Salmonella typhimurium newD and Escherichia coli leuC genes code for a functional isopropylmalate isomerase in Salmonella typhimurium-Escherichia coli hybrids.

The supQ newD gene substitution system in Salmonella typhimurium restores leucine prototrophy to leuD mutants by providing the newD gene product which is capable of replacing the missing leuD polypeptide in the isopropylmalate isomerase, a complex of the leuC and leuD gene product. Mutations in the supQ gene are required to make the newD protein available. An Escherichia coli F' factor was constructed which carried supQ- newD+ from S. typhimurium on a P22-specialized transducing genome. This F' pro lac (P22dsupQ394newD) episome was transferred into S. typhimurium strains containing th leuD798-ara deletion; the resulting merodiploid strains had a Leu+ phenotype, indicating that supQ- newD+ is dominant over supQ+ newD+, and eliminating the possibility that the supQ gene codes for a repressor of the newD gene. Furthermore, transfer of the F' pro lac (P22dsupQ39newD) into E. coli leuD deletion strains restored leucine prototrophy, showing that the S. typhimurium newD gene can complment the E. coli leuC gene. Growth rates of the S. typhimurium-E coli hybrid strains indicated that the mutant isopropylmalate isomerase in these strains does not induce a leucine limitation, as it does in S. typhimurium leuD supQ mutants. In vitro activity of the mutant isopropylmalate isomerase was demonstrated; the Km values for alpha-isopropylmalate of both the S. typhimurium leuC-newD isomerase and the S. typhimurium-E. coli hybrid isomerase were as much as 100 times higher than the Km values for alpha-isopropylmalate of the wild-type enzyme, which was 3 x 10(-4) M. Mutagenesis of E. coli leuD deletion strains failed to restore leucine prototrophy, indicating that E. coli does not have genes analogous to the S. typhimurium supQ newD genes, of that, if present, activation of a newD is a rare event or is lethal to the cell.     

Regulation of isopropylmalate isomerase synthesis in Neurospora crassa.

The capacity to synthetize isopropylmalate isomerase (EC 4.2.1.33) by Neurospora crassa increased during induction in the presence of cycloheximide but was inhibited by proflavine and other inhibitors of RNA synthesis. Turnover of the enzyme once formed appeared negligible, but the message (measured as enzyme-forming capacity) had a half-life of 4 to 8 min. A comparison of the kinetics of induction in the wild type and a newly isolated alpha-isopropylmalate-permeable strain suggested strongly that feedback control by leucine of alpha-isopropylmalate production can adequately serve as the primary physiological regulator of endogenous inducer concentration. Genetic data are presented which implicate the involvement of two unlinked genes, ipm-1 and ipm-2, in determining permeation of alpha-isopropylmalate.     

Phylogenetic Relationships between different D-Xylose Biogroups in Wild-type Salmonella typhimurium strains and a suggested Evolutionary Pathway

Sixty-two wild-type Salmonella typhimurium strains were characterized for their D-xylose enzyme activities. Strains from the xylose strong biogroup synthesized high levels of D-xylose isomerase and D-xylulokinase and transported D-xylose. Strains from the xylose weak biogroup synthesized only low levels of D-xylulokinase and low, or no, levels of D-xylose isomerase and were deficient in the ability to transport D-xylose. These findings are discussed in the light of known phylogenetic relationships among the biotypes of Salm. typhimurium.     

pepM is an essential gene in Salmonella typhimurium.

The pepM gene of Salmonella typhimurium codes for a methionine-specific aminopeptidase that removes N-terminal methionine residues from proteins. This gene was inactivated in vitro by the insertion of a DNA fragment coding for kanamycin resistance. The inactivated gene could not replace the wild-type chromosomal pepM gene unless another functional copy was present in the cell. The lethal effect of the pepM insertion was not a result of polarity on any gene downstream, nor was it affected by the presence or absence of other peptidases.     

Type VI collagen is composed of a 200 kd subunit and two 140 kd subunits.

We have isolated type VI collagen, a transformation-sensitive glycoprotein of the extracellular matrix, in an intact, disulfide-bonded form. The protein contains a 200 kd subunit and two different 140 kd subunits in a stoichiometric ratio. Based on the amount of hydroxyproline and hydroxylysine, the sensitivity to bacterial collagenase and the cross-reactivity with antibodies to pepsin-extracted type VI collagen, we have identified the 200 kd subunit as the alpha 3(VI) chain and the two 140 kd subunits as the alpha 1(VI) and alpha 2(VI) chains. The alpha 3(VI) chain is synthesized by cells in culture as a precursor of 260 kd, while no precursor form of the other two chains could be detected.     

