Structural and mechanistic perspectives on Nse5/6 regulation of the Smc5/6 complex

초록

The Smc5/6 complex is a vital protector of eukaryotic genome stability, coordinating DNA repair, replication fork maintenance, recombination intermediate processing, and chromosome organization. Within this complex, the Nse5/6 heterodimer has recently emerged as a key factor influencing Smc5/6 dynamics, acting at the interface of structural control, enzymatic regulation, and chromatin recruitment. Structural studies from yeast to mammals show that Nse5/6 associate with the Smc5/6 head–neck region, restricting ATPase head engagement and stabilizing an inactive, chromatin-loading-ready state. Upon ATP binding and DNA interaction, conformational changes displace or reposition Nse5/6, facilitating Nse4-mediated head closure, DNA entrapment, and loop-modulating activity. Functional analyses across Saccharomyces cerevisiae, Schizosaccharomyces pombe, mammals, and plants indicate that Nse5/6 is essential for recruiting Smc5/6 to damaged or stalled replication forks, stabilizing chromatin association, and coordinating SUMO-dependent repair pathways. Loss of Nse5/6 leads to defects in replication stress tolerance, accumulation of recombination intermediates, impaired chromatin loading, and widespread genome instability. This review synthesizes emerging structural and functional insights into Nse5/6, emphasizing its conserved yet species-adapted mechanisms that regulate ATPase gating, DNA substrate selection, and chromatin recruitment. Collectively, these findings redefine Nse5/6 not as a peripheral structural factor but as a dynamic regulatory hub that orchestrates Smc5/6 activity in genome maintenance, development, and antiviral defense.

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