High mutation frequencies among Escherichia coli and Salmonella pathogens.

Here it is reported that the incidence of mutators among isolates of pathogenic Escherichia coli and Salmonella enterica is high (over 1 percent). These findings counter the theory, founded on studies with laboratory-attenuated strains, that suggests mutators are rare among bacterial populations. Defects in methyl-directed mismatch repair underlie all mutator phenotypes described here. Of nine independently derived hypermutable strains, seven contained a defective mutS allele. Because these mutant alleles increase the mutation rate and enhance recombination among diverse species, these studies may help explain both the rapid emergence of antibiotic resistance and the penetrance of virulence genes within the prokaryotic community.

DNA deaminating ability and genotoxicity of nitric oxide and its progenitors.

Nitric oxide (NO), a multifaceted bioregulatory agent and an environmental pollutant, can also cause genomic alterations. In vitro, NO deaminated deoxynucleosides, deoxynucleotides, and intact DNA at physiological pH. That similar DNA damage can also occur in vivo was tested by treating Salmonella typhimurium strain TA1535 with three NO-releasing compounds, including nitroglycerin. All proved mutagenic. Observed DNA sequence changes were greater than 99% C----T transitions in the hisG46 (CCC) target codon, consistent with a cytosine-deamination mechanism. Because exposure to endogenously and exogenously produced NO is extensive, this mechanism may contribute to the incidence of deamination-related genetic disease and cancer.

Galactosyltransferase from commerical preparations of fetuin.

A galactosyltransferase that transfers galactose from UDPgalactose to asialoagalacto fetuin or N-acetylglucosamine was partly purified from two commerical preparations of fetuin and its kinetic properties were characterized. Several other preparations of fetuin were also found to contain galactosyltransferase activity.

Sequence analysis of mutations arising during prolonged starvation of Salmonella typhimurium.

We have examined the effects of prolonged histidine deprivation on the reversion of Salmonella typhimurium histidine auxotrophs containing either hisG46, a missense mutation (CTC----CCC), or hisG428, an ochre mutation (CAA----TAA). Both of these mutants can revert to His+ via intragenic and extragenic mechanisms. Whereas the hisG46 mutant site consists of G/C base pairs, extragenic suppression of hisG46 requires mutation at an A/T site. Conversely, the hisG428 site itself contains only A/T base pairs, and extragenic suppression of hisG428 occurs principally at G/C sites. Thus, by examining the mutational spectrum of hisG46 and hisG428 revertants that occurred in the presence and in the absence of histidine, it was possible to determine the effects of histidine starvation on mutations at G/C vs. A/T sites as well as on intragenic sites vs. extragenic suppressor sites. Using DNA-colony hybridization, we determined the DNA sequences of over 1300 hisG46 and hisG428 revertants. Histidine-independent revertants that arose during growth in liquid medium that contained histidine included both intragenic and extragenic suppressor mutations. The relative frequency of such extragenic suppressors was greatly reduced among the His+ revertants that were isolated after 5-10 days of histidine starvation on agar medium. Moreover, DNA sequence analysis revealed striking differences in the distribution of particular transversions at the hisG428 locus in revertants arising after prolonged histidine starvation as compared to those arising after growth in the presence of histidine.

Adaptive mutation and slow-growing revertants of an Escherichia coli lacZ amber mutant.

We have studied revertants, selected on lactose minimal agar medium, of the Escherichia coli lacZam strain that was first used by Cairns and his colleagues to demonstrate the phenomenon of "adaptive mutation." We have found, by performing appropriate reconstruction studies, that most of the late-arising Lac+ revertants of this lac amber strain (appearing as colonies in 3-5 days) are slow-growing ochre suppressor mutants that probably existed in the culture prior to plating and cannot, therefore, be classified as "adaptive." The appearance of a small number of fast-growing, late-arising Lac+ revertants may result from residual cell growth and turnover or from phenomena related to the fact that the lacZam mutation in strain SM195 is carried on an F' plasmid. Thus, the appearance of late-arising revertants in this lacZam system does not provide convincing evidence that selective conditions specifically increase the rate of occurrence of favorable mutations.

Competitor template RNA for detection and quantitation of hepatitis A virus by PCR.

