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

UvrD-like helicase Hmi1 Has an ATP independent role in yeast mitochondrial DNA maintenance

Hmi1 is a UvrD-like DNA helicase required for the maintenance of the yeast Saccharomyces cerevisiae mitochondrial DNA (mtDNA). Deletion of the HMI1 ORF leads to the formation of respiration-deficient petite mutants, which either contain a short fragment of mtDNA arranged in tandem repeats or lack mtDNA completely. Here we characterize point mutants of the helicase designed to target the ATPase or ssDNA binding activity and show that these mutations do not separately lead to complete loss of the Hmi1 function. The mutant strains support ATP production via oxidative phosphorylation and enable us to directly analyze the impact of both activities on the stability of wild-type mtDNA in this petite-positive yeast. Our data reveal that Hmi1 mutants affecting ssDNA binding display a stronger defect in the maintenance of mtDNA compared to the mutants of ATP binding/hydrolysis. Hmi1 mutants impaired in ssDNA binding demonstrate sensitivity to UV irradiation and lower levels of Cox2 encoded by the mitochondrial genome. This suggests a complex and multifarious role for Hmi1 in mtDNA maintenance-linked transactions, some of which do not require the ATP-dependent helicase activity.

Simplified modeling of E. coli mortality after genome damage induced by UV-C light exposure

UV light is a group of high-energy waves from the electromagnetic spectrum. There are three types of UV radiations: UV-A, -B and -C. UV-C light are the highest in energy, but most are retained by the ozone layer. UV-A and -B reach the earth's surface and cause damage on living organisms, being considered as mutagenic physical agents. Numerous test models are used to study UV mutagenicity; some include special lamps, cell cultures and mathematical modeling. Mercury lamps are affordable and useful sources of UV-C light due to their emission at near the maximum absorption peak of nucleic acids. E. coli cultures are widely used because they have DNA-damage and -repairing mechanisms fairly similar to humans. In here we present two simple models that describe UV-C light incidence on a genome matrix, using fundamental quantum-mechanical concepts and considering light as a particle with a discontinuous distribution. To test the accuracy of our equations, stationary phase cultures of several E. coli strains were exposed to UV-C light in 30 s-intervals. Surviving CFUs were counted and survival/mortality curves were constructed. These graphs adjusted with high goodness of fit to the regression predictions. Results were also analyzed using three main parameters: quantum yield, specific speed and time of mortality.

Rep and UvrD Antagonize One Another at Stalled Replication Forks and This Is Exacerbated by SSB

The Rep and UvrD DNA helicases are proposed to act at stalled DNA replication forks to facilitate replication restart when RNA polymerase stalls forks. To clarify the role of these DNA helicases in fork rescue, we used a coupled spectrophotometric ATPase assay to determine how they act on model fork substrates. For both enzymes, activity is low on regressed fork structures, suggesting that they act prior to the regression step that generates a Holliday junction. In fact, the preferred cofactors for both enzymes are forks with a gap in the nascent leading strand, consistent with the 3'-5' direction of translocation. Surprisingly, for Rep, this specificity is altered in the presence of stoichiometric amounts of a single-strand DNA-binding protein (SSB) relative to a fork with a gap in the nascent lagging strand. Even though Rep and UvrD are similar in structure, elevated concentrations of SSB inhibit Rep, but they have little to no effect on UvrD. Furthermore, Rep and UvrD antagonize one another at a fork. This is surprising given that these helicases have been shown to form a heterodimer and are proposed to act together to rescue an RNA polymerase-stalled fork. Consequently, the results herein indicate that although Rep and UvrD can act on similar fork substrates, they cannot function on the same fork simultaneously.

Limited Capacity or Involvement of Excision Repair, Double-Strand Breaks, or Translesion Synthesis for Psoralen Cross-Link Repair in Escherichia coli

DNA interstrand cross-links are complex lesions that covalently bind complementary strands of DNA and whose mechanism of repair remains poorly understood. In Escherichia coli, several gene products have been proposed to be involved in cross-link repair based on the hypersensitivity of mutants to cross-linking agents. However, cross-linking agents induce several forms of DNA damage, making it challenging to attribute mutant hypersensitivity specifically to interstrand cross-links. To address this, we compared the survival of UVA-irradiated repair mutants in the presence of 8-methoxypsoralen-which forms interstrand cross-links and monoadducts-to that of angelicin-a congener forming only monoadducts. We show that incision by nucleotide excision repair is not required for resistance to interstrand cross-links. In addition, neither RecN nor DNA polymerases II, IV, or V is required for interstrand cross-link survival, arguing against models that involve critical roles for double-strand break repair or translesion synthesis in the repair process. Finally, estimates based on Southern analysis of DNA fragments in alkali agarose gels indicate that lethality occurs in wild-type cells at doses producing as few as one to two interstrand cross-links per genome. These observations suggest that E. coli may lack an efficient repair mechanism for this form of damage.

The structure and function of an RNA polymerase interaction domain in the PcrA/UvrD helicase

The PcrA/UvrD helicase functions in multiple pathways that promote bacterial genome stability including the suppression of conflicts between replication and transcription and facilitating the repair of transcribed DNA. The reported ability of PcrA/UvrD to bind and backtrack RNA polymerase (1,2) might be relevant to these functions, but the structural basis for this activity is poorly understood. In this work, we define a minimal RNA polymerase interaction domain in PcrA, and report its crystal structure at 1.5 Å resolution. The domain adopts a Tudor-like fold that is similar to other RNA polymerase interaction domains, including that of the prototype transcription-repair coupling factor Mfd. Removal or mutation of the interaction domain reduces the ability of PcrA/UvrD to interact with and to remodel RNA polymerase complexes in vitro. The implications of this work for our understanding of the role of PcrA/UvrD at the interface of DNA replication, transcription and repair are discussed.

A novel papillation assay for the identification of genes affecting mutation rate in Pseudomonas putida and other pseudomonads

Formation of microcolonies (papillae) permits easy visual screening of mutational events occurring in single colonies of bacteria. In this study, we have established a novel papillation assay employable in a wide range of pseudomonads including Pseudomonas aeruginosa and Pseudomonas putida for monitoring mutation frequency in distinct colonies. With the aid of this assay, we conducted a genome-wide search for the factors affecting mutation frequency in P. putida. Screening ∼27,000 transposon mutants for increased mutation frequency allowed us to identify 34 repeatedly targeted genes. In addition to genes involved in DNA replication and repair, we identified genes participating in metabolism and transport of secondary metabolites, cell motility, and cell wall synthesis. The highest effect on mutant frequency was observed when truA (tRNA pseudouridine synthase), mpl (UDP-N-acetylmuramate-alanine ligase) or gacS (multi-sensor hybrid histidine kinase) were inactivated. Inactivation of truA elevated the mutant frequency only in growing cells, while the deficiency of gacS affected mainly stationary-phase mutagenesis. Thus, our results demonstrate the feasibility of the assay for isolating mutants with elevated mutagenesis in growing as well as stationary-phase bacteria.

