Salmonella typhimurium mutants lacking NAD pyrophosphatase.

NAD can serve as both a purine and a pyridine source for Salmonella typhimurium. Exogenous NAD is rapidly broken down into nicotinamide mononucleotide and AMP by an NAD pyrophosphatase, the first step in the pathway for the assimilation of exogenous NAD. We isolated and characterized mutants of S. typhimurium lacking NAD pyrophosphatase activity; such mutants were identified by their failure to use exogenous NAD as a purine source. These mutants carry mutations that map at a new locus, designated pnuE, between 86 and 87 min on the Salmonella chromosome.     

Oligopeptidase-deficient mutants of Salmonella typhimurium.

An oligopeptidase that hydrolyzes N-acetyl-L-alanyl-L-alanyl-L-alanyl-L-alanine (AcAla4) has been identified in extracts of Salmonella typhimurium. Mutants lacking this activity have been isolated in dcp mutant strains by screening extracts of mutagenized clones for failure to hydrolyze AcAla4 or by screening colonies for inability to use AcAla4 as a nitrogen source. Double mutants (dcp optA) lacking both oligopeptidase A and dipeptidyl carboxypeptidase cannot use AcAla4 as a nitrogen source, although dcp+ optA and dcp optA+ strains grow on this peptide. The mutations responsible for the loss of activity map at a locus (optA) between asd (75 map units) and xylA (78 map units). Oligopeptidase A hydrolyzes certain N-blocked tetrapeptides, unblocked pentapeptides, and unblocked hexapeptides, usually but not always liberating the C-terminal tripeptide. These two activities seem to be responsible for the production of a large fraction of the dipeptides that accumulate during protein breakdown in a pepN pepA pepB pepD strain.     

5-Fluoroorotate-resistant mutants of Salmonella typhimurium.

Spontaneously occurring mutants of Salmonella typhimurium resistant to 5-fluoroorotate (5-FOA) were isolated. One class of mutant showed marked derepression of pyrimidine biosynthetic enzymes and had the unusual property of being unable to grow on nutrient agar. However, when the osmotic strength of nutrient agar was increased, the mutants were able to grow. The genetic basis for the osmotic fragility and elevated pyr enzyme synthesis was the result of mutations affecting pyrH, encoding the enzyme uridine 5'-monophosphate kinase.     

Dipeptidyl carboxypeptidase-deficient mutants of Salmonella typhimurium.

Mutants of Salmonella typhimurium deficient in dipeptidyl carboxypeptidase have been isolated by screening for clones unable to use N-acetyl-L-alanyl-L-alanyl-L-alanine (AcAla3) as the sole nitrogen source. An insertion of the transposable element Tn10 near dcp (the locus coding for dipeptidyl carboxypeptidase) has been isolated and used to map the locus in the interval between purB and trp, an otherwise genetically silent region of the S. typhimurium map. All dcp mutants could still grow using N-acetyl-L-alanyl-L-alanyl-L-alanyl-L-alanine (AcAla4) as the sole nitrogen source. Crude extracts from the dcp mutants failed to hydrolyze AcAla3 but retained approximately 80% of the wild-type activity toward AcAla4. Several lines of evidence indicate that hydrolysis of AcAla4 in the dcp mutant results from the action of a new peptidase distinct from dipeptidyl carboxypeptidase. A mutant strain lacking dipeptidyl carboxypeptidase in addition to peptidases N, A, B, and D showed reduced protein breakdown during carbon starvation compared with a strain lacking only peptidases N, A, B, and D.     

Salmonella typhimurium mutants defective in acetohydroxy acid synthases I and II.

