Studies on radiation-sensitive mutants of E. coli. I. Mutants defective in the repair synthesis

Structural and functional investigation of GajB protein in Gabija anti-phage defense

Bacteriophages (phages) are viruses that infect bacteria and archaea. To fend off invading phages, the hosts have evolved a variety of anti-phage defense mechanisms. Gabija is one of the most abundant prokaryotic antiviral systems and consists of two proteins, GajA and GajB. GajA has been characterized experimentally as a sequence-specific DNA endonuclease. Although GajB was previously predicted to be a UvrD-like helicase, its function is unclear. Here, we report the results of structural and functional analyses of GajB. The crystal structure of GajB revealed a UvrD-like domain architecture, including two RecA-like core and two accessory subdomains. However, local structural elements that are important for the helicase function of UvrD are not conserved in GajB. In functional assays, GajB did not unwind or bind various types of DNA substrates. We demonstrated that GajB interacts with GajA to form a heterooctameric Gabija complex, but GajB did not exhibit helicase activity when bound to GajA. These results advance our understanding of the molecular mechanism underlying Gabija anti-phage defense and highlight the role of GajB as a component of a multi-subunit antiviral complex in bacteria.

Structure and Mechanisms of SF1 DNA Helicases

Superfamily I is a large and diverse group of monomeric and dimeric helicases defined by a set of conserved sequence motifs. Members of this class are involved in essential processes in both DNA and RNA metabolism in all organisms. In addition to conserved amino acid sequences, they also share a common structure containing two RecA-like motifs involved in ATP binding and hydrolysis and nucleic acid binding and unwinding. Unwinding is facilitated by a "pin" structure which serves to split the incoming duplex. This activity has been measured using both ensemble and single-molecule conditions. SF1 helicase activity is modulated through interactions with other proteins.

UvrD Participation in Nucleotide Excision Repair Is Required for the Recovery of DNA Synthesis following UV-Induced Damage in Escherichia coli

UvrD is a DNA helicase that participates in nucleotide excision repair and several replication-associated processes, including methyl-directed mismatch repair and recombination. UvrD is capable of displacing oligonucleotides from synthetic forked DNA structures in vitro and is essential for viability in the absence of Rep, a helicase associated with processing replication forks. These observations have led others to propose that UvrD may promote fork regression and facilitate resetting of the replication fork following arrest. However, the molecular activity of UvrD at replication forks in vivo has not been directly examined. In this study, we characterized the role UvrD has in processing and restoring replication forks following arrest by UV-induced DNA damage. We show that UvrD is required for DNA synthesis to recover. However, in the absence of UvrD, the displacement and partial degradation of the nascent DNA at the arrested fork occur normally. In addition, damage-induced replication intermediates persist and accumulate in uvrD mutants in a manner that is similar to that observed in other nucleotide excision repair mutants. These data indicate that, following arrest by DNA damage, UvrD is not required to catalyze fork regression in vivo and suggest that the failure of uvrD mutants to restore DNA synthesis following UV-induced arrest relates to its role in nucleotide excision repair.

The nucleotide excision repair (NER) system of Helicobacter pylori: role in mutation prevention and chromosomal import patterns after natural transformation

Background

Extensive genetic diversity and rapid allelic diversification are characteristics of the human gastric pathogen Helicobacter pylori, and are believed to contribute to its ability to cause chronic infections. Both a high mutation rate and frequent imports of short fragments of exogenous DNA during mixed infections play important roles in generating this allelic diversity. In this study, we used a genetic approach to investigate the roles of nucleotide excision repair (NER) pathway components in H. pylori mutation and recombination.

Results

Inactivation of any of the four uvr genes strongly increased the susceptibility of H. pylori to DNA damage by ultraviolet light. Inactivation of uvrA and uvrB significantly decreased mutation frequencies whereas only the uvrA deficient mutant exhibited a significant decrease of the recombination frequency after natural transformation. A uvrC mutant did not show significant changes in mutation or recombination rates; however, inactivation of uvrC promoted the incorporation of significantly longer fragments of donor DNA (2.2-fold increase) into the recipient chromosome. A deletion of uvrD induced a hyper-recombinational phenotype.

Conclusions

Our data suggest that the NER system has multiple functions in the genetic diversification of H. pylori, by contributing to its high mutation rate, and by controlling the incorporation of imported DNA fragments after natural transformation.

Modulation of UvrD helicase activity by covalent DNA-protein cross-links

UvrD (DNA helicase II) has been implicated in DNA replication, DNA recombination, nucleotide excision repair, and methyl-directed mismatch repair. The enzymatic function of UvrD is to translocate along a DNA strand in a 3' to 5' direction and unwind duplex DNA utilizing a DNA-dependent ATPase activity. In addition, UvrD interacts with many other proteins involved in the above processes and is hypothesized to facilitate protein turnover, thus promoting further DNA processing. Although UvrD interactions with proteins bound to DNA have significant biological implications, the effects of covalent DNA-protein cross-links on UvrD helicase activity have not been characterized. Herein, we demonstrate that UvrD-catalyzed strand separation was inhibited on a DNA strand to which a 16-kDa protein was covalently bound. Our sequestration studies suggest that the inhibition of UvrD activity is most likely due to a translocation block and not helicase sequestration on the cross-link-containing DNA substrate. In contrast, no inhibition of UvrD-catalyzed strand separation was apparent when the protein was linked to the complementary strand. The latter result is surprising given the earlier observations that the DNA in this covalent complex is severely bent ( approximately 70 degrees ), with both DNA strands making multiple contacts with the cross-linked protein. In addition, UvrD was shown to be required for replication of plasmid DNAs containing covalent DNA-protein complexes. Combined, these data suggest a critical role for UvrD in the processing of DNA-protein cross-links.

