The hisD-hisC gene border of the Salmonella typhimurium histidine operon

Summary We have sequenced the hisD-hisC gene border of the Salmonella typhimurium histidine operon. The translation termination codon of the hisD gene overlaps with the translation initiation codon of the hisC gene in the manner . The Shine-Dalgarno sequence of the hisC gene is contained entirely within hisD and there is no intercistronic space since all of the bases are utilized in coding. Two mutations that alter the hisD-hisC gene border are analyzed. Both mutations simultaneously abolish the termination codon of hisD and modify the initiation codon of hisC. One of the mutations changes the hisC initiation codon from AUG to AUU. The AUU codon is 10 to 20% as efficient as AUG for initiation of translation of the hisC gene. The mutant hisC ribosome binding site is compared to the ribosome binding site of the Escherichia coli infC gene which has been reported to contain an AUU initiation codon. The role of overlapping termination/initiation codons in regulating translation of polycistronic mRNAs in bacterial operons is discussed.     

Structure based design of novel inhibitors for histidinol dehydrogenase from Geotrichum candidum

Histidinol dehydrogenase, the product of the HisD gene, mediates the final step in the histidine biosynthetic pathway. This enzyme has captured attention for drug discovery studies in past few years. Recently, our group cloned and expressed Geotrichum candidum histidinol dehydrogenase and successful screening of substrate analog inhibitors of histidinol dehydrogenase led to some antifungal compounds with IC₅₀ values in micromolar range. In this study, we have done docking analysis of these antifungal agents in G. candidum. Two new compounds were designed based on the docking results and these compounds turned out to be potent inhibitors of G. candidum histidinol dehydrogenase, showing IC₅₀ values as low as 3.17 μM.     

Histidine regulation in Salmonella typhimurium: XVI. A sensitive radiochemical assay for histidinol dehydrogenase

A sensitive radiochemical assay for measurement of histidinol dehydrogenase is presented. The method is based upon separation of the product of the reaction. [¹⁴C]histidine, from the substrate, [¹⁴C]histidinol, on small Dowex 50 columns. The assay can be performed on cell extracts or on toluenized cells and is approximately 100 times more sensitive than previously reported assays for this enzyme.[¹⁴C]histidinol is obtained in high yields through conversion of uniformly labeled ¹⁴C-glucose by a strain of Salmonella typhimurium derepressed for the histidine operon and blocked at the histidinol dehydrogenase step. Accumulated [¹⁴C]histidinol is purified from the culture supernatant by ion-exchange chromatography.This sensitive assay has facilitated measurement of reduced levels of histidine operon expression in promoter mutants, and has been adapted for study of histidine operon regulation in a cell free protein synthesizing system.     

Pleiotropic effect of his gene mutations on nitrogen fixation in Klebsiella pneumoniae

Several his mutations were found to influence nitrogen fixation in Klebsiella pneumoniae: hisB, hisC, and hisD mutants had 50% of wild-type levels of nitrogenase activity when supplied with 30 μg or less histidine/ml although this concentration did not limit protein synthesis and the mutants retained a Nif⁺ plate phenotype. A hisA mutation had a similar but more dramatic effect. At low concentrations of histidine the hisA mutant strain had only 5% of the nitrogenase activity found at high histidine concentration or in a his⁺ strain, and was also Nif^- on low histidine agar plates. Addition of adenine restored nitrogenase activity in the hisA but not the hisB, hisC, or hisD mutants. Low levels of intracellular ATP, a consequence of hisG enzyme activity, correlated with loss of nitrogen-fixing ability in the hisA mutant which failed to sustain nif gene expression under these conditions. Synthesis of other major cell proteins was relatively unaffected indicating that nif gene expression is selectively regulated by the energy status of the organism.     

