Loss and restoration of viability of E. coli due to combinations of mutations affecting DNA polymerase I and repair activities

Hansenula polymorpha NMR2 and NMR4, two new loci involved in nitrogen metabolite repression

In the yeast Hansenula polymorpha (Pichia angusta) nitrate assimilation is tightly regulated and subject to a dual control: nitrogen metabolite repression (NMR), triggered by reduced nitrogen compounds, and induction, elicited by nitrate itself. In a previous paper [Serrani, F., Rossi, B. and Berardi, E (2001) Nitrogen metabolite repression in Hansenula polymorpha: the nmrl-l mutation. Curr. Genet. 40, 243-250], we identified five loci (NMR1-NMR5) involved in NMR, and characterised one of them (NMR1), which likely identifies a regulatory factor. Here, we describe two more mutants, namely nmr2-1 and nmr4-1. The first one possibly identifies a regulatory factor involved in nitrogen metabolite repression by various nitrogen sources alternative to ammonium. The second one, apparently involved in ammonium assimilation, probably has sensor functions.

A fork-clearing role for UvrD

The inactivation of a replication protein causes the disassembly of the replication machinery and creates a need for replication reactivation. In several replication mutants, restart occurs after the fork has been isomerized into a four-armed junction, a reaction called replication fork reversal. The repair helicase UvrD is essential for replication fork reversal upon inactivation of the polymerase (DnaE) or the beta-clamp (DnaN) subunits of the Escherichia coli polymerase III, and for the viability of dnaEts and dnaNts mutants at semi-permissive temperature. We show here that the inactivation of recA, recFOR, recJ or recQ recombination genes suppresses the requirement for UvrD for replication fork reversal and suppresses the lethality conferred by uvrD inactivation to Pol IIIts mutants at semi-permissive temperature. We propose that RecA binds inappropriately to blocked replication forks in the dnaEts and dnaNts mutants in a RecQ- RecJ- RecFOR-dependent way and that UvrD acts by removing RecA or a RecA-made structure, allowing replication fork reversal. This work thus reveals the existence of a futile reaction of RecA binding to blocked replication forks, that requires the action of UvrD for fork-clearing and proper replication restart.

uvrB-dependent, recF-independent post-replication (or replication) repair in Escherichia coli

In UV-damaged cells, a large fraction of pyrimidine dimers may remain unexcised and may be tolerated by a uvrB recA lexA-dependent non-excisional mode of repair (M. Sedliaková, J. Brozmanová, F. Maŝek and K. Kleibl, Biophys. J., 36 (1981) 429-441). We show here that a similar repair pathway operates in the Escherichia coli recF 143 single mutant but not in the recF uvrB double mutant. This indicates that the putative repair pathway is recF independent.

Construction and analysis of deletions in the structural gene (uvrD) for DNA helicase II of Escherichia coli

DNA helicase II, the product of the uvrD gene, has been implicated in DNA repair, replication, and recombination. Because the phenotypes of individual uvrD alleles vary significantly, we constructed deletion-insertion mutations in the uvrD gene to determine the phenotype of cells lacking DNA helicase II. Deletion mutants completely lacking the protein, as well as one which contains a truncated protein retaining the ATP-binding site, remained viable. However, they were sensitive to UV light and exhibited elevated levels of homologous recombination and spontaneous mutagenesis. In addition, mutations mapping in or near rep which allow construction of rep uvrD double mutants at a high frequency were isolated.

Escherichia coli DNA helicase II (uvrD gene product) catalyzes the unwinding of DNA.RNA hybrids in vitro

DNA helicase II is a well-characterized Escherichia coli enzyme capable of unwinding duplex DNA and known to be involved in both methyl-directed mismatch repair and excision repair of pyrimidine dimers. Here it is shown that this enzyme also catalyzes the ATP-dependent unwinding of a DNA.RNA hybrid consisting of a radioactively labeled RNA molecule annealed on M13 single-stranded DNA. The DNA.RNA unwinding reaction required less protein to unwind more base pairs than the corresponding unwinding of duplex DNA. In addition, the rate of unwinding of the DNA.RNA hybrid was more than an order of magnitude faster than unwinding of a DNA partial duplex of similar length. The unwinding of the DNA.RNA hybrid is a property unique to helicase II since helicase I, Rep protein, and helicase IV failed to catalyze the reaction. In light of these results it seems likely that helicase II is involved in some previously unrecognized aspect of nucleic acid metabolism, in addition to its known roles in DNA repair reactions.