The unstructured C-terminal extension of UvrD interacts with UvrB, but is dispensable for nucleotide excision repair

During nucleotide excision repair (NER) in bacteria the UvrC nuclease and the short oligonucleotide that contains the DNA lesion are removed from the post-incision complex by UvrD, a superfamily 1A helicase. Helicases are frequently regulated by interactions with partner proteins, and immunoprecipitation experiments have previously indicated that UvrD interacts with UvrB, a component of the post-incision complex. We examined this interaction using 2-hybrid analysis and surface plasmon resonance spectroscopy, and found that the N-terminal domain and the unstructured region at the C-terminus of UvrD interact with UvrB. We analysed the properties of a truncated UvrD protein that lacked the unstructured C-terminal region and found that it showed a diminished affinity for single-stranded DNA, but retained the ability to displace both UvrC and the lesion-containing oligonucleotide from a post-incision nucleotide excision repair complex. The interaction of the C-terminal region of UvrD with UvrB is therefore not an essential feature of the mechanism by which UvrD disassembles the post-incision complex during NER. In further experiments we showed that PcrA helicase from Bacillus stearothermophilus can also displace UvrC and the excised oligonucleotide from a post-incision NER complex, which supports the idea that PcrA performs a UvrD-like function during NER in Gram-positive organisms.

Suppression of constitutive SOS expression by recA4162 (I298V) and recA4164 (L126V) requires UvrD and RecX in Escherichia coli K-12

Sensing DNA damage and initiation of genetic responses to repair DNA damage are critical to cell survival. In Escherichia coli, RecA polymerizes on ssDNA produced by DNA damage creating a RecA-DNA filament that interacts with the LexA repressor inducing the SOS response. RecA filament stability is negatively modulated by RecX and UvrD. recA730 (E38K) and recA4142 (F217Y) constitutively express the SOS response. recA4162 (I298V) and recA4164 (L126V) are intragenic suppressors of the constitutive SOS phenotype of recA730. Herein, it is shown that these suppressors are not allele specific and can suppress SOS(C) expression of recA730 and recA4142 in cis and in trans. recA4162 and recA4164 single mutants (and the recA730 and recA4142 derivatives) are Rec(+), UV(R) and are able to induce the SOS response after UV treatment like wild-type. UvrD and RecX are required for the suppression in two (recA730,4164 and recA4142,4162) of the four double mutants tested. To explain the data, one model suggests that recA(C) alleles promote SOS(C) expression by mimicking RecA filament structures that induce SOS and the suppressor alleles mimic RecA filament at end of SOS. UvrD and RecX are attracted to these latter structures to help dismantle or destabilize the RecA filament.

UvrD303, a hyperhelicase mutant that antagonizes RecA-dependent SOS expression by a mechanism that depends on its C terminus

Genomic integrity is critical for an organism's survival and ability to reproduce. In Escherichia coli, the UvrD helicase has roles in nucleotide excision repair and methyl-directed mismatch repair and can limit reactions by RecA under certain circumstances. UvrD303 (D403A D404A) is a hyperhelicase mutant, and when expressed from a multicopy plasmid, it results in UV sensitivity (UV(s)), recombination deficiency, and antimutability. In order to understand the molecular mechanism underlying the UV(s) phenotype of uvrD303 cells, this mutation was transferred to the E. coli chromosome and studied in single copy. It is shown here that uvrD303 mutants are UV sensitive, recombination deficient, and antimutable and additionally have a moderate defect in inducing the SOS response after UV treatment. The UV-sensitive phenotype is epistatic with recA and additive with uvrA and is partially suppressed by removing the LexA repressor. Furthermore, uvrD303 is able to inhibit constitutive SOS expression caused by the recA730 mutation. The ability of UvrD303 to antagonize SOS expression was dependent on its 40 C-terminal amino acids. It is proposed that UvrD303, via its C terminus, can decrease the levels of RecA activity in the cell.

UvrD helicase of Plasmodium falciparum

Malaria caused by the mosquito-transmitted parasite Plasmodium is the cause of enormous number of deaths every year in the tropical and subtropical areas of the world. Among four species of Plasmodium, Plasmodium falciparum causes most fatal form of malaria. With time, the parasite has developed insecticide and drug resistance. Newer strategies and advent of novel drug targets are required so as to combat the deadly form of malaria. Helicases is one such class of enzymes which has previously been suggested as potential antiviral and anticancer targets. These enzymes play an essential role in nearly all the nucleic acid metabolic processes, catalyzing the transient opening of the duplex nucleic acids in an NTP-dependent manner. DNA helicases from the PcrA/UvrD/Rep subfamily are important for the survival of the various organisms. Members from this subfamily can be targeted and inhibited by a variety of synthetic compounds. UvrD from this subfamily is the only member present in the P. falciparum genome, which shows no homology with UvrD from human and thus can be considered as a strong potential drug target. In this manuscript we provide an overview of UvrD family of helicases and bioinformatics analysis of UvrD from P. falciparum.

