Initiation of recA+-dependent recombination in Escherichia coli (lambda). I. Undamaged covalent circular lambda DNA molecules in uvrA+ recA+ lysogenic host cells are cut following superinfection with psoralen-damaged lambda phages

Cleavage of holliday junctions by the Escherichia coli RuvABC complex

The Escherichia coli RuvABC proteins process recombination intermediates during genetic recombination and recombinational repair. Although early biochemical studies indicated distinct RuvAB-mediated branch migration and RuvC-mediated Holliday junction resolution reactions, more recent studies have shown that the three proteins act together as a "resolvasome" complex. In this work we have used recombination intermediates made by RecA to determine whether the RuvAB proteins affect the sequence specificity of the RuvC resolvase. We find that RuvAB proteins do not alter significantly the site specificity of RuvC-dependent cleavage, although under certain conditions, they do affect the efficiency of cleavage at particular sites. The presence of RecA also influences cleavage at some sites. We also show that the RuvAB proteins act upon transient strand exchange intermediates made using substrates that have the opposite polarity of those preferred by RecA. Together, our results allow us to develop further a model for the recombinational repair of DNA lesions that lead to the formation of post-replication gaps during DNA replication. The novel features of this model are as follows: (i) the RuvABC resolvasome recognizes joints made by RecA; (ii) resolution by RuvABC occurs at specific sites containing the RuvC consensus cleavage sequence 5'-(A/T)TT downward arrow(G/C)-3'; and (iii) Holliday junction resolution often occurs close to the initiating gap without significant heteroduplex DNA formation.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

lambda Rap protein is a structure-specific endonuclease involved in phage recombination

Bacteriophage lambda encodes a number of genes involved in the recombinational repair of DNA double-strand breaks. The product of one of these genes, rap, has been purified. Truncated Rap proteins that copurify with the full-length form are derived, at least in part, from a rho-dependent transcription terminator located within its coding sequence. Full-length and certain truncated Rap polypeptides bind preferentially to branched DNA substrates, including synthetic Holliday junctions and D-loops. In the presence of manganese ions, Rap acts as an endonuclease that cleaves at the branch point of Holliday and D-loop substrates. It shows no obvious sequence preference or symmetry of cleavage on a Holliday junction. The biochemical analysis of Rap gives an insight into how recombinants could be generated by the nicking of a D-loop without the formation of a classical Holliday junction.

Resolution of an early RecA-recombination intermediate by a junction-specific endonuclease

The nucleoprotein filament formed on a circular single strand by Escherichia coli RecA protein in vitro can pair with homologous duplex DNA even when the latter lacks a free homologous end, but subsequent progression of the reaction through strand exchange requires an end in at least one strand of the duplex DNA. We purified from E. coli an endonuclease activity that cleaves the outgoing strand of duplex DNA at the junction of homologous and heterologous sequences in three-stranded RecA-recombination intermediates. This endonuclease activity also cleaves specifically at the junctions of duplex and single-stranded regions in synthetic double-stranded oligonucleotides whose central portion consists of unpaired heterologous sequences. These activities are consistent with a role in recombination and repair of DNA.

Inhibition of dimer excision in repeatedly UV-irradiated Escherichia coli: its requirement for RecA protein and de novo protein synthesis

In UV-irradiated Escherichia coli dimer excision was found to be inhibited by predamage (M. Sedliaková, F. Masek and J. Brozmanová, FEBS Lett., 23 (1972) 325-326) or overproduction of RecA protein, which suggests that the coating of the dimers by this protein may make them inaccessible to the excision nuclease (M. Sedliaková, K. Kleibl and F. Masek, Mutat. Res., 191 (1987) 13-16). We measured the levels of RecA protein and dimer excision in cells irradiated with (i) a single dose of 50 J m-2, (ii) two separate doses of 30 and 50 J m-2, post-incubated with chloramphenicol; (iii) two separate doses of 30 and 50 J m-2, post-incubated without chloramphenicol. Dimer excision was complete in the first two cases, but in the latter it was inhibited by 40%. At the time of active dimer excision, there were marked differences in RecA protein content between the cells irradiated with a single dose and cells irradiated with two separate doses (both post-incubated without chloramphenicol), which might account for the differences in dimer excision. However, relatively small differences in RecA protein content were found in cells irradiated with two doses and post-incubated with or without chloramphenicol, which could therefore not account for the differences in dimer excision. The data suggest that the inhibition of dimer excision involves some short-lived component(s) other than RecA protein.

