Abstract
AbstractThe PIWI-interacting RNA (piRNA) pathway is an adaptive defense system wherein piRNAs guide PIWI-family Argonaute proteins to recognize and silence ever-evolving selfish genetic elements and ensure genome integrity. Driven by this intensive host-pathogen arms race, piRNA pathway and its targeted transposons have co-evolved rapidly in a species-specific manner, but how the piRNA pathway specifically adapts to target silencing in mammals remains elusive. Here, we show that mouse MILI and human HILI piRISCs bind and cleave targets more efficiently than their invertebrate counterpart from spongeEphydatia fluviatilis. The inherent functional differences comport with structural features identified by cryo-EM studies of piRISCs. In the absence of target, MILI and HILI piRISCs adopt a wider nucleic-acid-binding channel and display an extended prearranged piRNA seed as compared toEfPiwi piRISC, consistent with their ability to capture targets more efficiently thanEfPiwi piRISC. In the presence of target, the seed gate—which enforces seed-target fidelity in microRNA RISC—adopts a relaxed state in mammalian piRISC, revealing how MILI and HILI tolerate seed-target mismatches to broaden the target spectrum. A vertebrate-specific lysine distorts the piRNA seed, shifting the trajectory of the piRNA-target duplex out of the central cleft and toward the PAZ lobe. Functional analyses reveal that this lysine promotes target binding and cleavage. Our study therefore provides a molecular basis for the piRNA targeting mechanism in mouse and human, and suggests that mammalian piRNA machinery can achieve broad target silencing using a limited supply of piRNA species.
Publisher
Cold Spring Harbor Laboratory