Rad54 protein stimulates the postsynaptic phase of Rad51 protein-mediated DNA strand exchange.

Rad54 and Rad51 are important proteins for the repair of double-stranded DNA breaks by homologous recombination in eukaryotes. As previously shown, Rad51 protein forms nucleoprotein filaments on single-stranded DNA, and Rad54 protein directly interacts with such filaments to enhance synapsis, the homologous pairing with a double-stranded DNA partner. Here we demonstrate that Saccharomyces cerevisiae Rad54 protein has an additional role in the postsynaptic phase of DNA strand exchange by stimulating heteroduplex DNA extension of established joint molecules in Rad51/Rpa-mediated DNA strand exchange. This function depended on the ATPase activity of Rad54 protein and on specific protein:protein interactions between the yeast Rad54 and Rad51 proteins.

Rad54 protein stimulates heteroduplex DNA formation in the synaptic phase of DNA strand exchange via specific interactions with the presynaptic Rad51 nucleoprotein filament.

RAD54 is an important member of the RAD52 group of genes that carry out recombinational repair of DNA damage in the yeast Saccharomyces cerevisiae. Rad54 protein is a member of the Snf2/Swi2 protein family of DNA-dependent/stimulated ATPases, and its ATPase activity is crucial for Rad54 protein function. Rad54 protein and Rad54-K341R, a mutant protein defective in the Walker A box ATP-binding fold, were fused to glutathione-S-transferase (GST) and purified to near homogeneity. In vivo, GST-Rad54 protein carried out the functions required for methyl methanesulfonate sulfate (MMS), UV, and DSB repair. In vitro, GST-Rad54 protein exhibited dsDNA-specific ATPase activity. Rad54 protein stimulated Rad51/Rpa-mediated DNA strand exchange by specifically increasing the kinetics of joint molecule formation. This stimulation was accompanied by a concurrent increase in the formation of heteroduplex DNA. Our results suggest that Rad54 protein interacts specifically with established Rad51 nucleoprotein filaments before homology search on the duplex DNA and heteroduplex DNA formation. Rad54 protein did not stimulate DNA strand exchange by increasing presynaptic complex formation. We conclude that Rad54 protein acts during the synaptic phase of DNA strand exchange and after the formation of presynaptic Rad51 protein-ssDNA filaments.

Rad54 protein is targeted to pairing loci by the Rad51 nucleoprotein filament.

Rad51 and Rad54 proteins are important for the repair of double-stranded DNA (dsDNA) breaks by homologous recombination in eukaryotes. Rad51 assembles on single-stranded DNA (ssDNA) to form a helical nucleoprotein filament that performs homologous pairing with dsDNA; Rad54 stimulates this pairing substantially. Here, we demonstrate that Rad54 acts in concert with the mature Rad51-ssDNA filament. Enhancement of DNA pairing by Rad54 is greatest at an equimolar ratio relative to Rad51 within the filament. Reciprocally, the Rad51-ssDNA filament enhances both the dsDNA-dependent ATPase and the dsDNA unwinding activities of Rad54. We conclude that Rad54 participates in the DNA homology search as a component of the Rad51-nucleoprotein filament and that the filament delivers Rad54 to the dsDNA pairing locus, thereby linking the unwinding of potential target DNA with the homology search process.

Active-site mutations in the Xrn1p exoribonuclease of Saccharomyces cerevisiae reveal a specific role in meiosis.

Xrn1p of Saccharomyces cerevisiae is a major cytoplasmic RNA turnover exonuclease which is evolutionarily conserved from yeasts to mammals. Deletion of the XRN1 gene causes pleiotropic phenotypes, which have been interpreted as indirect consequences of the RNA turnover defect. By sequence comparisons, we have identified three loosely defined, common 5'-3' exonuclease motifs. The significance of motif II has been confirmed by mutant analysis with Xrn1p. The amino acid changes D206A and D208A abolish singly or in combination the exonuclease activity in vivo. These mutations show separation of function. They cause identical phenotypes to that of xrn1Delta in vegetative cells but do not exhibit the severe meiotic arrest and the spore lethality phenotype typical for the deletion. In addition, xrn1-D208A does not cause the severe reduction in meiotic popout recombination in a double mutant with dmc1 as does xrn1Delta. Biochemical analysis of the DNA binding, exonuclease, and homologous pairing activity of purified mutant enzyme demonstrated the specific loss of exonuclease activity. However, the mutant enzyme is competent to promote in vitro assembly of tubulin into microtubules. These results define a separable and specific function of Xrn1p in meiosis which appears unrelated to its RNA turnover function in vegetative cells.

A mouse cytoplasmic exoribonuclease (mXRN1p) with preference for G4 tetraplex substrates.

Exoribonucleases are important enzymes for the turnover of cellular RNA species. We have isolated the first mammalian cDNA from mouse demonstrated to encode a 5'-3' exoribonuclease. The structural conservation of the predicted protein and complementation data in Saccharomyces cerevisiae suggest a role in cytoplasmic mRNA turnover and pre-rRNA processing similar to that of the major cytoplasmic exoribonuclease Xrn1p in yeast. Therefore, a key component of the mRNA decay system in S. cerevisiae has been conserved in evolution from yeasts to mammals. The purified mouse protein (mXRN1p) exhibited a novel substrate preference for G4 RNA tetraplex-containing substrates demonstrated in binding and hydrolysis experiments. mXRN1p is the first RNA turnover function that has been localized in the cytoplasm of mammalian cells. mXRN1p was distributed in small granules and was highly enriched in discrete, prominent foci. The specificity of mXRN1p suggests that RNAs containing G4 tetraplex structures may occur in vivo and may have a role in RNA turnover.

Identification of functional domains in the Sep1 protein (= Kem1, Xrn1), which is required for transition through meiotic prophase in Saccharomyces cerevisiae.

The Sep1 (also known as Kem1, Xrn1, Rar5, DST2/Stpbeta) protein of Saccharomyces cerevisiae is an Mr 175,000 multifunctional exonuclease with suspected roles in RNA turnover and in the microtubular cytoskeleton as well as in DNA recombination and DNA replication. The most striking phenotype of SEP1 null mutations is quantitative arrest during meiotic prophase at the pachytene stage. We have constructed a set of N- and C-terminal as well as internal deletions of the large SEP1 gene. Analysis of these deletion mutations on plasmids in a host carrying a null allele (sep1 ) revealed that at least 270 amino acids from the C-terminus of the wild-type protein were dispensable for complementing the slow growth and benomyl hypersensitivity of a null mutant. In contrast, any deletion at the N-terminus abrogated complementing activity for these phenotypes. The sequences essential for function correspond remarkably well with the regions of Sep1 that are homologous to its Schizosaccharomyces pombe counterpart Exo2. In addition, these experiments showed that, despite the high intracellular levels of Sep1, over-expression of this protein above these levels is detrimental to the cell. We discuss the potential cellular roles of the Sep1 protein as a microtubule-nucleic acid interface protein linking its suspected function in the microtubular cytoskeleton with its role as a nucleic acid binding protein.

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.