Abstract
KIF1A-associated neurological disorder (KAND) encompasses a group of rare neurodegenerative conditions caused by variants in KIF1A, a gene that encodes an anterograde neuronal microtubule (MT) motor protein. Here we characterize the natural history of KAND in 117 individuals using a combination of caregiver or self-reported medical history, a standardized measure of adaptive behavior, clinical records, and neuropathology. We developed a heuristic severity score using a weighted sum of common symptoms to assess disease severity. Focusing on 100 individuals, we compared the average clinical severity score for each variant with in silico predictions of deleteriousness and location in the protein. We found increased severity is strongly associated with variants occurring in protein regions involved with ATP and MT binding: the P loop, switch I, and switch II. For a subset of variants, we generated recombinant proteins, which we used to assess transport in vivo by assessing neurite tip accumulation and to assess MT binding, motor velocity, and processivity using total internal reflection fluorescence microscopy. We find all modeled variants result in defects in protein transport, and we describe three classes of protein dysfunction: reduced MT binding, reduced velocity and processivity, and increased non-motile rigor MT binding. The rigor phenotype is consistently associated with the most severe clinical phenotype, while reduced MT binding is associated with milder clinical phenotypes. Our findings suggest the clinical phenotypic heterogeneity in KAND likely reflects and parallels diverse molecular phenotypes. We propose a different way to describe KAND subtypes to better capture the breadth of disease severity.
| Original language | English (US) |
|---|---|
| Article number | 100026 |
| Journal | Human Genetics and Genomics Advances |
| Volume | 2 |
| Issue number | 2 |
| DOIs | |
| State | Published - Apr 8 2021 |
Funding
We thank KIF1A.org for their ongoing partnership and Autism Brain Net for the collection of postmortem brain specimens. We thank Scott Robinson, Jennifer Shahar, Emily Horowitz, and Rachel Cogny for their assistance with this project. We thank Kristen Verhey for her assistance with optimizing the neurite tip accumulation and in vitro gliding assays. Molecular graphics were generated with UCSF Chimera, developed by the Resource for Biocomputing, Visualization, and Informatics at the University of California, San Francisco, with support from NIH grant P41-GM103311. Support was also received from NIH grants TL1TR001875 (L.B.), R01N114636 (L.R. A.G. and W.K.C.), and UL1TR001873 and from KIF1A.org. Research conducted at the Murdoch Children's Research Institute was supported by the Victorian Government's Operational Infrastructure Support Program. The authors declare no competing interests. We thank KIF1A.org for their ongoing partnership and Autism Brain Net for the collection of postmortem brain specimens. We thank Scott Robinson, Jennifer Shahar, Emily Horowitz, and Rachel Cogny for their assistance with this project. We thank Kristen Verhey for her assistance with optimizing the neurite tip accumulation and in vitro gliding assays. Molecular graphics were generated with UCSF Chimera, developed by the Resource for Biocomputing, Visualization, and Informatics at the University of California, San Francisco, with support from NIH grant P41-GM103311 . Support was also received from NIH grants TL1TR001875 (L.B.), R01N114636 (L.R., A.G., and W.K.C.), and UL1TR001873 and from KIF1A.org . Research conducted at the Murdoch Children\u2019s Research Institute was supported by the Victorian Government\u2019s Operational Infrastructure Support Program .
Keywords
- KAND
- KIF1A
- ataxia
- kinesin
- microtubule
- spastic paraplegia
ASJC Scopus subject areas
- Molecular Medicine
- Genetics(clinical)