Project description:Cell fate specification relies on the action of critical transcription factors that become available at distinct stages of embryonic development. One such factor is NeuroD1, which is essential for eliciting the neuronal development program and possesses the ability to reprogram other cell types into neurons. Given this capacity, it is important to understand its targets and the mechanism underlying neuronal specification. Here, we show that NeuroD1 directly binds regulatory elements of neuronal genes that are developmentally silenced by epigenetic mechanisms. This targeting is sufficient to initiate events that confer transcriptional competence, including reprogramming of transcription factor landscape, conversion of heterochromatin to euchromatin and increased chromatin accessibility, indicating potential pioneer factor ability of NeuroD1. The transcriptional induction of neuronal fate genes is maintained via epigenetic memory despite a transient NeuroD1 induction during neurogenesis. Our study not only reveals the NeuroD1-dependent gene regulatory program driving neurogenesis but also increases our understanding of how cell-fate specification during development involves a concerted action of transcription factors and epigenetic mechanisms. 1. Ectopic NeuroD1 was induced for 48 hours (+Dox) in ES cells for checking initiation of neuronal transcriptional program in comparison to uninduced condition (-Dox) 2. ChIP-seq was performed after 24 hours of NeuroD1 induction in ES cells.

Project description:Cell-fate specification relies on a close cooperation of distinct transcription factors and their crosstalk with the epigenetic landscape during embryonic development. NeuroD1 is known to be essential for eliciting neurogenesis and is able to reprogram other cell types into neurons. Despite progress, its global impact on the epigenome and cooperativity with other transcription factors during neurogenesis remains unknown. Here we show that despite NeuroD1 binding and a gain of active chromatin, only sites that show high local density of adjacent bHLH motifs, higher minor groove width and propeller twist as well as enrichment of another novel bHLH motif were able to get transcriptionally induced. Transcription factor activity analysis on the epigenome timecourse following NeuroD1 induction further identified this bHLH factor among top factors that gained activity during this process. Importantly, this bHLH factor was induced simultaneously to NeuroD1 as cells transit from an apical to a basal progenitor state during cortical development. Moreover, this bHLH factor interacts with NeuroD1 and co-occupies NeuroD1 target distinct genomic regions. We further show that the loss of this bHLH factor during cortical development severely impairs neurogenesis. Our study not only reveals the mechanistic basis underlying a productive transcriptional response of NeuroD1 during neurogenesis but also identified a novel bHLH transcription factor that partners with NeuroD1 and plays a critical role during cortical development.

Project description:While diabetes incidence is gradually rising worldwide, novel therapeutical approaches are required in the search for a replacement of dysfunctional endocrine tissue, especially beta-cells. A promising potential lies in direct cellular reprogramming of similar cell types sharing common multipotent progenitors. With the knowledge of molecular mechanisms determining the endocrine cell fate commitment and endocrine lineage differentiation, other endocrine cells contained within the islets of Langerhans or closely related cells could be trans- or dedifferentiated either in situ or in vitro with their subsequent transplantation into the patient. NEUROD1 is a transcription factor situated on the base of the gene regulatory network of the developing endocrine precursors, directly downstream of endocrine lineage master regulator NEUROG3. While NEUROG3 initiates a rapid cascade of chromatin reorganization in numerous bivalent promoters resulting in spatiotemporal gene expression leading to differentiation of all endocrine cell subtypes from pancreatic multipotent progenitors, the role of NEUROD1 has yet to be clarified. Notably, NEUROD1 can induce neuronal program through pioneering and chromatin remodelling in other cell types. In this study, we performed advanced molecular and phenotypic analyses in early endocrine-specific Neurod1-deficient mouse model, including RNA and CUT&Tag sequencing and lightsheet microscopy, to gain insight into the NEUROD1-regulated transcription network driving endocrine lineage cell fate commitment. Besides a postnatal diabetic phenotype, disrupted endocrine differentiation and associated altered islet architecture, we observed an apparent elevation in the non-endocrine gene expression pattern and uncovered alterations in the epigenetic landscape of characteristic genes, specifically in the H3K4me3 and H3K27me3 distribution. Therefore, we provide evidence that NEUROD1 is critical player responsible for the establishment of the endocrine cell identity, which further affects endocrine development and may serve as a potent proendocrine reprogramming driver.