UvrD helicase unwinds DNA one base pair at a time by a two-part power stroke

Helicases use the energy derived from nucleoside triphosphate hydrolysis to unwind double helices in essentially every metabolic pathway involving nucleic acids. Earlier crystal structures have suggested that DNA helicases translocate along a single-stranded DNA in an inchworm fashion. We report here a series of crystal structures of the UvrD helicase complexed with DNA and ATP hydrolysis intermediates. These structures reveal that ATP binding alone leads to unwinding of 1 base pair by directional rotation and translation of the DNA duplex, and ADP and Pi release leads to translocation of the developing single strand. Thus DNA unwinding is achieved by a two-part power stroke in a combined wrench-and-inchworm mechanism. The rotational angle and translational distance of DNA define the unwinding step to be 1 base pair per ATP hydrolyzed. Finally, a gateway for ssDNA translocation and an alternative strand-displacement mode may explain the varying step sizes reported previously.

UvrD limits the number and intensities of RecA-green fluorescent protein structures in Escherichia coli K-12

RecA is important for recombination, DNA repair, and SOS induction. In Escherichia coli, RecBCD, RecFOR, and RecJQ prepare DNA substrates onto which RecA binds. UvrD is a 3'-to-5' helicase that participates in methyl-directed mismatch repair and nucleotide excision repair. uvrD deletion mutants are sensitive to UV irradiation, hypermutable, and hyper-rec. In vitro, UvrD can dissociate RecA from single-stranded DNA. Other experiments suggest that UvrD removes RecA from DNA where it promotes unproductive reactions. To test if UvrD limits the number and/or the size of RecA-DNA structures in vivo, an uvrD mutation was combined with recA-gfp. This recA allele allows the number of RecA structures and the amount of RecA at these structures to be assayed in living cells. uvrD mutants show a threefold increase in the number of RecA-GFP foci, and these foci are, on average, nearly twofold higher in relative intensity. The increased number of RecA-green fluorescent protein foci in the uvrD mutant is dependent on recF, recO, recR, recJ, and recQ. The increase in average relative intensity is dependent on recO and recQ. These data support an in vivo role for UvrD in removing RecA from the DNA.

Fitness evolution and the rise of mutator alleles in experimental Escherichia coli populations

We studied the evolution of high mutation rates and the evolution of fitness in three experimental populations of Escherichia coli adapting to a glucose-limited environment. We identified the mutations responsible for the high mutation rates and show that their rate of substitution in all three populations was too rapid to be accounted for simply by genetic drift. In two of the populations, large gains in fitness relative to the ancestor occurred as the mutator alleles rose to fixation, strongly supporting the conclusion that mutator alleles fixed by hitchhiking with beneficial mutations at other loci. In one population, no significant gain in fitness relative to the ancestor occurred in the population as a whole while the mutator allele rose to fixation, but a substantial and significant gain in fitness occurred in the mutator subpopulation as the mutator neared fixation. The spread of the mutator allele from rarity to fixation took >1000 generations in each population. We show that simultaneous adaptive gains in both the mutator and wild-type subpopulations (clonal interference) retarded the mutator fixation in at least one of the populations. We found little evidence that the evolution of high mutation rates accelerated adaptation in these populations.

Cloning and characterization of the uvrD gene from an extremely thermophilic bacterium, Thermus thermophilus HB8

The uvrD gene encodes a DNA helicase which plays an important role in prokaryotic nucleotide (nt) excision repair, mismatch repair and DNA replication. A cosmid-based genomic DNA library for Thermus thermophilus (Tt) HB8 was constructed, and this was screened by Southern hybridization using a uvrD fragment amplified by PCR as the probe. The nt sequence of cloned Tt uvrD was then determined. Characteristic helicase motifs, made up of seven elements, were all conserved in the amino acid (aa) sequence of Tt UvrD. The aa sequence showed 41% homology with that of Escherichia coli (Ec). In the aa composition of Tt UvrD, the number of Asn, Gln, Met and Cys residues was decreased, and the number of Pro residues was increased. The distribution of Pro residues and recent data on X-ray crystallographic structure suggested the importance of the structural dynamics of the protein. These changes are thought to stabilize the native protein conformation against heat denaturation. Tt uvrD complemented the UV sensitivity of a Ec uvrD mutant. Thus, the thermophilic bacterium has a UvrD helicase, whose function is common to Ec UvrD.

Photochemistry of DNA and related biomolecules: quantum yields and consequences of photoionization

The reactions of nucleic acids and constituents, which can be induced by laser UV irradiation, are described. Emphasis is placed on the quantum yields of various stable photoproducts of DNA and model compounds upon irradiation at 193, 248, 254 or 266 nm. In particular, those quantum yields and processes are discussed which involve photoionization as the initial step and occur in aqueous solution under well defined conditions, e.g. type of atmosphere. The efficiencies of some photoproducts, with respect to photoionization using irradiation at 193 or 248 nm, are presented. Radical cations of nucleobases are important sources of damage of biological substrates since they can cause lesions other than dimers and adducts, e.g. strand breakage, abasic sites, crosslinks or inactivation of plasmid and chromosomal DNA. While competing photoreactions, such as hydration, dimerization or adduct formation, diminish the selectivity of the photoionization method, a combination with model studies on pyrimidine- and purine-containing constituents of DNA has brought about an enhanced insight into the reaction mechanisms. The knowledge concerning the lethal events in plasmid and cellular DNA has been greatly improved by correlation with the chemical effects obtained by gamma-radiolysis, vacuum-UV (< 190 nm) and low-intensity irradiation at 254 nm.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

Photolesions and biological inactivation of plasmid DNA on 254 nm irradiation and comparison with 193 nm laser irradiation