Single Strand Annealing Plays a Major Role in RecA-Independent Recombination between Repeated Sequences in the Radioresistant Deinococcus radiodurans Bacterium

The bacterium Deinococcus radiodurans is one of the most radioresistant organisms known. It is able to reconstruct a functional genome from hundreds of radiation-induced chromosomal fragments. Our work aims to highlight the genes involved in recombination between 438 bp direct repeats separated by intervening sequences of various lengths ranging from 1,479 bp to 10,500 bp to restore a functional tetA gene in the presence or absence of radiation-induced DNA double strand breaks. The frequency of spontaneous deletion events between the chromosomal direct repeats were the same in recA+ and in ΔrecA, ΔrecF, and ΔrecO bacteria, whereas recombination between chromosomal and plasmid DNA was shown to be strictly dependent on the RecA and RecF proteins. The presence of mutations in one of the repeated sequence reduced, in a MutS-dependent manner, the frequency of the deletion events. The distance between the repeats did not influence the frequencies of deletion events in recA⁺ as well in ΔrecA bacteria. The absence of the UvrD protein stimulated the recombination between the direct repeats whereas the absence of the DdrB protein, previously shown to be involved in DNA double strand break repair through a single strand annealing (SSA) pathway, strongly reduces the frequency of RecA- (and RecO-) independent deletions events. The absence of the DdrB protein also increased the lethal sectoring of cells devoid of RecA or RecO protein. γ-irradiation of recA⁺ cells increased about 10-fold the frequencies of the deletion events, but at a lesser extend in cells devoid of the DdrB protein. Altogether, our results suggest a major role of single strand annealing in DNA repeat deletion events in bacteria devoid of the RecA protein, and also in recA⁺ bacteria exposed to ionizing radiation.

Deinococcus radiodurans is known for its exceptional ability to tolerate exposure to DNA damaging agents and, in particular, to very high doses of ionizing radiation. This exceptional radioresistance results from many features including efficient DNA double strand break repair. Here, we examine genome stability in D. radiodurans before and after exposure to ionizing radiation. Rearrangements between repeated sequences are a major source of genome instability and can be deleterious to the organism. Thus, we measured the frequency of recombination between direct repeats separated by intervening sequences of various lengths in the presence or absence of radiation-induced DNA double strand breaks. Strikingly, we showed that the frequency of deletions was as high in strains devoid of the RecA, RecF or RecO proteins as in wild type bacteria, suggesting a very efficient RecA-independent process able to generate genome rearrangements. Our results suggest that single strand annealing may play a major role in genome instability in the absence of homologous recombination.

The UvrD303 hyper-helicase exhibits increased processivity

DNA helicases use energy derived from nucleoside 5'-triphosphate hydrolysis to catalyze the separation of double-stranded DNA into single-stranded intermediates for replication, recombination, and repair. Escherichia coli helicase II (UvrD) functions in methyl-directed mismatch repair, nucleotide excision repair, and homologous recombination. A previously discovered 2-amino acid substitution of residues 403 and 404 (both Asp → Ala) in the 2B subdomain of UvrD (uvrD303) confers an antimutator and UV-sensitive phenotype on cells expressing this allele. The purified protein exhibits a "hyper-helicase" unwinding activity in vitro. Using rapid quench, pre-steady state kinetic experiments we show the increased helicase activity of UvrD303 is due to an increase in the processivity of the unwinding reaction. We suggest that this mutation in the 2B subdomain results in a weakened interaction with the 1B subdomain, allowing the helicase to adopt a more open conformation. This is consistent with the idea that the 2B subdomain may have an autoregulatory role. The UvrD303 mutation may enable the helicase to unwind DNA via a "strand displacement" mechanism, which is similar to the mechanism used to processively translocate along single-stranded DNA, and the increased unwinding processivity may contribute directly to the antimutator phenotype.

Direct DNA Lesion Reversal and Excision Repair in Escherichia coli

Cellular DNA is constantly challenged by various endogenous and exogenous genotoxic factors that inevitably lead to DNA damage: structural and chemical modifications of primary DNA sequence. These DNA lesions are either cytotoxic, because they block DNA replication and transcription, or mutagenic due to the miscoding nature of the DNA modifications, or both, and are believed to contribute to cell lethality and mutagenesis. Studies on DNA repair in Escherichia coli spearheaded formulation of principal strategies to counteract DNA damage and mutagenesis, such as: direct lesion reversal, DNA excision repair, mismatch and recombinational repair and genotoxic stress signalling pathways. These DNA repair pathways are universal among cellular organisms. Mechanistic principles used for each repair strategies are fundamentally different. Direct lesion reversal removes DNA damage without need for excision and de novo DNA synthesis, whereas DNA excision repair that includes pathways such as base excision, nucleotide excision, alternative excision and mismatch repair, proceeds through phosphodiester bond breakage, de novo DNA synthesis and ligation. Cell signalling systems, such as adaptive and oxidative stress responses, although not DNA repair pathways per se, are nevertheless essential to counteract DNA damage and mutagenesis. The present review focuses on the nature of DNA damage, direct lesion reversal, DNA excision repair pathways and adaptive and oxidative stress responses in E. coli.

Functional characterization of UvrD helicases from Haemophilus influenzae and Helicobacter pylori

Haemophilus influenzae and Helicobacter pylori are major bacterial pathogens that face high levels of genotoxic stress within their host. UvrD, a ubiquitous bacterial helicase that plays important roles in multiple DNA metabolic pathways, is essential for genome stability and might, therefore, be crucial in bacterial physiology and pathogenesis. In this study, the functional characterization of UvrD helicase from Haemophilus influenzae and Helicobacter pylori is reported. UvrD from Haemophilus influenzae (HiUvrD) and Helicobacter pylori (HpUvrD) exhibit strong single-stranded DNA-specific ATPase and 3'-5' helicase activities. Mutation of highly conserved arginine (R288) in HiUvrD and glutamate (E206) in HpUvrD abrogated their activities. Both the proteins were able to bind and unwind a variety of DNA structures including duplexes with strand discontinuities and branches, three- and four-way junctions that underpin their role in DNA replication, repair and recombination. HiUvrD required a minimum of 12 nucleotides, whereas HpUvrD preferred 20 or more nucleotides of 3'-single-stranded DNA tail for efficient unwinding of duplex DNA. Interestingly, HpUvrD was able to hydrolyze and utilize GTP for its helicase activity although not as effectively as ATP, which has not been reported to date for UvrD characterized from other organisms. HiUvrD and HpUvrD were found to exist predominantly as monomers in solution together with multimeric forms. Noticeably, deletion of distal C-terminal 48 amino acid residues disrupted the oligomerization of HiUvrD, whereas deletion of 63 amino acids from C-terminus of HpUvrD had no effect on its oligomerization. This study presents the characteristic features and comparative analysis of Haemophilus influenzae and Helicobacter pylori UvrD, and constitutes the basis for understanding the role of UvrD in the biology and virulence of these pathogens.

