factor binding sites, including C/EBP, NFIL6, HNF5, AP2/KER1, MNF, and others, are also identified in the 5' flanking region. Consistent with the hepatic and epidermal expression of histidase, this finding suggests that histidase transcription may be regulated by these factors. We further identify a polymorphism (A to G transition) in the histidase coding region of exon 16. The human histidase genomic structure presented here should facilitate the molecular investigation of symptomatic and asymptomatic forms of histidinemia.

Catabolite repression of the Bacillus subtilis hut operon requires a cis-acting site located downstream of the transcription initiation site.

Expression of the Bacillus subtilis hut operon is subject to regulation by catabolite repression. A set of hut-lacZ transcriptional fusions was constructed and used to identify two cis-acting sites involved in catabolite repression. The hutOCR1 operator site lies immediately downstream of the hut promoter and weakly regulates hut expression in response to catabolite repression. The downstream hutOCR2 operator site lies within the hutP gene, between positions +203 and +216, and is required for wild-type levels of catabolite repression. Both the hutOCR1 and hutOCR2 operators have sequence similarity to the sites which mediate catabolite repression of several other B. subtilis genes. Two mutations which relieve catabolite repression of hut expression were found to alter the nucleotide sequence of the hutOCR2 operator. Catabolite repression of hut expression was partially relieved in strains containing the ccpA mutation but not in strains containing either the pai or hpr mutation.

Modulation of Bacillus subtilis catabolite repression by transition state regulatory protein AbrB.

The first enzyme of the Bacillus subtilis histidine-degradative (hut) pathway, histidase, was expressed at higher levels during the onset of the stationary growth phase in nutrient sporulation medium in early-blocked sporulation mutants (spo0A) than in wild-type strains. Histidase expression was also elevated in spo0A mutant cultures compared with wild-type cultures during the logarithmic growth phase in minimal medium containing slowly metabolized carbon sources. Histidase expression was not derepressed in spo0A abrB mutant cultures under these growth conditions, suggesting that the AbrB protein is responsible for the derepression of histidase synthesis seen in spo0A mutant cultures. spo0A mutants contain higher levels of the AbrB protein than do wild-type strains because the Spo0A protein represses AbrB expression. A direct correlation between the levels of abrB transcription and histidase expression was found in spo0A mutant cultures. The hutOCR2 operator, which is required for wild-type regulation of hut expression by catabolite repression, was also required for AbrB-dependent derepression of hut expression in spo0A mutants. Purified AbrB protein bound to the hutOCR2 operator in vitro, suggesting that AbrB protein alters hut expression by competing with the hut catabolite repressor protein for binding to the hutOCR2 site. During the logarithmic growth phase in media containing slowly metabolized carbon sources, the expression of several other enzymes subject to catabolite repression was elevated in spo0A mutants but not in spo0A abrB mutants. This suggests that the AbrB protein acts as a global modulator of catabolite repression during carbon-limited growth.

Purification and characterization of Pseudomonas putida histidine ammonia-lyase expressed in Escherichia coli.

Histidine ammonia-lyase (HAL) from Pseudomonas putida PRS1 contains a catalytically important electrophilic center reported to be dehydroalanine. Little is known about the origin of this group or its linkage to the protein. To initiate structural studies on this enzyme, P. putida HAL was purified from an Escherichia coli high-expression clone in which the HAL gene (hutH) was under the control of the lambda PL promoter on a plasmid vector. In this clone from 6 to 10% of the soluble cell protein after heat induction was HAL and approximately 200 mg of 95% pure HAL could be obtained from 120 g wet weight of cells in a 40 to 60% yield. The overexpressed protein was identical to P. putida HAL in native molecular weight (220 kDa), subunit composition (four identical subunits of 53 kDa each), affinity for substrate (L-histidine Km of 5.3 mM at pH 9.0), and its sensitivity to inactivation by cyanide and bisulfite. The N-terminal amino acid sequence was in agreement with the DNA-predicted sequence, indicating proper translational initiation. These features make this enzyme an appropriate candidate for protein structure investigations regarding the nature of the electrophilic center and its association with the protein.

The product of the Klebsiella aerogenes nac (nitrogen assimilation control) gene is sufficient for activation of the hut operons and repression of the gdh operon.