Plasmid pTZ18R and calf thymus DNA in aerated neutral aqueous solution were irradiated by continuous 254 nm light. The quantum yields are phi ssb = 4.0 x 10(-5) and phi dsb = 1.4 x 10(-6) for single- and double-strand break formation, respectively, phi br = 2.3 x 10(-5) for base release, phi dn = 2.1 x 10(-3) for destruction of nucleotides, and phi icl approximately phi lds approximately 1 x 10(-6) for interstrand cross-links and locally denatured sites, respectively. The presence of Tris-HCl/ethylenediaminetetraacetic acid (10:1, pH 7.5) buffer strongly reduces phi ssb. The corresponding phi values, obtained on employing pulsed 193 nm laser irradiation, are much larger than those using lambda irr = 254 nm. This is ascribed to a contribution of chemical reactions induced by photoionization, which is absent for 254 nm irradiation. The quantum yields of inactivation of plasmid DNA (lambda irr = 254 nm) were measured by transformation of the Escherichia coli strains AB1157 (wild type), phi ina (1157) = 1.6 x 10(-4), AB1886 (uvr-), phi ina (1886) = 4.2 x 10(-4), AB2463 (rec-), phi ina (2463) = 4.1 x 10(-4) and AB2480 (uvr- rec-), phi ina (2480) = 3.1 x 10(-3). The quantum yields of inactivation of plasmid DNA are compared with those of the four E. coli strains (denoted as chromosomal DNA inactivation) obtained from the literature. The results for E. coli strain AB2480 show that the chromosomal DNA and the plasmid DNA are both inactivated by a single pyrimidine photodimer per genome.(ABSTRACT TRUNCATED AT 250 WORDS)

Nucleotide excision repair

Nucleotide excision repair is the major DNA repair mechanism in all species tested. This repair system is the sole mechanism for removing bulky adducts from DNA, but it repairs essentially all DNA lesions, and thus, in addition to its main function, it plays a back-up role for other repair systems. In both pro- and eukaryotes nucleotide excision is accomplished by a multisubunit ATP-dependent nuclease. The excision nuclease of prokaryotes incises the eighth phosphodiester bond 5' and the fourth or fifth phosphodiester bond 3' to the modified nucleotide and thus excises a 12-13-mer. The excision nuclease of eukaryotes incises the 22nd, 23rd, or 24th phosphodiester bond 5' and the fifth phosphodiester bond 3' to the lesion and thus removes the adduct in a 27-29-mer. A transcription repair coupling factor encoded by the mfd gene in Escherichia coli and the ERCC6 gene in humans directs the excision nuclease to RNA polymerase stalled at a lesion in the transcribed strand and thus ensures preferential repair of this strand compared to the nontranscribed strand.

Characterization of DNA helicase II from a uvrD252 mutant of Escherichia coli

The loss of DNA helicase II (UvrD) in Escherichia coli results in sensitivity to UV light and increased levels of spontaneous mutagenesis. While the effects of various uvrD alleles have been analyzed in vivo, the proteins produced by these alleles have not been examined in any detail. We have cloned one of these alleles, uvrD252, and determined the site of the mutation conferring the phenotype. In addition, the protein it encodes has been purified to homogeneity and characterized in vitro. The mutation responsible for the phenotype was identified as a glycine-to-aspartic-acid change in the putative ATP-binding domain. In comparison to wild-type DNA helicase II, the UvrD252 enzyme exhibited reduced levels of ATPase activity and a large increase in the Km for ATP. The ability of UvrD252 to unwind DNA containing single-stranded regions, as well as DNA containing only nicks, was reduced in comparison to that of the wild-type enzyme. Possible interpretations of these results in relation to the phenotypes of the uvrD252 mutant are discussed. This represents the first detailed analysis of the biochemical properties of a mutant DNA helicase II protein.

Repair of helix-stabilizing anthramycin-N2 guanine DNA adducts by UVRA and UVRB proteins

The transfectivity of anthramycin (Atm)-modified phi X174 replicative form (RF) DNA in Escherichia coli is lower in uvrA and uvrB mutant cells but much higher in uvrC mutant cells compared to wild-type cells. Pretreatment of the Atm-modified phage DNA with purified UVRA and UVRB significantly increases the transfectivity of the DNA in uvrA or uvrB mutant cells. This pretreatment greatly reduces the UVRABC nuclease-sensitive sites (UNSS) and Atm-induced absorbance at 343 nm in the Atm-modified DNA without producing apurinic sites. The reduction of UNSS is proportional to the concentrations of UVRA and UVRB and the enzyme-DNA incubation time and requires ATP. We conclude that there are two different mechanisms for repairing Atm-N2 guanine adducts by UVR proteins: (1) UVRA and UVRB bind to the Atm-N2 guanine double-stranded DNA region and consequently release the Atm from the adducted guanine; (2) UVRABC makes an incision at both sides of the Atm-DNA adduct. The latter mechanism produces potentially lethal double-strand DNA breaks in Atm-modified phi X174 RF DNA in vitro.

Galactose utilization in Lactobacillus helveticus: isolation and characterization of the galactokinase (galK) and galactose-1-phosphate uridyl transferase (galT) genes

By complementing appropriate gal lesions in Escherichia coli K802, we were able to isolate the galactokinase (galK) and galactose-1-phosphate uridyl transferase (galT) genes of Lactobacillus helveticus. Tn10 transposon mutagenesis, together with in vivo complementation analysis and in vitro enzyme activity measurements, allowed us to map these two genes. The DNA sequences of the genes and the flanking regions were determined. These revealed that the two genes are organized in the order galK-galT in an operonlike structure. In an in vitro transcription-translation assay, the galK and galT gene products were identified as 44- and 53-kDa proteins, respectively, data which corresponded well with the DNA sequencing data. The deduced amino acid sequence of the galK gene product showed significant homologies to other prokaryotic and eukaryotic galactokinase sequences, whereas galactose-1-phosphate uridyl transferase did not show any sequence similarities to other known proteins. This observation, together with a comparison of known gal operon structures, suggested that the L. helveticus operon developed independently to a translational expression unit having a different gene order than that in E. coli, Streptococcus lividans, or Saccharomyces cerevisiae. DNA sequencing of the flanking regions revealed an open reading frame downstream of the galKT operon. It was tentatively identified as galM (mutarotase) on the basis of the significant amino acid sequence homology with the corresponding Streptococcus thermophilus gene.