Important role for Mycobacterium tuberculosis UvrD1 in pathogenesis and persistence apart from its function in nucleotide excision repair

Mycobacterium tuberculosis survives and replicates in macrophages, where it is exposed to reactive oxygen and nitrogen species that damage DNA. In this study, we investigated the roles of UvrA and UvrD1, thought to be parts of the nucleotide excision repair pathway of M. tuberculosis. Strains in which uvrD1 was inactivated either alone or in conjunction with uvrA were constructed. Inactivation of uvrD1 resulted in a small colony phenotype, although growth in liquid culture was not significantly affected. The sensitivity of the mutant strains to UV irradiation and to mitomycin C highlighted the importance of the targeted genes for nucleotide excision repair. The mutant strains all exhibited heightened susceptibility to representatives of reactive oxygen intermediates (ROI) and reactive nitrogen intermediates (RNI). The uvrD1 and the uvrA uvrD1 mutants showed decreased intracellular multiplication following infection of macrophages. Most importantly, the uvrA uvrD1 mutant was markedly attenuated following infection of mice by either the aerosol or the intravenous route.

Superfamily I helicases as modular components of DNA-processing machines

Helicases are a ubiquitous and abundant group of motor proteins that couple NTP binding and hydrolysis to processive unwinding of nucleic acids. By targeting this activity to a wide range of specific substrates, and by coupling it with other catalytic functionality, helicases fulfil diverse roles in virtually all aspects of nucleic acid metabolism. The present review takes a look back at our efforts to elucidate the molecular mechanisms of UvrD-like DNA helicases. Using these well-studied enzymes as examples, we also discuss how helicases are programmed by interactions with partner proteins to participate in specific cellular functions.

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.

Characterization of the mycobacterial NER system reveals novel functions of the uvrD1 helicase

In this study, we investigated the role of the nucleotide excision repair (NER) pathway in mycobacterial DNA repair. Mycobacterium smegmatis lacking the NER excinuclease component uvrB or the helicase uvrD1 gene and a double knockout lacking both genes were constructed, and their sensitivities to a series of DNA-damaging agents were analyzed. As anticipated, the mycobacterial NER system was shown to be involved in the processing of bulky DNA adducts and interstrand cross-links. In addition, it could be shown to exert a protective effect against oxidizing and nitrosating agents. Interestingly, inactivation of uvrB and uvrD1 significantly increased marker integration frequencies in gene conversion assays. This implies that in mycobacteria (which lack the postreplicative mismatch repair system) NER, and particularly the UvrD1 helicase, is involved in the processing of a subset of recombination-associated mismatches.

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.

Regulation of bacterial RecA protein function

The RecA protein is a recombinase functioning in recombinational DNA repair in bacteria. RecA is regulated at many levels. The expression of the recA gene is regulated within the SOS response. The activity of the RecA protein itself is autoregulated by its own C-terminus. RecA is also regulated by the action of other proteins. To date, these include the RecF, RecO, RecR, DinI, RecX, RdgC, PsiB, and UvrD proteins. The SSB protein also indirectly affects RecA function by competing for ssDNA binding sites. The RecO and RecR, and possibly the RecF proteins, all facilitate RecA loading onto SSB-coated ssDNA. The RecX protein blocks RecA filament extension, and may have other effects on RecA activity. The DinI protein stabilizes RecA filaments. The RdgC protein binds to dsDNA and blocks RecA access to dsDNA. The PsiB protein, encoded by F plasmids, is uncharacterized, but may inhibit RecA in some manner. The UvrD helicase removes RecA filaments from RecA. All of these proteins function in a network that determines where and how RecA functions. Additional regulatory proteins may remain to be discovered. The elaborate regulatory pattern is likely to be reprised for RecA homologues in archaeans and eukaryotes.

RecQ promotes toxic recombination in cells lacking recombination intermediate-removal proteins

The RecQ-helicase family is widespread, is highly conserved, and includes human orthologs that suppress genomic instability and cancer. In vivo, some RecQ homologs promote reduction of steady-state levels of bimolecular recombination intermediates (BRIs), which block chromosome segregation if not resolved. We find that, in vivo, E. coli RecQ can promote the opposite: the net accumulation of BRIs. We report that cells lacking Ruv and UvrD BRI-resolution and -prevention proteins die and display failed chromosome segregation attributable to accumulation of BRIs. Death and segregation failure require RecA and RecF strand exchange proteins. FISH data show that replication is completed during chromosome-segregation failure/death of ruv uvrD recA(Ts) cells. Surprisingly, RecQ (and RecJ) promotes this death. The data imply that RecQ promotes the net accumulation of BRIs in vivo, indicating a second paradigm for the in vivo effect of RecQ-like proteins. The E. coli RecQ paradigm may provide a useful model for some human RecQ homologs.

Characterization of the helicase activity and substrate specificity of Mycobacterium tuberculosis UvrD

UvrD is a helicase that is widely conserved in gram-negative bacteria. A uvrD homologue was identified in Mycobacterium tuberculosis on the basis of the homology of its encoded protein with Escherichia coli UvrD, with which it shares 39% amino acid identity, distributed throughout the protein. The gene was cloned, and a histidine-tagged form of the protein was expressed and purified to homogeneity. The purified protein had in vitro ATPase activity that was dependent upon the presence of DNA. Oligonucleotides as short as four nucleotides were sufficient to promote the ATPase activity. The DNA helicase activity of the enzyme was only fueled by ATP and dATP. UvrD preferentially unwound 3'-single-stranded tailed duplex substrates over 5'-single-stranded ones, indicating that the protein had a duplex-unwinding activity with 3'-to-5' polarity. A 3' single-stranded DNA tail of 18 nucleotides was required for effective unwinding. By using a series of synthetic oligonucleotide substrates, we demonstrated that M. tuberculosis UvrD has an unwinding preference towards nicked DNA duplexes and stalled replication forks, representing the likely sites of action in vivo. The potential role of M. tuberculosis UvrD in maintenance of bacterial genomic integrity makes it a promising target for drug design against M. tuberculosis.