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.

Accurate measurement of psoralen-crosslinked DNA: direct biochemical measurements and indirect measurement by hybridization

This paper evaluates methods to measure crosslinkage due to psoralen plus light in total DNA and in specific sequences. DNA exposed in cells or in vitro to a bifunctional psoralen and near ultraviolet light accumulates interstrand crosslinks. Crosslinkage is the DNA mass fraction that is attached in both strands to a crosslink. We show here biochemical methods to measure psoralen photocrosslinkage accurately in total DNA. We also describe methods to measure photocrosslinkage indirectly, in specific sequences, by nucleic acid hybridization. We show that a single 4,5',8-trimethylpsoralen (TMP) crosslink causes at least 50 kbp of alkali-denatured DNA contiguous in both strands with it to snap back into the duplex form when the denatured preparation is returned to neutral pH. This process was so efficient that the DNA was not nicked by the single-strand nuclease S1 at 100-fold excess after snapping back. Uncrosslinked DNA was digested to acid-soluble material by the enzyme. Crosslinkage therefore equals the fraction of S1-resistant nucleotide in this kind of experiment. We alkali-denatured DNA samples crosslinked to varying degrees by varying TMP concentration at constant light exposure. We then measured crosslinkage by ethidium bromide (EtBr) fluorometry at pH 11.8; by EtBr fluorometry at neutral pH of S1 digests of the DNA; and by the fraction of radioactivity remaining acid insoluble in S1-digests of DNA labeled uniformly with [3H]deoxythymidine. These assays measure distinct physical properties of crosslinked DNA. Numerical agreement is expected only when all three measurements are accurate. Under optimum conditions, the three methods yielded identical results over the range of measurement. Using alkaline EtBr fluorescence in crude cell lysates, we detected crosslinks at frequencies in the range of 1.6 X 10(-7) per base pair. These levels were compatible with cell survival, attesting to the sensitivity of the measurement system. Crosslinkage affected hybridization as well. One crosslink prevented all alkali-denatured DNA contiguous in both strands with it from hybridizing to complementary DNA either on solid supports or in solution. Strand-length effects on crosslinkage and on reassociation caused solution hybridization levels to exceed those predicted by simple theory. In a quantitative, dot-blotting assay hybridization was linear up to membrane saturation by denatured, uncrosslinked DNA of any strand length.(ABSTRACT TRUNCATED AT 400 WORDS)

Repair and recombination of nonreplicating UV-irradiated phage DNA in E. coli II. Stimulation of RecF-dependent recombination by excision repair of cyclobutane pyrimidine dimers and of other photoproducts

Three aspects of recombination of UV-irradiated nonreplicating lambda phage DNA were addressed: the photoproduct(s) responsible, the role of UvrABC-mediated excision repair, and the dependence on RecF function. Cyclobutane pyrimidine dimers appeared responsible for some recombination because photoreactivation reduced the frequency of 254-nm-stimulated recombination and because photosensitized 313-nm irradiation stimulated recombination. Other photoproducts seemed recombinogenic as well, because high fluences of 254-nm irradiation stimulated recombination considerably more, per cyclobutane dimer induced, than photosensitized 313-nm irradiation, and because photoreactivation did not eliminate 254-nm stimulated recombination. For both treatments, much, but not all, of the recombination was UvrABC-dependent. Recombination was mostly RecF-dependent, but was not affected by recB recC or recE mutations

Repair of psoralen and acetylaminofluorene DNA adducts by ABC excinuclease

Escherichia coli UvrA, UvrB and UvrC proteins acting in concert remove the major ultraviolet light-induced photoproduct, the pyrimidine dimer, from DNA in the form of a 12 to 13-nucleotide long single-stranded fragment. In vivo data indicate that the UvrABC enzyme is also capable of removing other nucleotide diadducts as well as certain nucleotide monoadducts from DNA and initiating the repair process that leads to removal of interstrand crosslinks caused by some bifunctional chemical agents. We have determined the action mechanism of the enzyme on nucleotide monoadducts produced by 4'-hydroxymethyl-4,5',8-trimethylpsoralen and N-acetoxy-N-2-acetylaminofluorene. In both cases we find that the enzyme hydrolyzes the eighth phosphodiester bond 5' and the fifth phosphodiester bond 3' to the modified base. This cutting pattern is similar to that observed with diadduct substrate, the only difference being that while the enzyme incises the fourth or fifth phosphodiester bond 3' to the pyrimidine dimer it always hydrolyzes the fifth bond relative to monoadducts. Our results also suggest that ABC excinuclease cuts the same two phosphodiester bonds on both sides of a T whether that T has a psoralen monoadduct or is involved in psoralen-mediated interstrand crosslink.

