Purification and characterization of a protein from human cells which promotes homologous pairing of DNA

The herpes simplex virus type 1 alkaline nuclease and single-stranded DNA binding protein mediate strand exchange in vitro

The replication of herpes simplex virus type 1 (HSV-1) DNA is associated with a high degree of homologous recombination. While cellular enzymes may take part in mediating this recombination, we present evidence for an HSV-1-encoded recombinase activity. HSV-1 alkaline nuclease, encoded by the UL12 gene, is a 5'-->3' exonuclease that shares homology with Redalpha, commonly known as lambda exonuclease, an exonuclease required for homologous recombination by bacteriophage lambda. The HSV-1 single-stranded DNA binding protein ICP8 is an essential protein for HSV DNA replication and possesses single-stranded DNA annealing activities like the Redbeta synaptase component of the phage lambda recombinase. Here we show that UL12 and ICP8 work together to effect strand exchange much like the Red system of lambda. Purified UL12 protein and ICP8 mediated the complete exchange between a 7.25-kb M13mp18 linear double-stranded DNA molecule and circular single-stranded M13 DNA, forming a gapped circle and a displaced strand as final products. The optimal conditions for strand exchange were 1 mM MgCl(2), 40 mM NaCl, and pH 7.5. Stoichiometric amounts of ICP8 were required, and strand exchange did not depend on the nature of the double-stranded end. Nuclease-defective UL12 could not support this reaction. These data suggest that diverse DNA viruses appear to utilize an evolutionarily conserved recombination mechanism.

Cloning and characterization of mouse Dhm2 cDNA, a functional homolog of budding yeast SEP1

We have isolated mouse Dhm2 cDNAs encoding a homolog of budding yeast SEP1, whose product is involved in many cellular processes including meiosis, cellular senescence, and telomere maintenance. The putative Dhm2 protein (Dhm2p), which consists of 1687 amino acids and whose molecular weight is 191,400, matches the size of Sep1p and shares extensive homology with Sep1p especially in their N-terminal regions. A multicopy plasmid containing of the Dhm2 cDNA complements the slow growth phenotype, sporulation defect, and DNA recombination defect caused by the sep1 mutation in yeast, indicating that Dhm2 is a functional homolog of SEP1. Since Dhm1, another SEP1 homolog we reported previously, only partially compensates for the sep1 mutation, we conclude that Dhm2 is a true homolog of SEP1. Northern analysis revealed that 5.8 kb mRNA corresponding to Dhm2 open reading frame is produced highly in testis. These results strongly suggest that Dhm2p participates in gametogenesis in mouse.

Preferential binding of poly(A)-binding protein 1 to an inhibitory RNA element in the human immunodeficiency virus type 1 gag mRNA

Human immunodeficiency virus type 1 (HIV-1) mRNAs encoding structural proteins contain multiple inhibitory/instability elements (INS), which decrease the efficiency of viral protein expression. We have previously identified a strong INS element (INS-1) within the p17(gag) coding region. Here we show that poly(A)-binding protein 1 (PABP1) binds preferentially to INS-1 within the p17(gag) mRNA, but not to a mutated mRNA in which INS-1 function is eliminated. Competition experiments performed in the presence of different nucleic acids and homoribopolymers demonstrated preferential binding of PABP1 to the INS-1-containing RNA. In contrast to HeLa cells and several lymphoid cell lines, certain human glioma cell lines exhibit high levels of gag expression in the absence of Rev upon transient transfection with wild type gag expression vectors. We analyzed extracts of different cell lines and found that the binding of PABP1 to INS-1 RNA is significantly diminished in glial cell extracts. The expression levels of gag correlate with the absence of binding of PABP1 to the INS-1 RNA in cellular extracts. These results suggest a role for PABP1 in the inhibition of gag expression mediated through INS-1.