The DNA repair helicase UvrD is essential for replication fork reversal in replication mutants

Replication forks arrested by inactivation of the main Escherichia coli DNA polymerase (polymerase III) are reversed by the annealing of newly synthesized leading- and lagging-strand ends. Reversed forks are reset by the action of RecBC on the DNA double-strand end, and in the absence of RecBC chromosomes are linearized by the Holliday junction resolvase RuvABC. We report here that the UvrD helicase is essential for RuvABC-dependent chromosome linearization in E. coli polymerase III mutants, whereas its partners in DNA repair (UvrA/B and MutL/S) are not. We conclude that UvrD participates in replication fork reversal in E. coli.

Mutations in the E. coli Rep helicase increase the amount of DNA per cell

The mbrA4 mutation confers camphor resistance, severe growth defects and up to a two-fold increase in the amount of chromosomal DNA per cell. The extra DNA is replicated from oriC in a synchronous fashion. Cells containing mbrA4 are more resistant to X-rays, indicating that the extra DNA represents complete or nearly complete chromosomes. I report here that mbrA4 is an unusual allele of the leading strand DNA helicase, Rep. Eight independently isolated alleles of rep(mbrA) contain the same three changes in the rep gene: a G to A at position -44 from the start of the mRNA (+1); an opal stop at codon 142; and a glycine to serine at codon 414 (G414S). My data indicate that rep(mbrA4) is not a null mutation and that the third mutation, G414S, is necessary for camphor resistance, the phenotype associated with increased DNA content per cell. I also show that increase in DNA content does not lead to independently segregating chromosomes.

Answering the Call: Coping with DNA Damage at the Most Inopportune Time

DNA damage incurred during the process of chromosomal replication has a particularly high possibility of resulting in mutagenesis or lethality for the cell. The SOS response of Escherichia coli appears to be well adapted for this particular situation and involves the coordinated up-regulation of genes whose products center upon the tasks of maintaining the integrity of the replication fork when it encounters DNA damage, delaying the replication process (a DNA damage checkpoint), repairing the DNA lesions or allowing replication to occur over these DNA lesions, and then restoring processive replication before the SOS response itself is turned off. Recent advances in the fields of genomics and biochemistry has given a much more comprehensive picture of the timing and coordination of events which allow cells to deal with potentially lethal or mutagenic DNA lesions at the time of chromosomal replication.

The SOS-dependent upregulation of uvrD is not required for efficient nucleotide excision repair of ultraviolet light induced DNA photoproducts in Escherichia coli

We have shown previously that induction of the SOS response is required for efficient nucleotide excision repair (NER) of the major ultraviolet light (UV) induced DNA lesion, the cyclobutane pyrimidine dimer (CPD), but not for repair of 6-4 photoproducts (6-4PP) or for transcription-coupled repair of CPDs [1]. We have proposed that the upregulation of cellular NER capacity occurs in the early stages of the SOS response and enhances the rate of repair of the abundant yet poorly recognized genomic CPDs. The expression of three NER genes, uvrA, uvrB, and uvrD, is upregulated as part of the SOS response. UvrD differs from the others in that it is not involved in lesion recognition but rather in promoting the post-incision steps of NER, including turnover of the UvrBC incision complex. Since uvrC is not induced during the SOS response, its turnover would seem to be of great importance in promoting efficient NER. Here we show that the constitutive level of UvrD is adequate for carrying out efficient NER of both CPDs and 6-4PPs. Thus, the upregulation of uvrA and uvrB genes during the SOS response is sufficient for inducible NER of CPDs. We also show that cells with a limited NER capacity, in this case due to deletion of the uvrD gene, repair 6-4PPs but cannot perform transcription-coupled repair of CPDs, indicating that the 6-4PP is a better substrate for NER than is a CPD targeted for transcription-coupled repair.

lon incompatibility associated with mutations causing SOS induction: null uvrD alleles induce an SOS response in Escherichia coli

The uvrD gene in Escherichia coli encodes a 720-amino-acid 3'-5' DNA helicase which, although nonessential for viability, is required for methyl-directed mismatch repair and nucleotide excision repair and furthermore is believed to participate in recombination and DNA replication. We have shown in this study that null mutations in uvrD are incompatible with lon, the incompatibility being a consequence of the chronic induction of SOS in uvrD strains and the resultant accumulation of the cell septation inhibitor SulA (which is a normal target for degradation by Lon protease). uvrD-lon incompatibility was suppressed by sulA, lexA3(Ind(-)), or recA (Def) mutations. Other mutations, such as priA, dam, polA, and dnaQ (mutD) mutations, which lead to persistent SOS induction, were also lon incompatible. SOS induction was not observed in uvrC and mutH (or mutS) mutants defective, respectively, in excision repair and mismatch repair. Nor was uvrD-mediated SOS induction abolished by mutations in genes that affect mismatch repair (mutH), excision repair (uvrC), or recombination (recB and recF). These data suggest that SOS induction in uvrD mutants is not a consequence of defects in these three pathways. We propose that the UvrD helicase participates in DNA replication to unwind secondary structures on the lagging strand immediately behind the progressing replication fork, and that it is the absence of this function which contributes to SOS induction in uvrD strains.

Cell division, guillotining of dimer chromosomes and SOS induction in resolution mutants (dif, xerC and xerD) of Escherichia coli

We have studied the growth and division of xerC, xerD and dif mutants of Escherichia coli, which are unable to resolve dimer chromosomes. These mutants express the Dif phenotype, which includes reduced viability, SOS induction and filamentation, and abnormal nucleoid morphology. Growth was studied in synchronous cultures and in microcolonies derived from single cells. SOS induction and filamentation commenced after an apparently normal cell division, which sheared unresolved dimer chromosomes. This has been called guillotining. Microcolony analysis demonstrated that cell division in the two daughter cells was inhibited after guillotining, and microcolonies formed that consisted of two filaments lying side by side. Growth of these filaments was severely reduced in hipA+ strains. We propose that guillotining at dif destroys the expression of the adjacent hipBA genes and, in the absence of continued formation of HipB, HipA inhibits growth. The length of the filaments was also affected by SfiA: sfiA dif hipA mutants initially formed filaments, but cell division at the ends of the filaments ultimately produced a number of DNA-negative cells. If SOS induction was blocked by lexA3 (Ind-), filaments did not form, and cell division was not inhibited. However, pedigree analysis of cells in microcolonies demonstrated that lethal sectoring occurred as a result of limited growth and division of dead cells produced by guillotining.

