Structural relationship of bacterial RecA proteins to recombination proteins from bacteriophage T4 and yeast

Isolation of the Helicobacter pylori recA gene and involvement of the recA region in resistance to low pH

To understand the potential roles of the important DNA repair protein RecA in Helicobacter pylori pathogenesis, we cloned the recA gene from H. pylori 84-183. Degenerate PCR primers based on conserved RecA protein regions were used to amplify a portion of H. pylori recA, which was used as a probe to isolate the full-length recA gene from H. pylori genomic libraries. The H. pylori recA gene encoded a protein of 347 amino acids with a molecular mass of 37.6 kDa. As expected, H. pylori RecA was highly similar to other RecA proteins and most closely resembled that of Campylobacter jejuni (75% identity). Immediately downstream of recA was an open reading frame whose predicted product showed 58% identity to the Bacillus subtilis enolase protein. recA and eno were disrupted in H. pylori 84-183 by insertion of antibiotic resistance genes. Reverse transcription-PCR demonstrated that recA and eno were cotranscribed and that insertion of the kanamycin resistance gene into recA had polar effects on expression of the downstream eno. The H. pylori recA mutants were severely impaired in their ability to survive treatment with UV light and methyl methanesulfonate and with the antimicrobial agents ciprofloxacin and metronidazole. The eno mutant had sensitivities to UV light and metronidazole intermediate to those of wild-type and recA strains, suggesting that truncation of the recA-eno transcript resulted in lowered recA expression. For survival at low pH, a recA mutant was approximately 10-fold more sensitive than strain 84-183, while the eno mutant demonstrated intermediate susceptibility. This difference occurred in the presence or absence of urea, implying the involvement of a gene in the recA region in an acid resistance mechanism distinct from that mediated by urease.

How specific is the first recognition step of homologous recombination?

The Escherichia coli RecA protein promotes homologous recognition in base triplets via non-Watson-Crick bonds that differ from those formed nonenzymically from DNA consisting of runs of purines or pyrimidines. Base substitutions reveal recognition to be permissive, consistent with a search for homology that achieves speed at the cost of precision.

RecA protein mediates homologous recognition via non-Watson-Crick bonds in base triplets

E. coli RecA protein, the prototype of a class, forms a helical nucleoprotein filament on single-stranded DNA that recognizes homology in duplex DNA, and initiates the exchange of strands in homologous recombination. The discovery of this reaction some years ago posed a quandary on how a third strand recognizes homology in duplex DNA, whose Watson-Crick bonds face inward in a hydrophobic core of stacked bases. Recent studies have shown that RecA protein promotes homologous recognition via non-Watson-Crick bonds in base triplets. The intermediates in the RecA reaction differ distinctly from triplex DNA that forms non-enzymically. The biological significance of the novel set of DNA interactions by which RecA protein effects homologous recognition is indicated by the importance of this protein in recombination, and the widespread distribution of homologous proteins in prokaryotes and eukaryotes.

RecA homologs Dmc1 and Rad51 interact to form multiple nuclear complexes prior to meiotic chromosome synapsis

Dmc1 and Rad51, yeast homologs of the E. coli RecA protein, are shown by immunostaining to localize to as many as 64 sites within spread meiotic nuclei. Genetic requirements for this punctate pattern suggest it represents recombination intermediates. Dmc1 and Rad51 colocalize and are therefore likely to act together during recombination. Despite their similarities, the two proteins have specialized functions: Dmc1 complexes do not form in rad51 mutants, while Rad51 complexes are retained indefinitely in dmc1 mutants. Dmc1 and, by inference, Rad51 form complexes before synapsis as monitored by immunostaining for Zip1 protein. Analysis of zip1 mutants shows that Zip1 promotes dissociation of Dmc1 complexes. Colocalization of Dmc1 and Zip1 raises the possibility that Dmc1 and Rad51 are components of recombination nodules.