PCR was used to introduce a 63-bp deletion into the putative RNA replicase coding sequence of hepatitis A virus. RNA was synthesized in vitro from the deletion mutant cloned into a transcription vector. Upon amplification by PCR, cDNA made from the competitor RNA generated an amplified fragment that could be easily distinguished from the product generated from wild-type hepatitis A virus genomic RNA by gel electrophoresis, when the same primers were used, without further manipulation. The competitor RNA was used as a positive control in PCR-based detection of very low copy numbers of hepatitis A virus genomic RNA in the presence of unrelated hard-shell clam RNA. When the competitor RNA was used for competitive PCR to quantitate wild-type RNA, the presence of one template at a 10-fold to 100-fold higher level almost completely inhibited product formation from the underrepresented template. The competitor RNA should be useful as a control for reverse transcription and PCRs to determine hepatitis A virus genome RNA when accidental contamination of test samples by a wild-type positive control template would compromise the results.

Identification of genetic variants of hepatitis A virus.

Although detection of hepatitis A virus (HAV) has been greatly aided by the development of polymerase chain reaction (PCR) technology, identification of genetic variants requires sequencing PCR products, which necessarily limits the length of the HAV genome (typically 2%) that can be analyzed. From a regulatory standpoint, identification of the specific strain detected by PCR is a prerequisite not only to overrule contamination of test samples in the diagnostic laboratory, but also to possibly locate the origin of the virus detected by PCR. We explored alternatives to sequencing PCR products to achieve these goals. The findings indicate that restriction fragment length polymorphism (RFLP) analysis of PCR products from two noncontiguous regions of the HAV genome encompassing 765 nucleotides (approximately 10% of the genome) by the restriction endonucleases HinfI and AluI, which cut frequently within the HAV genome, can distinguish the common tissue culture adapted strains of HAV from stool isolates. The resolution can be greatly enhanced by combining single strand conformation polymorphism (SSCP) analysis with restriction enzyme digestion, when most of the seventeen strains analyzed could be identified.

Analysis of Salmonella typhimurium hisD3052 revertants: the use of oligodeoxyribonucleotide colony hybridization, PCR, and direct sequencing in mutational analysis.

A rapid method for determining the DNA sequences of Salmonella typhimurium hisD3052 revertants is presented. DNA colony hybridization was used to analyze revertants previously studied by Isono and Yourno [Proc Natl Acad Sci USA 71:1612-1617, 1974]. Synthetic oligodeoxyribonucleotide probes (18-mers) were able to distinguish sequences that differed by a single base pair. Mutant his sequences not identified by probing analysis were amplified using polymerase chain reaction (PCR) and directly sequenced. The combined use of DNA-colony hybridization and direct sequencing offers a precise and rapid means for the molecular characterization of hisD3052 revertants.

Mutant alleles of tRNA(Thr) genes suppress the hisG46 missense mutation in Salmonella typhimurium.

Extragenic suppressors of the hisG46 missense mutation were mapped to the 71 and 88 min regions of the Salmonella typhimurium chromosome, positions that in Escherichia coli contain the thrV (tRNA(Thr1)) and thrT (tRNA(Thr3)) genes, respectively. The suppressor loci were identified as mutant alleles of thrV and thrT, using allele-specific colony hybridization. An oligomer, based on the conserved 5' sequence of the thrT and thrV genes in E. coli and designed to contain the putative mutant anticodon, discriminated between suppressor-containing and wild-type strains. Similarly, probes specific for the thrV[SuGGG] and thrT[SuGGG] were used to differentiate the two suppressors. To date, all extragenic suppressors of hisG46 have been identified as either thrV[SuGGG] or thrT[SuGGG]. A near equal distribution of thrV[SuGGG] and thrT[SuGGG] suppressors was found among 29 spontaneous and 43 mutagen-induced hisG46 extragenic suppressor revertants. It was concluded, therefore, that mutant alleles of thrV and thrT are predominantly, if not solely, responsible for intergenic suppression of the hisG46 mutation.

Molecular models that may account for nitrous acid mutagenesis in organisms containing double-stranded DNA.