Characterization of the uup locus and its role in transposon excisions and tandem repeat deletions in Escherichia coli

Null mutations in the Escherichia coli uup locus (at 21.8 min) serve to increase the frequency of RecA-independent precise excision of transposable elements such as Tn10 and to reduce the plaque size of bacteriophage Mu (Uup(-) phenotype). By the combined approaches of physical mapping of the mutations, complementation analyses, and protein overexpression from cloned gene fragments, we have demonstrated in this study that the Uup(-) phenotype is the consequence of the absence of expression of the downstream gene (uup) of a two-gene operon, caused either directly by insertions in uup or indirectly by the polar effect of insertions in the upstream gene (ycbY). The promoter for uup was mapped upstream of ycbY by primer extension analysis on cellular RNA, and assays of reporter gene expression indicated that it is a moderately active, constitutive promoter. The uup mutations were also shown to increase, in a RecA-independent manner, the frequencies of nearly precise excision of Tn10 derivatives and of the deletion of one copy of a chromosomal tandem repeat, suggesting the existence of a shared step or intermediate in the pathways of these latter events and that of precise excision. Finally, we found that mutations that increase the frequency of precise excision of Tn10 are divisible into two categories, depending upon whether they did (uup, ssb, polA, and topA) or did not (mutHLS, dam, and uvrD) also increase precise excision frequency of the mini-Tn10 derivatives. It is suggested that the differential response of mini-Tn10 and Tn10 to the second category of mutations is related to the presence, respectively, of perfect and of imperfect terminal inverted repeats in them.

Sister chromatid exchange frequencies in Escherichia coli analyzed by recombination at the dif resolvase site

Sister chromatid exchange (SCE) in Escherichia coli results in the formation of circular dimer chromosomes, which are converted back to monomers by a compensating exchange at the dif resolvase site. Recombination at dif is site specific and can be monitored by utilizing a density label assay that we recently described. To characterize factors affecting SCE frequency, we analyzed dimer resolution at the dif site in a variety of genetic backgrounds and conditions. Recombination at dif was increased by known hyperrecombinogenic mutations such as polA, dut, and uvrD. It was also increased by a fur mutation, which increased oxidative DNA damage. Recombination at dif was eliminated by a recA mutation, reflecting the role of RecA in SCE and virtually all homologous recombination in E. coli. Interestingly, recombination at dif was reduced to approximately half of the wild-type levels by single mutations in either recB or recF, and it was virtually eliminated when both mutations were present. This result demonstrates the importance of both RecBCD and RecF to chromosomal recombination events in wild-type cells.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Site-directed mutations in motif VI of Escherichia coli DNA helicase II result in multiple biochemical defects: evidence for the involvement of motif VI in the coupling of ATPase and DNA binding activities via conformational changes

Two site-directed mutants of Escherichia coli DNA helicase II (UvrD) were constructed to examine the functional significance of motif VI in a superfamily I helicase. Threonine 604 and arginine 605, representing two of the most highly conserved residues in motif VI, were replaced with alanine, generating the mutant alleles uvrD-T604A and uvrD-R605A. Genetic complementation studies indicated that UvrD-T604A, but not UvrD-R605A, functioned in methyl-directed mismatch repair and UvrABC-mediated nucleotide excision repair. Both mutant enzymes were purified and single-stranded DNA (ssDNA)-stimulated ATP hydrolysis, duplex DNA unwinding, and ssDNA binding were studied in the steady-state and compared to wild-type UvrD. UvrD-T604A exhibited a serious defect in ssDNA binding in the absence of nucleotide. However, in the presence of a non-hydrolyzable ATP analog, DNA binding was only slightly compromised. Limited proteolysis experiments suggested that UvrD-T604A had a "looser" conformation and could not undergo conformational changes normally associated with ATP binding/hydrolysis and DNA binding. UvrD-R605A, on the other hand, exhibited nearly normal DNA binding but had a severe defect in ATP hydrolysis (kcat=0.063 s-1 compared to 162 s-1 for UvrD). UvrD-T604A exhibited a much less severe decrease in ATPase activity (kcat=8.8 s-1). The Km for ATP for both mutants was not significantly changed. The results suggest that residues within motif VI of helicase II are essential for multiple biochemical properties associated with the enzyme and that motif VI is potentially involved in conformational changes related to the coupling of ATPase and DNA binding activities.

Evidence for a physical interaction between the Escherichia coli methyl-directed mismatch repair proteins MutL and UvrD

UvrD (DNA helicase II) is an essential component of two major DNA repair pathways in Escherichia coli: methyl-directed mismatch repair and UvrABC-mediated nucleotide excision repair. In addition, it has an undefined role in the RecF recombination pathway and possibly in replication. In an effort to better understand the role of UvrD in these various aspects of DNA metabolism, a yeast two-hybrid screen was used to search for interacting protein partners. Screening of an E.coli genomic library revealed a potential interaction between UvrD and MutL, a component of the methyl-directed mismatch repair pathway. The interaction was confirmed by affinity chromatography using purified proteins. Deletion analysis demonstrated that the C-terminal 218 amino acids (residues 398-615) of MutL were sufficient to produce the two-hybrid interaction with UvrD. On the other hand, both the N- and C-termini of UvrD were required for interaction with MutL. The implications of this interaction for the mismatch repair mechanism are discussed.

Identification and characterization of Escherichia coli DNA helicase II mutants that exhibit increased unwinding efficiency

Using a combination of both ethyl methanesulfonate and site-directed mutagenesis, we have identified a region in DNA helicase II (UvrD) from Escherichia coli that is required for biological function but lies outside of any of the seven conserved motifs (T. C. Hodgman, Nature 333:22-23, 1988) associated with the superfamily of proteins of which it is a member. Located between amino acids 403 and 409, alterations in the amino acid sequence DDAAFER lead to both temperature-sensitive and dominant uvrD mutations. The uvrD300 (A406T) and uvrD301 (A406V) alleles produce UV sensitivity at 44 degrees C but do not affect sensitivity to methyl methanesulfonate (MMS). In contrast, the uvrD303 mutation (D403AD404A) causes increased sensitivity to both UV and MMS and is dominant to uvrD+ when present at six to eight copies per cell. Several of the alleles demonstrated a strong antimutator phenotype. In addition, conjugal recombination is reduced 10-fold in uvrD303 strains. Of all of the amino acid substitutions tested, only an alanine-to-serine change at position 406 (uvrD302) was neutral. To determine the biochemical basis for the observed phenotypes, we overexpressed and purified the UvrD303 protein from a uvrD delta294 deletion background and characterized its enzymatic activities. The highly unusual UvrD303 protein exhibits a higher specific activity for ATP hydrolysis than the wild-type control, while its Km for ATP binding remains unchanged. More importantly, the UvrD303 protein unwinds partial duplex DNA up to 10 times more efficiently than wild-type UvrD. The DNA binding affinities of the two proteins appear comparable. Based on these results, we propose that the region located between amino acids 403 and 409 serves to regulate the unwinding activity of DNA helicase II to provide the proper balance between speed and overall effectiveness in the various DNA repair systems in which the protein participates.