Project description:While diabetes incidence is gradually rising worldwide, novel therapeutical approaches are required in the search for a replacement of dysfunctional endocrine tissue, especially beta-cells. A promising potential lies in direct cellular reprogramming of similar cell types sharing common multipotent progenitors. With the knowledge of molecular mechanisms determining the endocrine cell fate commitment and endocrine lineage differentiation, other endocrine cells contained within the islets of Langerhans or closely related cells could be trans- or dedifferentiated either in situ or in vitro with their subsequent transplantation into the patient. NEUROD1 is a transcription factor situated on the base of the gene regulatory network of the developing endocrine precursors, directly downstream of endocrine lineage master regulator NEUROG3. While NEUROG3 initiates a rapid cascade of chromatin reorganization in numerous bivalent promoters resulting in spatiotemporal gene expression leading to differentiation of all endocrine cell subtypes from pancreatic multipotent progenitors, the role of NEUROD1 has yet to be clarified. Notably, NEUROD1 can induce neuronal program through pioneering and chromatin remodelling in other cell types. In this study, we performed advanced molecular and phenotypic analyses in early endocrine-specific Neurod1-deficient mouse model, including RNA and CUT&Tag sequencing and lightsheet microscopy, to gain insight into the NEUROD1-regulated transcription network driving endocrine lineage cell fate commitment. Besides a postnatal diabetic phenotype, disrupted endocrine differentiation and associated altered islet architecture, we observed an apparent elevation in the non-endocrine gene expression pattern and uncovered alterations in the epigenetic landscape of characteristic genes, specifically in the H3K4me3 and H3K27me3 distribution. Therefore, we provide evidence that NEUROD1 is critical player responsible for the establishment of the endocrine cell identity, which further affects endocrine development and may serve as a potent proendocrine reprogramming driver.

Project description:Identifying the mechanisms behind neuronal fate specification are key to understanding neurodevelopmental disorders such as autism and schizophrenia. In vivo nervous system fate specification is difficult to study in vertebrates. However, the nematode Caenorhabditis elegans, with its invariant cell lineage and simple nervous system of 302 neurons, is an ideal organism to explore the earliest stages of neural development. We took a comparative transcriptome approach to understanding the role of cnd-1/NeuroD1 in C. elegans nervous system development and function. This basic helix-loop-helix transcription factor is deeply conserved across phyla, and plays a crucial role in cell fate specification in both the vertebrate nervous system and pancreas. We find that cnd-1 partially represses its own expression during C. elegans embryogenesis. In addition, we show that cnd-1 controls the expression of ceh-5, a Vax2-like homeobox class transcription factor expressed in the nervous system and in head muscles. We also demonstrate a role for the Hox gene ceh-13/labial in defining the fate of cnd-1-expressing motorneurons. Finally, we show that cnd-1 also controls the expression levels of genes required for post-mitotic function, including the RING-finger ubiquitin ligase rpm-1. These data highlight the utility of comparative transcriptomes for understanding the nuances of transcription factor control, and establish a paradigm for future transcriptome-based studies.

Project description:Rest (RE1 silencing transcription factor, also called NRSF) is involved in the maintenance of the undifferentiated state of neuronal stem/progenitor cells in vitro by preventing precocious expression of neuronal genes. However, the function of Rest during neurogenesis in vivo remains to be elucidated because of the early embryonic lethal phenotype of the conventional Rest knockout mice. In the present study, we have generated Rest conditional knockout mice, and the effect of genetic ablation of Rest during the embryonic neurogenesis can be examined in vivo. We herein show that Rest plays a role in suppressing the expression of neuronal genes in cultured neuronal cells in vitro, as well as in non-neuronal cells outside of the central nervous system, but that it is dispensable for the embryonic neurogenesis in vivo. Our findings highlight the significance of extrinsic signals for the proper intrinsic regulation of neuronal gene expression levels in the specification of cell fate during embryonic neurogenesis in vivo. Total RNAs from E13.5 limbs and brains were analyzed for global gene expressions by Agilent microarray.

