RPA directly stimulates Mer3 helicase processivity to ensure normal crossover formation in meiosis
Veronika Altmannova, Lucija Orlić, Carolina Carrasco, Céline Adam, Clara Aicart-Ramos, Dario Guerrini, Petra Janning, Valérie Borde, Joao Matos, Fernando Moreno-Herrero, John R. Weir

TL;DR
This study shows how the Mer3 helicase works with RPA to ensure proper genetic recombination during meiosis, which is vital for fertility and genetic diversity.
Contribution
The study reveals a direct interaction between Mer3 and RPA that enhances Mer3's helicase activity during meiosis.
Findings
Mer3 interacts directly with RPA in both yeast and humans.
RPA binding is necessary for Mer3 helicase processivity under low DNA tension.
A Mer3 mutant lacking RPA binding shows reduced crossovers and unresolved recombination intermediates.
Abstract
Meiotic crossover formation is critical for generating viable gametes and enhancing genetic diversity. The helicase Mer3 (HFM1 in humans) is a highly conserved factor essential for promoting crossovers and ensuring their proper distribution. Here, we identify replication protein A (RPA) as a direct interactor of budding yeast Mer3. We demonstrate that this interaction is conserved between human HFM1 and RPA. Cross-linking mass spectrometry and structural modelling with AlphaFold2 reveal a conserved and specific Mer3-RPA interface. Single-molecule magnetic tweezers assays demonstrate that direct RPA interaction is required for Mer3 helicase processivity under conditions of low DNA tension. Consistently, a mer3 mutant deficient in RPA binding exhibits reduced crossover frequencies and accumulates unresolved recombination intermediates during budding yeast meiosis. Via genome-wide…
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Taxonomy
TopicsDNA Repair Mechanisms · PARP inhibition in cancer therapy · Microtubule and mitosis dynamics
