Mutator factor in Neisseria meningitidis associated with increased sensitivity to ultraviolet light and defective transformation

The rise and spread of a new pathogen: seroresistant Moraxella catarrhalis

The nosocomial human pathogen Moraxella catarrhalis is one the most important agents of human respiratory tract infections. This species is composed of two distinct lineages, one of only moderate virulence, the so-called serosensitive subpopulation, and a second, the seroresistant one, which is enriched among strains that harbor two major virulence traits: complement resistance and adherence to epithelial cells. Using a suite of population genetics tools, we show that the seroresistant lineage is also characterized by higher homologous recombination and mutation rates at housekeeping genes relative to its less pathogenic counterpart. Thus, sex and virulence have evolved in tandem in M. catarrhalis. Moreover, phylogenetic and Bayesian analyses that take into account recombination between the two clades show that the ancestral group was avirulent, is possibly 70 million years old, and must have infected mammals prior to the evolution of humans, which occurred later. The younger seroresistant isolates went through an important population expansion some 5 million years ago, coincident with the hominid expansion. This rise and spread was possibly coupled with a host shift and the acquisition of virulence genes.

The mutator mut7-1 of Saccharomyces cerevisiae

The mut7-1 mutant of Saccharomyces cerevisiae is a cell-division-cycle mutant, exhibiting temperature-sensitive lethality and enhancement of mutator activity with increases in temperature. The base-sequence alterations in mutants arising in a mut7-1 background differed from the control by there being a higher transversion/transition ratio and by the much increased production of multi-base deletions. The deletions were, in every instance, associated with repeated oligonucleotide sequences (3-8 bases in length), where one of the two sequences was removed during the deletion process. The mutant mut7-1 failed to complement with cdc2, the temperature-sensitive mutant of the locus which encodes DNA polymerase III (delta).

Isolation and characterization of a UV-sensitive mutator (mutB1) mutant of Haemophilus influenzae

The mutB1 mutant of Haemophilus influenzae is very sensitive to UV radiation but only slightly sensitive to methylmethane sulfonate or N-methyl-N'-nitro-N-nitrosoguanidine. Cultures of mutB1 cells contain high numbers of spontaneous mutants and show hypermutability after exposure to the latter mutagen. Normally high-efficiency transforming markers, as well as low-efficiency ones, transform mutB1 recipients at similarly low efficiencies. Significant host cell reactivation was observed when mutB1 cells were exposed to UV-damaged phage; however, these mutants showed a decrease in phage recombination. This mutant did not degrade its DNA following exposure to UV. It is speculated that the mutB1 mutation is similar to the Escherichia coli uvrD mutation.

Spontaneous mutagenesis: the roles of DNA repair, replication, and recombination

There appears to be no dearth of mechanisms to explain spontaneous mutagenesis. In the case of base substitutions, data for bacteriophage T4 and especially for E. coli and S. cerevisiae suggest important roles in spontaneous mutagenesis for the error-prone repair of DNA damage (to produce mutations) and for error-free repair of DNA damage (to avoid mutagenesis). Data from the very limited number of studies on the subject suggest that about 50% of the spontaneous base substitutions in E. coli, and perhaps 90% in S. cerevisiae are due to error-prone DNA repair. On the other hand, spontaneous frameshifts and deletions seem to result from mechanisms involving recombination and replication. Spontaneous insertions have been shown to be important in the strongly polar inactivation of certain loci, but it is less important at other loci. Perhaps with continued study, the term "spontaneous mutagenesis" will be replaced by more specific terms such as 5-methylcytosine deamination mutagenesis, fatty acid oxidation mutagenesis, phenylalanine mutagenesis, and imprecise-recombination mutagenesis. While most studies have concentrated on mutator mutations, the most conclusive data for the actual source of spontaneous mutations have come from the study of antimutator mutations. Further study in this area, perhaps along with an understanding of chemical antimutagens, should be invaluable in clarifying the bases of spontaneous mutagenesis.

Spontaneous mutability in UV-sensitive excision-defective strains of Saccharomyces

The genes RAD1, RAD2, RAD3 and RAD4 encode enzymes in the pathway leading to excision repair of UV-induced DNA damage in Saccharomyces cerevisiae. Four mutant alleles of these loci (rad1-1, rad2-2, rad3-12, and rad4-3) were studied for their effect on spontaneous reversion rate to lysine and histidine independence, by means of the 1000-compartment fluctuation test of von Borstel, Cain and Steinberg. Of these four excision-defective alleles, only rad3-12 was found to substantially increase the spontaneous reversion rate of the nonsense-suppressible lys1-1 allele, both through locus reversion as well as by forward mutation at one of eight suppressor loci. Similarly, only rad3-12 conferred a considerable increase in the reversion frequency of the missense his1-7 mutant. As the RAD3 gene product is believed to mediate the first step in the excision-repair pathway, it is assumed that spontaneous lesions in the rad3 strain are channelled into a mutagenic repair pathway, thus accounting for the enhanced spontaneous mutation rate.

