Michael Rolfsmeier

Rad54: the Swiss Army knife of homologous recombination?

Homologous recombination (HR) is a ubiquitous cellular pathway that mediates transfer of genetic information between homologous or near homologous (homeologous) DNA sequences. During meiosis it ensures proper chromosome segregation in the first division. Moreover, HR is critical for the tolerance and repair of DNA damage, as well as in the recovery of stalled and broken replication forks. Together these functions preserve genomic stability and assure high fidelity transmission of the genetic material in the mitotic and meiotic cell divisions. This review will focus on the Rad54 protein, a member of the Snf2-family of SF2 helicases, which translocates on dsDNA but does not display strand displacement activity typical for a helicase. A wealth of genetic, cytological, biochemical and structural data suggests that Rad54 is a core factor of HR, possibly acting at multiple stages during HR in concert with the central homologous pairing protein Rad51.

Phosphorylation of Rad55 on Serines 2, 8, and 14 Is Required for Efficient Homologous Recombination in the Recovery of Stalled Replication Forks

ABSTRACT DNA damage checkpoints coordinate the cellular response to genotoxic stress and arrest the cell cycle in response to DNA damage and replication fork stalling. Homologous recombination is a ubiquitous pathway for the repair of DNA double-stranded breaks and other checkpoint-inducing lesions. Moreover, homologous recombination is involved in postreplicative tolerance of DNA damage and the recovery of DNA replication after replication fork stalling. Here, we show that the phosphorylation on serines 2, 8, and 14 (S2,8,14) of the Rad55 protein is specifically required for survival as well as for normal growth under genome-wide genotoxic stress. Rad55 is a Rad51 paralog in Saccharomyces cerevisiae and functions in the assembly of the Rad51 filament, a central intermediate in recombinational DNA repair. Phosphorylation-defective rad55-S2,8,14A mutants display a very slow traversal of S phase under DNA-damaging conditions, which is likely due to the slower recovery of stalled replication forks or the slower repair of replication-associated DNA damage. These results suggest that Rad55-S2,8,14 phosphorylation activates recombinational repair, allowing for faster recovery after genotoxic stress.

Repair of DNA double-strand breaks following UV damage in three Sulfolobus solfataricus strains.

DNA damage repair mechanisms have been most thoroughly explored in the eubacterial and eukaryotic branches of life. The methods by which members of the archaeal branch repair DNA are significantly less well understood but have been gaining increasing attention. In particular, the approaches employed by hyperthermophilic archaea have been a general source of interest, since these organisms thrive under conditions that likely lead to constant chromosomal damage. In this work we have characterized the responses of three Sulfolobus solfataricus strains to UV-C irradiation, which often results in double-strand break formation. We examined S. solfataricus strain P2 obtained from two different sources and S. solfataricus strain 98/2, a popular strain for site-directed mutation by homologous recombination. Cellular recovery, as determined by survival curves and the ability to return to growth after irradiation, was found to be strain specific and differed depending on the dose applied. Chromosomal damage was directly visualized using pulsed-field gel electrophoresis and demonstrated repair rate variations among the strains following UV-C irradiation-induced double-strand breaks. Several genes involved in double-strand break repair were found to be significantly upregulated after UV-C irradiation. Transcript abundance levels and temporal expression patterns for double-strand break repair genes were also distinct for each strain, indicating that these Sulfolobus solfataricus strains have differential responses to UV-C-induced DNA double-strand break damage.

The single-stranded DNA binding protein of Sulfolobus solfataricus acts in the presynaptic step of homologous recombination.

Homologous recombination is an important pathway in the repair of DNA double-strand breaks in all organisms. In mesophiles, single-stranded DNA binding proteins (SSBs) are believed to be involved in the removal of single-stranded DNA (ssDNA) secondary structure during the presynaptic step of homologous recombination, facilitating the formation of a contiguous Rad51/RecA nucleoprotein filament. Here we report a role for the thermophilic archaeal Sulfolobus solfataricus SSB (SsoSSB) in the presynaptic step of homologous recombination. We have identified multiple quaternary structural forms of this protein in vivo and examined the activity of SsoSSB with the strand-exchange protein S. solfataricus RadA (SsoRadA). Using gel-shift analysis, we found that the two major forms of SsoSSB have different DNA binding affinities and site sizes. Biochemical examination of the monomeric form of SsoSSB suggests that it has a minor role in presynapsis and may slightly inhibit the ssDNA-dependent ATPase activity of SsoRadA. The tetrameric form of SsoSSB, however, significantly inhibits SsoRadA ssDNA-dependent ATPase activity under both saturating and subsaturating conditions. Order-of-addition experiments indicate that preincubation of tetrameric SsoSSB and SsoRadA prior to reaction initiation with ssDNA relieves the inhibition observed when SsoSSB is added either before or after SsoRadA. In addition, we demonstrate a direct interaction between SsoRadA and SsoSSB using coimmunoprecipitation. Taken together, these results suggest that a direct interaction between SsoSSB and SsoRadA may occur in vivo prior to the formation of the SsoRadA nucleoprotein filament.