Nascent SecM Chain Outside the Ribosome Reinforces Translation Arrest

SecM, a bacterial secretion monitor protein, contains a specific amino acid sequence at its C-terminus, called arrest sequence, which interacts with the ribosomal tunnel and arrests its own translation. The arrest sequence is sufficient and necessary for stable translation arrest. However, some previous studies have suggested that the nascent chain outside the ribosome affects the stability of translation arrest. To clarify this issue, we performed in vitro translation assays with HaloTag proteins fused to the C-terminal fragment of E. coli SecM containing the arrest sequence or the full-length SecM. We showed that the translation of HaloTag proteins, which are fused to the fragment, is not effectively arrested, whereas the translation of HaloTag protein fused to full-length SecM is arrested efficiently. In addition, we observed that the nascent SecM chain outside the ribosome markedly stabilizes the translation arrest. These results indicate that changes in the nascent polypeptide chain outside the ribosome can affect the stability of translation arrest; the nascent SecM chain outside the ribosome stabilizes the translation arrest.     

Genetic fusions that place the lactose genes under histidine operon control

The genes of the Salmonella histidine operon (his) have been placed on an F′ pro lac plasmid using genetic methods that rely on recombinational homology provided by Tn10 transposon insertions. The position and orientation of the transposed his genes permit subsequent deletion mutations to form operon fusions that put the lac genes under his operon control. Strains carrying such fusions show co-ordinate regulation of histidinol dehydrogenase and beta-galactosidase expression. While all of the operon fusions have an intact hisD gene, complementation testing and deletion mapping reveal that the genes downstream of hisD are deleted to varying extents. The beta-galactosidase produced by these operon fusions is itself a fused protein containing the amino terminus of one or another of the his enzymes. Two of the operon fusions having join-points in the hisB gene retain histidinol phosphate phosphatase activity and may produce a bifunctional protein having beta-galactosidase as well as the phosphatase activity. The methods that have been used to isolate these his-lac fusions should be applicable to other genetic systems.     

Non-suppressible addition frameshift in Salmonella

A frameshift mutation in the histidinol dehydrogenase gene of Salmonella was isolated after induction with the intercalating agent, ICR-191⁴. Reversion of the frameshift, 2578, is strongly enhanced by ICR and by the alkylating agent N-methyl-?-nitro-N-nitrosoguanidine. In all cases previously examined, frame-shifts with this reversion profile have proven to be +1 types, most likely containing an extra G·C pair in a DNA repeat of G·C pairs. Most are suppressible by external suppressors, which appear to translate the +1 site on mRNA as proline or glycine. Frameshift 2578, however, is one of a small minority which, while reverted by ICR-191 and N-methyl-?-nitro-N-nitrosoguanidine, does not appear to be suppressible by external suppressors. Sequence studies of revertant histidinol dehydrogenase suggest that 2578 is an addition of one or two G·C pairs in a DNA repeat of G·C pairs. This addition, however, produces mRNA quadruplets which are in an incorrect phase for suppressor translation.     

The amino terminal sequence of ATP-phosphoribosyltransferase, the first gene product of the histidine operon.

The amino terminal sequence of ATP-phosphoribosyltransferase of $\text{Salmonella typhimurium}$ has been determined by automated Edman degradation. Since this protein is the first gene product of the histidine operon, comparison of its amino terminal sequence with the genetic code allows the deduction of a partial base sequence of its mRNA and the corresponding DNA. Five of the first nine residues of ATP-phosphoribosyltransferase align with the amino terminal sequence of histidinol dehydrogenase, the second gene product of the histidine operon.     

HOL1 mutations confer novel ion transport in Saccharomyces cerevisiae.

Saccharomyces cerevisiae histidine auxotrophs are unable to use L-histidinol as a source of histidine even when they have a functional histidinol dehydrogenase. Mutations in the hol1 gene permit growth of His- cells on histidinol by enhancing the ability of cells to take up histidinol from the medium. Second-site mutations linked to HOL1-1 further increase histidinol uptake. HOL1 double mutants and, to a lesser extent, HOL1-1 single mutants show hypersensitivity to specific cations added to the growth medium, including Na+, Li+, Cs+, Be2+, guanidinium ion, and histidinol, but not K+, Rb+, Ca2+, or Mg2+. The Na(+)-hypersensitive phenotype is correlated with increased uptake and accumulation of this ion. The HOL1-1-101 gene was cloned and used to generate a viable haploid strain containing a hol1 deletion mutation (hol1 delta). The uptake of cations, the dominance of the mutant alleles, and the relative inability of hol1 delta cells to take up histidinol or Na+ suggest that hol1 encodes an ion transporter. The novel pattern of ion transport conferred by HOL1-1 and HOL1-1-101 mutants may be explained by reduced selectivity for the permeant ions.     