Genetic control of excision of Saccharomyces cerevisiae interstrand DNA cross-links induced by psoralen plus near-UV light

Excision of interstrand DNA cross-links induced by 4,5',8-trimethyl psoralen plus 360-nm light was examined in wild type (RAD+) and various radiation-sensitive (rad) mutants of Saccharomyces cerevisiae known to be defective in the excision of UV light-induced pyrimidine dimers. Alkaline sucrose sedimentation of DNA after incubation of psoralen-plus-light-treated cells indicated little or no nicking of cross-linked DNA in rad1-2, rad2-5, rad3-2, rad4-4, rad10-2, and mms19-1 mutants. In the rad14-2 mutant, substantial nicking was observed but to a much lesser extent than in the RAD+ strains, whereas the rad16-1 mutant was as proficient in nicking as the RAD+ strain. Removal of cross-links was also examined in RAD+, rad3-2, and rad14-2 strains by determining the sensitivity of alkali-denatured and -neutralized DNA to hydrolysis by S1 nuclease. No cross-link removal was observed in the rad3-2 mutants, and the rad14-2 mutant was much less efficient than the RAD+ strain in removing cross-links.

Postreplication repair in E. coli: strand exchange reactions of gapped DNA by RecA protein

We have used a sensitive gel electrophoresis assay to detect the products of Escherichia coli RecA protein catalysed strand exchange reactions between gapped and duplex DNA molecules. We identify structures that correspond to joint molecules formed by homologous pairing, and show that joint molecules are converted by RecA protein into heteroduplex monomers by reciprocal strand exchanges. However, strand exchanges only occur when there is a 3'-terminus complementary to the single stranded DNA in the gap. In the absence of a complementary free end, the two DNA molecules pair and short heteroduplex regions are formed by localised interwinding.

Role of SSB protein in RecA promoted branch migration reactions

The RecA protein of Escherichia coli is essential for genetic recombination and postreplicational repair of DNA. In vitro, RecA protein promotes strand transfer reactions between full length linear duplex and single stranded circular DNA of phi X174 to form heteroduplex replicative form II-like structures (Cox and Lehman 1981 a0. In a similar way, it transfers one strand of a short duplex restriction fragment to a single stranded circle. Both reactions require RecA and single strand binding protein (SSB) in amounts sufficient to saturate the ssDNA. The rate and extent of strand transfer is enhanced considerably when SSB is added after preincubation of the DNA with RecA protein. In contrast, SSB protein is not required for RecA protein catalysed reciprocal strand exchanges between regions of duplex DNA. These results indicate that while SSB is necessary for efficient transfer between linear duplex and ssDNA to form a single heteroduplex, it is not required for branch migration reactions between duplex molecules that form two heteroduplexes.

Genetic control of excision of Saccharomyces cerevisiae interstrand DNA cross-links induced by psoralen plus near-UV light

Excision of interstrand DNA cross-links induced by 4,5',8-trimethyl psoralen plus 360-nm light was examined in wild type (RAD+) and various radiation-sensitive (rad) mutants of Saccharomyces cerevisiae known to be defective in the excision of UV light-induced pyrimidine dimers. Alkaline sucrose sedimentation of DNA after incubation of psoralen-plus-light-treated cells indicated little or no nicking of cross-linked DNA in rad1-2, rad2-5, rad3-2, rad4-4, rad10-2, and mms19-1 mutants. In the rad14-2 mutant, substantial nicking was observed but to a much lesser extent than in the RAD+ strains, whereas the rad16-1 mutant was as proficient in nicking as the RAD+ strain. Removal of cross-links was also examined in RAD+, rad3-2, and rad14-2 strains by determining the sensitivity of alkali-denatured and -neutralized DNA to hydrolysis by S1 nuclease. No cross-link removal was observed in the rad3-2 mutants, and the rad14-2 mutant was much less efficient than the RAD+ strain in removing cross-links.