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.

DNA helicases of Escherichia coli

A great deal has been learned in the last 15 years with regard to how helicase enzymes participate in DNA metabolism and how they interact with their DNA substrates. However, many questions remain unanswered. Of critical importance is an understanding of how NTP hydrolysis and hydrogen-bond disruption are coupled. Several models exist and are being tested; none has been proven. In addition, an understanding of how a helicase disrupts the hydrogen bonds holding duplex DNA together is lacking. Recently, helicase enzymes that unwind duplex RNA and DNA.RNA hybrids have been described. In some cases, these are old enzymes with new activities. In other cases, these are new enzymes only recently discovered. The significance of these reactions in the cell remains to be clarified. However, with the availability of significant amounts of these enzymes in a highly purified state, and mutant alleles in most of the genes encoding them, the answers to these questions should be forthcoming. The variety of helicases found in E. coli, and the myriad processes these enzymes are involved in, were perhaps unexpected. It seems likely that an equally large number of helicases will be discovered in eukaryotic cells. In fact, several helicases have been identified and purified from eukaryotic sources ranging from viruses to mouse cells (4-13, 227-234). Many of these helicases have been suggested to have roles in DNA replication, although this remains to be shown conclusively. Helicases with roles in DNA repair, recombination, and other aspects of DNA metabolism are likely to be forthcoming as we learn more about these processes in eukaryotic cells.

Electron microscopic analysis of DNA forks generated by Escherichia coli DNA helicase II

T7 phage DNA eroded with lambda exonuclease (to create 3'-protruding strands) or exonuclease III (to create 5'-protruding strands) was treated under unwinding assay conditions with DNA helicase II. Single-stranded DNA-binding protein (of Escherichia coli or phage T4) was added to disentangle the denatured DNA and the complexes were examined in the electron microscope. DNA helicase II complexes filtered through a gel column before assay retain the ability to generate forks suggesting that DNA helicase II unwinds in a preformed complex by translocating along the bound DNA strand. The enzyme initiates preferentially at the ends of the lambda-exonuclease-treated duplexes and is found at a fork on the initially protruding strand. It also initiates at the ends of the exonuclease-III-treated duplexes where, as with approximately 5% of the forks traceable back to a single-stranded gap, it is found on the initially recessed strand. The results are consistent with the view that DNA helicase II unwinds in the 3'-5' direction relative to the bound strand. They also confirm that the enzyme can initiate at the end of a fully base-paired strand. At a fork, DNA helicase II is bound as a tract of molecules of approximately 110 nm in length. Tracts of enzyme assemble from non-cooperatively bound molecules in the presence of ATP. During unwinding, DNA helicase II apparently can translocate to the displaced strand which conceivably can deplete the leading strand of the enzyme. Continued adsorption of enzyme to DNA might replenish forks arrested by strand switch of the unwinding enzyme.

Direction of the DNA-unwinding reaction catalysed by Escherichia coli DNA helicase II

The direction of the DNA-unwinding reaction catalysed by Escherichia coli DNA helicase II was studied using gapped linear DNA molecules with short duplex ends as substrate. The results suggest that DNA helicase II unwinds with 3'-5' polarity relative to the single strand of the DNA partial duplex. At high enzyme DNA ratio the enzyme also unwinds the duplex connected to the 3' end of the single strand and, as further studies show, fully duplex linear DNA. The fraction of DNA unwound decreases as the length of the duplex substrate increases. The preference of DNA helicase II for a short duplex can obscure the fact that the typical substrate is duplex connected to the 5' end of a single strand.

Nucleotide excision repair in Escherichia coli

One of the best-studied DNA repair pathways is nucleotide excision repair, a process consisting of DNA damage recognition, incision, excision, repair resynthesis, and DNA ligation. Escherichia coli has served as a model organism for the study of this process. Recently, many of the proteins that mediate E. coli nucleotide excision have been purified to homogeneity; this had led to a molecular description of this repair pathway. One of the key repair enzymes of this pathway is the UvrABC nuclease complex. The individual subunits of this enzyme cooperate in a complex series of partial reactions to bind to and incise the DNA near a damaged nucleotide. The UvrABC complex displays a remarkable substrate diversity. Defining the structural features of DNA lesions that provide the specificity for damage recognition by the UvrABC complex is of great importance, since it represents a unique form of protein-DNA interaction. Using a number of in vitro assays, researchers have been able to elucidate the action mechanism of the UvrABC nuclease complex. Current research is devoted to understanding how these complex events are mediated within the living cell.

Two-quantum UV photochemistry of nucleic acids: comparison with conventional low-intensity UV photochemistry and radiation chemistry

The action of high-intensity laser u.v. radiation on nucleic acid molecules and their constituents in vitro and in vivo is compared with the results of low-intensity u.v. photolysis and gamma-radiolysis.