Mutational synergism between p-fluorophenylalanine and UV in Coprinus lagopus

Previous studies have shown that the amino acid analogue p-fluorophenylalanine (PFP) is mutagenic to Coprinus lagopus due to its incorporation into proteins [32]. Spontaneous mutations, PFP and UV mutagenesis and PFP/UV synergism have been studied in a UV resistant strain and in two complementing UV sensitive mutant strains. By comparison to the UV resistant strain, one UV sensitive strain shows normal spontaneous mutations, 1.4% PFP-induced mutations and 50-fold UV mutagenesis. The second UV sensitive strain has 19-fold spontaneous mutation frequency, 8% PFP induced mutations and slightly elevated UV mutagenesis. In all 3 strains the PFP/UV synergism is comparable (4--5 times the arithmetic expected). The results indicate that PFP mutagenesis is due to the incorporation of PFP into enzymes normally functioning in the organism but which also participate in UV repair mechanisms. A model is proposed for UV repair which is based on a PFP sensitive excision repair system of at least two enzymes, and alternative "error proof" pathway which is not suscetible to PFP and an "error prone" pathway which is responsible for UV mutagenesis and is susceptible to PFP as shown by the PFP/UV synergism. Because PFP is given before UV treatment, this implies a UV inducible cofactor and a PFP sensitive enzyme which only functions after UV activation.

Fate of thymine-containing dimers in the deoxyribonucleic acid of ultraviolet-irradiated mutator T1 Escherichia coli transductants

In order to determine whether a relationship generally exists between the mutator property (mutT1) and repair of ultraviolet (UV) irradiation damaged DNA, we performed spontaneous mutation rate and UV-survival determinations without and with acriflavin (4 mug/ml) in P1 phage mediated mut T1 Escherichia coli transductants. The strains constructed were assumed to be coisogenic except for the mutator factor. The mutT1 uvrA, uvrB or exrA transductants had mutation rates similar to the donor strain. Double mutants containing mutT1 and uvrB or exrA had the same level of UV survival as the parent with the same mutator phenotype. Mutator strains were normal for host-cell reactivation of UV-irradiated phage T1, and phage lambda was UV-inducible. The fate of UV-induced thymine-containing dimers in the deoxyribonucleic acid (DNA) of mutT1 transductants was investigated. Dark repair of pyrimidine dimers is equally acriflavin sensitive in the nonmutator and mutator Hcr+ strains. During incubation in the dark, dimers were excised to the same extent from the DNA of the HCR+ mutator and nonmutator transductants, but remained in the DNA of the HCR- MUTANT. A preliminary report of these studies was presented at the 70th Annual Meeting of the American Scoeity of Microbiology, Boston, 1970.

Inheritance of low-level resistance to penicillin, tetracycline, and chloramphenicol in Neisseria gonorrhoeae

The genetics of low-level resistance to penicillin and other antibiotics in a clinical isolate and a multistep laboratory mutant of Neisseria gonorrhoea was studied by transformation. Mutations at three loci affected sensitivity to penicillin. Mutation at penA resulted in an eightfold increase in resistance to penicillin without affecting response to other antimicrobial agents. Mutation at ery resulted in a two- to fourfold increase in resistance to penicillin and similar increases in resistance to many other antibiotics, dyes, and detergents. Mutation at penB resulted in a fourfold increase in resistance to penicillin and tetracycline, the phenotypic expression of which was dependent on the presence of mutation at ery. The cumulative effect of mutations at penA, ery, and penB was an approximate 128-fold increase in penicillin resistance, to a minimum inhibitory concentration of 1.0 mug/ml. Low-level resistance to tetracycline or chloramphenicol was due to similar additive effects between mutations at the nonspecific ery and penB loci and a locus specific for resistance to each drug (tet and chl, respectively). No evidence was found for penicillinases or other drug-inactivating enzymes.