Nitrous acid (NA) is often presumed to cause base substitutions in organisms with double-stranded DNA as a direct consequence of oxidative deamination of adenine and of cytosine residues. Here we summarize evidence indicating that other mechanisms are involved in the case of NA-induced G/C-->A/T transition mutations. We present several models for pathways of NA mutagenesis that may account for our experimental results and overlapping data noted in the literature. One model proposes that the base substitution mutations observed are due to DNA alkylation damage mediated via nitrosation of polyamines and/or other ubiquitous cellular molecules. Other models assume that predisposing lesions, such as G-to-G cross-links, are first formed. The cross-links are pictured as leading to perturbations in DNA structure that allow subsequent opportunity for NA-induced deaminations of cytosine residues in their immediate vicinity. The deaminations preferentially result in G/C-->A/T transition mutations at sites highly dependent on adjoining base sequence context (i.e., in NA "mutational hotspots"). A final model proposes that NA-induced G/C-->A/T transition mutations arise mainly from oxidative deamination of guanosine residues and not from deamination of cytosine residues in duplex DNA.

Specificity of base substitution mutations induced by the dietary carcinogens 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhlP) and 2-amino-3-methylimidazo[4,5-f]quinoline (IQ) in Salmonella.

The base pair substitution mutational profiles induced by the heterocyclic amine cooked food mutagens PhlP and IQ in Salmonella typhimurium strains TA100 and TA1535 were determined by colony hybridization analysis. Both PhlP and IQ induced predominantly GC-->TA transversions in strain TA100 (rfa,delta uvrB/pKM101) with a pronounced preference for the second codon position (CCC--> CAC; 72% of total). PhlP also reverted strain TA1535 (rfa, delta uvrB) efficiently at concentrations similar to those required for strain TA100. In contrast to the PhlP-induced mutational profile observed in strain TA100, in strain TA1535 PhlP induced exclusively GC-->AT transitions at the second codon position (CCC-->CTC; 96-99% of total). Base substitution mutagenesis induced by heterocyclic amines related to PhlP is generally SOS-dependent, requiring the presence of plasmid pKM101 in Salmonella hisG46 strains. Thus, the SOS dependent reversion of S. typhimurium strain TA100 probably reflects error-prone lesion bypass at the major PhlP- guanosine adduct at the C-8 position. The GC-->AT transition mutations induced by PhlP in strain TA1535 appear to be SOS-independent, however, suggesting that these mutations may arise from the formation of PhlP-DNA adducts other than the replication-blocking C8-dG lesion.

Three R's of bacterial evolution: how replication, repair, and recombination frame the origin of species.

The genetic diversity of bacteria results not only from errors in DNA replication and repair but from horizontal exchange and recombination of DNA sequences from similar and disparate species as well. New individuals carrying adaptive changes are thus being spawned constantly among the population at large. When new selection pressures appear, these are the individuals that survive, at the expense of the general population, to forge new populations. Depending on the severity and uniqueness of the selection pressure, this could lead to new speciation. It is becoming more and more evident that, as nucleotide sequences of numerous loci from many bacterial strains continue to amass, horizontal transfer has played a key role in configuring the Escherichia coli chromosome. Here, we examine views, both old and new, for the role of recombination in the evolution of bacterial chromosomes. We present novel phylogenetic evidence for horizontal transfer of three genes involved in DNA replication and repair (mutS, uvrD, and polA). These data reveal a prominent role for horizontal transfer in the evolution of genes known to play a key role in the fidelity of DNA replication and, thus, ultimate survival of the organism. Our data underscore that recombination plays both a diversifying and a homogenizing role in defining the structure of the E. coli genome.

Reversion profiles of coolwhite fluorescent light compared with far ultraviolet light: homologies and differences.

General Electric and Sylvania 15 W coolwhite fluorescent lamps emit roughly 6% of their total irradiance as light in the UV spectrum. Illumination of sensitive Salmonella tester strains results in both lethal and mutagenic activities. In contrast, comparable Philips lamps emit lower levels of UV light, especially UVB, and exhibit no detectable lethal or mutagenic effects. The spectra of mutations induced by General Electric coolwhite lamps in histidine-requiring base substitution mutants hisG46 and hisG428 ("reversion profiles") resemble mutagenesis by far UV light (UVC) and differ quite markedly from the spectra of mutations that occur spontaneously. Coolwhite and UVC reversion profiles are not identical, however. The percentage of C to A transversion mutations induced in hisG46 are elevated over those found after UVC treatment, and a strong bias for one particular class of tandem base substitutions (TAA-->TGT) prevails after treatment of hisG428 with coolwhite light, a bias not observed with UVC. Increased attention needs to be given to minimization of exposure to UV light from fluorescent lamps commonly used in homes and workplaces.

