Loss of non-motor kinesin KIF26A causes congenital brain malformations via dysregulated neuronal migration and axonal growth as well as apoptosis

Kinesins are canonical molecular motors but can also function as modulators of intracellular signaling. KIF26A, an unconventional kinesin that lacks motor activity, inhibits growth-factor-receptor-bound protein 2 (GRB2)- and focal adhesion kinase (FAK)-dependent signal transduction, but its function...

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Published inDevelopmental cell Vol. 57; no. 20; pp. 2381 - 2396.e13
Main Authors Qian, Xuyu, DeGennaro, Ellen M, Talukdar, Maya, Akula, Shyam K, Lai, Abbe, Shao, Diane D, Gonzalez, Dilenny, Marciano, Jack H, Smith, Richard S, Hylton, Norma K, Yang, Edward, Bazan, J Fernando, Barrett, Lee, Yeh, Rebecca C, Hill, R Sean, Beck, Samantha G, Otani, Aoi, Angad, Jolly, Mitani, Tadahiro, Posey, Jennifer E, Pehlivan, Davut, Calame, Daniel, Aydin, Hatip, Yesilbas, Osman, Parks, Kendall C, Argilli, Emanuela, England, Eleina, Im, Kiho, Taranath, Ajay, Scott, Hamish S, Barnett, Christopher P, Arts, Peer, Sherr, Elliott H, Lupski, James R, Walsh, Christopher A
Format Journal Article
LanguageEnglish
Published United States 24.10.2022
Subjects
Animals
Apoptosis
Brain - metabolism
Focal Adhesion Protein-Tyrosine Kinases - metabolism
Humans
Kinesins - genetics
Mice
Neurons - metabolism
cerebral cortex
congenital brain malformation
development
genetics
kinesin
migration
apoptosis
corpus callosum
organoid
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Summary:Kinesins are canonical molecular motors but can also function as modulators of intracellular signaling. KIF26A, an unconventional kinesin that lacks motor activity, inhibits growth-factor-receptor-bound protein 2 (GRB2)- and focal adhesion kinase (FAK)-dependent signal transduction, but its functions in the brain have not been characterized. We report a patient cohort with biallelic loss-of-function variants in KIF26A, exhibiting a spectrum of congenital brain malformations. In the developing brain, KIF26A is preferentially expressed during early- and mid-gestation in excitatory neurons. Combining mice and human iPSC-derived organoid models, we discovered that loss of KIF26A causes excitatory neuron-specific defects in radial migration, localization, dendritic and axonal growth, and apoptosis, offering a convincing explanation of the disease etiology in patients. Single-cell RNA sequencing in KIF26A knockout organoids revealed transcriptional changes in MAPK, MYC, and E2F pathways. Our findings illustrate the pathogenesis of KIF26A loss-of-function variants and identify the surprising versatility of this non-motor kinesin.
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Author Contributions
X.Q., and C.A.W. designed research; X.Q., E.M.D., S.K.A., D.D.S., D.G., J.H.M., R.S.S., R.C.Y., S.B. N.K.H. and A.O. performed research; X.Q., E.M.D, M.T., S.K.A., R.S.S., J.F.B., L.B., and K.I. analyzed data; E.Y., J.A., T.M., J.E.P., D.P., K.C.P., E.A., E.E., A.T., H.S.S., B.P., C.P.B., P.A., E.H.S. and J.R.L contributed clinical and genetic data; A.L., J.N., D.D.S. and R.S.H coordinated clinical data; and X.Q., E.M.D., S.K.A., A.L. and C.A.W. wrote the paper.
ISSN:1534-5807
1878-1551
1878-1551
DOI:10.1016/j.devcel.2022.09.011