Patient-specific mutation of Dync1h1 in mice causes brain and behavioral deficits

Cytoplasmic dynein heavy chain (DYNC1H1) is a multi-subunit protein complex that provides motor force for movement of cargo on microtubules and traffics them back to the soma. In humans, mutations along the DYNC1H1 gene result in intellectual disabilities, cognitive delays, and neurologic and motor...

Full description

Saved in:
Bibliographic Details
Published in:Neurobiology of disease 2024-09, Vol.199, p.106594, Article 106594
Main Authors: Ramos, Raddy L., De Heredia, Maider Michelena Beltran, Zhang, Yongwei, Stout, Randy F., Tindi, Jaafar O., Wu, Liching, Schwartz, Gary J., Botbol, Yair M., Sidoli, Simone, Poojari, Ankita, Rakowski-Anderson, Tammy, Shafit-Zagardo, Bridget
Format: Article
Language:English
Subjects:
Abnormal neuronal positioning
Animals
Autism spectrum disorder (ASD)
Brain - metabolism
Brain - pathology
Cortical layer-specific transcription factors
Cytoplasmic Dyneins - genetics
Cytoplasmic Dyneins - metabolism
De novo dynein heavy chain mutation
Disease Models, Animal
Heterotopia
Humans
Intellectual Disability - genetics
Male
Mice
Mice, Transgenic
Mutation - genetics
Neuronal migration defects
Neurons - metabolism
Neurons - pathology
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Cytoplasmic dynein heavy chain (DYNC1H1) is a multi-subunit protein complex that provides motor force for movement of cargo on microtubules and traffics them back to the soma. In humans, mutations along the DYNC1H1 gene result in intellectual disabilities, cognitive delays, and neurologic and motor deficits. The aim of the study was to generate a mouse model to a newly identified de novo heterozygous DYNC1H1 mutation, within a functional ATPase domain (c9052C > T(P3018S)), identified in a child with motor deficits, and intellectual disabilities. P3018S heterozygous (HET) knockin mice are viable; homozygotes are lethal. Metabolic and EchoMRI™ testing show that HET mice have a higher metabolic rate, are more active, and have less body fat compared to wildtype mice. Neurobehavioral studies show that HET mice perform worse when traversing elevated balance beams, and on the negative geotaxis test. Immunofluorescent staining shows neuronal migration abnormalities in the dorsal and lateral neocortex with heterotopia in layer I. Neuron-subtype specific transcription factors CUX1 and CTGF identified neurons from layers II/III and VI respectively in cortical layer I, and abnormal pyramidal neurons with MAP2+ dendrites projecting downward from the pial surface. The HET mice are a good model for the motor deficits seen in the child, and highlights the importance of cytoplasmic dynein in the maintenance of cortical function and dendritic orientation relative to the pial surface. Our results are discussed in the context of other dynein mutant mice and in relation to clinical presentation in humans with DYNC1H1 mutations. •Patient-specific cytoplasmic dynein gene mutation modeled in mice•DYNC1H1 P3018S mutant mice display motor deficits•Mutant mice display enlarged ventricles and layer 1 neocortical heterotopia•Neocortical neurons display loss of dendritic polarity and dendritic bundling
ISSN:0969-9961
1095-953X
1095-953X
DOI:10.1016/j.nbd.2024.106594