An analysis of transposon-induced mutants shows that Salmonella typhimurium possesses two major isozymes of acetohydroxy acid synthase, the enzymes which mediate the first common step in isoleucine and valine biosynthesis. A third (minor) acetohydroxy acid synthase is present, but its significance in isoleucine and valine synthesis may be negligible. Mutants defective in acetohydroxy acid synthase II (ilvG::Tn10) require isoleucine, alpha-ketobutyrate, or threonine for growth, a mutant defective in acetohydroxy acid synthase I (ilvB::Tn5) is a prototroph, and a double mutant (ilvG::Tn10 ilvB::Tn5) requires isoleucine plus valine for growth.     

Isolation and characterization Salmonella typhimurium mutants lacking a tripeptidase (peptidase T).

Salmonella typhimurium contains an enzyme, peptidase T, that hydrolyzes a variety of tripeptides. Specificity studies with a peptidase activity stain after gel electrophoresis of crude cell extracts showed that peptidase T hydrolyzes tripeptides containing N-terminal methionine, leucine, or phenylalanine. Little or no activity could be detected against dipeptides, N-blocked or C-blocked tripeptides, and tetrapeptides. Analysis of reaction products by high-pressure liquid chromatography showed that peptidase T removes the N-terminal amino acid from tripeptides. Mutants lacking peptidase T were isolated by screening microcultures grown in the wells of plastic microtitration plates for hydrolysis of Met-Ala-Ser or Met-Gly-Gly. Mutations (pepT) that eliminate this enzyme were found to be phage P22 cotransducible with purB at approximately 25 map units on the S. typhimurium map. Comparison of the growth properties of mutant and wild-type strains suggests that peptidase T does not function in utilization of tripeptides to provide amino acids during growth.     

Peptidase mutants of Salmonella typhimurium

Six peptidase activities have been distinguished electrophoretically in cell extracts of Salmonella typhimurium with the aid of a histochemical stain. The activities can also be partially separated by chromatography on diethylaminoethyl-cellulose. These peptidases show overlapping substrate specificities. Mutants (pepN) of the parent strain leu-485 lacking one of these enzymes (peptidase N) were obtained by screening for colonies that do not hydrolyze the chromogenic substrate l-alanyl-beta-naphthylamide. The absence of this broad-specificity peptidase in leu-485 pepN(-) mutants allowed the selection of mutants unable to use l-leucyl-l-alaninamide as a leucine source. These mutants (leu-485 pepN(-)pepA(-)) lack a broad-specificity peptidase (peptidase A) similar to aminopeptidase I previously described in Escherichia coli. Mutants (pepD) lacking a dipeptidase (peptidase D) have been isolated from a leu-485 pepN(-)pepA(-) parent by penicillin selection for mutants unable to use l-leucyl-l-glycine as a leucine source. Mutants (pepB) lacking a fourth peptidase (peptidase B) have been isolated from a leu-485 pepN(-)pepA(-)pepD(-) strain by penicillin selection for failure to utilize l-leucyl-l-leucine as a source of leucine. Single recombinants were obtained by transduction for each of the peptidases missing in a leu-485 pepN(-)pepA(-)pepD(-)pepB(-) strain. The growth response of these recombinants to leucine peptides shows that all of these peptidases can function in the catabolism of peptides and that they display overlapping substrate specificities in vivo.     

rfaP mutants of Salmonella typhimurium

Salmonella typhimurium rfaP mutants were isolated and characterised with respect to their sensitivity towards hydrophobic antibiotics and detergents, and their lipopolysaccharides were chemically analysed. The rfaP mutants were selected after diethylsulfate mutagenesis or as spontaneous mutants. The mutation in two independent mutants SH7770 (line LT2) and SH8551 (line TML) was mapped by cotransduction with cysE to the rfa locus. The mutants were sensitive to hydrophobic antibiotics (clindamycin, erythromycin and novobiocin) and detergents (benzalkoniumchloride and sodium dodecyl sulfate). Analysis of their lipopolysaccharides by chemical methods and by sodium dodecyl sulfate/polyacrylamide gel electrophoresis revealed that their saccharide portion was, to a large extent, of chemotype Rc with small proportions of material containing a more complete core oligosaccharide and O-specific chains. Only 2.5 mol phosphate/mol lipopolysaccharide was found whereas the phosphate content of the lipopolysaccharide of a galE mutant strain was 4.8 mol. Thus the rfaP mutant lipopolysaccharides lacked more than two phosphate residues. Assessment of the location of phosphate groups in rfaP lipopolysaccharides revealed the presence of at least 2 mol phosphate in lipid A, indicating that the core oligosaccharide was almost devoid of phosphate. The chemical, physiological and genetic data obtained for these mutants are in full agreement with those reported earlier for rfaP mutants of Salmonella minnesota.     

