Kinetics of presynaptic filament assembly in the presence of single-stranded DNA binding protein and recombination mediator protein

A real-time fluorescent gp32 probe-based assay for monitoring single-stranded DNA-dependent DNA processing enzymes

Single-stranded DNA (ssDNA) generated during DNA replication, recombination and damage repair reactions is an important intermediate and ssDNA-binding proteins that binds these intermediates coordinate various DNA metabolic processes. Mechanistic details of these ssDNA-dependent processes can be explored by monitoring the generation and consumption of ssDNA in real time. In this work, a fluorescein-labeled gp32-based sensor was employed to continuously monitor various aspects of ssDNA-dependent DNA replication and recombination processes in real time. The gp32 protein probe displayed high sensitivity and specificity to a variety of ssDNA-dependent processes of T4 phage. Several applications of the probe are illustrated here: the solution dynamics of ssDNA-binding protein, protein-protein and protein-DNA interactions involving gp32 protein and its mode of interaction, ssDNA translocation and protein displacement activities of helicases, primer extension activity of DNA polymerase holoenzyme and nucleoprotein filament formation during DNA recombination. The assay has identified new protein-protein interactions of gp32 during T4 replication and recombination. The fluorescent probe described here can thus be used as a universal probe for monitoring in real time various ssDNA-dependent processes, which is based on a well-characterized and easy-to-express bacteriophage T4 gene 32 protein, gp32.

In vitro reconstitution of DNA replication initiated by genetic recombination: a T4 bacteriophage model for a type of DNA synthesis important for all cells

Using a mixture of 10 purified DNA replication and DNA recombination proteins encoded by the bacteriophage T4 genome, plus two homologous DNA molecules, we have reconstituted the genetic recombination–initiated pathway that initiates DNA replication forks at late times of T4 bacteriophage infection. Inside the cell, this recombination-dependent replication (RDR) is needed to produce the long concatemeric T4 DNA molecules that serve as substrates for packaging the shorter, genome-sized viral DNA into phage heads. The five T4 proteins that catalyze DNA synthesis on the leading strand, plus the proteins required for lagging-strand DNA synthesis, are essential for the reaction, as are a special mediator protein (gp59) and a Rad51/RecA analogue (the T4 UvsX strand-exchange protein). Related forms of RDR are widespread in living organisms—for example, they play critical roles in the homologous recombination events that can restore broken ends of the DNA double helix, restart broken DNA replication forks, and cross over chromatids during meiosis in eukaryotes. Those processes are considerably more complex, and the results presented here should be informative for dissecting their detailed mechanisms.

Sak4 of Phage HK620 Is a RecA Remote Homolog With Single-Strand Annealing Activity Stimulated by Its Cognate SSB Protein

Bacteriophages are remarkable for the wide diversity of proteins they encode to perform DNA replication and homologous recombination. Looking back at these ancestral forms of life may help understanding how similar proteins work in more sophisticated organisms. For instance, the Sak4 family is composed of proteins similar to the archaeal RadB protein, a Rad51 paralog. We have previously shown that Sak4 allowed single-strand annealing in vivo, but only weakly compared to the phage λ Redβ protein, highlighting putatively that Sak4 requires partners to be efficient. Here, we report that the purified Sak4 of phage HK620 infecting Escherichia coli is a poorly efficient annealase on its own. A distant homolog of SSB, which gene is usually next to the sak4 gene in various species of phages, highly stimulates its recombineering activity in vivo. In vitro, Sak4 binds single-stranded DNA and performs single-strand annealing in an ATP-dependent way. Remarkably, the single-strand annealing activity of Sak4 is stimulated by its cognate SSB. The last six C-terminal amino acids of this SSB are essential for the binding of Sak4 to SSB-covered single-stranded DNA, as well as for the stimulation of its annealase activity. Finally, expression of sak4 and ssb from HK620 can promote low-level of recombination in vivo, though Sak4 and its SSB are unable to promote strand exchange in vitro. Regarding its homology with RecA, Sak4 could represent a link between two previously distinct types of recombinases, i.e., annealases that help strand exchange proteins and strand exchange proteins themselves.

The genome of AR9, a giant transducing Bacillus phage encoding two multisubunit RNA polymerases

Bacteriophage AR9 and its close relative PBS1 have been extensively used to construct early Bacillus subtilis genetic maps. Here, we present the 251,042bp AR9 genome, a linear, terminally redundant double-stranded DNA containing deoxyuridine instead of thymine. Multiple AR9 genes are interrupted by non-coding sequences or sequences encoding putative endonucleases. We show that these sequences are group I and group II self-splicing introns. Eight AR9 proteins are homologous to fragments of bacterial RNA polymerase (RNAP) subunits β/β'. These proteins comprise two sets of paralogs of RNAP largest subunits, with each paralog encoded by two disjoint phage genes. Thus, AR9 is a phiKZ-related giant phage that relies on two multisubunit viral RNAPs to transcribe its genome independently of host transcription apparatus. Purification of one of PBS1/AR9 RNAPs has been reported previously, which makes AR9 a promising object for further studies of RNAP evolution, assembly and mechanism.

RAD51 variant proteins from human lung and kidney tumors exhibit DNA strand exchange defects

In human cells, error-free repair of DNA double-strand breaks requires the DNA pairing and strand exchange activities of RAD51 recombinase. Activation of RAD51 recombination activities requires the assembly of RAD51 presynaptic filaments on the single-stranded DNA that forms at resected DSB ends. Mutations in proteins that control presynaptic filament assembly, such as BRCA2, and in RAD51 itself, are associated with human breast cancer. Here we describe the properties of two mutations in RAD51 protein that derive from human lung and kidney tumors, respectively. Sequence variants Q268P and Q272L both map to the DNA binding loop 2 (L2) region of RAD51, a motif that is involved in DNA binding and in the allosteric activation of ATP hydrolysis and DNA strand exchange activities. Both mutations alter the thermal stability, DNA binding, and ATPase properties of RAD51, however both variants retain intrinsic DNA strand exchange activity towards oligonucleotide substrates under optimized conditions. In contrast, both Q268P and Q272L variants exhibit drastically reduced DNA strand exchange activity in reaction mixtures containing long homologous ssDNA and dsDNA substrates and human RPA protein. Mixtures of wild-type and variant proteins also exhibit reduced DNA strand exchange activity, suggesting that heterozygous mutations could negatively affect DNA recombination and repair processes in vivo. Together, the findings of this study suggest that hypomorphic missense mutations in RAD51 protein could be drivers of genomic instability in cancer cells, and thereby contribute to the etiology of metastatic disease.

DNA-pairing and annealing processes in homologous recombination and homology-directed repair

The formation of heteroduplex DNA is a central step in the exchange of DNA sequences via homologous recombination, and in the accurate repair of broken chromosomes via homology-directed repair pathways. In cells, heteroduplex DNA largely arises through the activities of recombination proteins that promote DNA-pairing and annealing reactions. Classes of proteins involved in pairing and annealing include RecA-family DNA-pairing proteins, single-stranded DNA (ssDNA)-binding proteins, recombination mediator proteins, annealing proteins, and nucleases. This review explores the properties of these pairing and annealing proteins, and highlights their roles in complex recombination processes including the double Holliday junction (DhJ) formation, synthesis-dependent strand annealing, and single-strand annealing pathways--DNA transactions that are critical both for genome stability in individual organisms and for the evolution of species.