A possible role of the C-terminal domain of the RecA protein. A gateway model for double-stranded DNA binding

According to the crystal structure, the RecA protein has a domain near the C terminus consisting of amino acid residues 270-328 (from the N terminus). Our model building pointed out the possibility that this domain is a part of "gateway" through which double-stranded DNA finds a path for direct contact with single-stranded DNA within a presynaptic RecA filament in the search for homology. To test this possible function of the domain, we made mutant RecA proteins by site-directed single (or double, in one case) replacement of 2 conserved basic amino acid residues and 5 among 9 nonconserved basic amino acid residues in the domain. Replacement of either of the 2 conserved amino acid residues caused deficiencies in repair of UV-damaged DNA, an in vivo function of RecA protein, whereas the replacement of most (except one) of the tested nonconserved ones gave little or no effect. Purified mutant RecA proteins showed no (or only slight) deficiencies in the formation of presynaptic filaments as assessed by various assays. However, presynaptic filaments of both proteins that had replacement of a conserved amino acid residue had significant defects in binding to and pairing with duplex DNA (secondary binding). These results are consistent with our model that the conserved amino acid residues in the C-terminal domain have a direct role in double-stranded DNA binding and that they constitute a part of a gateway for homologous recognition.

Characterisation of a DNA pairing activity copurifying with DNA ligase in a partially purified extract from rat testis

Rat testicular nuclear extracts were fractionated sequentially on phosphocellulose, heparin-agarose and ssDNA-cellulose columns, in order to isolate and characterise a strand-transfer activity from a mammalian meiotic tissue. A partially purified fraction, eluting at 0.6 M KCl from ssDNA-cellulose column, catalyzed the formation of two classes of products migrating slowly on an agarose gel. The formation of one of these classes of products-the aggregates-was dependent on the presence of both the substrates (M13mp19 RF III and M13mp19 ssDNA) and on homology. The presence of ATP was essential for the formation of aggregates, though its hydrolysis was not required. EM analysis of the products indicated the presence of structures which resembled paired DNA molecules: duplex-duplex paired (Y-shaped and ds-ds paired structures) and ss-ds paired (duplex DNA paired with the single-stranded DNA) structures, indicating the presence of a pairing protein in the fraction. However, alpha- and sigma-structures were not observed. The other class of products, seen as discrete bands, were identified biochemically and by electron microscopy as ligated products. A DNA ligase-adenylate adduct of molecular weight 100 kDa was formed by the fraction. Both 5' to 3' and 3' to 5' exonucleases were absent and hence did not contribute to the formation of the products.

Partial purification and characterization of two types of homologous DNA pairing activity from rat testis nuclei

We describe the partial purification and characterization of two different types of homologous DNA pairing activity from rat testis nuclear extracts. The activities are separated from each other by single-stranded DNA-cellulose affinity chromatography. One activity requires single-stranded DNA ends and promotes the homologous pairing of single-stranded DNA fragments with double-stranded circular DNA and has an apparent molecular mass of 100 kDa as determined by gel filtration chromatography. This pairing activity does not require the addition of exogenous ATP and is strongly Mg2+ -dependent. The second pairing activity promotes strand-transfer between single-stranded circular DNA and homologous double-stranded DNA fragments and has an apparent molecular mass of 30 kDa as determined by gel filtration chromatography. This pairing activity also does not require ATP but, in contrast to the former, is Mg2+ -independent.

Analysis of the mammalian recombination protein complex RC-1

Based on a novel cell-free assay for DNA recombination, we previously reported the purification and initial characterization of RC-1, a protein complex catalyzing the recombinational repair of deletions and gaps. RC-1 was isolated from calf thymus nuclear extracts and shown to copurify with several enzymatic activities, among them a DNA polymerase. Here, additional evidence is reported identifying the polymerase as DNA polymerase epsilon. Furthermore, a novel DNA structure-dependent endonuclease associated with RC-1 was observed, which recognizes and cleaves branched DNA substrates at specific sites. Implications of this endonuclease activity for the recombination reaction are discussed.