In Klebsiella aerogenes, the formation of a large number of enzymes responds to the quality and quantity of the nitrogen source provided in the growth medium, and this regulation requires the action of the nitrogen regulatory (NTR) system in every case known. Nitrogen regulation of several operons requires not only the NTR system, but also NAC, the product of the nac gene, raising the question of whether the role of NAC is to activate operons directly or by modifying the specificity of the NTR system. We isolated an insertion of the transposon Tn5tac1 which puts nac gene expression under the control of the IPTG-inducible tac promoter rather than the nitrogen-responsive nac promoter. When IPTG was present, cells carrying the tac-nac fusion activated NAC-dependent operons and repressed NAC-repressible operons independent of the nitrogen supply and even in the absence of an active NTR system. Thus, NAC is sufficient to regulate operons like hut (encoding histidase) and gdh (encoding glutamate dehydrogenase), confirming the model that the NTR system activates nac expression and NAC activates hut and represses gdh. Activation of urease formation occurred at a lower level of NAC than that required for glutamate dehydrogenase repression, and activation of histidase formation required still more NAC.

gltF, a member of the gltBDF operon of Escherichia coli, is involved in nitrogen-regulated gene expression.

We report here the construction and analysis of insertional mutations in each of the three genes of the gltBDF operon and the nucleotide sequence of the region downstream from gltD. Two open reading frames were identified, the first of which corresponds to gltF. The gltB and gltD genes code for the large and small subunits, respectively, of the enzyme glutamate synthase (GOGAT). gltF codes for a protein, with a molecular mass of 26,350 Da, which is required for Ntr induction. Histidase synthesis was determined as a measure of Ntr function. First, insertions in gltB, gltD or gltF all prevent Ntr induction. Second, complementation analysis indicates that high-level expression of both the gltD and gltF genes is required for the induction of the Ntr enzymes under nitrogen-limiting conditions, indicating that the phenotype of the gltB insertion probably results from polarity on gltD and gltF. Third, glutamate-dependent repression of the glt operon appears to be mediated by the product of the gltF gene. Thus, the gltBDF operon of Escherichia coli is involved in induction of the so-called Ntr enzymes in response to nitrogen deprivation, as well as in glutamate biosynthesis.

Regulation of histidine and proline degradation enzymes by amino acid availability in Bacillus subtilis.

The first enzymes of the histidine (hut) and proline degradative pathways, histidase and proline oxidase, could not be induced in Bacillus subtilis cells growing in glucose minimal medium containing a mixture of 16 amino acids. Addition of the 16-amino-acid mixture to induced wild-type cells growing in citrate minimal medium repressed histidase synthesis 25- to 250-fold and proline oxidase synthesis 16-fold. A strain containing a transcriptional fusion of the hut promoter to the beta-galactosidase gene was isolated from a library of Tn917-lacZ transpositions. Examination of histidase and beta-galactosidase expression in extracts of a hut-lacZ fusion strain grown in various media showed that induction, catabolite repression, and amino acid repression of the hut operon were mediated at the level of transcription. This result was confirmed by measurement of the steady-state level of hut RNA in cells grown in various media. Since amino acid repression was not defective in B. subtilis mutants deficient in nitrogen regulation of glutamine synthetase and catabolite repression, amino acid repression appears to be mediated by a system that functions independently of these regulatory systems.

[Effectiveness of a new Soviet drug Benzonal, inductor of microsomal enzymes of the liver, in the complex treatment of hemolytic disease of newborn]. / Effektivnost' primeneniia novogo otechestvennogo induktora mikro- somal'nykh fermentov pecheni benzonala v kompleksnoi terapii hemoliticheskoi bolezni novorozhdennykh.

The effects of benzonal on the course of neonatal hemolytic disease due to the Rhesus factor-conflict was studied in comparison with that of phenobarbital. Dynamic follow-up of infants in the early neonatal period showed benzonal to produce a more pronounced hypobilirubinemic effect which was manifested as a prompter disappearance of skin jaundice and lower percentages of complications. By depressing the activity of organospecific enzymes and lowering the serum biliary acid levels, benzonal promotes normalization of the metabolic shifts present in neonatal hemolytic disease. The findings make it possible to recommend the new inductor of microsomal liver enzymes benzonal as part of the combined therapy of neonatal hemolytic disease.

