Tresor O. Mukiza scite author profile

Davidson

et al. 2021

It has long been known (circa 1917) that environmental conditions, as well as speciation, can affect dramatically the frequency distribution of Spo11/Rec12-dependent meiotic recombination. Here, by analyzing DNA sequence-dependent meiotic recombination hotspots in the fission yeast Schizosaccharomyces pombe, we reveal a molecular basis for these phenomena. The impacts of changing environmental conditions (temperature, nutrients, osmolarity) on local rates of recombination are mediated directly by DNA site-dependent hotspots (M26, CCAAT, Oligo-C). This control is exerted through environmental condition-responsive signal transduction networks (involving Atf1, Pcr1, Php2, Php3, Php5, Rst2). Strikingly, individual hotspots modulate rates of recombination over a very broad dynamic range in response to changing conditions. They can range from being quiescent to being highly proficient at promoting activity of the basal recombination machinery (Spo11/Rec12 complex). Moreover, each different class of hotspot functions as an independently controlled rheostat; a condition that increases the activity of one class can decrease the activity of another class. Together, the independent modulation of recombination rates by each different class of DNA site-dependent hotspots (of which there are many) provides a molecular mechanism for highly dynamic, large-scale changes in the global frequency distribution of meiotic recombination. Because hotspot-activating DNA sites discovered in fission yeast are conserved functionally in other species, this process can also explain the previously enigmatic, Prdm9-independent, evolutionarily rapid changes in hotspot usage between closely related species, subspecies, and isolated populations of the same species.

Residues in the RecQ C-terminal Domain of the Human Werner Syndrome Helicase Are Involved in Unwinding G-quadruplex DNA

Ketkar

Voehler

Journal of Biological Chemistry

et al. 2017

The structural and biophysical properties typically associated with G-quadruplex (G4) structures render them a significant block for DNA replication, which must be overcome for cell division to occur. The Werner syndrome protein (WRN) is a RecQ family helicase that has been implicated in the efficient processing of G4 DNA structures. The aim of this study was to identify the residues of WRN involved in the binding and ATPase-driven unwinding of G4 DNA. Using a c-Myc G4 DNA model sequence and recombinant WRN, we have determined that the RecQ-C-terminal (RQC) domain of WRN imparts a 2-fold preference for binding to G4 DNA relative to non-G4 DNA substrates. NMR studies identified residues involved specifically in interactions with G4 DNA. Three of the amino acids in the WRN RQC domain that exhibited the largest G4-specific changes in NMR signal were then mutated alone or in combination. Mutating individual residues implicated in G4 binding had a modest effect on WRN binding to DNA, decreasing the preference for G4 substrates by ∼25%. Mutating two G4-interacting residues (T1024G and T1086G) abrogated preferential binding of WRN to G4 DNA. Very modest decreases in G4 DNA-stimulated ATPase activity were observed for the mutant enzymes. Most strikingly, G4 unwinding by WRN was inhibited ∼50% for all three point mutants and >90% for the WRN double mutant (T1024G/T1086G) relative to normal B-form dsDNA substrates. Our work has helped to identify residues in the WRN RQC domain that are involved specifically in the interaction with G4 DNA.

Diverse DNA Sequence Motifs Activate Meiotic Recombination Hotspots Through a Common Chromatin Remodeling Pathway

Protacio

Davidson

et al. 2019

Molecular mechanisms for environmentally induced plasticity in the positioning of meiotic recombination at hotspots

Protacio

Davidson

et al. 2020

Preprint

In meiosis, Spo11/Rec12-initiated homologous recombination is clustered at hotspots that regulate its frequency and distribution across the genome. Intriguingly, the intensities and positions of recombination hotspots can change dramatically in response to intracellular and extracellular conditions, and can display epigenetic memory. Here, using the fission yeast Schizosaccharomyces pombe, we reveal mechanisms for hotspot plasticity. We show that each of six hotspot-activating proteins (transcription factors Atf1, Pcr1, Php2, Php3, Php5, Rst2) is rate-limiting for promoting recombination at its own DNA binding site, allowing each class of hotspot to be regulated independently by agonistic and antagonistic signals. We also discovered that the regulatory protein-DNA complexes can establish a recombinationally poised epigenetic state before meiosis. Notably, Atf1 and Pcr1 controlled the activation of DNA sequence-dependent hotspots to which they do not bind; and they do so by regulating the expression of other hotspot-activating proteins. Thus, while each transcription factor activates its own class of DNA sequence-dependent hotspots directly in cis, cross-talk between regulatory networks modulates in trans the frequency and positioning of recombination at other classes of DNA sequence-dependent hotspots. We posit that such mechanisms allow cells to alter the frequency distribution of meiotic recombination in response to metabolic states and environmental cues.