Thomas Portmann scite author profile

Two ETS transcription factors of the Pea3 subfamily are induced in subpopulations of dorsal root ganglion (DRG) sensory and spinal motor neurons by target-derived factors. Their expression controls late aspects of neuronal differentiation such as target invasion and branching. Here, we show that the late onset of ETS gene expression is an essential requirement for normal sensory neuron differentiation. We provide genetic evidence in the mouse that precocious ETS expression in DRG sensory neurons perturbs axonal projections, the acquisition of terminal differentiation markers, and their dependence on neurotrophic support. Together, our findings indicate that DRG sensory neurons exhibit a temporal developmental switch that can be revealed by distinct responses to ETS transcription factor signaling at sequential steps of neuronal maturation.

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MicroRNA-mediated conversion of human fibroblasts to neurons

Yoo

Sun

et al. 2011

Nature

889

791

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Neurogenic transcription factors and evolutionarily conserved signalling pathways have been found to be instrumental in the formation of neurons1,2. However, the instructive role of microRNAs (miRNAs) in neurogenesis remains unexplored. We recently discovered that miR-9* and miR-124 instruct compositional changes of SWI/SNF-like BAF chromatin-remodelling complexes, a process important for neuronal differentiation and function3–6. Nearing mitotic exit of neural progenitors, miR-9* and miR-124 repress the BAF53a subunit of the neural-progenitor (np)BAF chromatin-remodelling complex. After mitotic exit, BAF53a is replaced by BAF53b, and BAF45a by BAF45b and BAF45c, which are then incorporated into neuron-specific (n)BAF complexes essential for post-mitotic functions4. Because miR-9/9* and miR-124 also control multiple genes regulating neuronal differentiation and function5,7–13, we proposed that these miRNAs might contribute to neuronal fates. Here we show that expression of miR-9/9* and miR-124 (miR-9/9*-124) in human fibroblasts induces their conversion into neurons, a process facilitated by NEUROD2. Further addition of neurogenic transcription factors ASCL1 and MYT1L enhances the rate of conversion and the maturation of the converted neurons, whereas expression of these transcription factors alone without miR-9/9*-124 was ineffective. These studies indicate that the genetic circuitry involving miR-9/9*-124 can have an instructive role in neural fate determination.

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

Paşca

Portmann

Voineagu

et al. 2011

Nat Med

525

471

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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 calcium (Ca2+) signaling and activity-dependent gene expression. They also show abnormalities in differentiation, including decreased expression of genes that are expressed in lower cortical layers and in callosal projection neurons. In addition, neurons derived from individuals with Timothy syndrome show abnormal expression of tyrosine hydroxylase and increased production of norepinephrine and dopamine. This phenotype can be reversed by treatment with roscovitine, a cyclin-dependent kinase inhibitor and atypical L-type–channel blocker 2, 3, 4. These findings provide strong evidence that Cav1.2 regulates the differentiation of cortical neurons in humans and offer new insights into the causes of autism in individuals with Timothy syndrome.

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SHANK3 and IGF1 restore synaptic deficits in neurons from 22q13 deletion syndrome patients

Shcheglovitov

Shcheglovitova

Yazawa

et al. 2013

Nature

410

403

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Phelan-McDermid Syndrome (PMDS) is a complex neurodevelopmental disorder characterized by global developmental delay, severely impaired speech, intellectual disability, and an increased risk of Autism Spectrum Disorders (ASDs)1. PMDS is caused by heterozygous deletions of chromosome 22q13.3. Among the genes in the deleted region is SHANK3, which encodes a protein in the postsynaptic density (PSD)2,3. Rare mutations in SHANK3 have been associated with idiopathic ASDs4–7, non-syndromic intellectual disability8, and schizophrenia9. Although SHANK3 is considered to be the most likely candidate gene for the neurological abnormalities in PMDS patients10, the cellular and molecular phenotypes associated with this syndrome in human neurons are unknown. We generated induced pluripotent stem cells (iPSCs) from individuals with PMDS and autism and used them to produce functional neurons. We show that PMDS neurons have reduced Shank3 expression and major defects in excitatory but not inhibitory synaptic transmission. Excitatory synaptic transmission in PMDS neurons can be corrected by restoring Shank3 expression or by treating neurons with insulin-like growth factor 1 (IGF1). IGF1 treatment promotes formation of excitatory synapses that lack Shank3 but contain PSD95 and NMDA receptors with fast deactivation kinetics. Our findings provide direct evidence for a disruption in the ratio of cellular excitation and inhibition in PMDS neurons, and point to a molecular pathway that can be recruited to restore it.

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Thomas Portmann

A Developmental Switch in the Response of DRG Neurons to ETS Transcription Factor Signaling

MicroRNA-mediated conversion of human fibroblasts to neurons

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

SHANK3 and IGF1 restore synaptic deficits in neurons from 22q13 deletion syndrome patients

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