Analysis of spontaneous and psoralen-induced Salmonella typhimurium hisG46 revertants by oligodeoxyribonucleotide colony hybridization: use of psoralens to cross-link probes to target sequences.

An improved DNA colony-hybridization method for the rapid characterization of Salmonella typhimurium hisG46 revertants is described. Oligodeoxyribonucleotides (15-mers) complementary to each of 6 possible transition or transversion mutations and an extragenic suppressor mutation, underlying the His+ phenotype, were prepared. Optimal sequence discrimination was achieved by hybridizing 15-mers at the apparent dissociation temperature (Td) for 2 h with chromosomal DNA of revertant colonies affixed to Whatman 541 filters. Subsequent exposure of filters to UVA radiation (320-400 nm) in the presence of 4'-hydroxymethyl-4,5',8-trimethylpsoralen (HMT) resulted in cross-linking of perfectly matched probes and target DNA sequences while sequences containing a single base-pair mismatch could be discriminated with a brief denaturing wash. No false negative results were obtained with the new procedure. An analysis of 204 spontaneous and 174 PUVA-induced TA100 revertants is presented.

Fidelity of replication of repetitive DNA in mutS and repair proficient Escherichia coli.

Replication fidelity is not constant among strains within a species or at all genetic loci within a genome. Altered fidelity of replication may affect patterns of pathogenesis and the evolution of these strains. We have been studying replication fidelity in Escherichia coli, both in laboratory attenuated strains and in food-borne pathogens. To understand the altered patterns of mutagenesis at the molecular level, we used a shuttle vector plasmid with a tRNA mutational marker gene which had been altered to include homopolymeric runs of five, seven and nine [G:C] pairs, as well as non-repetitive DNA. Replication of the plasmid in mutS strains resulted in a 20-fold increase in mutant progeny plasmids. The mutations were almost all (>90%) frameshift mutations, while base substitution mutations were rare. Most mutations were insertions or deletions of one or two [G:C] pairs in the longest homopolymeric runs. Larger deletions (5 to >70bp), also targeted to the repetitive sequence, were likewise common. Mutations increased exponentially with the length of the homopolymeric run. These patterns of mutation, including unexpectedly high levels in repair proficient strains, led to an examination of the E. coli K-12 genome for homopolymeric DNA. This sequence motif was found to be rare, particularly in genes and open reading frames. Amino acid homotrimers were found to avoid usage of homopolymeric codons, even when they are preferred among synonymous codons in E. coli. There appears to be active selection against tandem direct nucleotide repeats in the E. coli genome, correlated with the inability of the organism to accurately replicate such sequence.

Detection of mutator subpopulations in Salmonella typhimurium LT2 by reversion of his alleles.

Defects in the methyl-directed mismatch repair lead to both the hypermutability phenotype and removal of a barrier to genetic exchange between species. Mutator bacteria carrying such defects occur frequently among bacterial pathogens, suggesting that subpopulations of mutators are contained within pathogen clones and give rise to the genetic variants that are acted upon by selective forces to allow survival or successful infection. We report here on the detection of the mutator subpopulation in Salmonella typhimurium and determination of its frequency in laboratory cultures. The analysis involved screening for mutators among revertants of S. typhimurium histidine auxotrophs selected for the His+ phenotype, since the frequency of mutators is expected to be increased in the selected mutant population they helped to spawn. The increases in spontaneous reversion of histidine mutations were first measured in isogenic strains carrying mismatch repair-defective mutH, mutL, mutS, or uvrD alleles, relative to their mismatch repair-proficient counterparts. Screening for the mutator phenotype in nearly 12,000 revertants of repair-proficient strains carrying his mutations highly stimulated for reversion in mutator backgrounds, the base substitution in hisG428 and frameshift in hisC3076, yielded five mutator strains (0.04%). The his+ reversion mutations contained within the newly-arisen mutator strains were characteristic of the predominant nucleotide changes expected in such mutators, as assessed by comparison with the spectra for reversion events in wild-type and mismatch correction-defective backgrounds. The results show that subpopulations of mutators, residing in normal populations at a finite frequency, can be culled from the culture by strong selection for a required phenotype. We calculate that the frequency of mutators in the unselected population of S. typhimurium is 1-4x10-6, an incidence 10-fold lower than that expected based on studies of laboratory cultures of Escherichia coli.