The molecular genetics of the incision step in the DNA excision repair process

This review describes the evolution of research into the genetic basis of how different organisms use the process of excision repair to recognize and remove lesions from their cellular DNA. One particular aspect of excision repair, DNA incision, and how it is controlled at the genetic level in bacteriophage, bacteria, S. cerevisae, D. melanogaster, rodent cells and humans is examined. In phage T4, DNA is incised by a DNA glycosylase-AP endonuclease that is coded for by the denV gene. In E. coli, the products of three genes, uvrA, uvrB and uvrC, are required to form the UVRABC excinuclease that cleaves DNA and releases a fragment 12-13 nucleotides long containing the site of damage. In S. cerevisiae, genes complementing five mutants of the RAD3 epistasis group, rad1, rad2, rad3, rad4 and rad10 have been cloned and analyzed. Rodent cells sensitive to a variety of mutagenic agents and deficient in excision repair are being used in molecular studies to identify and clone human repair genes (e.g. ERCC1) capable of complementing mammalian repair defects. Most studies of the human system, however, have been done with cells isolated from patients suffering from the repair defective, cancer-prone disorder, xeroderma pigmentosum, and these cells are now beginning to be characterized at the molecular level. Studies such as these that provide a greater understanding of the genetic basis of DNA repair should also offer new insights into other cellular processes, including genetic recombination, differentiation, mutagenesis, carcinogenesis and aging.

Specificity of N-acetoxy-N-2-acetylaminofluorene-induced frameshift mutation spectrum in mismatch repair deficient Escherichia coli strains mutH, L, S and U

The mismatch repair system of Escherichia coli is known to contribute to the fidelity of the replicational process. This system involves the functions of mutH, mutL, mutS and mutU (uvrD) loci which recognize mispaired bases as a consequence of errors due to the polymerase itself. Chemical modifications of DNA have also been suspected to create mispaired bases which, if the mispaired bases are removed, will lead to mutations by frameshift. Using the pBR322 plasmid DNA modified by the ultimate carcinogen N-acetoxy-N-2-acetylaminofluorene (N-Aco-AAF) we have investigated this possibility in a forward mutational assay (tetracycline sensitivity). This fluorene derivative has been shown to induce predominantly frameshift mutations. Our results show that: The sensitivity of the deficient strains mutH, mutL and mutS to the AAF adducts is similar to that of the corresponding wild-type strain. However, the mutU strain appears much more sensitive to those adducts although less than a uvrA, B or C-deficient strain. This suggests that the mutU gene product is involved in the repair of AAF adducts. For the four mut deficient strains, and as it was shown with the wild-type strain, AAF adducts induced mutations to tetracycline sensitivity are only observed when the SOS system of the host bacteria is induced by irradiation of the cells prior to transformation with the modified plasmid. The mutation frequencies depend upon the ultraviolet light doses and similar maxima were found for the four mut strains and the corresponding wild-type strain. In agreement with the results obtained with wild-type or uvrA strains we observe that AAF adducts induce mostly frameshift mutations in the mut strains. Two types of hot spots of mutagenesis were described in wild-type and uvrA strains occurring either at repetitive sequences or at sequences of the type 5' G-G-C-G-C-C 3' (NarI restriction enzyme recognition sequence). While the second type of mutational hot spot does exist in the mismatch repair-deficient strains, we observe that the repetitive sequences are no longer hot spots of mutations in these strains, suggesting that the mismatch repair protein complex is involved in the establishment of AAF-induced frameshift mutations at repetitive sequences.

