Dependence of Escherichia coli K-12 viability and mutability on the balance of DNA and protein syntheses. VI. Molecular mechanisms underlying the phenomena of imbalance death and metabolic mutagenesis

In this report the results of further studies of the molecular mechanisms of the disbalance death and metabolic (disbalance) mutagenesis are presented. As reported previously, the relationship of viability and mutability of Escherichia coli cells from the extent disturbance of DNA-protein synthesis balance is determined by the processes of stabilization and repair of metabolic disbalance gaps in DNA strands. It is established that polB, recB, SSB gene products are involved in the processes of stabilization and repair of metabolic disbalance gaps.     

Relation between Escherichia coli K-12 viability and mutability and the balance between DNA and protein synthesis. III. Relation between disruptions in the balance between DNA and protein synthesis and mutagenesis and viability during thymidine deprivation of thy- cells defective with respect to recB and polA genes

The phenomenon of metabolic mutagenesis is found to be determined by stabilization of metabolic breaks in DNA chains, being linked with disbalance of intracellular synthesis of DNA and protein. The rate of metabolic mutagenesis observed in case of the DNA-protein synthesis disbalance due to thymine starvation is influenced by cell genotype. The lack of exonuclease V in recB-thy- cells decreases (reduces) the rate of metabolic mutagenesis and does not effect the viability. The lack of DNA polymerase I activity in polA-thy- cells causes a sharp increase in the metabolic mutagenesis rate and a parallel sharp drop in the survival under thymine starvation, as compared to cells with polA+thy- genotype.     

Inhibition of DNA replication by transformation in a Haemophilus influenzae mutant carrying an altered Rec-1 protein.

In the HM5 mutant of Haemophilus influenzae, which carries a mutation in the rec-1 gene region and in which the replication of donor-recipient DNA complexes formed in transformation is inhibited, the transformation frequency could be greatly enhanced by inhibition of protein synthesis during transformation, indicating that transformation in the HM5 mutant induces the synthesis of a protein that inhibits the replication of the donor-recipient DNA complexes. This induction occurred in an early step of the recombination. Synthesis of the wild-type Rec-1 protein after transformation of the HM5 mutant with wild-type DNA could diminish the inhibiting effect on DNA replication. The HM5 mutant synthesized an altered Rec-1 protein (molecular weight, 38,000) whose pI differed from that of the wild type. As a result of the mutation in the rec-1 gene, two other proteins (molecular weights, 37,500 and 43,000) are lacking in the HM5 mutant.     

DNA repair in E. coli strains deficient in single-strand DNA binding protein

Summary Weigle reactivation and mutagenesis have been found to be defective in strains of E. coli deficient in single-strand DNA binding protein (SSB). These defects parallel those previously found in prophage induction and amplification of recA protein synthesis in ssb strains. Together, these results demonstrate a role for SSB in the induction of SOS responses. UV survival studies of ssb ^- recA^- and ssb ^- uvr^- strains are presented which also suggest a role for SSB in recombinational repair processes but not in excision repair. Studies of host cell reactivation support this latter conclusion.     

Repair of bleomycin-induced damage to Escherichia coli DNA. II. Participation of inducible processes

The role of inducible cell functions in repair and mutagenesis after bleomycin-induced DNA damages was studied in Escherichia coli. Influence on these processes of some rec genes as well as sbcB, the structural gene for exonuclease I, was investigated. The data obtained suggest that this enzyme plays a negative role in the repair of DNA damaged by bleomycin. The hypersensitivity of recA mutant to bleomycin and recAlexA-dependence of bleomycin-induced mutagenesis do not suggest any principal differences between UV-induced pyrimidine dimers and apyrimidinic sites in the case of post-replication repair.     

Photochemistry and photobiology of 5-azacytidine: effect of repair on photostabilization of Escherichia coli.