The control of mutational instability by a new mutator gene of Drosophila melanogaster

The isolation and genetic characterization of a new mutator gene,Mutator-forked3N(Mu-f3N), ofDrosophila melanogasterare described. This mutator gene is unique in that it seems to increase specifically the reversion frequency of the unstable mutantforked3N(f3N, 1–56.7), since the frequency of spontaneous sex-linked recessive lethals in males and females and the frequency of reverse mutations at eight additional X-linked alleles were unaffected byMu-f3N. The mutator is a dominant gene that has been mapped to the region betweenf3N(1–56.7) andBeadex-2 (Bx2, 1–59.4) in theXchromosome, and it seems to function only in the ‘ cis’ configuration. The mode of action ofMu-f3Nis compared with that of other mutator genes.

Ultraviolet-sensitive mutator strain of Escherichia coli K-12

An ultraviolet (UV)-sensitive mutator gene, mutU, was identified in Escherichia coli K-12. The mutation mutU4 is very close to uvrD, between metE and ilv, on the E. coli chromosome. It was recessive as a mutator and as a UV-sensitive mutation. The frequency of reversion of trpA46 on an F episome was increased by mutU4 on the chromosome. The mutator gene did not increase mutation frequencies in virulent phages or in lytically grown phage lambda. The mutU4 mutation predominantly induced transitional base changes. Mutator strains were normal for recombination and host-cell reactivation of UV-irradiated phage T1. They were normally resistant to methyl methanesulfonate and were slightly more sensitive to gamma irradiation than Mut(+) strains. UV irradiation induced mutations in a mutU4 strain, and phage lambda was UV-inducible. Double mutants containing mutU4 and recA, B, or C were extremely sensitive to UV irradiation; a mutU4 uvrA6 double mutant was only slightly more sensitive than a uvrA6 strain. The mutU4 uvrA6 and mutU4 recA, B, or C double mutants had mutation rates similar to that of a mutU4 strain. Two UV-sensitive mutators, mut-9 and mut-10, isolated by Liberfarb and Bryson in E. coli B/UV, were found to be co-transducible with ilv in the same general region as mutU4.

Isolation, characterization, and genetic analysis of mutator genes in Escherichia coli B and K-12

Twenty-one Mut mutants were obtained from Escherichia coli B (B/UV) and K-12 (JC355) after treatment with mutagens. These Mut strains are characterized by rates of mutation to streptomycin resistance and T-phase resistance which are significantly higher than the parental (Mut(+)) rates. Mutator genes in 12 strains have been mapped at three locations on the E. coli chromosome: one close to the leu locus; five close to the purA locus; and six close to cysC. In addition, eight mutator strains derived from E. coli B/UV are still unmapped. Some effort was made to deduce the mode of action of the mutator genes. These isolates have been examined for possible defects in deoxyribonucleic acid repair mechanisms (dark repair of ultraviolet damage, host-cell reactivation, recombination ability, repair of mitomycin C damage). By using transductional analysis, it was found that the ultraviolet sensitivity of NTG119 and its mutator property results from two separate but closely linked mutations. PurA(+) transductants that receive mut from NTG119 or NTG35 are all more sensitive to mitomycin C than is the PurA recipient. Unless transduction selects for sensitivity, a probable interpretation is that defective repair of mitomycin C-induced damage is related to the mode of action of mut in these transductants and the donor. Abnormal purine synthesis may be involved in the mutability of some strains with cotransduction of the mutator properly and purA (100% cotransduction for NTG119). Three mutators are recombination-deficient and may have a defective step in recombination repair. One maps near three rec genes close to cysC.

Recombination-deficient mutants of colicinogenic Salmonella typhimurium detected by their failure to produce colicin

Survivors of nitrosoguanidine-treated cultures of a colicinogenic strain of Salmonella typhimurium were tested for spontaneous production of colicin E1. Of about 1,000 colonies tested, 13 produced no (or very narrow) colicin zones. Four of these isolates proved to be more sensitive to ultraviolet (UV) light, X rays, and methyl methane sulfonate than the parent strain and did not show enhanced production of colicin when treated with mitomycin C (which acts as an inducer on wild-type cells). Further studies showed that these isolates were of two classes. Three mutants were extremely sensitive to UV, failed to show spontaneous release of two temperate phages, and were infertile as recipients in transduction or in an Hfr cross although they accepted an F' factor normally. These independently isolated mutants were inferred to be recombination-deficient; one of them had the additional property of increased spontaneous mutability at two loci. The other colicin-nonreleasing isolate was only moderately sensitive to UV, showed enhanced spontaneous release of two temperate phages, and was of approximately normal fertility as a recipient in transduction or conjugation.