Lethality of the double mutations rho rep and rho ssb in Escherichia coli

The similarity of rho mutants to rep and ssb mutants in sensitivity to UV light and in recombination deficiency suggested that the function of the Rho protein might be related to that of Rep and Ssb. In support of that idea, we found that rho rep and rho ssb double mutants are either nonviable, or at best only marginally viable. Viability could be restored by suppressor mutations, one of which mapped either in the rho gene or close to its 5'-end. Rho may thus share a role with Rep and Ssb in replication and the structural maintenance of DNA; a multifunctional Rho protein could account for the diversity of the defects seen in rho mutants, some of which appear to have no relation to the defect in transcription termination.

The nucleotide sequence of the uvrD gene of E. coli

The nucleotide sequence of a cloned section of the E. coli chromosome containing the uvrD gene has been determined. The coding region for the UvrD protein consists of 2,160 nucleotides which would direct the synthesis of a polypeptide 720 amino acids long with a calculated molecular weight of 82 kd. The predicted amino acid sequence of the UvrD protein has been compared with the amino acid sequences of other known adenine nucleotide binding proteins and a common sequence has been identified, thought to contribute towards adenine nucleotide binding.

Long repair replication patches are produced by the short-patch pathway in a uvrD252 (recL152) mutant of Escherichia coli K-12

The uvrD252 mutation leads to increased UV sensitivity, diminished dimer excision and host cell reactivation capacity, and an increase in the average patch size after repair replication. A recA56 uvrD252 double mutant was far more resistant to UV than was a recA56 uvrB5 double mutant. Its host cell reactivation capacity was identical to that of uvrD252 single mutant and was far greater than that of the uvrB5 single mutant. The strain showed no Weigle reactivation. From these results, we concluded that the double mutant has no inducible DNA repair (including long-patch excision repair) but retains dimer excision capabilities comparable to the uvrD252 single mutant. It appears, therefore, that the long patches detected in the uvrD mutant were not identical to the recA-dependent patches seen in wild-type cells.

Nucleotide sequence of the regulatory region of the uvrD gene of Escherichia coli

We have sequenced the control region of the Escherichia coli uvrD gene and demonstrated the presence of a nucleotide sequence which is a perfect match for the consensus LexA protein binding site [Little and Mount, Cell 29 (1982) 11-22]. Upstream of this presumed LexA binding site is a promoter sequence, uvrD P1 which would be under LexA control while farther downstream is another possible promoter, uvrD P2, which would be independent of LexA control. Downstream of the LexA binding site is a potential transcription terminator in the form of a stem-loop structure followed by a series of T residues. On the basis of this sequence analysis, expression of the uvrD gene would be expected to increase after DNA damage or replication inhibition as part of the SOS response, as is reported in the preceding paper [Arthur and Eastlake, Gene 25 (1983) 309-316].

The E. coli uvrD gene product is DNA helicase II

We have shown that the uvrD gene product, previously identified in maxicell extracts as a 73 kilodalton protein, copurifies with single stranded DNA-dependent ATPase and ATP-dependent DNA helicase activities. This protein is specifically precipitated from maxicell extracts by antibodies raised against DNA helicase II. In order to facilitate purification of the UvrD protein we have subcloned the uvrD gene into a plasmid vector in which its transcription is under the control of the phage lambda leftward promoter. Using cells harbouring this recombinant plasmid as a source of elevated levels of the UvrD protein we have purified this protein to homogeneity by a simple, rapid procedure. The purified protein has single stranded DNA-dependent ATPase activity and ATP-dependent DNA helicase activity, and both activities are specifically inactivated by antibodies raised against DNA helicase II. We conclude that DNA helicase II is the uvrD gene product.