Conserved motifs II to VI of DNA helicase II from Escherichia coli are all required for biological activity

There are seven conserved motifs (IA, IB, and II to VI) in DNA helicase II of Escherichia coli that have high homology among a large family of proteins involved in DNA metabolism. To address the functional importance of motifs II to VI, we employed site-directed mutagenesis to replace the charged amino acid residues in each motif with alanines. Cells carrying these mutant alleles exhibited higher UV and methyl methanesulfonate sensitivity, increased rates of spontaneous mutagenesis, and elevated levels of homologous recombination, indicating defects in both the excision repair and mismatch repair pathways. In addition, we also changed the highly conserved tyrosine(600) in motif VI to phenylalanine (uvrD309, Y600F). This mutant displayed a moderate increase in UV sensitivity but a decrease in spontaneous mutation rate, suggesting that DNA helicase II may have different functions in the two DNA repair pathways. Furthermore, a mutation in domain IV (uvrD307, R284A) significantly reduced the viability of some E. coli K-12 strains at 30 degrees C but not at 37 degrees C. The implications of these observations are discussed.

Two pathways for removal of nonhomologous DNA ends during double-strand break repair in Saccharomyces cerevisiae

During repair of a double-strand break (DSB) by gene conversion, one or both 3' ends of the DSB invade a homologous donor sequence and initiate new DNA synthesis. The use of the invading DNA strand as a primer for new DNA synthesis requires that any nonhomologous bases at the 3' end be removed. We have previously shown that removal of a 3' nonhomologous tail in Saccharomyces cerevisiae depends on the nucleotide excision repair endonuclease Rad1/Rad10, and also on the mismatch repair proteins Msh2 and Msh3. We now report that these four proteins are needed only when the nonhomologous ends of recombining DNA are 30 nucleotides (nt) long or longer. An additional protein, the helicase Srs2, is required for the RAD1-dependent removal of long 3' tails. We suggest that Srs2 acts to extend and stabilize the initial nascent joint between the invading single strand and its homolog. 3' tails shorter than 30 nt are removed by another mechanism that depends at least in part on the 3'-to-5' proofreading activity of DNA polymerase delta.

Mutation of a highly conserved arginine in motif IV of Escherichia coli DNA helicase II results in an ATP-binding defect

A site-directed mutation in motif IV of Escherichia coli DNA helicase II (UvrD) was generated to examine the functional significance of this region. The highly conserved arginine at position 284 was replaced with alanine to construct UvrD-R284A. The ability of the mutant allele to function in methyl-directed mismatch repair and UvrABC-mediated nucleotide excision repair was examined by genetic complementation assays. The R284A substitution abolished function in both DNA repair pathways. To identify the biochemical defects responsible for the loss of biological function, UvrD-R284A was purified to apparent homogeneity, and its biochemical properties were compared with wild-type UvrD. UvrD-R284A failed to unwind a 92-base pair duplex region and was severely compromised in unwinding a 20-base pair duplex region. The Km of UvrD-R284A for ATP was significantly greater than 3 mM compared with 80 microM for UvrD. A large decrease in ATP binding was confirmed using a nitrocellulose filter binding assay. These data suggested that the R284A mutation severely reduced the affinity of helicase II for ATP. The reduced unwinding activity and loss of biological function of UvrD-R284A was probably the result of decreased affinity for ATP. These results implicate motif IV of superfamily I helicases in nucleotide binding and represent the first characterization of a helicase mutation outside motifs I and II that severely impacted the Km for ATP.

A point mutation in Escherichia coli DNA helicase II renders the enzyme nonfunctional in two DNA repair pathways. Evidence for initiation of unwinding from a nick in vivo

Biosynthetic errors and DNA damage introduce mismatches and lesions in DNA that can lead to mutations. These abnormalities are susceptible to correction by a number of DNA repair mechanisms, each of which requires a distinct set of proteins. Escherichia coli DNA helicase II has been demonstrated to function in two DNA repair pathways, methyl-directed mismatch repair and UvrABC-mediated nucleotide excision repair. To define further the role of UvrD in DNA repair a site-specific mutant was characterized. The mutation, uvrDQ251E, resides within helicase motif III, a conserved segment of amino acid homology found in a superfamily of prokaryotic and eukaryotic DNA helicases. The UvrD-Q251E protein failed to complement the mutator and ultraviolet light-sensitive phenotypes of a uvrD deletion strain indicating that the mutant protein is inactive in both mismatch repair and excision repair. Biochemical characterization revealed a significant defect in the ability of the mutant enzyme to initiate unwinding at a nick. The elongation phase of the unwinding reaction was nearly normal. Together, the biochemical and genetic data provide evidence that UvrD-Q251E is dysfunctional because the mutant protein fails to initiate unwinding at the nick(s) used to initiate excision and subsequent repair synthesis. These results provide direct evidence to support the notion that helicase II initiates unwinding from a nick in vivo in mismatch repair and excision repair.

Role of E. coli DNA helicase II in a umuCD-dependent Wiegle reactivation

Wiegle reactivation is a manifestation of a umuCD-mediated enhancement in the replication of damaged phage DNA (Caillet-Fauquet et al., 1977; Defais et al., 1989; Rajagopalan et al., 1992). I have obtained Wiegle reactivation of lambda by irradiating the uvrA cells in rich growth medium. This Wiegle reactivation was lost upon transduction of the umuC mutation into the strain. There was also a drastic reduction of Wiegle reactivation in an isogenic strain carrying the uvrA mutation and deletion of the uvrD gene. (uvrD codes for E. coli DNA helicase II). The effect of the uvrD deletion on Wiegle reactivation can indicate a specific requirement of DNA helicase II for the unwinding of damaged phage DNA during its replication or (and) an inefficient induction of the SOS response in delta uvrD uvrA cells.