Analysis of an L-histidinol-utilizing mutant of Pseudomonas aeruginosa.

Transductional analysis was applied to the Pseudomonas aeruginosa mutant PAO14 (hnc-1). This mutant can utilize L-histidinol as sole source of carbon and nitrogen and has a 60-fold increased histidinol dehydrogenase (HDH) content (Dhawale, Creaser & Loper, 1972). Transductional analysis was carried out using 18 histidine-requiring mutants to see where the hnc-1 locus maps in relation to the structural genes of histidine biosynthesis. The hnc-1 marker cotransduced with group IV genes at 97 to 100 % and not at all with group I, which is known to be the structural gene for HDH. The data obtained in the studies of Km (histidinol) and Km (NAD), and the effect of pH and temperature on the HDH activity from PAO1 and PAO14 are in full agreement with the genetic data that the hnc-1 mutation is not in the structural gene for HDH. It is suggested that hnc-1 may be a mutation in a regulatory gene affecting HDH synthesis in PAO14 and may map close to his-IV whose function in histidine biosynthesis is not known.     

Ontogeny of hemoglobins: Evidence for hemoglobin M

A new autosomal codominant hemoglobin mutation alters hemoglobin M of the primitive red cell line and hemoglobin D found in definitive cells. That Hb M and Hb D are altered by the same gene mutation supports the idea that Hb M shares a polypeptide chain with Hb D. It is concluded that in the switch from primitive hemoglobins to those of the definitive type, there are at least two α chains conserved; α^A of Hb E in Hb A and α^D of Hb M in Hb D.     

Deletion mutants of nitrogen fixation in Klebsiella pneumoniae: Mapping of a cluster of nif genes essential for nitrogenase activity

Deletions of the nitrogen fixation (nif) region of the Klebsiella genome were isolated by selecting for resistance to virulent phages whose resistance loci are adjacent to nif. The extent of the various deletions was monitored by assaying several different enzymes or gene products coded for by this segment of DNA. Three classes of deletion mutants were detected: (1) gluconate-6-phosphate dehydrogenase minus (gnd^?), histidine minus but histidinol dehydrogenase plus (his^?, his D⁺), nitrogenase plus (nif⁺), shikimate utilization plus (shu⁺); (2) gnd^?, his D^?, nif^?, shu⁺; (3) gnd^?, his D^?, nif^?, shu^?. From these studies we conclude that the cluster of nif genes essential for nitrogenase activity is located on the genetic linkage map of Klebsiella between his and shu; the gene order in this region in thus phage-resistance locus (rfb?), gnd, his operon, nif, shu. Genetic analysis substantiates the finding that the nif cluster is located proximally to the operator end of the his operon.     

Detection and properties of l-histidinol dehydrogenase in wheat germ

The presence and partial characterization of the properties of l-histidinol dehydrogenase (EC 1.1.1.23), the enzyme catalysing the last step in the pathway of histidine biosynthesis, has been described in higher plants for the first time. The activity has been found in cell-free extracts from wheat germ, turnip root, radish root and squash fruit. The enzyme has been partially purified and characterized from extracts of acetone powders of wheat germ. DEAE-cellulose chromatography revealed two peaks of histidinol dehydrogenase activity. In one there was a rapid reduction of NAD⁺ in the absence of histidinol; however, the rate was stimulated by the addition of histidinol. The rate in the absence of substrate became quite low after several min and the histidinol-dependent rate was then easily observed. The second peak of activity did not reduce NAD⁺ unless l-histidinol was present in the assay mixture. The K^ms for l-histidinol and NAD⁺ were determined for this latter enzyme. The values obtained at saturating concentrations of the other substrate were l-histidinol, 8.8 μM and NAD⁺, 0.14 mM. The product of the dehydrogenase reaction was histidine as determined by paper chromatography.     