Identification of the uvrD gene product of Salmonella typhimurium LT2

The product of the uvrD gene of Salmonella typhimurium LT2 and Escherichia coli K-12 is thought to play a role in both the correction of mismatched bases and the repair of DNA damage, since insertion mutations in the uvrD gene increase the spontaneous mutation frequency and make the cells more sensitive to killing by UV irradiation. To clone the uvrD gene of S. typhimurium, we first generated a uvrD-specific probe by using DNA from an S. typhimurium uvrD421::Tn5 mutant. This probe was used to screen a lambda library of S. typhimurium DNA. Bacteriophage carrying intact uvrD+ genes were subsequently identified, and the uvrD+ gene was subcloned onto a low-copy-number vector. By using a combination of Tn1000 insertion mutagenesis and the maxicell technique, the product of the uvrD gene was shown to be a 75,000-dalton protein, and the relative direction of transcription of this protein was determined. Introduction of a low-copy-number plasmid carrying the S. typhimurium uvrD+ gene into uvrD insertion mutants of either S. typhimurium or E. coli restored the spontaneous mutation frequency and degree of UV sensitivity to the levels in the corresponding uvrD+ strains.

Molecular cloning of the uvrD gene of Escherichia coli that controls ultraviolet sensitivity and spontaneous mutation frequency

The uvrD gene of Escherichia coli that controls UV sensitivity and spontaneous mutation frequency has been cloned with phage lambda as vector. The increased sensitivity to ultraviolet light (UV) of uvrD3, uvrE502, recL152, and pdeB41 mutants, high mutability of uvrD3 and pdeB41 mutants, and conditional lethality of strain TS41 that carried pdeB41, polA1, and supl26 mutations were all suppressed by lysogenization of the mutant cells with lambda uvrD+. These results were consistent with the idea that the uvrD, uvrE, recL, and pdeB mutations are alleles of the uvrD gene. In addition to the uvrD gene, lambda uvrD+ carried the corA gene that controls transport of Mg++, Mn++, and Co++ through the cell membrane. Hybrid plasmids carrying both uvrD and corA genes were also constructed by using pKY2289 as a cloning vehicle. Orientational isomers that carried the same 12.0 kb fragment in the opposite direction were equally efficient in complementing the UvrD- as well as CorA- defects of the transformed host cells, suggesting that the DNA insert contains all the genetic signals needed to express the two gene products. Insertion of the gamma delta sequence into recombinant plasmids was performed to generate appropriate restriction endonuclease target sites in the cloned DNA fragments.

Mutagenesis at the ad-3A and ad-3B loci in haploid UV-sensitive strains of Neurospora crassa. V. Comparison of dose--response curves of single- and double-mutant strains with wild-type

The interactions of mutant alleles that individually confer radiation sensitivity in Neurospora crassa are being studied with regard to their effects on radiation-induced inactivation and forward-mutation induction at the ad-3 loci. This paper reports attempts to construct 3 double-mutant strains containing the following pair-wise combinations of repair-deficient mutants: upr-1,uvs-2; uvs-2,uvs-6; and uvs-3,uvs-6. The double-mutant strain with the 2 excision-repair-deficient mutants upr-1 and uvs-2 shows increased sensitivity to X-ray-induced mutagenesis and inactivation, relative to that shown by either of the parental single-mutant strains. This double mutant is no more sensitive than the parental single-mutant strains to either UV mutagenesis or inactivation. The combination of the uvs-2 and uvs-6 double-mutant strain is considerably more sensitive to both UV and X-ray inactivation than either the uvs-2 or uvs-6 strain, but it shows no greater sensitivity than the parental strains to ad-3 mutation induction by either agent. The combination of the uvs-3 and uvs-6 alleles is inviable. Tetrad analysis and microscopical examination of ascospores shows that ascospores of presumptive genotype uvs-3, uvs-6 do not grow beyond the formation of a few hyphal threads. The lethal and mutagenic effects of UV and X-irradiation in these double-mutant strains are interpreted in terms of the repair systems in Neurospora and other microorganisms.

Hyper-recombination in uvrD mutants of Escherichia coli K-12

A mutant strain of E. coli which was isolated initially because of its strong hyper-recombination phenotype was shown to carry a lesion in uvrD. The presence of this mutation, designated uvrD210, increased the frequency of recombination between chromosomal duplications in F-prime repliconant cells and reduced linkage between closely linked markers in crosses with Hfr donors. A comparable hyper-rec phenotype was demonstrated in strains carrying other alleles of uvrD previously referred to as mutU4, uvr502 and recL152. The recombination activity of a uvrD210 strain was abolished by mutation of recA but the mutator activity associated with this allele proved to be independent of recA. It is suggested that uvrD mutations reduce the fidelity of DNA replication and that the accumulation of lesions in the newly synthesized strand provides additional sites for initiating recombination.