Use of monoclonal antibodies in the functional characterization of the Saccharomyces cerevisiae Sep1 protein

The Saccharomyces cerevisiae strand-exchange protein 1 (Sep1 also known as Xrn1, Kem1, Rar5, Stp beta/DST2) has been demonstrated to mediate the formation of hybrid DNA from model substrates of linear double-stranded and circular single-stranded DNA in vitro. To delineate the mechanism by which Sep1 acts in the strand-exchange reaction, we analyzed mouse anti-Sep1 monoclonal antibodies for inhibition of the Sep1 in vitro activity. Of 12 class-G immunoglobulins tested, four were found to consistently inhibit the Sep1-mediated strand-exchange reaction. The inhibiting antibodies were tested for inhibition of a variety of Sep1-catalyzed DNA reactions including exonuclease activity on double-stranded and single-stranded DNA, renaturation of complementary single-stranded DNA and condensation of DNA into large aggregates. All four inhibiting antibodies had no effect on the exonuclease activity of Sep1. Three antibodies specifically blocked DNA aggregation. In addition, one antibody inhibited renaturation of complementary single-stranded DNA. This inhibition pattern underlines the importance of condensation of DNA into large aggregates in conjunction with double-stranded DNA exonuclease activity for the in vitro homologous pairing activity of Sep1. The implications of these data for the interpretation of proteins which promote homologous pairing of DNA are discussed, in particular in light of the reannealing activity of the p53 human tumor-suppressor protein.

Saccharomyces cerevisiae cells lacking the homologous pairing protein p175SEP1 arrest at pachytene during meiotic prophase

Saccharomyces cerevisiae cells containing null mutations in the SEP1 gene, which encodes the homologous pairing and strand exchange protein p175SEP1, enter pachytene with a delay. They arrest uniformly at this stage of meiotic prophase, probably revealing a checkpoint in the transition from pachytene to meiosis I. At the arrest point, the cells remain largely viable and are cytologically characterized by the duplicated but unseparated spindle pole bodies of equal size and by the persistence of the synaptonemal complex, a cytological marker for pachytene. In addition, fluorescence in situ hybridization revealed that in arrested mutant cells maximal chromatin condensation and normal homolog pairing is achieved, typical for pachytene in wild type. A hallmark of meiosis is the high level of homologous recombination, which was analyzed both genetically and physically. Formation and processing of the double-strand break intermediate in meiotic recombination is achieved prior to arrest. Physical intragenic (conversion) and intergenic (crossover) products are formed just prior to, or directly at, the arrest point. Structural deficits in synaptonemal complex morphology, failure to separate spindle pole bodies, and/or defects in prophase DNA metabolism might be responsible for triggering the observed arrest. The pachytene arrest in sep1 cells is likely to be regulatory, but is clearly different from the RAD9 checkpoint in meiotic prophase, which occurs prior to the pachytene stage.

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 human mutator gene homolog MSH2 and its association with hereditary nonpolyposis colon cancer

We have identified a human homolog of the bacterial MutS and S. cerevisiae MSH proteins, called hMSH2. Expression of hMSH2 in E. coli causes a dominant mutator phenotype, suggesting that hMSH2, like other divergent MutS homologs, interferes with the normal bacterial mismatch repair pathway. hMSH2 maps to human chromosome 2p22-21 near a locus implicated in hereditary nonpolyposis colon cancer (HNPCC). A T to C transition mutation has been detected in the -6 position of a splice acceptor site in sporadic colon tumors and in affected individuals of two small HNPCC kindreds. These data and reports indicating that S. cerevisiae msh2 mutations cause an instability of dinucleotide repeats like those associated with HNPCC suggest that hMSH2 is the HNPCC gene.

Isolation of multiple activities from mouse FM3A cells which promote homologous pairing of DNA molecules

We describe the detection and partial purification of three homologous pairing activities from extracts of mouse mammary carcinoma FM3A cells. These activities, designated MHP1a, 1b, and 1c, form joint molecules between circular single-stranded DNA and homologous linear duplex DNA and are distinguished from one another by their chromatographic behaviors or isoelectric properties. The reactions promoted by these activities require homologous substrates but not ATP. All the reactions also show Mg2+ dependence in the absence of exogenous ATP. Analysis of the reaction products has revealed that strand exchange proceeds for lengths of up to at least 271 bp during the homologous pairing reaction. The finding of multiple types of homologous pairing and strand exchange activity in mouse cells may facilitate the elucidation of the mechanism of homologous recombination in somatic mammalian cells.