Homotypic and heterotypic protein associations control Rad51 function in double-strand break repair

Rad51 is essential for efficient repair of DNA double-strand breaks (DSBs) and recombination in Saccharomyces cerevisiae. Here, we examine Rad51 protein-protein interactions and their biological significance. GAL4 two-hybrid fusion analysis demonstrated that the amino-terminal region of Rad51 mediates both a strong Rad51:Rad51 self-association and a Rad51:Rad52 interaction. Several Rad51 variants were characterized that imparted DSB repair defects; these defects appear to result from Rad51 protein-protein interactions. First, a rad51 allele bearing a missense mutation in the consensus ATP-binding sequence disrupted DSB repair in wild-type yeast. The effect of this allele was dependent on the presence of wild-type Rad51 because MMS sensitivity of rad51 delta strains were not increased by its expression. Second, we identified a highly conserved RAD51 homolog from Kluyveromyces lactis (KlRAD51) that only partially complemented rad51 delta strains and impaired DSB repair in wild-type S. cerevisiae. Third, fusions of Gal4 domains to Rad51 disrupted DSB repair in a manner that required the presence of either Rad51 or Rad52. Because K. lactis RAD51 and RAD52 did not complement a S. cerevisiae rad51 delta rad52 delta strain, Rad51-Rad52 functions appear to be mediated through additional components. Thus, multiple types of Rad51 protein interactions, including self-association, appear to be important for DSB repair.

Structure of REC2, a recombinational repair gene of Ustilago maydis, and its function in homologous recombination between plasmid and chromosomal sequences

Mutation in the REC2 gene of Ustilago maydis leads to defects in DNA repair, recombination, and meiosis. Analysis of the primary sequence of the Rec2 protein reveals a region with significant homology to bacterial RecA protein and to the yeast recombination proteins Dmc1, Rad51, and Rad57. This homologous region in the U. maydis Rec2 protein was found to be functionally sensitive to mutation, lending support to the hypothesis that Rec2 has a functional RecA-like domain essential for activity in recombination and repair. Homologous recombination between plasmid and chromosomal DNA sequences is reduced substantially in the rec2 mutant following transformation. The frequency can be restored to a level approaching, but not exceeding, that observed in the wild-type strain if transformation is performed with cells containing multiple copies of REC2.

Structure of REC2, a recombinational repair gene of Ustilago maydis, and its function in homologous recombination between plasmid and chromosomal sequences

Mutation in the REC2 gene of Ustilago maydis leads to defects in DNA repair, recombination, and meiosis. Analysis of the primary sequence of the Rec2 protein reveals a region with significant homology to bacterial RecA protein and to the yeast recombination proteins Dmc1, Rad51, and Rad57. This homologous region in the U. maydis Rec2 protein was found to be functionally sensitive to mutation, lending support to the hypothesis that Rec2 has a functional RecA-like domain essential for activity in recombination and repair. Homologous recombination between plasmid and chromosomal DNA sequences is reduced substantially in the rec2 mutant following transformation. The frequency can be restored to a level approaching, but not exceeding, that observed in the wild-type strain if transformation is performed with cells containing multiple copies of REC2.

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.

Catalysis of ATP-dependent homologous DNA pairing and strand exchange by yeast RAD51 protein

The RAD51 gene of Saccharomyces cerevisiae is required for genetic recombination and DNA double-strand break repair. Here it is demonstrated that RAD51 protein pairs circular viral single-stranded DNA from phi X 174 or M13 with its respective homologous linear double-stranded form. The product of synapsis between these DNA partners is further processed by RAD51 to yield nicked circular duplex DNA, which indicates that RAD51 can catalyze strand exchange. The pairing and strand exchange reaction requires adenosine triphosphate, a result consistent with the presence of a DNA-dependent adenosine triphosphatase activity in RAD51 protein. Thus, RAD51 is a eukaryotic recombination protein that can catalyze the strand exchange reaction.