The photochemical stability of the anomalous nucleic acid base 5-azacytidine (z5Cyd) on irradiation at 254 nm is by about one order of magnitude less than that of cytidine (Cyd). Contrary to the photochemical behaviour, incorporation of z5Cyd into the nucleic acids of E. coli strains SR 20 (uvr+ rec+), SR 74 (uvr+ rec-) and SR 22 (uvr- rec+) produced a higher resistance to UV light. Only the SR 73 (uvr- rec-) strain was shown to have an increased UV sensitivity. This latter finding is in accord with the photochemical properties of z5Cyd. The results led to the conclusion that excision and recombination repair processes contribute to the observable protective effect. The fact that inhibition of excission repair by caffeine or proflavine of the mutant uvr+ rec- changes protection into sensitization supports this idea.     

Interrelationships of protein and DNA syntheses during replication of mammalian cells.

During the replication of chromatin, the syntheses of the histone protein and DNA components are closely coordinated but not totally linked. The interrelationships of total protein synthesis, histone protein synthesis, DNA synthesis, and mRNA levels have been investigated in Chinese hamster ovary cells subjected to several different types of inhibitors in several different temporal combinations. The results from these studies and results reported elsewhere can be brought together into a consistent framework which combines the idea of autoregulation of histone biosynthesis as originally proposed by W. B. Butler and G. C. Mueller (Biochim. Biophys. Acta 294:481-496, 1973] with the presence of basal histone synthesis and the effects of protein synthesis on DNA synthesis. The proposed framework obviates the difficulties of Butler and Mueller's model and may have wider application in understanding the control of cell growth.     

DNA repair in competent cells of Bacillus subtilis.

A series of isogenic transformable strains of Bacillus subtilis carrying the uvr-19 or rec-43 mutation or both were constructed. Both mutations made competent cells defective in repairing UV-irradiated cellular or transforming DNA, and their effects were additive in a doubly deficient strain, suggesting that two repair processes, requiring uvr-19+ and rec-43+ gene products, are independently functional in competent cells of B. subtilis.     

A new model for SOS-induced mutagenesis: how RecA protein activates DNA polymerase V

In Escherichia coli, cell survival and genomic stability after UV radiation depends on repair mechanisms induced as part of the SOS response to DNA damage. The early phase of the SOS response is mostly dominated by accurate DNA repair, while the later phase is characterized with elevated mutation levels caused by error-prone DNA replication. SOS mutagenesis is largely the result of the action of DNA polymerase V (pol V), which has the ability to insert nucleotides opposite various DNA lesions in a process termed translesion DNA synthesis (TLS). Pol V is a low-fidelity polymerase that is composed of UmuD′₂C and is encoded by the umuDC operon. Pol V is strictly regulated in the cell so as to avoid genomic mutation overload. RecA nucleoprotein filaments (RecA*), formed by RecA binding to single-stranded DNA with ATP, are essential for pol V-catalyzed TLS both in vivo and in vitro. This review focuses on recent studies addressing the protein composition of active DNA polymerase V, and the role of RecA protein in activating this enzyme. Based on unforeseen properties of RecA*, we describe a new model for pol V-catalyzed SOS-induced mutagenesis.     

Effect of repair deficiency and R plasmids on spontaneous and radiation-induced mutability in Pseudomonas aeruginosa.

The effect of R plasmids on spontaneous and radiation (ultraviolet and gamma)-induced mutability in Pseudomonas aeruginosa was studied in strains containing the radiation-sensitive markers polA3 or rec-2 and the revertable auxotrophic markers hisO27 and trpB1. In the absence of an R plasmid, the radiation-induced mutability was dependent on the recA+ genotype and independent of the polA+ genotype, whereas spontaneous mutability was similar in all genetic backgrounds. R plasmids pPL1, R2, and pMG15 increased the ultraviolet radiation survival and ultraviolet-induced mutability of wild-type and polA host cells but did not alter either effect in a recA mutant. These R plasmids also increased the gamma radiation survival and gamma-induced mutability of wild-type host cells bud pMG15 also enhanced the level of spontaneous mutagenesis in wild-type host cells but not in a polA or recA mutant. These data suggested that a common plasmid gene product(s) may participate in various recA-dependent, error-prone deoxyribonucleic acid repair pathways of P. aeruginosa. The properties of a mutant R plasmid, pPL2, originally selected because it lacked enhanced ultraviolet-induced mutability, supported this conclusion.     

