DNA strand exchange in the absence of homologous pairing

DNA binding, annealing, and strand exchange activities of Brh2 protein from Ustilago maydis

Brh2 is the Ustilago maydis ortholog of the BRCA2 tumor suppressor. It functions in repair of DNA by homologous recombination by controlling the action of Rad51. A critical aspect in the control appears to be the recruitment of Rad51 to single-stranded DNA regions exposed as lesions after damage or following a disturbance in DNA synthesis. In previous experimentation, Brh2 was shown to nucleate formation of the Rad51 nucleoprotein filament that becomes the active element in promoting homologous pairing and DNA strand exchange. Nucleation was found to be initiated at junctions of double-stranded and single-stranded DNA. Here we investigated the DNA binding specificity of Brh2 in more detail using oligonucleotide substrates. We observed that Brh2 prefers partially duplex structures with single-stranded branches, flaps, or D-loops. We found also that Brh2 has an inherent ability to promote DNA annealing and strand exchange reactions on free as well as RPA-coated substrates. Unlike Rad51, Brh2 was able to promote DNA strand exchange when preincubated with double-stranded DNA. These findings raise the notion that Brh2 may have roles in homologous recombination beyond the previously established Rad51 mediator activity.

Strand exchange protein 1 (Sep1) from Saccharomyces cerevisiae does not promote branch migration in vitro

It has been shown in vitro that Saccharomyces cerevisiae strand exchange protein 1 (Sep1) promotes the transfer of one strand of a linear duplex DNA to a homologous single-stranded DNA circle. Sep1 also has an exonuclease active on DNA and RNA. By using exonuclease III-treated linear duplex DNA with various lengths of single-stranded tail as well as Ca2+ to inhibit the exonuclease activity of Sep1, we show that the processivity of exonuclease activity of Sep1 is greater than previously reported. The results in this work also demonstrate that the joint molecule between the linear duplex and single-stranded circle observed from the Sep1-promoted strand transfer reaction is just the pairing between the long single-stranded tail of the linear duplex DNA (generated by the exonuclease activity of Sep1) and the single-stranded circular DNA. When a synthetic Holliday junction was used as substrate, branch migration facilitated by Sep1 could not be detected. Finally, using electron microscopy no alpha-structure, a joint molecule with displaced single-stranded DNA tail that indicates branch migration could be observed. The results imply that Sep1 cannot promote branch migration in vitro. Further investigation is needed to determine the role of Sep1 in recombination in vivo.

Cruciform structures and functions

In this paper, a structure-function analysis of B-DNA self-fitting is reviewed in the light of recent oligonucleotide crystal structures. Their crystal packings provided a high-resolution view of B-DNA helices closely and specifically fitted by groove-backbone interaction, a natural and biologically relevant manner to assemble B-DNA helices. In revealing that new properties of the DNA molecule emerge during condensation, these crystallographic studies have pointed to the biological importance of DNA—DNA interactions.

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.

Homologous DNA pairing promoted by a 20-amino acid peptide derived from RecA

The molecular structure of the Escherichia coli RecA protein in the absence of DNA revealed two disordered or mobile loops that were proposed to be DNA binding sites. A short peptide spanning one of these loops was shown to carry out the key reaction mediated by the whole RecA protein: pairing (targeting) of a single-stranded DNA to its homologous site on a duplex DNA. In the course of the reaction the peptide bound to both substrate DNAs, unstacked the single-stranded DNA, and assumed a beta structure. These events probably recapitulate the underlying molecular pathway or mechanism used by homologous recombination proteins.

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.

Accelerated hybridization of oligonucleotides to duplex DNA

We report two strategies for accelerating the hybridization of oligonucleotides to DNA. We demonstrate that oligodeoxyribonucleotides and peptide nucleic acid oligomers hybridize to inverted repeats within duplex DNA by D-loop formation. Oligonucleotides and duplex template form an active complex, which can be recognized by T7 DNA polymerase to prime polymerization. Quantitation of polymerization products allowed the rate of hybridization to be estimated, and peptide nucleic acid oligomers and oligonucleotide-protein adducts anneal with association constants 500- and 12,000-fold greater, respectively, than the analogous unmodified oligonucleotides. Together, these results indicate that sequences within duplex DNA can be targeted by Watson-Crick base pairing and that chemical modifications can dramatically enhance the rate of strand association. These findings should facilitate targeting of oligomers for priming DNA polymerization, the detection of diagnostic sequences, and the disruption of gene expression. The observed acceleration of hybridization may offer a new perspective on the ability of RecA or other proteins to accelerate strand invasion.