Evidence that dimers remaining in preinduced Escherichia coli B/r Hcr+ become insensitive after DNA replication to the extract from Micrococcus luteus

In Escherichia coli B/r Her+ irradiated with two separate fluences, dimer excision is prematurely interrupted. The present study was designed to follow tha fate of dimers remaining unexcised. The results imply that these dimers (or distortions containing dimers) are transformed on replication from the state of sensitivity to the state of insensitivity to endonuclease from Micrococcus luteus. This conclusion is based on the following findings: (a) dimers were radiochromatographically detectable in DNA replicated after UV, which indicated that they were tolerated on replication. (b) Similar amounts of dimers were detected radiochromatographically both in DNA remaining unreplicated and DNA twice replicated after UV, This along with the low transfer of parental label into daughter DNA, indicated that dimers remained in situ in parental chains. (c) Immediately after UV, all parental DNA contained numerous sites sensitive to the extract from M. luteus. 2 h after UV, a portion of parental DNA still contained a number of endonuclease-sensitive (Es) sites, while another portion of parental DNA and all daughter DNA were free of Es sites. (d) The occurrence of parental DNA free of Es sites was not temporally correlated with dimer excision, but with the first round of DNA replication. (e) The amount of DNA free of Es sites corresponded to the amount of replicated DNA. (f) Separation of replicated and unreplicated DNA, and detection of Es sites in both portions separately showed that the replicated DNA was almost free of Es sites, whereas unreplicated DNA contained a number of such sites.

Heteroduplex formation by recA protein: polarity of strand exchanges

Purified recA protein promotes strand exchanges between linear duplex DNA and homologous circular single-stranded phage phi X174 DNA that carries a short hybridized fragment [West, S. C., Cassuto, E. & Howard-Flanders, P. (1981) Proc. Natl. Acad. Sci. USA 78, 2100-2104]. In this paper we investigate the mechanism of this strand exchange reaction. We show that recA protein initiates strand exchanges by pairing the free end of the duplex fragment with the single-stranded DNA. In addition, we find that strand exchanges are polar, stable heteroduplex molecules being formed by the directional transfer transfer of the (-) strands starting at 3' termini.

Homologous pairing can occur before DNA strand separation in general genetic recombination

In the presence of ATP and Mg2+, purified Escherichia coli recA protein promotes the formation of joint molecules between closed circular duplex DNA and homologous circular single-stranded DNA carrying a short annealed fragment. The presence of this fragment is essential for pairing between molecules. In similar conditions recA protein is unable to act as a helicase and does not cause strand separation of the fragment from the single-stranded circle. Thus, homologous pairing between DNA molecules can take place without prior unwinding of a free end.

Shutoff of lambda gene expression by bacteriophage T4: role of the T4 alc gene

Bacteriophage T4 normally contains 5-hydroxymethylcytosine instead of cytosine in its DNA. Multiple mutants of T4 which synthesize DNA with cytosine do not transcribe their late genes due to the action of the T4 alc gene (Snyder et al., Proc. Natl. Acad. Sci. U.S.A. 73:3098--3102, 1976), which is also responsible for unfolding the host nucleoid after T4 infection (Sirotkin et al., Nature [London] 265:28--32, 1977; Tigges et al., J. Virol. 24:775--785, 1977). It seems reasonable that T4 alc function plays a role in shutting off host transcription, and the observation that some of the RNA made after infection with a T4 alc mutant hybridizes to Escherichia coli DNA (Sirotkin et al., Nature [London] 265:28--32, 1977; Tigges et al., J. Virol. 24:775--785, 1977) supports this hypothesis. Although it is likely that the roles of the alc function in the blocking of some types of transcription and in the unfolding of the host nucleoid are related, it is not known how these effects are achieved or, in fact, whether all types of transcription are affected equally by the alc function. In an attempt to answer these questions, we studied the effect of T4 alc function on bacteriophage lambda transcription and on the structure of intracellular lambda DNA. We found that the alc function is responsible for the shutoff of lambda late transcription but probably not for the shutoff of lambda early transcription. We also found that alc does not block lambda transcription by directly removing the supercoils from circular lambda DNA via either a nicking or topoisomerase activity. Furthermore, we conclude that T4 infection also prevents the translation of non-T4 mRNA because late lambda mRNA's were made after superinfection by a T4 alcs mutant and were of normal length but were not translated into lambda late proteins.