[PDF][PDF] Human CFEOM1 mutations attenuate KIF21A autoinhibition and cause oculomotor axon stalling

L Cheng, J Desai, CJ Miranda, JS Duncan, W Qiu… - Neuron, 2014 - cell.com
L Cheng, J Desai, CJ Miranda, JS Duncan, W Qiu, AA Nugent, AL Kolpak, CC Wu
Neuron, 2014cell.com
The ocular motility disorder" Congenital fibrosis of the extraocular muscles type 1"(CFEOM1)
results from heterozygous mutations altering the motor and third coiled-coil stalk of the
anterograde kinesin, KIF21A. We demonstrate that Kif21a knockin mice harboring the most
common human mutation develop CFEOM. The developing axons of the oculomotor nerve's
superior division stall in the proximal nerve; the growth cones enlarge, extend excessive
filopodia, and assume random trajectories. Inferior division axons reach the orbit but branch …
Summary
The ocular motility disorder "Congenital fibrosis of the extraocular muscles type 1" (CFEOM1) results from heterozygous mutations altering the motor and third coiled-coil stalk of the anterograde kinesin, KIF21A. We demonstrate that Kif21a knockin mice harboring the most common human mutation develop CFEOM. The developing axons of the oculomotor nerve's superior division stall in the proximal nerve; the growth cones enlarge, extend excessive filopodia, and assume random trajectories. Inferior division axons reach the orbit but branch ectopically. We establish a gain-of-function mechanism and find that human motor or stalk mutations attenuate Kif21a autoinhibition, providing in vivo evidence for mammalian kinesin autoregulation. We identify Map1b as a Kif21a-interacting protein and report that Map1b−/− mice develop CFEOM. The interaction between Kif21a and Map1b is likely to play a critical role in the pathogenesis of CFEOM1 and highlights a selective vulnerability of the developing oculomotor nerve to perturbations of the axon cytoskeleton.
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