Specific binding of the first enzyme for histidine biosynthesis to the DNA of histidine operon.

Studies were done to examine direct binding of the first enzyme of the histidine biosynthetic pathway (phosphoribosyltransferase) to 32P-labeled phi80dhis DNA and competition of this binding by unlabeled homologous DNA and by various preparations of unlabeled heterologous DNA, including that from a defective phi80 bacteriophage carrying the histidine operon with a deletion of part of its operator region. Our findings show that phosphoribosyltransferase binds specifically to site in or near the regulatory region of the histidine operon. The stability of the complex formed by interaction of the enzyme with the DNA was markedly decreased by the substrates of the enzyme and was slightly increased by the allosteric inhibitor, histidine. These findings are consistent with previous data that indicate that phosphoribosyltransferase plays a role in regulating expression of the histidine operon.     

Expression of the histidine operon in rho mutants of Escherichia coli.

Expression of the Escherichia coli histidine operon was measured in four independently isolated sets of strains carrying ten different rho mutations. Rho factor does not act as a major regulatory element of histidine operon attenuation.     

Mutational analysis of the histidine operon promoter of Salmonella typhimurium.

We isolated a collection of 67 independent, spontaneous Salmonella typhimurium his operon promoter mutants with decreased his expression. The mutants were isolated by selecting for resistance to the toxic lactose analog o-nitrophenyl-beta-D-thiogalactoside in a his-lac fusion strain. The collection included base pair substitutions. small insertions, a deletion, and one large insertion identified as IS30 (IS121), which is resident on the Mu d1 cts(Apr lac) phage used to construct the his-lac fusion. Of the 37 mutations that were sequenced, 14 were unique. Six of the 14 were isolated more than once, with the IS30 insertion occurring 16 times. The mutations were located throughout the his promoter region, with two in the conserved - 35 hexamer sequence, four in the conserved - 10 hexamer sequence (Pribnow box), seven in the spacer between the - 10 and -35 hexamer sequences, and the IS30 insertions just upstream of the -35 hexamer sequence. Four of the five substitution mutations changed a consensus base pair recognized by E sigma 70 RNA polymerase in the -10 or -35 hexamer. Decreased his expression caused by the 14 different his promoter mutations was measured in vivo. Relative to the wild-type promoter, the mutations resulted in as little as a 4-fold decrease to as much as a 357-fold decrease in his expression, with the largest decreases resulting from changes in the most highly conserved features of E sigma 70 promoters.     

Aminotransferase from a deletion mutant in the histidine operon

The imidazolylacetolphosphate:l-glutamate aminotransferase from the deletion mutant hisHB22 has been partially characterized. Although genetic studies have not yet shown the deletion to involve the structural information for this enzyme, physical studies indicate that an abnormal enzyme is produced. Evidence is presented which, together with previous data on the characterization of the enzyme, indicates that the catalytic integrity of the enzyme is intact, and that the low specific activity seen in cell extracts is due to formation of an enzyme which has a reduced coenzyme content. It is suggested that this reduced coenzyme content is due primarily to a reduced affinity of the enzyme (nascent or apo-) for its coenzyme, and that the coenzyme must be incorporated into the enzyme at the moment of synthesis for formation of a functional protein.     

ICR-induced frameshift mutations in the histidine operon of Salmonella

Both the acridine half-mustard, ICR191, and the nonalkylating azaacridine derivative, ICR364-OH, induce three classes of frameshift mutations in the histidine operon of Salmonella typhimurium. (i) One class is completely stable in reversion tests and is presumed to represent deletion of one or a few critical nucleotide pairs or two nearby frameshifts. One extended deletion was found out of 11 stable mutations. (ii) Of two spontaneously reverting classes which also are considered to predominantly involve base deletions, one is unaffected in reversion with ICR191, nitrosoguanidine, and diethylsulfate, and the other is induced to revert with ICR191. (iii) A third class, considered to predominantly involve base additions, responds in reversion tests with ICR191 as well as with nitrosoguanidine and diethylsulfate. Other investigators have shown that one mutant of this class is a "plus" frameshift and that nitrosoguanidine acts in reversion to delete a guanine plus cytosine base pair. Although such plus frameshifts are found with high frequency among mutations selected from acridine-treated bacteria or when strong selection pressure is applied for their detection in reversion tests, data from this laboratory indicate that this class of plus frameshifts is rare among mutations derived spontaneously or after treatment with a variety of other mutagens. Finally, we demonstrate that the alkylating ICR191 and the nonalkylating ICR364-OH preferentially cause mutations in different chromosome regions and that their spectra of activity only partially overlap that found for spontaneous frameshift mutations.     