Mutations in uvrD induce the SOS response in Escherichia coli

We have isolated three new mutations in uvrD that increase expression of the Escherichia coli SOS response in the absence of DNA damage. Like other uvrD (DNA helicase II) mutants, these strains are sensitive to UV irradiation and have high spontaneous mutation frequencies. Complementation studies with uvrD+ showed that UV sensitivity and spontaneous mutator activity were recessive in these new mutants. The SOS-induction phenotype, however, was not completely complemented, which indicated that the mutant proteins were functioning in some capacity. The viability of one of the mutants in combination with rep-5 suggests that the protein is functional in DNA replication. We suggest that these mutant proteins are deficient in DNA repair activities (since UV sensitivity is complemented) but are able to participate in DNA replication. We believe that defective DNA replication in these mutants increases SOS expression.

Intragenic suppression in the uvrD gene of Escherichia coli. I. Temperature-sensitive uvrD mutations

A temperature-sensitive uvrD mutant, HD323 uvrD4, was isolated from the uvrD mutant HD4 uvrD3. The temperature sensitivity of the uvrD4 gene product was reversible. The suppressor mutation uvrD44 which rendered the uvrD3 mutant temperature-sensitive could be separated from the uvrD3 mutation by replacing the PstI fragment, which encodes the C-terminal half of the UvrD protein. The uvrD44 mutation was found to make host bacteria lethal at non-permissive temperatures only when cloned on a low copy vector pMF3. The nucleotide sequence of the uvrD3 and uvrD4 mutant genes was determined. The nucleotide change found in the uvrD3 at +1235, GAA to AAA, only alters the amino acid sequence from Glu at 387 to Lys. The uvrD44 has another nucleotide change at +1859, GAA to AAA (Glu at 595 to Lys), which is considered to be the suppressor mutation uvrD44.

Phototoxic potential of afloqualone, a quinazolinone derivative, as determined by photosensitized inactivation of bacteriophage

Effect of UV-A irradiation on bacteriophage lambda in the presence of afloqualone (AQ) was examined to obtain in vitro evidence for phototoxic potential of AQ, a centrally acting muscle relaxant. Neither AQ itself nor the long-lived photoproducts affected viability of the phage, but the phage was inactivated when it was irradiated in the presence of the drug. Photosensitized inactivation was efficiently repressed by the presence of radical scavengers such as hydroquinone, cysteamine and cystein but not by D-mannitol, benzoate, formate and dimethyl sulfoxide (.OH scavengers). Methionine also inhibited inactivation as well. Sodium azide and tryptophan followed them, but 1,4-diazabicyclo[2.2.2]octaine (DABCO) did not reduce the inactivation rate. Deuterium effect was not observed. AQ-sensitized photoinactivation occurred even under anoxic conditions although the rate was lower than under aerobic conditions. In view of these results, Type I process is more suitable for explanation of AQ-sensitized photoinactivation than Type II process.

Differential suppressor effects of the ssb-1 and ssb-113 alleles on uvrD mutator of Escherichia coli in DNA repair and mutagenesis

We have constructed double mutants carrying either ssb-1 or ssb-113 alleles, which encode temperature-sensitive single strand DNA binding proteins (SSB), and the uvrD::Tn5 allele causing deficiency in DNA helicase II, and have examined sensitivity to ultraviolet light (UV), recombination and spontaneous as well as UV-induced mutagenesis. We have found in a recA+ background that (i) none of the ssb uvrD double mutants was more sensitive to UV than either single mutant; (ii) the ssb-1 allele partially suppressed the strong UV sensitivity of uvrD::Tn5 mutants; (iii) in the recA730 background with constitutive SOS expression, the ssb-1 and ssb-113 alleles suppressed the strong UV-sensitivity caused by the uvrD::Tn5 mutation; (iv) in ssb-113 mutants, the level of recombination was reduced only 10-fold but 100-fold in ssb-1 mutants, showing that there was no correlation between the DNA repair deficiency and the recombination deficiency; (v) the hyper-recombination phenotype of the uvrD::Tn5 mutant was suppressed by the addition of either the ssb-1 or the ssb-113 allele; (vi) no addition of the spontaneous mutator effects promoted by the uvrD::Tn5 and the ssb-113 alleles was observed. These results suggest a possible functional interaction between SSB and Helicase II in DNA repair and mutagenesis.

Phototoxic potential of mequitazine, a phenothiazine derivative, as determined by the photosensitized action on microbiological systems

In order to determine phototoxic potential of mequitazine (MQZ), a phenothiazine derivative, in vitro tests were attempted using microbiological systems. When Escherichia coli was irradiated with ultraviolet-A light in the presence of MQZ, the surviving fraction was decreased with increasing fluence. Irradiation of bacteriophage lambda in the presence of the drug decreased the surviving fraction as well. Possible targets for the photosensitized action in these systems were discussed.

The influence of repair systems on the presence of sensitive and resistant fractions in the relation of survival of colony-forming ability in Escherichia coli to UV exposure

In the experimentally observed relationship between survival of colony-forming ability and the amount of exposure to ultraviolet light, two characteristics are generally found. First, sensitive and resistant components often show. Second, there is often a shouldered character to the survival. We present evidence that the first is largely due to the presence of active replication forks in the genome, and that the second is related to the operation of the recombinational repair system. We are able to describe our data in terms of a superposition of single and multiple-hit fractions and to show that the latter are greatly increased, in excision-repair-competent strains, by prevention of protein synthesis for 1 h prior to irradiation. Applying this analysis and treatment to a number of mutant strains enables us to make suggestions as to the interaction between recombinational and excision repair.