DNA repair protein Rad55 is a terminal substrate of the DNA damage checkpoints

Checkpoints, which are integral to the cellular response to DNA damage, coordinate transient cell cycle arrest and the induced expression of DNA repair genes after genotoxic stress. DNA repair ensures cellular survival and genomic stability, utilizing a multipathway network. Here we report evidence that the two systems, DNA damage checkpoint control and DNA repair, are directly connected by demonstrating that the Rad55 double-strand break repair protein of the recombinational repair pathway is a terminal substrate of DNA damage and replication block checkpoints. Rad55p was specifically phosphorylated in response to DNA damage induced by the alkylating agent methyl methanesulfonate, dependent on an active DNA damage checkpoint. Rad55p modification was also observed after gamma ray and UV radiation. The rapid time course of phosphorylation and the recombination defects identified in checkpoint-deficient cells are consistent with a role of the DNA damage checkpoint in activating recombinational repair. Rad55p phosphorylation possibly affects the balance between different competing DNA repair pathways.     

Effects of multiple yeast rad3 mutant alleles on UV sensitivity, mutability, and mitotic recombination.

A yeast strain was constructed that had a disruption of the chromosomal RAD3 gene and carried a series of centromeric plasmids with defined mutations in this gene. Using this isogenic collection, we examined sensitivity to UV radiation, spontaneous and UV radiation-induced mutagenesis, and mitotic recombination. Several alleles resulted in a marked increase in UV sensitivity. Most of these alleles were found to carry mutations located in consensus motifs for DNA helicases. Other alleles caused a modest or no increase in UV sensitivity and carried mutations in regions of the Rad3 polypeptide that are apparently not conserved. This correlation suggests that the DNA helicase activity of Rad3 protein is required for nucleotide excision repair of DNA. Some rad3 alleles conferred a marked increase in the frequency of spontaneous mutagenesis, including nonsuppressor reversion of the lys2-1 ochre mutation. These alleles also showed a good correlation with conserved DNA helicase domains, suggesting that the Rad3 DNA helicase also plays a role in the fidelity of DNA synthesis or postreplicative mismatch correction. Several rad3 mutator alleles also resulted in increased levels of mitotic recombination. Increased spontaneous mutagenesis and mitotic recombination are characteristic features of the Rem- phenotype. However, in contrast to the prototypic Rem- phenotype, the rad3 mutator alleles identified in this study did not confer inviability in the presence of mutations in the RAD50 or RAD52 gene required for strand break repair of DNA.     

Repair and survival after UV in quiescent and proliferating Microtus agrestis cells: different rates of incision and different dependence on DNA precursor supply.

Cultured cells of Microtus agrestis, the common field vole, perform unscheduled DNA synthesis after UV irradiation. They respond to incubation with a DNA synthesis inhibitor (1-beta-D-arabinofuranosylcytosine) following UV in ways typical of cells capable of excision repair, with reduced survival and an accumulation of breaks in pre-existing DNA. Microtus cells irradiated with UV in a quiescent pre-S-phase state are more sensitive to UV than are proliferating cells, in terms of survival. Adding DNA precursors (deoxyribonucleosides), and--in case of proliferating cells--growing in complete rather than dialysed serum, enhance UV survival. Quiescent cells show a higher rate of endonucleolytic incision of DNA after UV than do proliferating cells. The balance between incision (producing single-strand DNA breaks) and repair DNA synthesis (leading to rejoining of breaks) is shifted by the addition of deoxyribonucleosides, which suggests that DNA precursor supply is a rate-limiting factor in repair. The lower survival of quiescent cells (in the absence of added deoxyribonucleosides) may be due to insufficient precursor supply to meet the demands of the high incision rate.     

Mutagenic DNA repair in Escherichia coli. VII. Constitutive and inducible manifestations.

