AI Article Synopsis
- Cells position the Spo11-dependent initiation of meiotic recombination at hotspots through various DNA sequence-specific, protein-DNA complexes, which are essential for hotspot activation.
- Recent research shows that species use multiple regulatory elements that can work together in different ways, showcasing interactions like synergism, antagonism, and redundancy.
- The study finds that key regulatory components have been conserved across diverse taxa for over a billion years, suggesting a fundamental shift in understanding that meiotic recombination is regulated similarly to transcription through specific protein-DNA interactions.
Article Abstract
How do cells position the Spo11 (Rec12)-dependent initiation of meiotic recombination at hotspots? The mechanisms are poorly understood and a prevailing view is that they differ substantially between phylogenetic groups. However, recent work discovered that individual species have multiple different DNA sequence-specific, protein-DNA complexes that regulate (and are essential for the activation of) recombination hotspots. The cis-acting elements function combinatorially with documented examples of synergism, antagonism and redundancy. Furthermore, we provide evidence that all currently well-defined modules of this multifactorial, cis-acting regulation are conserved functionally between taxa whose latest common ancestor occurred more than 1 billion years ago. Functionally conserved components include the ATF/CREB-family heterodimer Atf1-Pcr1 and its CRE-like DNA site M26, the CCAAT-box-binding complex Php2-Php3-Php5 and the CCAAT-box, and the zinc-finger protein Rst2 and its Oligo-C motif. The newfound multiplicity, functional redundancy and conservation of cis-acting controls constitute a paradigm shift with broad implications. They provide compelling evidence that most meiotic recombination is, like transcription, regulated by sequence-specific protein-DNA complexes. And the new findings provide important mechanistic insight, such as a solution to the conundrum that Prdm9 is a 'master regulator' of--yet is dispensable for--hotspot activity in mammals.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3488224 | PMC |
| http://dx.doi.org/10.1093/nar/gks761 | DOI Listing |
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