A chimeric Rec-A protein that implicates non-Watson-Crick interactions in homologous pairing

The helical filament formed by RecA protein on single-stranded DNA plays an important role in homologous recombination and pairs with a complementary single strand or homologous duplex DNA. The RecA nucleoprotein filament also recognizes an identical single strand. The chimeric protein, RecAc38, forms a nucleoprotein filament that recognizes a complementary strand but is defective in recognition of duplex DNA, and is associated with phenotypic defects in repair and recombination. As described here, RecAc38 nucleoprotein filament is also defective in recognition of an identical strand, either when the filament has within it a single strand or duplex DNA. A model that postulates three DNA binding sites rationalizes these observations and suggests that the third binding site mediates non-Watson-Crick interactions that are instrumental in recognition of homology in duplex DNA.

The Sep1 strand exchange protein from Saccharomyces cerevisiae promotes a paranemic joint between homologous DNA molecules

Strand exchange protein 1 (Sep1) from the yeast Saccharomyces cerevisiae promotes the transfer of one strand of a linear duplex DNA to a homologous single-stranded DNA circle. Using a nitrocellulose filter binding assay and electron microscopy, we find that Sep1 promotes the pairing of homologous DNA molecules via a paranemic joint. In this joint there is no net intertwining of the parental DNA molecules, as in the standard plectonemic double helix. The paranemic joints form with as little as 41 bp of homology between the parental DNA molecules. The substrates used were a circular molecule (either single-stranded DNA or duplex supercoiled DNA) and a linear duplex with heterologous regions at both ends to bar duplex plectonemic intertwining. We excluded the possibility that the exonuclease activity of Sep1 exposes complementary single-stranded regions that constitute the joint. The paranemic joint is the key intermediate in the search for homologous DNA by the RecA protein of Escherichia coli. Our results imply that the search process in a eukaryote such as yeast can be mechanistically similar.

Sequence of the RAD55 gene of Saccharomyces cerevisiae: similarity of RAD55 to prokaryotic RecA and other RecA-like proteins

The RAD55 gene is required for radiation resistance and meiotic viability and presumably acts in recombination and recombinational DNA repair pathways. The nucleotide (nt) sequence of RAD55 from Saccharomyces cerevisiae was determined. The amino-acid sequence predicted from the nt sequence showed similarity to the RecA protein of bacteria and the RecA-like proteins from yeast: RAD51, RAD57 and DMC1. Similarity was strongest in the region of RecA that interacts with ATP cofactor.

Recombination genes and proteins

The recombination of DNA takes place by a multistep process involving numerous gene products. In the past year, studies using bacterial proteins have led to a number of significant advances in our understanding of the enzymes of recombination and of the reactions that they catalyze. Moreover, the identification of eukaryotic proteins that are structurally analogous to the principal bacterial recombination enzyme, RecA protein, suggests that the basic mechanisms of homologous pairing and strand exchange have been conserved through evolution from bacteria to man.

The search for the right partner: homologous pairing and DNA strand exchange proteins in eukaryotes

Finding the right partner is a central problem in homologous recombination. Common to all models for general recombination is a homologous pairing and DNA strand exchange step. In prokaryotes this process has mainly been studied with the RecA protein of Escherichia coli. Two approaches have been used to find homologous pairing and DNA strand exchange proteins in eukaryotes. A biochemical approach has resulted in numerous proteins from various organisms. Almost all of these proteins are biochemically fundamentally different from RecA. The in vivo role of these proteins is largely not understood. A molecular-genetical approach has identified structural homologs to the E. coli RecA protein in the yeast Saccharomyces cerevisiae and subsequently in other organisms including other fungi, mammals, birds, and plants. The biochemistry of the eukaryotic RecA homologs is largely unsolved. For the fungal RecA homologs (S. cerevisiae RAD51, RAD55, RAD57, DMC1; Schizosaccharomyces pombe rad51; Neurospora crassa mei3) a role in homologous recombination and recombinational repair is evident. Besides recombination, homologous pairing proteins might be involved in other cellular processes like chromosome pairing or gene inactivation.

