Using iPSC-derived neurons to uncover cellular phenotypes associated with Timothy syndrome

Abstract: Monogenic neurodevelopmental disorders provide key insights into the pathogenesis of disease and help us understand how specific genes control the development of the human brain. Timothy syndrome is caused by a missense mutation in the L-type calcium channel Cav1.2 that is associated with developmental delay and autism 1. We generated cortical neuronal precursor cells and neurons from induced pluripotent stem cells derived from individuals with Timothy syndrome. Cells from these individuals have defects in cal… Show more

“…23,25,29,30 Although the findings of the differences in the number of dendritic segments, branching points and trees did not agree between the iPSC model and postmortem tissue, we did observed a similar trend for WS iPSC-derived neurons to have a higher number of dendritic segments and branching points, as observed in WS postmortem brains. It is possible that iPSC-derived neurons lack the dynamics from environmental inputs, and deficiencies in dendritic segments and branching points may occur later in development, resulting in the only partial dendritic changes observed in postmortem specimens.…”

Modeling Williams syndrome with induced pluripotent stem cells

“…23,25,29,30 Although the findings of the differences in the number of dendritic segments, branching points and trees did not agree between the iPSC model and postmortem tissue, we did observed a similar trend for WS iPSC-derived neurons to have a higher number of dendritic segments and branching points, as observed in WS postmortem brains. It is possible that iPSC-derived neurons lack the dynamics from environmental inputs, and deficiencies in dendritic segments and branching points may occur later in development, resulting in the only partial dendritic changes observed in postmortem specimens.…”

Modeling Williams syndrome with induced pluripotent stem cells

“…Autistic patients seem to have callosal abnormalities (19)(20)(21)(22)(23)(24)(25)(26), and in this context it is relevant that Auts2, a gene associated with autism, is regulated by Tbr1, which in turn is regulated by Satb2, a callosal fate specification gene. Recent studies suggest that a mutation in CAv1/2 (an L-type calcium channel) that is associated with Timothy syndrome, a form of autism, results in lower numbers of Satb2-expressing cells and an increase in Ctip2-expressing cells (31). The authors suggest that the reduction in callosal neurons in Timothy syndrome is consistent with the emerging view that autism spectrum disorders arise from defects in connectivity between cortical areas (31).…”

“…Recent studies suggest that a mutation in CAv1/2 (an L-type calcium channel) that is associated with Timothy syndrome, a form of autism, results in lower numbers of Satb2-expressing cells and an increase in Ctip2-expressing cells (31). The authors suggest that the reduction in callosal neurons in Timothy syndrome is consistent with the emerging view that autism spectrum disorders arise from defects in connectivity between cortical areas (31).…”

A network of genetic repression and derepression specifies projection fates in the developing neocortex

“…For example, iPSC-derived neurons were generated from patients diagnosed with the autism-associated disorder TS, which results from mutations in the L-type calcium channel Ca v 1.2 and leads to decreased channel inactivation. TS neurons show dysregulation of genes involved in catecholamine synthesis, which can be reversed by treatment with an L-type-channel blocker, roscovitine [195]. In another study, disruption of calcium signaling, changes in gene expression, and decreased neurite growth were observed in iPSC-derived neurons from a nonsyndromic patient with autism with a translocation disrupting the cation channel gene TRPC6.…”

Discovery of Rare Mutations in Autism: Elucidating Neurodevelopmental Mechanisms