Deoxynucleoside-sensitive mutants of Salmonella typhimurium

Summary Thymineless mutants ofSalmonella typhimurium which are able to grow with low added concentrations of thymine (20 M) fall into two classes on the basis of growth on deoxyribose as sole carbon source. Those which can grow are deoxyribomutase negative and those which cannot are deoxyriboaldolase negative. The former class are inhibited by deoxynucleosides and this provides a method for discriminating between different classes oftlr mutants ofEscherichia coli K12, which cannot utilize deoxyribose as a carbon source. It is suggested that the sensitivity of deoxyriboaldolase negative strains is due to the accumulation of deoxyribose-5-phosphate. The data also indicate that deoxyribose-5-phosphate is the inducer of thymidine phosphorylase. It seems that one or both of the deoxyribose phosphates is the toxic compound, and that reversal of inhibition by ribonucleosides is due to inhibition of the enzymes catalysing their formation from deoxynucleosides. We propose that the symbolsdrm anddra be used to denote the structural genes for deoxyribomutase and deoxyriboaldolase respectively.     

Mapping of the genetic determinant controlling Salmonella K-antigen synthesis. II. Nonmotile mutants of Salmonella typhimurium

According to the preliminary data, S. typhimurium K-antigen is located in the area of minutes 40-44 on the Salmonella chromosome map. The formation of nonmotile mutants from motile Salmonella strains was induced by the action of nitrosoguanidine. Two main groups of mutants differing in their reaction of agglutination with H- and K-antisera were obtained: Mot-H-K- (motA or motB mutants) and Mot-H-K- (H1- or fla- mutants). The transduction transfer of the sign of motility by phage P22HT to H-K- mutants and to H1- and flaE- mutants led to the restoration of agglutination ability with respect to H- and K-antisera in all Mot+ transductants under study simultaneously. The restoration of H+K+ phenotype was also observed in spontaneous motile revertants obtained from H-K- mutants. Thus, the gene controlling the synthesis of K-antigen in Salmonellae was shown to be incorporated into the Fla operon, the regulatory system of the operon controlling the expression of this gene.     

Salmonella typhimurium mutants generally defective in chemotaxis.

The mutations of eight chemotaxis-deficient strains of Salmonella typhimurium, including five new mutants in strain LT2, were mapped by P22 transduction in relation to various fla mot deletions in S. abortus-equi. Seven recessive che mutations mapped between motB and flaC: three, all nontumbling, the che region I, adjacent to motB, and four, including one ever-tumbling, in che region II, adjacent to flaC. Mutant che-107, never-tumbling and dominant to wild type, mapped at flaAII, other mutations of which cause either absence of flagella or lack of locomotor function. We surmise that gene flaAII specifies a protein that polymerizes to form an essential component of the basal apparatus (so that absence of gene product prevents formation of flagela); that a component built up from certain mutationally altered proteins cannot transmit (or generate) active rotation of the hook and flagellum, and so causes the Mot (paralysis) phenyotype; and that a component built up from protein with the che-107 alteration permits only counterclockwise rotation, so that the tumble, normally produced by transient clockwise rotation, cannot be effected.     

Temperature-sensitive glutamate dehydrogenase mutants of Salmonella typhimurium.