Z-DNA binding and inhibition by GTP of Drosophila topoisomerase II

A Z-DNA binding protein has been isolated and characterized by biochemical means from Drosophila melanogaster tissue culture cells and embryos. This protein shares the following properties with the known, cloned Drosophila topoisomerase II: (1) expression of an ATP-dependent relaxation activity on supercoiled DNA; (2) a monomer mass of 165 kDa in SDS denaturing gels; (3) a sedimentation coefficient, S20,w, of approximately 10 S for the active enzyme; (4) cross-reactivity for the respective monoclonal and polyclonal antibodies; (5) generation of covalent enzyme-DNA intermediates at preferred cutting sites in the Drosophila HSP70 intergenic spacer region; (6) inhibition of DNA relaxation activity by antitumor drugs, e.g., the etoposide VM26, and by monospecific antibodies raised against the protein; and (7) in vitro phosphorylation by a casein kinase activity. However, we have identified new properties for our topoisomerase II preparation not previously reported for the conventionally isolated enzyme: (1) The enzyme binds to Z-DNA with an affinity 2 orders of magnitude greater than that for B-DNA. (2) The binding to Z-DNA is increased 5-10-fold by GTP or GTP-gamma-S. (3) GTP and GTP-gamma-S inhibit the catalytic activity of topoisomerase II through a proposed allosteric mechanism. (4) Z-DNA inhibits the relaxation of closed circular supercoiled DNA. (5) The preparation consists of a single polypeptide chain of 165 kDa on denaturing SDS gels with no evidence of proteolytic degradation. We postulate that the Z-DNA binding activity of undegraded topoisomerase II may be important in targeting the enzyme both to structural motifs required for chromatin organization and to sites of local supercoiling. Some of these features arise during processes such as replication and gene expression and may be more frequent during embryogenesis and early development.

ATP hydrolysis and the displaced strand are two factors that determine the polarity of RecA-promoted DNA strand exchange

When the recA protein (RecA) of Escherichia coli promotes strand exchange between single-stranded DNA (ssDNA) circles and linear double-stranded DNAs (dsDNA) with complementary 5' or 3' ends a polarity is observed. This property of RecA depends on ATP hydrolysis and the ssDNA that is displaced in the reaction since no polarity is observed in the presence of the non-hydrolyzable ATP analog, ATP gamma S, or in the presence of single-strand specific exonucleases. Based on these results a model is presented in which both the 5' and 3' complementary ends of the linear dsDNA initiate pairing with the ssDNA circle but only one end remains stably paired. According to this model, the association/dissociation of RecA in the 5' to 3' direction on the displaced strand determines the polarity of strand exchange by favoring or blocking its reinvasion into the newly formed dsDNA. Reinvasion is favored when the displaced strand is coated with RecA whereas it is blocked when it lacks RecA, remains covered by single-stranded DNA binding protein or is removed by a single-strand specific exonuclease. The requirement for ATP hydrolysis is explained if the binding of RecA to the displaced strand occurs via the dissociation and/or transfer of RecA, two functions that depend on ATP hydrolysis. The energy for strand exchange derives from the higher binding constant of RecA for the newly formed dsDNA as compared with that for ssDNA and not from ATP hydrolysis.

Identification of two types of homologous DNA pairing activity in mouse cells

We have identified two types of homologous DNA pairing activity in mouse cell extracts by a strand-transfer assay. Both activities are separated from each other by anion-exchange chromatography; neither of them needs ATP. One requires magnesium ion and is stimulated by Escherichia coli single-stranded DNA binding protein, whereas the other does not require the ion and shows a higher affinity for a left-handed Z-DNA.

Biochemical activities of the parA partition protein of the P1 plasmid

The unit-copy P1 plasmid depends for stability on a plasmid-encoded partition region called par, consisting of the parA and parB genes and the parS site. ParA is absolutely required for partition, but its partition-critical role is not known. Purified ParA protein is shown to possess an ATPase activity in vitro which is specifically stimulated by purified ParB protein and by DNA. ParA is responsible for regulation of expression of parA and parB, and purified ParA has an ATP-dependent, site-specific DNA binding activity which recognizes a sequence that overlaps the parA promoter. The role of the ATP-dependence of the binding activity, as well as other possible functions of the ATPase activity in partition, is discussed.