UV protection and mutagenesis in uvrD, uvrE and recL strains of Escherichia coli carrying the pKM101 plasmid

The effect of the pKM101 plasmid on UV mutagenesis and survival was examined in DNA-repair-deficient strains of E. coli carrying the uvrD, uvrE and recL mutations. Although enhancement of UV mutagenesis by pKM101 was found in all 3 strains, UV protection was only observed in the uvrD strain. We conclude that the plasmid not only requires lexA+ recA+ functions of the cell, but also those of uvrE+ recL+ for its UV-protective effect.

A new conditional lethal mutator (dnaQ49) in Escherichia coli K12

A conditional lethal mutator, dnaQ49, was found in Escherichia coli K12. The dnaQ49 mutation caused stimulation of rifampicin-, nalidixic acid- and streptomycin-resistant mutation frequencies 100 to 2000 fold at 30 degrees C and the frequencies were further increased 50 to 100 fold at 35 degrees C or higher temperatures. Cells carrying dnaQ49 were unable to grow in salt-free L-broth at 44.5 degrees C, and DNA synthesis but not protein synthesis of the cells was suppressed under the restrictive conditions. The dnaQ gene was located at about 5 min on the E. coli linkage map and the order of the genes residing in this region was determined to be ton A-dnaE-metD-dnaQ-pro A.

Defective excision and postreplication repair of UV-damaged DNA in a recL mutant strain of E. coli K-12

The mutation recL152 leads to a reduction of excision repair as measured by an increase in the time required to close uvrA uvrB dependent incision breaks, and by a reduction of host cell reactivation ability. Postreplication repair is also delayed when measured in a uvrB5 recL152 double mutant. Such a determination could not be made using the recL152 single mutant because the excision defect led to an accumulation of breaks in the unlabeled high molecular weight DNA to which the labeled DNA synthesized after irradiation must attach in order to achieve normal high molecular weight. Further, the recL gene product seems to be required to rejoin breaks in parental strand DNA which are generated during postreplication repair, since such gaps accumulate in a recL152 uvrB5 double mutant but not in a recL+ uvrB5 single mutant. We have noticed a striking phenotypic similarity between recL152 and polA1 and suggest that recL152 is required for full in vivo activity of DNA polymerase I.

Evidence that the gene uvrB is indispensable for a polymerase I deficient strain of Escherichia coli K-12

Conclusive evidence in presented to show that the gene uvrA is dispensable, but the uvrB is indispensable for an Escherichia coli strain carrying gene polA1. We constructed strains E139 (sup-126 polAl uvrB59) and E159 (sup-126 polAl uvrA43) where mutations polAl, uvrB59 and uvrA43 are amber mutations and mutation sup-126 is an amber suppressor mutation effective at 30 degrees C but not at 42 degrees C. At 42 degrees C, strain E139 is inviable but strain E159 viable whereas both are viable at 30 degrees C. Revertants of E139 viable at 42 degrees C occurred spontaneously at a frequency of about 3 X 10(-4). One of the revertants was shown to be caused by suppressor mutation, designated spu, rather than back mutation of the gene uvrB59 or polAl or amber suppressor mutation. Viabilities of the revertants varied from 10(-3) to 1.0 at 42 degrees C compared with those of 30 degrees C. At 42 degrees C, all the revertants with normal viabilities at 42 degrees C were non-filamentous in contrast to the filamentous character of E139. However, strain E159 was viable at 42 degrees C despite its filamentous character. We conclude that the gene uvrB is involved not only in excision repair but also in normal growth in a polA background.