Mutants of Salmonella typhimurium defective in glutamate dehydrogenase activity were isolated in parent strains lacking glutamate synthase activity by localizcd mutagenesis or by a general mutagenesis combined with a cycloserine enrichment for glutamate auxotrophs. Two mutants with temperature-sensitive phenotypes had glutamate dehydrogenase activities that were more thermolabile than that of an isogenic control strain. Eight other mutants had less than 10% of the wild-type glutamate dehydrogenase activity. All the mutations were cotransducible with a Tn10 element (zed-2:Tn10) located at approximately 23 U on the S. typhimurium linkage map. These data strongly indicate that this region contains the structural gene (gdhA) for glutamate dehydrogenase.     

Subunit-specific phenotypes of Salmonella typhimurium HU mutants.

Salmonella hupA and hupB mutants were studied to determine the reasons for the high degree of conservation in HU structure in bacteria. We found one HU-1-specific effect; the F'128 plasmid was 25-fold less stable in hupB compared with hupA or wild-type cells. F' plasmids were 120-fold more unstable in hupA hupB double mutants compared with wild-type cells, and the double mutant also had a significant alteration in plasmid DNA structure. pBR322 DNA isolated from hupA hupB strains was deficient in supercoiling by 10 to 15% compared with wild-type cells, and the topoisomer distribution was significantly more heterogeneous than in wild-type or single-mutant strains. Other systems altered by HU inactivation included flagellar phase variation and phage Mu transposition. However, Mu transposition rates were only about fourfold lower in Salmonella HU double mutants. One reason that Salmonella HU double mutants may be less defective for Mu transposition than E. coli is the synthesis in double mutants of a new, small, basic heat-stable protein, which might partially compensate for the loss of HU. The results indicate that although either HU-1 or HU-2 subunit alone may accommodate the cellular need for general chromosomal organization, the selective pressure to conserve HU-1 and HU-2 structure during evolution could involve specialized roles of the individual subunits.     

6-Aminonicotinamide-resistant mutants of Salmonella typhimurium

Resistance to the nicotinamide analog 6-aminonicotinamide has been used to identify the following three new classes of mutants in pyridine nucleotide metabolism. (i) pncX mutants have Tn10 insertion mutations near the pncA locus which reduce but do not eliminate the pncA product, nicotinamide deamidase. (ii) nadB (6-aminonicotinamide-resistant) mutants have dominant alleles of the nadB gene, which we propose are altered in feedback inhibition of the nadB enzyme, L-aspartate oxidase. Many of these mutants also exhibit a temperature-sensitive nicotinamide requirement phenotype. (iii) nadD mutants have mutations that affect a new gene involved in pyridine nucleotide metabolism. Since a high proportion of nadD mutations are temperature-sensitive lethal mutations, this appears to be an essential gene for NAD and NADP biosynthesis. In vivo labeling experiments indicate that in all the above cases, resistance is gained by increasing the ratio of NAD to 6-aminonicotinamide adenine dinucleotide. 6-Aminonicotinamide adenine dinucleotide turns over significantly more slowly in vivo than does normal NAD.     

Refined genetic analysis of the region II che mutants in Salmonella typhimurium

Summary From a detailed complementation analysis of the region II che mutants of Salmonella typhimurium, we have located five che genes, cheA, cheW, cheR, cheB, and cheY. We have shown that corrections are required in the previous assignment of the mutations in four strains: both SL2514 and SL2515 which have been reported to be cheY mutants are cheR mutants, SL2539 is not a cheA but a cheW mutant, and ST171 which has been reported to be a cheZ mutant is a double mutant with defects in both cheA and cheB. Since ST171 is the only cheZ mutant so far isolated, the idea that the cheZ gene might play an essential role in chemotaxis in S. typhimurium as in Escherichia coli has lost its experimental basis. Furthermore, a number of deletion mutants in region II resulting from the excision of Tn10 have been isolated and analysed. From these experiments, we propose that the gene order in region II is flaK-flaE-motA-motB-cheA-cheW-cheR-cheB-cheY-flaM-flaC, which is identical with that in E. coli.     