Primary structure of the RAD52 gene in Saccharomyces cerevisiae

The RAD52 gene of Saccharomyces cerevisiae, which is involved in genetic recombination and DNA repair, was cloned by transformation of rad52-1 mutant cells to methyl methanesulfonate resistance with BamHI fragments of Rad+ genomic DNA inserted into the Escherichia coli-S. cerevisiae shuttle vector YRp7. A plasmid carrying a 2.0-kilobase BamHI fragment was found to partially complement methyl methanesulfonate sensitivity of the rad52-1 mutant. By using this fragment as a hybridization probe, a plasmid that fully complemented the methyl methanesulfonate sensitivity of the mutant was isolated, which carries a 3.3-kilobase SalI fragment containing most of the 2.0-kilobase BamHI fragment. Analysis of the nucleotide sequence of the SalI fragment revealed the presence of a large open reading frame of 1,512 nucleotides. The rad52-1 mutant DNA has a single-base change in this reading frame, which leads to an amino acid substitution. Analysis of mRNA synthesized in yeast by the S1 mapping technique disclosed possible transcription initiation and termination points of the RAD52 gene and suggested formation of the gene product without splicing of the transcript.

Stimulation of the UvrABC enzyme-catalyzed repair reactions by the UvrD protein (DNA helicase II)

An in vitro assay system was constructed using highly purified preparations of UvrA, UvrB, UvrC, UvrD proteins and DNA polymerase I, the objective being to analyse the role of UvrD protein in excision repair of UV-induced DNA damage. UvrABC enzyme-initiated repair synthesis was greatly enhanced by the addition of UvrD protein to the reaction mixture. Further analysis revealed that UvrD protein stimulated introduction of strand breaks in irradiated DNA by UvrABC enzyme but had no effect on the DNA polymerase I reaction. Thus, the site of action of UvrD protein is probably at the incision-excision step and not in later steps in excision repair.

Single-strand breakage of DNA in UV-irradiated uvrA, uvrB, and uvrC mutants of Escherichia coli

We transduced the uvrA6, uvrB5, uvrC34, and uvrC56 markers from the original mutagenized strains into an HF4714 background. Although in the original mutagenized strains uvrA6 cells are more UV sensitive than uvrB5 and uvrC34 cells, in the new background no significant difference in UV sensitivity is observed among uvrA6, uvrB5, and uvrC34 cells. No DNA single-strand breaks are detected in UV-irradiated uvrA6 or uvrB5 cells, whereas in contrast a significant number of single-strand breaks are detected in both UV-irradiated uvrC34 and uvrC56 cells. The number of single-strand breaks in these cells reaches a plateau at 20-J/m2 irradiation. Since these single-strand breaks can be detected by both alkaline sucrose and neutral formamide-sucrose gradient sedimentation, we concluded that the single-strand breaks observed in UV-irradiated uvrC cells are due to phosphodiester bond interruptions in DNA and are not due to apurinic/apyrimidinic sites.

Molecular cloning and characterization of the alkB gene of Escherichia coli

Using methods of in vitro recombination we constructed hybrid plasmids that can suppress the increased methylmethane sulfonate sensitivity caused by alkB mutation. Since the cloned DNA fragment was mapped at 47 min on the Escherichia coli K12 genetic map, an area where the alkB gene is located, we concluded that the cloned DNA fragment contains the alkB gene itself but not other genes that suppress alkB mutation. Specific labeling of plasmid-encoded proteins by the maxicell method revealed that the alkB codes for a polypeptide with a molecular weight of about 27,000. Introduction of a small deletion into the alkB region of the bacterial chromosome resulted in inactivation of both the alkB and ada genes, thereby suggesting that the two genes are adjacent on the E. coli chromosome.

The effect of inhibition of protein synthesis on UV-irradiated Escherichia coli uvrE cells

The uvrE (E. coli KS 114) cells carry a mutation in the gene that codes for helicase II. This is the protein responsible for replicative unwinding of double-helical DNA. The repair mode of such cells may be altered as compared with the wild type. The survival of uvrE cells during postirradiation incubation under inhibition of de novo protein synthesis was increased which indicates that this process of repair in uvrE cells is mediated by constitutive proteins and does not require any inducible products but takes a certain time. This inhibition of de novo protein synthesis causes also an inhibition of dimer excision, an increase of the parental DNA degradation and a decrease of parental and daughter DNA molar mass. On the other hand, it seems that induced proteins are formed in uvrE cells after UV irradiation but their influence is low in inducible repair and they can act only under conditions of complete protein synthesis.

Primary structure of the RAD52 gene in Saccharomyces cerevisiae

The RAD52 gene of Saccharomyces cerevisiae, which is involved in genetic recombination and DNA repair, was cloned by transformation of rad52-1 mutant cells to methyl methanesulfonate resistance with BamHI fragments of Rad+ genomic DNA inserted into the Escherichia coli-S. cerevisiae shuttle vector YRp7. A plasmid carrying a 2.0-kilobase BamHI fragment was found to partially complement methyl methanesulfonate sensitivity of the rad52-1 mutant. By using this fragment as a hybridization probe, a plasmid that fully complemented the methyl methanesulfonate sensitivity of the mutant was isolated, which carries a 3.3-kilobase SalI fragment containing most of the 2.0-kilobase BamHI fragment. Analysis of the nucleotide sequence of the SalI fragment revealed the presence of a large open reading frame of 1,512 nucleotides. The rad52-1 mutant DNA has a single-base change in this reading frame, which leads to an amino acid substitution. Analysis of mRNA synthesized in yeast by the S1 mapping technique disclosed possible transcription initiation and termination points of the RAD52 gene and suggested formation of the gene product without splicing of the transcript.