Increased spontaneous reversion of certain frameshift mutations in DNA polymerase I deficient strains of Escherichia coli

A tenfold increase in the spontaneous reversion frequency of two of six lacZ frameshift mutations tested was observed in strains containing the following DNA polymerase I mutations--polA1, polA5, polA6, polAex1, res-3 and resA1. Reconstruction experiments indicated that this increase was not the result of a selective effect. Only a fourfold increase in frameshift mutations was found in strains containing a polA107 mutation. Both the polAex1 and polA107 mutations result in defective 5' to 3' exonuclease activity and do not affect polymerizing activity, but have different effects on frameshift mutation. A polA mutation on the chromosome induced frameshift mutations in a gene on an F episome. None of three auxotrophic mutations studied showed high frequency reversion in the presence of the polA1 or polA6 mutations.

Escherichia coli mutants uvr D and uvr E deficient in gene conversion of lambda-heteroduplexes

Calcium-treated cells of E. coli K-12 C600 were transfected with lambda-heteroduplex DNA carrying the marker cIts857 in one strand and wildtype in the other. In single burst analyses of the phage progeny, 72-79% of the bursts were "pure" bursts containing either exclusively wildtype phage or exclusively mutant phage, indicating that conversion of the cIts857/+ mismatch to a homoduplex structure prior to replication occurred with this frequency. The r-strand1 appears to be "preferred", since pure bursts of progeny with the r-strand genotype were almost twice as frequent as those with the l-strand genotype. Examination of the conversion frequency of a number of rec and uvr E. coli mutants showed that the mutants uvr D and UVR E are deficient in mismatch repair. Conversion is reduced in the former by a factor of 2 and in the latter by a factor of 3.

The role of DNA polymerase I in genetic recombination and viability of Escherichia coli

The rate of formation of high-molecular-weight daughter DNA in the conditionally lethal double mutant polA12 uvrE502, incubated at nonpermissive temperature, was slower than that in the single polA12 mutant. There exist at least two pathways determining viability of Escherichia coli cells: one of them is dependent on polA+ and recB+ genes, while another is polA+ and recB+ genes, while another is polA recB independent but requires the uvrE+ gene and can be blocked by exonuclease I. The RecF but not the RecBC pathway of genetic recombination was found to be absolutely dependent on the polymerizing activity of DNA polymerase I. The involvement of DNA polymerase I in genetic recombination in the recB- C- sbsB strain and viability in the uvrE- or recB- strains suggest the existence of the common steps required for the accomplishing of the RecF pathway of recombination and for viability of E. coli.

Genetic analysis of a temperature-resistant revertant of the conditional lethal Escherichia coli double mutant polA12 uvrE502

Conditional lethality of the Escherichia coli polA12 uvrE502 double mutant may be overcome by a mutation that has been termed polA350. The polA350 mutation restored the polymerizing activity of deoxyribonucleic acid polymerase I at 42 C in the polA12 mutant and partially suppressed ultraviolet (UV) and methylmethane sulfonate sensitivities of the polA12. Mapping experiments have located polA350 between metE and polA12, very close to the latter. The strain carrying polA12 polA350 and recB21 was viable at 42 C. The effects of the recB21 and polA12 polA350 combination on the UV sensitivity were additive. The triple mutant polA12 polA350 uvrE502 was more UV sensitive than the single uvrE502 mutant.

Suppression of ultraviolet sensitivity in Escherichia coli uvr502 by the su58 missense suppressor

Introduction of the su58 missense suppressor into the chromosome of the uvr502 mutant, either by mutation or by transduction, results in a marked increase of ultraviolet resistance of the uvr502 mutant. In the uvr(+) genetic background, the su58 suppressor causes some decrease of ultraviolet resistance and marked increase in the spontaneous mutation frequency. The presence of the su58 suppressor did not decrease the high frequency of spontaneous mutants in the population of the uvr502 strain. However, the significant increase in spontaneous mutant frequency in the uvr(+)su58 strain makes the difference between the uvr502 su58 and the uvr(+)su58 strains 18 times lower than that between the uvr502 and the uvr(+) suppressor-free strains. Since the missense suppressors act at the level of translation, the results suggest that the product of the uvr(502) gene is a protein.