Effect of Zajdela ascites hepatoma on the activity and synthesis of liver histidase of tumor-bearing rats.

The synthesis of histidase occurs only in free polyribosomes. The relative content of histidase synthesizing polyribosomes in rat liver, in Zajdela ascites hepatoma cells and in the liver of tumor-bearing rats is equal to 1.35%, 0.11% and 0.57%, respectively (of the total amount of free polyribosomes). It was found that hepatoma cell sap has an inhibitory effect on the synthesis of proteins in the cell-free system reconstructed from polyribosomes and cell sap of control rats.

2-Ketoglutarate and the regulation of aconitase and histidase formation in Bacillus subtilis.

In contrast to wild-type cells, the Bacillus subtilis mutant SF109 that lacks the active 2-ketoglutarate dehydrogenase enzymatic complex is unable to increase the specific activity of two enzymes subject to glucose catabolite repression, aconitase and histidase, during limitation of growth by glucose. Examination of the intracellular metabolite pools in the mutant and wild-type cells grown in excess and limiting glucose medium showed that the complete derepression of aconitase and histidase could be correlated with the decrease in the intracellular concentration of 2-ketoglutarate. The complete repression of aconitase that occurred in wild-type and mutant cells could be correlated with a high intracellular concentration of 2-ketoglutarate.

Isolation of Bacillus subtilis mutants pleiotropically insensitive to glucose catabolite repression.

A pleiotropic mutant of Bacillus subtilis was isolated which overproduced in the presence of glucose several enzymes whose synthesis is subject to glucose catabolite repression. Examination of intracellular metabolites suggested that the mutation may have resulted in a defect in glycolysis, increasing phosphoenolpyruvate and decreasing pyruvate, 2-ketoglutarate, and oxaloacetate.

Nitrogen regulation system of Klebsiella aerogenes: the nac gene.

In Klebsiella aerogenes, the product of a his-linked gene, nac, appears to play a crucial role in tying the synthesis of enzymes activated or repressed by ammonia deprivation, such as histidase and glutamate dehydrogenase, to the known regulators of nitrogen assimilation, the products of glnG and glnF.

Studies on the induction of histidase in Vibrio el tor under nitrofurantoin resistant conditions.

Studies on the induction of histidase were made with normal and nitrofurantoin resistant strains of Vibrio el tor. Nitrofurantoin resistant strains showed decreased level of induction in comparison to normal Vibrio el tor. The effect of different inhibitors like actinomycin D, chloramphenicol, tetracycline, nitrofurantoin and rifampicin on histidase induction was also studied. The mechanism of inhibition caused by the antibiotics is discussed.

[Hormonal induction of tyrosine aminotransferase in animal liver during chronic poisoning with ethanol and carbon tetrachloride]. / Gormonal'naia induktsiia tirozinaminotransferazy pecheni zhivotnykh pri khronicheskoi intoksikatsii étanolom i chetyrekhkhloristym uglerodom.

Repeated administration of ethanol into animals within 14 and 21 days decreased or completely abolished the inducing effect of ethanol on the tyrosine aminotransferase activity (TAT) in liver tissue. At the same time, the inducing effect of hydrocortisone was maintained although at the lower level as compared with the intact animals. Chronic poisoning of the animals with CCl4 within 4 weeks inhibited the inducing effect. As compared with controls the inducing effect of hydrocortisone was distinctly lower in the animals poisoned with CCl4.

Histidine dissimilation in Streptomyces coelicolor.

A growth technique that allows strains of Streptomyces coelicolor to grow dispersed in defined liquid medium has been devised and used to determine the pathway of histidine degradation by S. coelicolor. Enzymic, chromatographic and stoichiometric analyses indicated that histidine is dissimilated via N-formyl-L-glutamic acid. The enzymes for histidine utilization (hut) are induced when histidine or urocanate is included in the culture medium. Biochemical evidence suggested that urocanate, or a further metabolite, is the physiological inducer. Three hut mutants were isolated and characterized. Two of the mutants exhibit an uninducible phenotype, whereas the third mutant appears to be defective in the structural gene for formiminoglutamate iminohydrolase. Haploid recombinant analysis was employed to locate all three mutations in the left empty region of the chromosomal map.