The recA gene from the thermophile Thermus aquaticus YT-1: cloning, expression, and characterization

We have cloned, expressed, and purified the RecA analog from the thermophilic eubacterium Thermus aquaticus YT-1. Analysis of the deduced amino acid sequence indicates that the T. aquaticus RecA is structurally similar to the Escherichia coli RecA and suggests that RecA-like function has been conserved in thermophilic organisms. Preliminary biochemical analysis indicates that the protein has an ATP-dependent single-stranded DNA binding activity and can pair and carry out strand exchange to form a heteroduplex DNA under reaction conditions previously described for E. coli RecA, but at 55 to 65 degrees C. Further characterization of a thermophilically derived RecA protein should yield important information concerning DNA-protein interactions at high temperatures. In addition, a thermostable RecA protein may have some general applicability in stabilizing DNA-protein interactions in reactions which occur at high temperatures by increasing the specificity (stringency) of annealing reactions.

ATP-dependent DNA renaturation and DNA-dependent ATPase reactions catalyzed by the Ustilago maydis homologous pairing protein

Purification of the ATP-dependent homologous pairing activity from Ustilago maydis yields a protein preparation that is enriched for a 70-kDa polypeptide as determined by SDS-gel electrophoresis. The protein responsible for the ATP-dependent pairing activity, using renaturation of complementary single strands of DNA as an assay, has a Stokes radius of 3.6 nm and a sedimentation coefficient of 4.3 S consistent with the interpretation that the activity arises from a monomeric globular protein of 70 kDa. Including heparin-agarose and FPLC gel filtration chromatography steps in the previously published protocol improves the purification of the protein. ATP and Mg2+ are necessary cofactors for optimal DNA renaturation activity. ADP inhibits the reaction. Analysis of the ATP-dependent renaturation kinetics indicates the reaction proceeds through a first-order mechanism. The protein has an associated DNA-dependent ATPase as indicated by co-chromatography with the purified ATP-dependent renaturation activity through an FPLC gel-filtration column. Single-stranded DNA and Mg2+ are required for optimal ATP hydrolytic activity, although a number of other polynucleotides and divalent cations can substitute to varying degrees. Hydrolysis of ATP is activated in a sigmoidal manner with increasing amounts of the protein. At ATP concentrations below 0.1 mM the ATPase activity exhibits positive cooperativity as indicated from the Hill coefficient of 1.8 determined by steady-state kinetic analysis of the reaction. ADP and adenosine 5'-[beta,gamma-imido]triphosphate are inhibitors of the ATPase activity although they appear to exert their inhibitory effects through different modes. These results are interpreted as evidence for protein-protein interactions.

A common element involved in transcriptional regulation of two DNA alkylation repair genes (MAG and MGT1) of Saccharomyces cerevisiae

The Saccharomyces cerevisiae MAG gene encodes a 3-methyladenine DNA glycosylase that protects cells from killing by alkylating agents. MAG mRNA levels are induced not only by alkylating agents but also by DNA-damaging agents that do not produce alkylated DNA. We constructed a MAG-lacZ gene fusion to help identify the cis-acting promoter elements involved in regulating MAG expression. Deletion analysis defined the presence of one upstream activating sequence and one upstream repressing sequence (URS) and suggested the presence of a second URS. One of the MAG URS elements matches a decamer consensus sequence present in the promoters of 11 other S. cerevisiae DNA repair and metabolism genes, including the MGT1 gene, which encodes an O6-methylguanine DNA repair methyltransferase. Two proteins of 26 and 39 kDa bind specifically to the MAG and MGT1 URS elements. We suggest that the URS-binding proteins may play an important role in the coordinate regulation of these S. cerevisiae DNA repair genes.