trans-Recessive mutation in the first structural gene of the histidine operon that results in constitutive expression of the operon.

The first enzyme for histidine biosynthesis, encoded in the hisG gene, is involved in regulation of expression of the histidine operon in Salmonella typhimurium. The studies reported here concern the question of how expression of the histidine operon is affected by a mutation in the hisG gene that alters the allosteric site of the first enzyme for histidine biosynthesis, rendering the enzyme completely resistant to inhibition by histidine. The intracellular concentrations of the enzymes encoded in the histidine operon in a strain carrying such a mutation on an episome and missing the chromosomal hisG gene are three- to fourfold higher than in a strain carrying a wild-type hisG gene on the episome. The histidine operon on such a strain fails to derepress in response to histidine limitation and fails to repress in response to excess histidine. Furthermore, utilizing other merodiploid strains, we demonstrate that the wild-type hisG gene is trans dominant to the mutant allele with respect to this regulatory phenomenon. Examination of the regulation of the histidine operon in strains carrying the feedback-resistant mutation in an episome and hisT and hisW mutations in the chromosome showed that the hisG regulatory mutation is epistatic to the hisT and hisW mutations. These data provide additional evidence that the first enzyme for histidine biosynthesis is involved in autogenous regulation of expression of the histidine operon.     

Tandem genetic duplications in Salmonella typhimurium: amplification of the histidine operon.

Bovine pancreatic phospholipase A₂ (M_r = 14,000) has been crystallized and its three-dimensional structure determined by X-ray diffraction analysis to a resolution of 2.4 Å. Three heavy-atom derivatives were used in the phase calculations with inclusion of the anomalous dispersion differences. The resulting electron density map allowed an easy and unambiguous tracing of the peptide chain. Two of the seven disulfide connections appeared to be different from what was suggested by the earlier chemical and structural work. The bovine phospholipase A₂ structure contains about 50% α-helix and 10% β-structure. The bovine enzyme structure was found to deviate substantially from the previously published porcine prophospholipase structure.     

Promoter- and attenuator-related metabolic regulation of the Salmonella typhimurium histidine operon.

Expression of the histidine (his) operon in Salmonella typhimurium was found to be positively correlated with the intracellular level of guanosine tetraphosphate (ppGpp). Limitation for amino acids other than histidine elicited a histidine-independent metabolic regulation of the operon. In bacteria grown at decreased growth rates, his operon expression was metabolically regulated up to a point, after which further decreases in growth rate no longer resulted in further enhancement of operon expression. Studies using strains carrying various regulatory and deletion mutations indicated that metabolic regulation is achieved predominantly by increased RNA chain initiations at the primary (P1) and internal (P2) promoters. Metabolic regulation ordinarly did not involve changes in RNA chain terminations at the attenuator site of the his operon. A model is proposed that involves ppGpp-induced changes in RNA polymerase initiation specificity at particular promoters. A second, special form of metabolic regulation may operate which also is histidine independent, but does involve relief of attenuation.     

Allosteric properties of the first enzyme of the histidine operon

PR-ATP synthetase, the first enzyme of histidine biosynthesis of Salmonella typhimurium has been purified by an improved procedure which yields enzyme which migrates as a single band in both gel electrophoresis and electrofocusing experiments. When stored in glycerol solution at −15°C, PR-ATP synthetase remains fully active and sensitive to inhibition by histidine for extended time periods. The enzyme requires manganese or magnesium ions for activity and is activated by numerous monovalent cations. The pH optimum is 8 to 10 and is strongly dependent upon the buffer employed. The equilibrium constant for the reaction is 10⁻³.