Sarah Grieder scite author profile

Normal differentiation and induced reprogramming require the activation of target cell programs and silencing of donor cell programs. In reprogramming, the same factors are often used to reprogram many different donor cell types. As most developmental repressors, such as RE1-silencing transcription factor (REST) and Groucho (also known as TLE), are considered lineage-specific repressors, it remains unclear how identical combinations of transcription factors can silence so many different donor programs. Distinct lineage repressors would have to be induced in different donor cell types. Here, by studying the reprogramming of mouse fibroblasts to neurons, we found that the pan neuron-specific transcription factor Myt1-like (Myt1l) exerts its pro-neuronal function by direct repression of many different somatic lineage programs except the neuronal program. The repressive function of Myt1l is mediated via recruitment of a complex containing Sin3b by binding to a previously uncharacterized N-terminal domain. In agreement with its repressive function, the genomic binding sites of Myt1l are similar in neurons and fibroblasts and are preferentially in an open chromatin configuration. The Notch signalling pathway is repressed by Myt1l through silencing of several members, including Hes1. Acute knockdown of Myt1l in the developing mouse brain mimicked a Notch gain-of-function phenotype, suggesting that Myt1l allows newborn neurons to escape Notch activation during normal development. Depletion of Myt1l in primary postmitotic neurons de-repressed non-neuronal programs and impaired neuronal gene expression and function, indicating that many somatic lineage programs are actively and persistently repressed by Myt1l to maintain neuronal identity. It is now tempting to speculate that similar 'many-but-one' lineage repressors exist for other cell fates; such repressors, in combination with lineage-specific activators, would be prime candidates for use in reprogramming additional cell types.

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Cross-platform validation of neurotransmitter release impairments in schizophrenia patient-derivedNRXN1-mutant neurons

Pak

Dankó

Mirabella

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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Heterozygous NRXN1 deletions constitute the most prevalent currently known single-gene mutation associated with schizophrenia, and additionally predispose to multiple other neurodevelopmental disorders. Engineered heterozygous NRXN1 deletions impaired neurotransmitter release in human neurons, suggesting a synaptic pathophysiological mechanism. Utilizing this observation for drug discovery, however, requires confidence in its robustness and validity. Here, we describe a multicenter effort to test the generality of this pivotal observation, using independent analyses at two laboratories of patient-derived and newly engineered human neurons with heterozygous NRXN1 deletions. Using neurons transdifferentiated from induced pluripotent stem cells that were derived from schizophrenia patients carrying heterozygous NRXN1 deletions, we observed the same synaptic impairment as in engineered NRXN1-deficient neurons. This impairment manifested as a large decrease in spontaneous synaptic events, in evoked synaptic responses, and in synaptic paired-pulse depression. Nrxn1-deficient mouse neurons generated from embryonic stem cells by the same method as human neurons did not exhibit impaired neurotransmitter release, suggesting a human-specific phenotype. Human NRXN1 deletions produced a reproducible increase in the levels of CASK, an intracellular NRXN1-binding protein, and were associated with characteristic gene-expression changes. Thus, heterozygous NRXN1 deletions robustly impair synaptic function in human neurons regardless of genetic background, enabling future drug discovery efforts.

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Pro-neuronal activity of Myod1 due to promiscuous binding to neuronal genes

et al. 2020

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Cross-Platform Validation of Neurotransmitter Release Impairments in Schizophrenia Patient-DerivedNRXN1-Mutant Neurons

Pak

Dankó

Mirabella

et al. 2020

Preprint

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Heterozygous NRXN1 deletions constitute the most prevalent currently known single-gene mutation predisposing to schizophrenia. Previous studies showed that engineered heterozygous NRXN1 deletions impaired neurotransmitter release in human neurons, suggesting a synaptic pathophysiological mechanism. Utilizing this observation for drug discovery, however, requires confidence in its robustness and validity. Here, we describe a multi-center effort to test the generality of this pivotal observation, using independent analyses at two laboratories of patient-derived and newly engineered human neurons with heterozygous NRXN1 deletions. We show that in neurons that were trans-differentiated from induced pluripotent stem cells derived from three NRXN1-deletion patients, the same impairment in neurotransmitter release was observed as in engineered NRXN1-deficient neurons. This impairment manifested as a decrease in spontaneous synaptic events and in evoked synaptic responses, and an alteration in synaptic paired-pulse depression. Nrxn1-deficient mouse neurons generated from embryonic stem cells by the same method as human neurons did not exhibit impaired neurotransmitter release, suggesting a human-specific phenotype. NRXN1 deletions produced a reproducible increase in the levels of CASK, an intracellular NRXN1-binding protein, and were associated with characteristic gene expression changes. Thus, heterozygous NRXN1 deletions robustly impair synaptic function in human neurons regardless of genetic background, enabling future drug discovery efforts.

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Rapid generation of functional and homogeneous excitatory human forebrain neurons using Neurogenin-2 (Ngn2)

Pak¹,

Grieder²,

Yang³

et al. 2018

Protocol Exchange

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Induced neuronal (iN) cells are versatile tools for modeling neurological disorders and human synapse development, and provide a novel cell-based platform for drug screening and discovery 1-9. In 2013 Zhang, Y. et al. study, we reported that inducible expression of a single basic helix-loop-helix transcription factor Neurogenin-2 (Ngn2) in human embryonic stem (ES) and induced pluripotent stem (iPS) cells generates a homogenous population of excitatory neurons that resemble those of cortical upper layer 2/3 neurons in the brain 3. Within 3-4 weeks in culture, Ngn2-iN cells display mature molecular, cellular and synaptic properties, which can be readily analyzed using various functional assays. Coupled with genome editing and/or patient iPS cell lines, Ngn2-iN cells provide an excellent experimental system that can harness rapid, reliable, and renewable source of human neurons in a culture dish. Here, we describe a stepwise protocol in generating Ngn2-iN cells from both feeder-free human pluripotent stem cells (previously published) and feeder-dependent human pluripotent stem cells (unpublished).

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Sarah Grieder

Myt1l safeguards neuronal identity by actively repressing many non-neuronal fates

Cross-platform validation of neurotransmitter release impairments in schizophrenia patient-derivedNRXN1-mutant neurons

Pro-neuronal activity of Myod1 due to promiscuous binding to neuronal genes

Cross-Platform Validation of Neurotransmitter Release Impairments in Schizophrenia Patient-DerivedNRXN1-Mutant Neurons

Rapid generation of functional and homogeneous excitatory human forebrain neurons using Neurogenin-2 (Ngn2)

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