Gene responsible for protecting Escherichia coli from sodium dodecyl sulfate and toluidine blue plus light

Escherichia coli cells were killed by visible light irradiation in the presence of the photosensitizing dye, toluidine blue. Two uvrB mutant strains of E. coli K-12 (AB1885 and N3-1) were much more sensitive than the isogenic uvrA and uvrC strains to treatment with toluidine blue plus light, suggesting that the uvrB+ gene product was involved in repair of DNA damage induced by the treatment. The uvrB+ gene cloned in a high- or low-copy-number plasmid was transformed into the uvrB strain (AB1885). Although all the transformants showed the same resistance as its wild-type strain (AB1157) to UV irradiation, they were as sensitive as AB1885 was to treatment with toluidine blue plus light. The two uvrB strains were more sensitive to sodium dodecyl sulfate than the other strains, suggesting that these strains had a defect in the cell surface. A sodium dodecyl sulfate-resistant revertant obtained from AB1885 was more resistant than AB1885 was to treatment with toluidine blue plus light. The two uvrB strains (AB1885 and N3-1) appear to have a defective gene (tentatively called dvl) different from uvrB. Its map position was around 7 min on the E. coli map.

Isolation and genetic characterization of a thymineless death-resistant mutant of Escherichia coli K12: identification of a new mutation (recQ1) that blocks the RecF recombination pathway

An Escherichia coli K12 mutant resistant to thymineless death (TLD) was isolated, and its genetic analysis led us to identify a new mutation (recQ1) located between corA and metE on the standard linkage map. The mutation was found to result in increased sensitivity to ultraviolet light and deficiency in conjugational recombination when placed in the recBC sbcB background, indicating that it blocked the RecF pathway of recombination. It seemed likely that this mutation is also capable of causing partial resistance to TLD, but we reserve the possibility of a separate mutation closely linked to recQ1 giving rise to this phenotype. The original mutant was shown to carry an additional mutation probably in the vicinity of the uhp locus, which was also required for the full TLD resistance of the mutant to be expressed.

Repair-defective mutants of Alteromonas espejiana, the host for bacteriophage PM2

The in vivo repair processes of Alteromonas espejiana, the host for bacteriophage PM2, were characterized, and UV- and methyl methanesulfonate (MMS)-sensitive mutants were isolated. Wild-type A. espejiana cells were capable of photoreactivation, excision, recombination, and inducible repair. There was no detectable pyrimidine dimer-DNA N-glycosylase activity, and pyrimidine dimer removal appeared to occur by a pathway analogous to the Escherichia coli Uvr pathway. The UV- and MMS-sensitive mutants of A. espejiana included three groups, each containing at least one mutation involved with excision, recombination, or inducible repair. One group that was UV sensitive but not sensitive to MMS or X rays showed a decreased ability to excise pyrimidine dimers. Mutants in this group were also sensitive to psoralen plus near-UV light and were phenotypically analogous to the E. coli uvr mutants. A second group was UV and MMS sensitive but not sensitive to X rays and appeared to contain mutations in a gene(s) involved in recombination repair. These recombination-deficient mutants differed from the E. coli rec mutants, which are MMS and X-ray sensitive. The third group of A. espejiana mutants was sensitive to UV, MMS, and X rays. These mutants were recombination deficient, lacked inducible repair, and were phenotypically similar to E. coli recA mutants.

Transcription of the uvrD gene of Escherichia coli is controlled by the lexA repressor and by attenuation

The nucleotide sequence of the control region and the presumptive N-terminal portion of the uvrD gene of Escherichia coli K-12 has been determined. The 1190 base pairs of DNA examined include the likely coding sequence for the first 258 amino acids of the uvrD protein. The transcription promoter for the uvrD gene was identified upstream of the protein coding region. Synthesis of messenger RNA in vitro from this promoter was inhibited by purified lexA protein. The lexA protein was found to bind downstream from the promoter at a sequence, CTGTATATATACCCAG, which is homologous to other known lexA protein binding sites. In the absence of the lexA protein, approximately half of the messages initiated in vitro at the uvrD promoter terminate after about 60 nucleotides at a sequence which resembles a rho-independent terminator. These results indicate that the uvrD gene is induced during the SOS response, and that the expression of the gene may also be regulated by transcription attenuation.

Defective complex formation between single-stranded DNA and mutant recA430 or recA1 protein of Escherichia coli

The formation of a complex between recA protein and single-stranded DNA (ssDNA) was studied by filter-binding assays and sucrose density gradient centrifugation. In the presence of excess ATP, the wild-type recA protein formed salt-resistant complexes with ssDNA. One mutant recA430 (lexB30) protein bound to ssDNA slightly less effectively than wild-type protein, and the complexes had lost the stability to salt. Another mutant recA1 protein did not form complexes with ssDNA. On the other hand, in the absence of ATP, all proteins bound to ssDNA with the same efficiency, but all of the complexes were unstable in the presence of salt. The hybridization reaction in which homologous ssDNA is converted to double-stranded DNA (dsDNA) catalyzed by the recA430 protein was more sensitive to salt than that catalyzed by the wild-type protein. No hybridization reaction was found with the recA1 protein.

recA+ gene-dependent regulation of a uvrD::lacZ fusion in Escherichia coli K12

The expression of the Escherichia coli uvrD gene was studied with a uvrD::Mud(Aprlac) insertion mutant. The results indicate that it is inducible by DNA damaging agents in a recA+ gene-dependent manner.