KIF5B drives meiotic chromosome dynamics via interaction with the KASH5-LINC complex

Telomere-led rapid prophase chromosome movements (RPMs) during meiotic prophase are critical for homologous chromosome pairing and proper meiotic progression. These movements are generated by the cytoskeleton and are transmitted to the telomeres via the LINC complex, yet the cytoplasmic components that generate these forces remain poorly defined. Among candidates of microtubule-associated motor proteins in mouse primary spermatocytes, we confirmed KIF5B as a specific interactor of the KASH5-LINC complex. Total internal reflection fluorescence microscopy and microtubule sedimentation assays performed with purified recombinant proteins suggest a direct interaction between KASH5 and KIF5B on microtubules, enhanced by MAP7, a known KIF5B-recruiting and activating cofactor. Mapping the KIF5B-binding surface of KASH5 revealed that KASH5 N-terminal EF-hand domains mediate the interaction. Further, in vivo KIF5B-KASH5 interaction and KIF5B role in RPMs are evidenced as (1) KIF5B is recruited by KASH5-SUN1 to the nuclear envelope in two different cultured somatic cell models, (2) KIF5B is telomere-associated and colocalizes with KASH5, and microtubules associated with the nuclear envelope in mouse spermatocytes, and (3) chemical inhibition of KIF5B reduces telomere-led chromosome motions. Altogether, our findings identify the KIF5B kinesin as a previously unrecognized component of the force-generating machinery that drives chromosome movement during meiotic prophase I, acting through KASH5 as a specific nuclear membrane adaptor.