A Biochemical Characterization of Histidine Auxotrophs of Corynebacterium glutamicum

Two imidazoleglycerol (IG)-producing mutants and one imidazoleacetol (IA)-producing mutant were selected out of 14 histidine auxotrophs of C. glutamicum, by means of paper-chromatographic analysis of the culture broths of these mutants. Three of the histidine biosynthetic enzymes were determined for these mutants and a previously isolated histidinol-producing mutant of C. glutamicum. The IA-producing mutant and the l-histidinol-producing mutant had a defect in histidinol phosphate aminotransferase and histidinol dehydrogenase, respectively. IG-producers were not defective in these enzymes. These results were consistent with the histidine biosynthetic sequence known in other microorganisms.     

Association of polymorphic markers I/D of gene ACE and A1166C of gene AT2R1 with ischemic chronic heart failure in the Russian and Tatar populations of Bashkortostan Republic

Polymerase chain reaction was used to study the association of polymorphic markers I/D of the angiotensin-converting enzyme gene (ACE) and A1166C of the angiotensin II type 1 receptor gene (AT2R1) with chronic heart failure (CHF) in Russian and Tatar patients that had had myocardial infarction. In Russian patients aged 50 years or younger that had had macrofocal myocardial infarction, the CC genotype of the A1166C polymorphic marker of gene AT2R1 was associated with an increased risk of CHF (OR = 11.36). Genotype DD and allele D of the I/D polymorphic marker of gene ACE were associated with a more severe CHF (functional class III–IV) in Russian patients (OR = 3.50 and 2.06). In Tatar patients, polymorphic markers I/D of gene ACE and A1166C of gene AT2R1 were not associated with CHF.     

Kinetic mechanism of histidinol dehydrogenase: histidinol binding and exchange reactions

Salmonella typhimurium histidinol dehydrogenase produces histidine from the amino alcohol histidinol by two sequential NAD-linked oxidations which form and oxidize a stable enzyme-bound histidinaldehyde intermediate. The enzyme was found to catalyze the exchange of 3H between histidinol and [4(R)-3H]NADH and between NAD and [4(S)-3H]NADH. The latter reaction proceeded at rates greater than kcat for the net reaction and was about 3-fold faster than the former. Histidine did not support an NAD/NADH exchange, demonstrating kinetic irreversibility in the second half-reaction. Specific activity measurements on [3H]histidinol produced during the histidinol/NADH exchange reaction showed that only a single hydrogen was exchanged between the two reactants, demonstrating that under the conditions employed this exchange reaction arises only from the reversal of the alcohol dehydrogenase step and not the aldehyde dehydrogenase reaction. The kinetics of the NAD/NADH exchange reaction demonstrated a hyperbolic dependence on the concentration of NAD and NADH when the two were present in a 1:2 molar ratio. The histidinol/NADH exchange showed severe inhibition by high NAD and NADH under the same conditions, indicating that histidinol cannot dissociate directly from the ternary enzyme-NAD-histidinol complex; in other words, the binding of substrate is ordered with histidinol leading. Binding studies indicated that [3H]histidinol bound to 1.7 sites on the dimeric enzyme (0.85 site/monomer) with a KD of 10 microM. No binding of [3H]NAD or [3H]NADH was detected. The nucleotides could, however, displace histidinol dehydrogenase from Cibacron Blue-agarose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Complementary roles of the DRY motif and C-terminus tail of GPCRS for G protein coupling and beta-arrestin interaction

β-arrestin mediates the desensitization of GPCRs and acts as an adaptor molecule to recruit the receptor complex to clathrin-rich regions. Class-A GPCRs subsequently dissociate from β-arrestin but class-B GPCRs internalize with β-arrestin in the endocytic vesicles. Here the dopamine D₂ and D₃ receptors, which have similar structural features but different intracellular trafficking properties, were used in an attempt to better understand the structural requirements for the classification of GPCRs. The C-terminus tail of the vasopressin type-2 receptor was added to the ends of D₂R and D₃R to increase their affinity to β-arrestin. A point mutation was introduced into the DRY motif to change their basal activation levels. Among a battery of constructs in which the C-terminus tail and/or DRY motif was altered, class-B behavior was observed with the constructs whose affinities for β-arrestin were increased complementarily and their signaling was either maintained or regained. In conclusion, the DRY motif and C-terminal tail of the GPCRs determine complementarily their intracellular trafficking behavior by regulating the affinity to β-arrestin and G protein coupling.