A Highly Conserved 310-Helix Within the Kinesin Motor Domain is Critical for Kinesin Function and Human Health

Abstract

AbstractKIF1A, a kinesin-3 family member, plays critical roles as a long-distance cargo-transporter within neurons. Over 100 known KIF1A mutations in humans result in KIF1A Associated Neurological Disease (KAND), developmental and degenerative neurological conditions for which there is no cure. A de novo missense mutation, P305L, was recently identified in several children diagnosed with KAND, but the underlying molecular basis for the disease phenotype is unknown. Interestingly, this residue is highly conserved in kinesin-family proteins, and together with adjacent conserved residues also implicated in KAND, forms an unusual 310-helical element immediately C-terminal to loop-12 (L12, also known as the K-loop in KIF1A) in the conserved kinesin motor core. In KIF1A, the disordered K-loop contains a highly charged insertion of lysines that is thought to endow the motor with a high microtubule-association rate. Here, we characterize the molecular defects of the P305L mutation in KIF1A using genetic, biochemical, and single-molecule approaches. We find the mutation negatively impacts the velocity, run-length, and force generation of the motor. However, a much more dramatic effect is observed on the microtubule-association rate of the motor, revealing that the presence of an intact K-loop is not sufficient for its function. We hypothesize that an elusive K-loop conformation, mediated by formation of a highly conserved adjacent 310-helix that is modulated via P305, is critically important for the kinesin-microtubule interaction. Importantly, we find that the function of this proline is conserved in the canonical kinesin, KIF5, revealing a fundamental principle of the kinesin motor mechanism.