Incubation of E. coli WP2 in the presence of chloramphenicol (CAP) for 90 min before and 60 min after γ-irradiation had no effect on the induction of Trp⁺ mutations. Bacteria that had been treated with CAP for 90 min prior to UV irradiation showed normal or near normal yields of induced mutations to streptomycin or colicin E2 resistance. Most of these mutations lost their photoreversibility (indicating “fixation”) during continued incubation with CAP for a further 60 min after irradiation, during which time neither protein nor DNA synthesis was detectable. It is suggested that CAP-sensitive protein synthesis is not required for mutagenic (error-prone) repair of lesions in pre-existing DNA, arguing against an inducible component in this repair.In contrast the frequency of UV-induced mutations to Trp⁺ (largely at suppressor loci) was drastically reduced by CAP pretreatment, confirming the need for an active replication fork for UV-mutagenesis at these loci. It is known from the work of others that CAP given after UV abolishes mutagenesis at these loci. We conclude that CAP-sensitive protein synthesis (consistent with a requirement for an inducible function) is necessary for mutagenic repair only in newly-replicated DNA (presumably at daughter strand gaps) and not in pre-existing DNA. The data are consistent with but do not prove the hypothesis that CAP-sensitive and insensitive modes of mutagenesis reflect minor differences in the operation of a single basic mutagenic repair system.     

Plasmid modification of radiation and chemical-mutagen sensitivity in Pseudomonas aeruginosa.

The R factor pMG2 protects Pseudomonas aeruginosa against the lethal effects of ultraviolet (u.v.) and gamma irradiation, and methyl methanesulphonate and N-methyl-N'-nitro-N-nitrosoguanidine treatment. Enhanced survival occurs in strains of uvr+ rec+ (wild-type) genotype and a variety of uvr rec+ type mutants. No protection occurs in a rec A-type mutant. The plasmid also enhances u.v.-induced mutagenesis. These effects appear to be due to host-cell controlled plasmid-determined DNA repair function(s). Studies on P. aeruginosa strains deficient in DNA polymerase I (polyA) suggest that a plasmid-determined repair resynthesis function may be responsible for increased u.v.-survival and enhanced u.v.-mutability in pMG2-containing bacteria.     

Influence of a uvrD mutation on survival and repair of X-irradiated Escherichia coli K-12 cells.

The presence of a uvrD mutation increased the X-ray sensitivities of E. coli wild-type and polA strains, but had no effect on the sensitivities of recA and recB strains, and little effect on a lexA strain. Incubation of irradiated cells in medium containing 2,4-dinitrophenol or chloramphenicol decreased the survival of wild-type and uvrD cells, but had no effect on the survival of recA, recB and lexA strains. Alkaline sucrose gradient sedimentation studies indicated that the uvrD strain is deficient in the growth-medium-dependent (Type III) repair of DNA single-strand breaks. These results indicate that the uvrD mutation inhibits certain rec+lex+-dependent repair processes, including the growth-medium-dependent (Type III) repair of X-ray-induced DNA single-strand breaks, but does not inhibit other rec+lex+-dependent processes that are sensitive to 2,4-dinitrophenol and chloramphenicol.     

Two Haemophilus influenzae Rd genes that complement the recA-like mutation rec-1.

Two Haemophilus influenzae Rd genes each complemented the pleiotropic defects of the recA-like mutation rec-1. One gene, fec, was isolated on a 3.6-kilobase-pair EcoRI restriction fragment by complementation of the Fec- phenotype of bacteriophage lambda. The other gene, rec, was identified on a 3.1-kilobase-pair EcoRI fragment by Southern hybridization by using recA-like gene probes from Erwinia carotovora and Pseudomonas aeruginosa PAO. In a rec-1 strain of H. influenzae, the cloned genes restored resistance to UV irradiation, transformation by chromosomal DNA, and spontaneous release of HP1 prophage to wild-type levels. The fec and rec genes were located on the cloned segments by insertion and deletion mutagenesis and subcloning. The restriction endonuclease cleavage maps of the two DNAs were similar but not identical. Southern hybridization demonstrated that the two EcoRI restriction fragments contained homologous DNA sequences, but a fec gene-specific probe was prepared. Each gene encoded a 38,000-dalton polypeptide.     

A mutational analysis of the yeast proliferating cell nuclear antigen indicates distinct roles in DNA replication and DNA repair.