Mutations in motif II of Escherichia coli DNA helicase II render the enzyme nonfunctional in both mismatch repair and excision repair with differential effects on the unwinding reaction

Site-directed mutagenesis has been employed to address the functional significance of the highly conserved aspartic and glutamic acid residues present in the Walker B (also called motif II) sequence in Escherichia coli DNA helicase II. Two mutant proteins, UvrDE221Q and UvrDD220NE221Q, were expressed and purified to apparent homogeneity. Biochemical characterization of the DNA-dependent ATPase activity of each mutant protein demonstrated a kcat that was < 0.5% of that of the wild-type protein, with no significant change in the apparent Km for ATP. The E221Q mutant protein exhibited no detectable unwinding of either partial duplex or blunt duplex DNA substrates. The D220NE221Q mutant, however, catalyzed unwinding of both partial duplex and blunt duplex substrates, but at a greatly reduced rate compared with that of the wild-type enzyme. Both mutants were able to bind DNA. Thus, the motif II mutants E221Q and D220NE221Q were able to bind ATP and DNA to the same extent as wild-type helicase II but demonstrate a significant reduction in ATP hydrolysis and helicase functions. The mutant uvrD alleles were also characterized by examining their abilities to complement the mutator and UV light-sensitive phenotypes of a uvrD deletion mutant. Neither the uvrDE221Q nor the uvrDD220NE221Q allele, supplied on a plasmid, was able to complement either phenotype. Further genetic characterization of the mutant uvrD alleles demonstrated that uvrDE221Q confers a dominant negative growth phenotype; the uvrDD220NE221Q allele does not exhibit this effect. The observed difference in effect on viability may reflect the gene products' dissimilar kinetics for unwinding duplex DNA substrates in vitro.

Regulation of the Saccharomyces cerevisiae Srs2 helicase during the mitotic cell cycle, meiosis and after irradiation

The expression of the SRS2 gene, which encodes a DNA helicase involved in DNA repair in Saccharomyces cerevisiae, was studied using an SRS2-lacZ fusion integrated at the chromosomal SRS2 locus. It is shown here that this gene is expressed at a low level and is tightly regulated. It is cell-cycle regulated, with induction probably being coordinated with that of the DNA-synthesis genes, which are transcribed at the G1-S boundary. It is also induced by DNA-damaging agents, but only during the G2 phase of the cell cycle; this distinguishes it from a number of other repair genes, which are inducible throughout the cycle. During meiosis, the expression of SRS2 rises at a time nearly coincident with commitment to recombination. Since srs2 null mutants are radiation sensitive essentially when treated in G1, the mitotic regulation pattern described here leads us to postulate that either secondary regulatory events limit Srs2 activity of G1 cells or Srs2 functions in a repair mechanism associated with replication.

Escherichia coli DNA polymerase III holoenzyme subunits alpha, beta, and gamma directly contact the primer-template

Escherichia coli DNA polymerase III holoenzyme forms a stable initiation complex with RNA-primed template in the presence of ATP. To determine the linear arrangement of the holoenzyme subunits along the primer-template duplex region, we cross-linked holoenzyme to a series of photo-reactive primers. Site-specific photo-cross-linking revealed that the alpha, beta, and gamma subunits formed ATP-dependent contacts with the primer-template. The alpha-polymerase catalytic subunit covalently attached to nucleotide positions -3, -9, and -13 upstream of the primer terminus, with the most efficient adduct formation occurring at position -9. The gamma subunit contacted the primer at positions -13, -18, and -22, with the strongest gamma-primer interactions occurring at position -18. The beta subunit predominated in cross-linking at position -22. Thus, within the initiation complex, alpha contacts roughly the first 13 nucleotides upstream of the 3'-primer terminus followed by gamma at -18 and beta at -22, and the gamma subunit remains a part of the initiation complex, bridging the alpha and beta subunits. Analyses of the interaction of photo-activatible primer-templates with the preinitiation complex proteins (gamma-complex (gamma-delta-delta'-chi-psi) and beta subunit) revealed the gamma subunit within the preinitiation complex covalently attached to primer at position -3. However, addition of core DNA polymerase III to preinitiation complex, fully reconstituting holoenzyme resulted in replacement of gamma by alpha at the primer terminus. These data indicate that assembly of holoenzyme onto a primer-template can occur in distinct stages and results in a structural rearrangement during initiation complex formation.

Structure and function of transcription-repair coupling factor. I. Structural domains and binding properties

The 130-kDa mfd gene product is required for coupling transcription to repair in Escherichia coli. Mfd displaces E. coli RNA polymerase (Pol) stalled at a lesion, binds to the damage recognition protein UvrA, and increases the template strand repair rate during transcription. Here, the interactions of Mfd (transcription-repair coupling factor, TRCF) with DNA, RNA Pol, and UvrA were investigated. TRCF bound nonspecifically to double stranded DNA; binding to DNA produced alternating DNase I-protected and -hypersensitive regions, suggesting possible wrapping of the DNA around the enzyme. Weaker binding to single stranded DNA and no binding to single stranded RNA were observed. DNA binding required ATP, and hydrolysis of ATP promoted dissociation. Removal of a stalled RNA Pol also requires ATP hydrolysis. Apparently, TRCF recognizes a stalled elongation complex by directly interacting with RNA Pol, since binding to a synthetic transcription bubble was no stronger than binding to double stranded DNA, and binding to free RNA Pol holoenzyme and to initiation and elongation complexes in the absence of adenosine 5'-O-(thiotriphosphate) were observed. Structure-function analysis showed that residues 379-571 are involved in binding to a stalled RNAP. The helicase motifs region, residues 571-931, binds to ATP and duplex polynucleotide (DNA:DNA or DNA:RNA). Dissociation of the ternary complex upon hydrolysis of ATP also requires the carboxyl terminus of TRCF. Finally, residues 1-378 bind to UvrA and deliver the damage recognition component of the excision nuclease to the lesion.

Genetics of selection-induced mutations: I. uvrA, uvrB, uvrC, and uvrD are selection-induced specific mutator loci

Selection-induced mutations, sometimes called "directed," "adaptive," or "Cairnsian" mutations, are spontaneous mutations that occur as specific responses to environmental challenges, usually during periods of prolonged stress, and that occur more often when they are selectively advantageous than when they are selectively neutral. In this study I show that lesions in uvrA, uvrB, uvrC, or uvrD increase the mutation rate from trpA46 to trpA+ by 10(2)- to 10(4)-fold during tryptophan starvation, but those same lesions do not affect random mutation rates in growing cells when tryptophan is present. The increased selection-induced mutation rates remain specific to the gene that is under selection in that no increase in the mutation rate from trpA46 to trpA+ is detected during proline starvation. Evidence is presented showing that proline starvation produces a state of cellular stress which results in a burst of mutations from trpA46 to trpA+ when proline-starved cells are plated onto medium lacking tryptophan but containing proline. These results are consistent with the hypermutable state model for selection-induced mutagenesis.