Conformational dynamics of two histidine-binding proteins of Salmonella typhimurium.

The Salmonella typhimurium periplasmic histidine-binding J-protein is one of four proteins encoded by the histidine transport operon. Mutant J-protein hisJ5625 binds L-histidine, but does not transport it. The tertiary structure and conformational dynamics of native and mutant J-protein have been compared using steady state fluorescence, fluorescence polarization, and fluorescence energy transfer measurements. The two proteins have different three-dimensional structures and exhibit different responses to histidine binding. Ligand-induced conformational changes were demonstrated in both J-proteins using fluorescence energy transfer (distant reporter method) between the single tryptophan residue per mole of protein and a fluorescein-labeled methionine residue. However, the conformational change of the mutant protein is qualitatively and quantitatively different from that of the wild-type protein. Moreover, the microenvironment of the tryptophan and its distance from the labeled methionine (44A for the wild type, 60A for the mutant J-protein) are different in the two proteins. In conclusion, these results indicate that the specific conformational change induced in the wild type J-protein is a necessary requirement for the transport of L-histidine.     

Allyl isothiocyanate is mutagenic in Salmonella typhimurium

Allyl isothiocyanate, a naturally occurring compound, component of oil of mustard and human food plants such as cabbage, cauliflower and horseradish, has up to now been regarded as nonmutagenic in bacterial mutagenicity testing systems. Recently, however, it was found to cause transitional-cell papillomas in the urinary bladder of male F344 rats. Contrary to earlier reports, in this study allyl isothiocyanate showed clear mutagenicity for Salmonella typhimurium TA100 in the preincubation assay after longer, non-standard preincubation times (greater than 20 min). The mutagenicity is expressed only in the presence of a rat-liver homogenate metabolising system, i.e. it is indirect. However, high concentrations of rat-liver homogenate suppress the mutagenicity of allyl isothiocyanate. SKF525, inhibitor of microsomal oxygenase, reduces the mutagenic potential which on the other hand is increased in the presence of 1,1,1-trichloropropene-2-oxide, inhibitor of epoxide hydrolase. This indicates the occurrence of an epoxide intermediate in allyl isothiocyanate metabolism. Another metabolic pathway, namely hydrolysis to allyl alcohol and oxidation to acrolein, a known mutagen, also seems possible as cyanamide, inhibitor of aldehyde dehydrogenase, can slightly increase the mutagenic potential. The reason(s) for allyl isothiocyanate's requirement for long preincubation times to express mutagenicity still requires elucidation, and the question arises: is allyl isothiocyanate a single, exceptional case or not?     

Isolation and characterization of human glucose-6-phosphate isomerase isoforms containing two different size subunits

Previously undetected isoforms of human glucose-6-phosphate isomerase (GPI) have been isolated utilizing substrate-induced elution of the enzyme from spherical cross-linked phosphocellulose as an affinity ligand and subjected to a series of physical and chemical studies. The two major isoforms (1, 48%, pI 9.13; 2, 36%, pI 9.00) are homodimers of subunits of 63.2 kDa (Type-A) and are charge isomers, probably representing deamidation of specific Asn-Gly sequences as in other species. Isoform 3 (13%, pI 8.84) is a heterodimer composed of the Type-A subunit and a previously unreported larger subunit of 69.8 kDa (Type-B). Isoform 4 (3%, pI 8.62) is a BB-homodimer. Structural differences in the two types of subunits are also apparent from CNBr fragmentation patterns. Carbohydrate analyses show that, even though potential N- and O-linked glycosylation sites exist, the isoforms are not due to glycosylation. Recently recognized sequence similarities between GPI and the neurotropic lymphokine, neuroleukin (NLK) suggest that GPI and NLK are either derived from the same gene or represent modifications of the same protein. The possibility of NLK-GPI dimers exists, but the new isoforms identified in this study do not appear to represent hybrids of GPI subunits with mature NLK.     

Studies on the subunits of the anthranilate synthetase-phosphoribosyltransferase enzyme complex from Salmonella typhimurium.