Accumulation of a lipid-linked intermediate involved in enterobacterial common antigen synthesis in Salmonella typhimurium mutants lacking dTDP-glucose pyrophosphorylase.

The heteropolysaccharide chains of enterobacterial common antigen (ECA) are composed of linear trisaccharide repeat units having the structure----3)-alpha-Fuc4NAc-(1----4)-beta-D-ManNAcA-(1---- 4)-alpha-D-GlcNAc- (1----. Mutants of Salmonella typhimurium lacking the structural gene for dTDP-glucose pyrophosphorylase (rfbA) are severely impaired in their ability to synthesize dTDP-glucose, which is a precursor of dTDP-4-acetamido-4,6-dideoxy-D-galactose (Fuc4NAc), the donor of Fuc4NAc residues for ECA synthesis. These mutants synthesize only trace amounts of ECA, and they are hypersensitive to sodium dodecyl sulfate (SDS). Incubation of delta rfbA mutants with [3H]N-acetylglucosamine ([3H]GlcNAc) resulted in the accumulation of radioactivity in N-acetyl-D-mannosaminuronic acid (ManNAcA)-GlcNAc-pyrophosphorylundecaprenol (lipid II), the putative acceptor of Fuc4NAc residues in ECA synthesis. Lipid II did not accumulate in either wild-type cells or in rff mutants unable to synthesize ManNAcA. Both the accumulation of lipid II and the synthesis of trace amounts of ECA were abolished when delta rfbA mutants were grown in the presence of the antibiotic tunicamycin. Tunicamycin also prevented the SDS-mediated lysis of the mutants. SDS-resistant derivatives of delta rfbA mutants were isolated that were no longer able to synthesize trace amounts of ECA. Characterization of these derivatives revealed that they were defective in various steps of ECA synthesis leading to the synthesis of lipid II. The data support the conclusion that accumulation of lipid II is responsible in some way for the hypersensitivity of delta rfbA mutants to SDS.     

DNA replication defect in Salmonella typhimurium mutants lacking the editing (epsilon) subunit of DNA polymerase III.

In Salmonella typhimurium, dnaQ null mutants (encoding the epsilon editing subunit of DNA polymerase III [Pol III]) exhibit a severe growth defect when the genetic background is otherwise wild type. Suppression of the growth defect requires both a mutation affecting the alpha (polymerase) subunit of DNA polymerase III and adequate levels of DNA polymerase I. In the present paper, we report on studies that clarify the nature of the physiological defect imposed by the loss of epsilon and the mechanism of its suppression. Unsuppressed dnaQ mutants exhibited chronic SOS induction, indicating exposure of single-stranded DNA in vivo, most likely as gaps in double-stranded DNA. Suppression of the growth defect was associated with suppression of SOS induction. Thus, Pol I and the mutant Pol III combined to reduce the formation of single-stranded DNA or accelerate its maturation to double-stranded DNA. Studies with mutants in major DNA repair pathways supported the view that the defect in DNA metabolism in dnaQ mutants was at the level of DNA replication rather than of repair. The requirement for Pol I was satisfied by alleles of the gene for Pol I encoding polymerase activity or by rat DNA polymerase beta (which exhibits polymerase activity only). Consequently, normal growth is restored to dnaQ mutants when sufficient polymerase activity is provided and this compensatory polymerase activity can function independently of Pol III. The high level of Pol I polymerase activity may be required to satisfy the increased demand for residual DNA synthesis at regions of single-stranded DNA generated by epsilon-minus pol III. The emphasis on adequate polymerase activity in dnaQ mutants is also observed in the purified alpha subunit containing the suppressor mutation, which exhibits a modestly elevated intrinsic polymerase activity relative to that of wild-type alpha.