The RecA protein as a recombinational repair system

The Escherichia coli RecA protein plays a central role in homologous genetic recombination, recombinational repair, and several other processes in bacteria. In vitro, an extended filament involving thousands of RecA monomers promotes a reaction in which individual DNA strands switch pairing partners (DNA strand exchange). This reaction has been extensively studied as a paradigm for the central steps in recombination. Because the strand-exchange reaction is relatively simple and isoenergetic, the complexity of the RecA system that carries it out has led to controversy about the functional significance of many fundamental properties of RecA. Filamentous protein structures involving thousands of RecA monomers, which hydrolyse 100 ATPs per base pair of heteroduplex DNA formed, are hard to rationalize in the context of recombination between two homologous DNAs. The thermodynamic barriers to strand exchange are much too small. These molecular features of the system can be easily rationalized, however, by shifting the focus to DNA repair.

An overview of homologous pairing and DNA strand exchange proteins

Processes fundamental to all models of genetic recombination include the homologous pairing and subsequent exchange of DNA strands. Biochemical analysis of these events has been conducted primarily on the recA protein of Escherichia coli, although proteins which can promote such reactions have been purified from many sources, both prokaryotic and eukaryotic. The activities of these homologous pairing and DNA strand exchange proteins are either ATP-dependent, as predicted based on the recA protein paradigm, or, more unexpectedly, ATP-independent. This review examines the reactions promoted by both classes of proteins and highlights their similarities and differences. The mechanistic implications of the apparent existence of 2 classes of strand exchange protein are discussed.

Biochemical studies of homologous and nonhomologous recombination in human cells

Purified and partially purified protein fractions from human cells have been developed that promote homologous and nonhomologous recombination reactions in vitro. Homologous pairing of model DNA substrates is catalyzed by the homologous pairing protein HPP-1 in a magnesium-dependent, ATP-independent reaction that requires stoichiometric amounts of the protein. Addition of the human single-strand binding (SSB) holoprotein complex hRP-A reduces the requirement of HPP-1 in the reaction up to 20-fold. Although the combination of homologous pairing and SSB activities is similar to the bacterial strand-exchange process, the numbers, size, and requirements of the human reaction appear to preclude any detailed comparisons. We have used Z-DNA affinity chromatography as a major step in isolation of human recombination proteins and found that the activities appear to elute as a complex form in approximate multiples of 500 kDa. Associated with the homologous recombination complex is a potent blunt-end ligation activity that appears to mimic the nonhomologous joining functions that are frequently seen following transfection of DNA into mammalian cells. A simple scheme for the association of homologous and nonhomologous recombination functions in mammalian cells is discussed.

Saccharomyces cerevisiae proteins involved in hybrid DNA formation in vitro

RecA-like activities that can form hybrid DNA in vitro have been identified in a wide variety of organisms. We have previously described the strand exchange protein 1 (SEP1) from the yeast Saccharomyces cerevisiae that can form hybrid DNA in vitro. Purified as an Mr 132,000 polypeptide, recent molecular and immunological studies have now shown that the native form is an Mr 175,000 polypeptide containing strand exchange activity. The gene encoding SEP1 has been cloned and sequenced. The primary sequence failed to reveal any significant sequence homology to other sequences in data base searches. In vivo SEP1 was found to be essential for normal meiosis as cells containing a homozygous insertion mutation in the SEP1 gene failed to sporulate. In order to identify additional factors that are involved in hybrid DNA formation in S cerevisiae, we used an in vitro stimulation assay to identify proteins that reconstitute strand exchange activity in reactions containing limiting amounts of SEP1. We have identified two proteins that functionally interact with SEP1. First, an Mr 34,000 single-stranded DNA binding protein stimulated the reaction by lowering the requirement for SEP1 about 3-4 fold. This protein is a fragment of the large subunit of a hetero-trimeric complex called yRP-A (yRF-A) which is thought to be the functional eukaryotic equivalent of single-stranded DNA binding proteins in prokaryotes. The gene encoding this protein (RPA1) is essential for growth. Second, an Mr 33,000 polypeptide, termed Stimulatory Factor 1 (SF1), dramatically stimulated the SEP1 catalyzed reaction by lowering the requirement for SEP1 about 300 fold.(ABSTRACT TRUNCATED AT 250 WORDS)