Both uncomplexed subunits of the anthranilate synthetase-phosphoribosyltransferase enzyme complex from Salmonella typhimurium have an absolute requirement for divalent metal ions which can be satisfied by Mg²⁺, Mn²⁺, or Co²⁺. The metal ion kinetics for uncomplexed anthranilate synthetase give biphasic double-reciprocal plots and higher apparent K_m values than those for anthranilate synthetase in the enzyme complex. In contrast, the apparent K_m values for phosphoribosyltransferase are the same whether the enzyme is uncomplexed or complexed with anthranilate synthetase. This suggests that the metal ion sites on anthranilate synthetase, but not those on phosphoribosyltransferase, are altered upon formation of the enzyme complex. These results and the results of studies reported by others, suggest that complex formation between anthranilate synthetase and phosphoribosyltransferase leads to marked alterations at the active site of the former, but not the latter enzyme. Uncomplexed anthranilate synthetase can be stoichiometrically labeled with Co(III) under conditions which lead to inactivation of 75% of its activity. A comparison of the effects of anthranilate and tryptophan on phosphoribosyltransferase activity in the uncomplexed and complexed forms shows that anthranilate, but not tryptophan, inhibits the uncomplexed enzyme. The complexed phosphoribosyltransferase shows substrate inhibition by anthranilate binding to the phosphoribosyltransferase subunits. In contrast, in a tryptophan-hypersensitive variant complex, anthranilate inhibits phosphoribosyltransferase activity by acting on the anthranilate synthetase subunits. The data are interpreted to mean that there are two classes of binding sites for anthranilate, one on each type of subunit, which may participate in the regulation of anthranilate synthetase and phosphoribosyltransferase under different conditions.     

Construction and characterization of two lexA mutants of Salmonella typhimurium with different UV sensitivities and UV mutabilities.

Salmonella typhimurium has a SOS regulon which resembles that of Escherichia coli. recA mutants of S. typhimurium have already been isolated, but no mutations in lexA have been described yet. In this work, two different lexA mutants of S. typhimurium LT2 have been constructed on a sulA background to prevent cell death and further characterized. The lexA552 and lexA11 alleles contain an insertion of the kanamycin resistance fragment into the carboxy- and amino-terminal regions of the lexA gene, respectively. SOS induction assays indicated that both lexA mutants exhibited a LexA(Def) phenotype, although SOS genes were apparently more derepressed in the lexA11 mutant than in the lexA552 mutant. Like lexA(Def) of E. coli, both lexA mutations only moderately increased the UV survival of S. typhimurium, and the lexA552 strain was as mutable as the lexA+ strain by UV in the presence of plasmids encoding MucAB or E. coli UmuDC (UmuDCEc). In contrast, a lexA11 strain carrying any of these plasmids was nonmutable by UV. This unexpected behavior was abolished when the lexA11 mutation was complemented in trans by the lexA gene of S. typhimurium. The results of UV mutagenesis correlated well with those of survival to UV irradiation, indicating that MucAB and UmuDCEc proteins participate in the error-prone repair of UV damage in lexA552 but not in lexA11. These intriguing differences between the mutagenic responses of lexA552 and lexA11 mutants to UV irradiation are discussed, taking into account the different degrees to which the SOS response is derepressed in these mutants.     

M ring, S ring and proximal rod of the flagellar basal body of Salmonella typhimurium are composed of subunits of a single protein, FliF.

The flagellar basal body, a major part of the flagellar motor, consists of a rod and four rings. When the fliF gene of Salmonella typhimurium, which was previously shown to code for the component protein of the M ring, was cloned and overexpressed in Escherichia coli, the FliF subunits formed ring structures in the cytoplasmic membrane. Electron microscopic observation of the purified ring structures revealed that each was composed of two adjacent rings and a short appendage extending from the center of the rings. Antibodies raised against the purified FliF protein decorated both the M and S rings of the intact basal body. We conclude that the FliF protein is the subunit protein of the M ring, and of the S ring and of part of the proximal rod of the flagellar basal body.     

Bacteriophage-resistant mutants of Salmonella typhimurium deficient in two major outer membrane proteins.

Mutants resistant to bacteriophages (P221 and PH105 or PH51) were isolated from a rfa strain of Salmonella typhimurium. They were found deficient in separate 33,000- to 36,000-dalton band proteins (major band proteins). Double mutants derived from both types of mutants were deficient in both of the bands. The growth behavior of all the mutants was normal. The outer membrane of the mutants appeared to be more wrinkled than normal and formed vesicles in many of the mutants. In freeze-fractured cells, changes were seen in the outer membrane (particleless patches in the concave fracture face, the particles themselves being smaller than normal). These changes were more marked in the double mutants.