Kinetic mechanism of adenine nucleotide binding to and hydrolysis by the Escherichia coli Rep monomer. 1. Use of fluorescent nucleotide analogues

The Escherichia coli Rep helicase catalyzes the unwinding of duplex DNA in a reaction that is coupled to ATP binding and hydrolysis. The Rep protein is a stable monomer in the absence of DNA but dimerizes upon binding either single-stranded or duplex DNA, and the dimer appears to be the functionally active form of the Rep helicase. As a first step toward understanding how ATP binding and hydrolysis are coupled energetically to DNA unwinding, we have investigated the kinetic mechanism of nucleotide binding to the Rep monomer (P) using stopped-flow techniques and the fluorescent ATP analogue, 2'(3')-O-(N-methylanthraniloyl-ATP (mantATP). The fluorescence of mantATP is enhanced upon Rep binding due to energy transfer from tryptophan. The results are consistent with the following two-step mechanism, in which the bimolecular association step is followed by a conformational change in the P-mantATP complex: P + mantATP [formula: see text] P-mantATP [formula: see text] (P-mantATP). The following rate and equilibrium constants were determined at 4 degrees C in 20 mM Tris.HCl (pH 7.5), 6 mM NaCl, 5 mM MgCl2, and 10% (v/v) glycerol: k+1 = (1.1 +/- 0.2) x 10(7) M-1 s-1; k-1 = 3.2 (+/- 0.5) s-1; k+2 = 2.9 (+/- 0.5) s-1; k-2 = 0.04 (+/- 0.005) s-1; K1 = k+1/k-1 = (3.4 +/- 0.8) x 10(6) M-1; K2 = k+2/k-2 = 73 (+/- 10); Koverall = K1K2 = (2.30 +/- 0.6) x 10(8) M-1. Similar rate and equilibrium constants are obtained with mantATP gamma S, whereas the apparent rate constant for mantAMPPNP binding is 15-fold lower than for mantATP and equilibrium binding is weaker (Koverall approximately 10(6) M-1). Rep monomer does bind mantATP in the absence of Mg2+ (Koverall approximately 5 x 10(5) M-1), although the four rate constants in the above reaction increase by at least 8-fold (k-1 and k-2 increase by approximately 100- and approximately 1000-fold, respectively). The affinities of Mg2+ for P-mantATP and (P-mantATP)* are 10- and 1000-fold higher than those for nucleotide-free Rep monomer, indicating that the second step in the reaction is associated with a marked increase in Mg2+ affinity. The bound Mg2+ in a (P-mantATP)*-Mg2+ complex dissociates at a rate that is comparable to the rate of mantATP release.(ABSTRACT TRUNCATED AT 400 WORDS)

Rates of spontaneous mutation in bacteriophage T4 are independent of host fidelity determinants

Bacteriophage T4 encodes most of the genes whose products are required for its DNA metabolism, and host (Escherichia coli) genes can only infrequently complement mutationally inactivated T4 genes. We screened the following host mutator mutations for effects on spontaneous mutation rates in T4: mutT (destruction of aberrant dGTPs), polA, polB and polC (DNA polymerases), dnaQ (exonucleolytic proofreading), mutH, mutS, mutL and uvrD (methyl-directed DNA mismatch repair), mutM and mutY (excision repair of oxygen-damaged DNA), mutA (function unknown), and topB and osmZ (affecting DNA topology). None increased T4 spontaneous mutation rates within a resolving power of about twofold (nor did optA, which is not a mutator but overexpresses a host dGTPase). Previous screens in T4 have revealed strong mutator mutations only in the gene encoding the viral DNA polymerase and proofreading 3'-exonuclease, plus weak mutators in several polymerase accessory proteins or determinants of dNTP pool sizes. T4 maintains a spontaneous mutation rate per base pair about 30-fold greater than that of its host. Thus, the joint high fidelity of insertion by T4 DNA polymerase and proofreading by its associated 3'-exonuclease appear to determine the T4 spontaneous mutation rate, whereas the host requires numerous additional systems to achieve high replication fidelity.

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.

DNA helicases: enzymes with essential roles in all aspects of DNA metabolism

DNA helicases catalyze the disruption of the hydrogen bonds that hold the two strands of double-stranded DNA together. This energy-requiring unwinding reaction results in the formation of the single-stranded DNA required as a template or reaction intermediate in DNA replication, repair and recombination. A combination of biochemical and genetic studies have been used to probe and define the roles of the multiple DNA helicases found in E. coli. This work and similar efforts in eukaryotic cells, although far from complete, have established that DNA helicases are essential components of the machinery that interacts with the DNA molecule.

Functions of the gene products of Escherichia coli

A list of currently identified gene products of Escherichia coli is given, together with a bibliography that provides pointers to the literature on each gene product. A scheme to categorize cellular functions is used to classify the gene products of E. coli so far identified. A count shows that the numbers of genes concerned with small-molecule metabolism are on the same order as the numbers concerned with macromolecule biosynthesis and degradation. One large category is the category of tRNAs and their synthetases. Another is the category of transport elements. The categories of cell structure and cellular processes other than metabolism are smaller. Other subjects discussed are the occurrence in the E. coli genome of redundant pairs and groups of genes of identical or closely similar function, as well as variation in the degree of density of genetic information in different parts of the genome.

Identification, molecular cloning and characterization of the gene encoding the chi subunit of DNA polymerase III holoenzyme of Escherichia coli

We have identified a previously reported open reading frame (ORF13) that maps between pepA and valS at 96.6 centisomes of the Escherichia coli genome as the structural gene for the chi subunit of DNA polymerase III holoenzyme. This conclusion is supported by a perfect match of the amino-terminal 24 residues of chi with the DNA sequence of ORF13 and a demonstration that ORF13 directs expression of a protein that co-migrates with authentic chi on SDS-polyacrylamide gels. ORF13, designated holC, was isolated from the E. coli chromosome and inserted into a tac promoter-based expression plasmid to direct production of the chi subunit to 5-7% of the total soluble protein. The 3' end of holC was sequenced to resolve discrepancies between two published versions.

Characterization of the Staphylococcus aureus chromosomal gene pcrA, identified by mutations affecting plasmid pT181 replication

The Staphylococcus aureus chromosomal gene pcrA, identified by mutations, such as pcrA3, that affect plasmid pT181 replication, has been cloned and sequenced. The pcrA gene encodes a protein with significant similarity (40% identity) to two Escherichia coli helicases: the helicase II encoded by the uvrD gene and the Rep helicase. The pcrA3 mutation was found to be a C to T transition leading to a threonine to isoleucine substitution at amino acid residue 61 of the protein. The pcrA gene seems to belong to an operon containing at least one other gene, tentatively named pcrB, upstream from pcrA. The PcrA protein was shown to be essential for cell viability and overproduction has deleterious effects on the host and plasmid replication.