A truncated DNA-damage-signaling response is activated after DSB formation in the G1 phase of Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the DNA damage response (DDR) is activated by the spatio-temporal colocalization of Mec1-Ddc2 kinase and the 9-1-1 clamp. In the absence of direct means to monitor Mec1 kinase activation in vivo, activation of the checkpoint kinase Rad53 has been taken as a proxy for DDR activation. Here, we identify serine 378 of the Rad55 recombination protein as a direct target site of Mec1. Rad55-S378 phosphorylation leads to an electrophoretic mobility shift of the protein and acts as a sentinel for Mec1 activation in vivo. A single double-stranded break (DSB) in G1-arrested cells causes phosphorylation of Rad55-S378, indicating activation of Mec1 kinase. However, Rad53 kinase is not detectably activated under these conditions. This response required Mec1-Ddc2 and loading of the 9-1-1 clamp by Rad24-RFC, but not Rad9 or Mrc1. In addition to Rad55–S378, two additional direct Mec1 kinase targets are phosphorylated, the middle subunit of the ssDNA-binding protein RPA, RPA2 and histone H2A (H2AX). These data suggest the existence of a truncated signaling pathway in response to a single DSB in G1-arrested cells that activates Mec1 without eliciting a full DDR involving the entire signaling pathway including the effector kinases.

Repair of DNA Double-Strand Breaks Induced by Ionizing Radiation Damage Correlates with Upregulation of Homologous Recombination Genes in Sulfolobus solfataricus

The mechanisms used by members of the archaeal branch of life to repair DNA damage are not well understood. DNA damage responses have been of particular interest in hyperthermophilic archaea, since these microbes live under environmental conditions that constantly elevate the potential for DNA damage. The work described here focuses on the response of four Sulfolobus solfataricus strains to ionizing radiation (IR) damage. Cellular survival of three wild-type strains and a defined deletion mutant strain was examined following exposure to various IR doses. Using pulsed-field gel electrophoresis, we determined chromosomal DNA double-strand break persistence and repair rates. Among the strains, variable responses were observed, the most surprising of which occurred with the defined deletion mutant strain. This strain displayed higher chromosomal repair rates than the parent strain and was also found to have increased resistance to IR. Using quantitative real-time PCR, we found that transcript levels of homologous recombination-related genes were strongly upregulated following damage in all the strains. The mutant strain again had an enhanced response and dramatically upregulated expression of recombination genes above levels observed for the parent strain, suggesting that increased levels of recombinational repair could account for its increased radiation resistance phenotype. Our results demonstrate a transcriptional response to IR in S. solfataricus for the first time and describe a defined deletion mutant strain that may give the first insight into a damage-based archaeal control element.

An archaeal RadA paralog influences presynaptic filament formation.

Recombinases of the RecA family play vital roles in homologous recombination, a high-fidelity mechanism to repair DNA double-stranded breaks. These proteins catalyze strand invasion and exchange after forming dynamic nucleoprotein filaments on ssDNA. Increasing evidence suggests that stabilization of these dynamic filaments is a highly conserved function across diverse species. Here, we analyze the presynaptic filament formation and DNA binding characteristics of the Sulfolobus solfataricus recombinase SsoRadA in conjunction with the SsoRadA paralog SsoRal1. In addition to constraining SsoRadA ssDNA-dependent ATPase activity, the paralog also enhances SsoRadA ssDNA binding, effectively influencing activities necessary for presynaptic filament formation. These activities result in enhanced SsoRadA-mediated strand invasion in the presence of SsoRal1 and suggest a filament stabilization function for the SsoRal1 protein.

The RadA Recombinase and Paralogs of the Hyperthermophilic Archaeon Sulfolobus solfataricus

Repair of DNA double-strand breaks is a critical function shared by organisms in all three domains of life. The majority of mechanistic understanding of this process has come from characterization of bacterial and eukaryotic proteins, while significantly less is known about analogous activities in the third, archaeal domain. Despite the physical resemblance of archaea to bacteria, archaeal proteins involved in break repair are remarkably similar to those used by eukaryotes. Investigating the function of the archaeal version of these proteins is, in many cases, simpler than working with eukaryotic homologs owing to their robust nature and ease of purification. In this chapter, we describe methods for purification and activity analysis for the RadA recombinase and its paralogs from the hyperthermophilic acidophilic archaeon Sulfolobus solfataricus.