The saccharomyces cerevisiae proliferating cell nuclear antigen (PCNA), encoded by the POL30 gene, is essential for DNA replication and DNA repair processes. Twenty-one site-directed mutations were constructed in the POL30 gene, each mutation changing two adjacently located charged amino acids to alanines. Although none of the mutant strains containing these double-alanine mutations as the sole source of PCNA were temperature sensitive or cold sensitive for growth, about a third of the mutants showed sensitivity to UV light. Some of those UV-sensitive mutants had elevated spontaneous mutation rates. In addition, several mutants suppressed a cold-sensitive mutation in the CDC44 gene, which encodes the large subunit of replication factor C. A cold-sensitive mutant, which was isolated by random mutagenesis, showed a terminal phenotype at the restrictive temperature consistent with a defect in DNA replication. Several mutant PCNAs were expressed and purified from Escherichia coli, and their in vitro properties were determined. The cold-sensitive mutant (pol30-52, S115P) was a monomer, rather than a trimer, in solution. This mutant was deficient for DNA synthesis in vitro. Partial restoration of DNA polymerase delta holoenzyme activity was achieved at 37 degrees C but not at 14 degrees C by inclusion of the macromolecular crowding agent polyethylene glycol in the assay. The only other mutant (pol30-6, DD41,42AA) that showed a growth defect was partially defective for interaction with replication factor C and DNA polymerase delta but completely defective for interaction with DNA polymerase epsilon. Two other mutants sensitive to DNA damage showed no defect in vitro. These results indicate that the latter mutants are specifically impaired in one or more DNA repair processes whereas pol30-6 and pol30-52 mutants show their primary defects in the basic DNA replication machinery with probable associated defects in DNA repair. Therefore, DNA repair requires interactions between repair-specific protein(s) and PCNA, which are distinct from those required for DNA replication.     

Chemically methylated DNA repair in Escherichia coli--the role of alkB protein

Methylating agents belong to mutagens occurring most frequently in our environment. They methylate mainly the nitrogen bases in DNA and RNA, affecting their functions. In E. coli the alkylated bases are repaired by proteins and enzymes either permanently present in the cells (Ogt, Ada) or produced transiently (Ada, AlkB, AlkA, Aid), after induction of the Ada defence system. Alkylating agents induce also the SOS system, which enhances the synthesis of about 40 proteins, including those participating in recombination, replication and mutagenesis of DNA. All DNA interactions, modifications and repairs constitute an amazing and highly efficiently functioning cellular system. Among the repair proteins there are some which affect the alkylated bases in a non-conventional way, very rarely occurring in nature. Especially amazing is the mechanism of action of dioxogenase AlkB, which combines the repair of methyl-, ethyl- and etheno-base derivatives with oxidation and dissociation of the modified groups, leading to direct recovery of natural bases. This review attempts to elucidate the role of the individual proteins involved in the repair processes.     

Mutational analysis of the structure and function of the xeroderma pigmentosum group A complementing protein. Identification of essential domains for nuclear localization and DNA excision repair.

We showed previously that the xeroderma pigmentosum group A complementing (XPAC) protein involved in the DNA excision repair pathway contains a zinc-finger motif and is localized in the nucleus of normal human cells. For detailed structural and functional analyses of the XPAC protein, we constructed various XPAC cDNAs by site-directed mutagenesis and isolated permanent cell lines expressing mutant proteins. Immunofluorescent analysis of these lines indicated that the nuclear localization signal is located in the region encoded by Exon 1, especially centered at amino acids 30-42. A UV survival study showed that regions from Exons 2 through 6 were essential for DNA repair function, but that Exon 1 was not. Interestingly, deletion of the glutamic acid cluster in the region encoded by Exon 2 resulted in a dramatic loss of DNA repair activity. Furthermore, replacements of each of the 4 cysteines supposed to form a zinc-finger structure in the region encoded by Exon 3 by serine or glycine resulted in similar levels of loss of repair activity. These results suggest that all 4 cysteines forming a zinc-finger structure and also the glutamic acid cluster are important for DNA repair function.