A common element involved in transcriptional regulation of two DNA alkylation repair genes (MAG and MGT1) of Saccharomyces cerevisiae

The Saccharomyces cerevisiae MAG gene encodes a 3-methyladenine DNA glycosylase that protects cells from killing by alkylating agents. MAG mRNA levels are induced not only by alkylating agents but also by DNA-damaging agents that do not produce alkylated DNA. We constructed a MAG-lacZ gene fusion to help identify the cis-acting promoter elements involved in regulating MAG expression. Deletion analysis defined the presence of one upstream activating sequence and one upstream repressing sequence (URS) and suggested the presence of a second URS. One of the MAG URS elements matches a decamer consensus sequence present in the promoters of 11 other S. cerevisiae DNA repair and metabolism genes, including the MGT1 gene, which encodes an O6-methylguanine DNA repair methyltransferase. Two proteins of 26 and 39 kDa bind specifically to the MAG and MGT1 URS elements. We suggest that the URS-binding proteins may play an important role in the coordinate regulation of these S. cerevisiae DNA repair genes.

Protein splicing: selfish genes invade cellular proteins

Protein splicing is a series of enzymatic events involving intramolecular protein breakage, rejoining and intron homing, in which introns are able to promote the recombinative transposition of their own coding sequences. Eukaryotic and prokaryotic spliced proteins have conserved similar gene structure, but little amino acid identity. The genes coding for these spliced proteins contain internal in-frame introns that encode polypeptides that apparently self-excise from the resulting host protein sequences. Excision of the 'protein intron' is coupled with joining of the two flanking protein regions encoded by exons of the host gene. Some introns of this type encode DNA endonucleases, related to Group I RNA intron gene products, that stimulate gene conversion and self-transmission.

Knowledge-based model building of proteins: concepts and examples

We describe how to build protein models from structural templates. Methods to identify structural similarities between proteins in cases of significant, moderate to low, or virtually absent sequence similarity are discussed. The detection and evaluation of structural relationships is emphasized as a central aspect of protein modeling, distinct from the more technical aspects of model building. Computational techniques to generate and complement comparative protein models are also reviewed. Two examples, P-selectin and gp39, are presented to illustrate the derivation of protein model structures and their use in experimental studies.

Restructuring of DNA sequences in the germline genome of Oxytricha

Most genes in the germline genome of hypotrichous ciliates are crippled by the presence of interrupting sequences. Some genes are additionally impaired because their sequences are in disorder. These gene defects are corrected when germline chromosomal DNA sequences are amplified, cut, spliced, reordered, and eliminated to produce somatic DNA.

Meiotic recombination in yeast

Over the past several years, the yeast Saccharomyces cerevisiae has proven to be an extremely useful model system for understanding how cells acquire high recombinational ability during meiosis. Due to recent advances in the physical monitoring of DNA intermediates during meiosis, new cytological methods for visualization of chromosomes during pairing and exchange, and progress in the identification and analysis of recombination-defective mutants, a general picture of the order and dependencies of specific recombination events is now emerging.

A rapid method for cloning mutagenic DNA repair genes: isolation of umu-complementing genes from multidrug resistance plasmids R391, R446b, and R471a

Genetic and physiological experiments have demonstrated that the products of the umu-like operon are directly required for mutagenic DNA repair in enterobacteria. To date, five such operons have been cloned and studied at the molecular level. Given the apparent wide occurrence of these mutagenic DNA repair genes in enterobacteria, it seems likely that related genes will be identified in other bacterial species and perhaps even in higher organisms. We are interested in identifying such genes. However, standard methods based on either DNA or protein cross-hybridization are laborious and, given the overall homology between previously identified members of this family (41 to 83% at the protein level), would probably have limited success. To facilitate the rapid identification of more diverse umu-like genes, we have constructed two Escherichia coli strains that allow us to identify umu-like genes after phenotypic complementation assays. With these two strains, we have cloned novel umu-like genes from three R plasmids, the IncJ plasmid R391 and two IncL/M plasmids, R446b and R471a.