Project description:ARP/ASCL transcription factors are key determinants of cell fate specification in a wide variety of tissues, coordinating the acquisition of generic cell fates and of specific subtype identities. How these factors, recognizing highly similar DNA motifs, display specific activities, is not yet fully understood. To address this issue, we overexpressed different ARP/ASCL factors in zebrafish ascl1a-/- mutant embryos to determine which one is able to rescue the intestinal secretory lineage. We found that Ascl1a/b, Atoh1a/b and Neurod1 factors are all able to trigger the first step of the secretory regulatory cascade but distinct secretory cells are induced by these factors. Indeed, Neurod1 rescues the enteroendocrine lineage while Ascl1a/b and Atoh1a/b rescue the goblet cells. Gain-of-function experiments with Ascl1a/Neurod1 chimeric proteins revealed that the functional divergence is encoded by a 19-aa ultra-conserved element (UCE), present in all Neurod members but absent in the other ARP/ASCL proteins. This novel domain acts as a goblet cell fate repressor and inhibits Gfi1aa expression, known to be important for goblet cell differentiation. Deleting the UCE domain of the endogenous Neurod1 protein leads to an increase in the number of goblet cells concomitant with a reduction of several EE subtypes, validating the importance of the UCE domain in enteroendocrine cell differentiation. Importantly, the neurod1 null mutant displays very similar defects supporting the crucial function of the UCE domain for NeuroD1 activity in the intestine. As Gfi1 acts as a binary cell fate switch in several tissues where Neurod1 is also expressed, we can envision a similar role of the UCE in other tissues, allowing Neurod1 to repress Gfi1 to influence the balance between cell fates.

Project description:NeuroD1 encodes a basic helix-loop-helix transcription factor involved in the development of neural and endocrine structures. NeuroD1 mRNA is highly abundant in the adult mammalian pineal gland and exhibits a developmental expression pattern similar to the retina. This is consistent with the common evolutionary origin of pinealocytes and retinal photoreceptors. Pinealocytes and retinal photoreceptors express a shared set of phototransduction genes and submammalian pinealocytes are photosensitive. In contrast to the retina, the pineal gland is a relatively homogeneous structure, composed 95% of pinealocytes. This makes the pineal gland a particularly useful model for understanding photoreceptor cell biology. The loss of NeuroD1 in the retina results in progressive photoreceptor degeneration and the molecular mechanisms underlying this retinal degeneration phenotype remain unknown. Similarly, the role that NeuroD1 plays in the pineal gland is unknown. To determine the function of NeuroD1 in the pineal gland and retina, a Cre/loxP recombination strategy was used to selectively target a NeuroD1 floxed allele and generate NeuroD1 conditional knockout (cKO) mice. Tissue specificity was conferred using Cre recombinase expressed under the control of the promoter of Crx, a transcription factor selectively expressed in the pineal gland and retina. Pineal and retinal tissues from two-month-old NeuroD1 cKO and control animals were used in microarray studies to identify candidate genes responsible for the photoreceptor degeneration phenotype. The Cre/loxP recombination strategy was used to target a NeuroD1 floxed allele and generate NeuroD1 conditional knockout mice (NeuroD1floxed::Crx-Cre+/-). NeuroD1 floxed mice (NeuroD1floxed::Crx-Cre-/-) served as the controls. Pineal glands and retinas from two-month-old control and conditional knockout mice were collected at ZT6 and ZT20. 3 pools of 6 pineal glands per genotype and respective time of day were collected for each sample. Similarly, 3 pools of 6 retinas each were also collected. RNA from each pool was extracted and hybridized on the Affymetrix Mouse 430 2.0 array.

Project description:Genome-wide Insm1 binding sites analysis revealed an overrepresentation of sequences predicted to bind bHLH and/or forkhead factors, and further analyses demonstrated that most Insm1 sites in the genome are co-occupied by Neurod1 and Foxa2. Binding regions co-occupied by all three factors but not single Insm1 sites explained a significant fraction of gene expression changes in Insm1 mutant β-cells. Together, our data provide evidence that an Insm1, Neurod1 and Foxa2 network maintains a mature gene expression program in β-cells. 6 samples include, replicates of Insm1 and Foxa2, IgG pull down as a control

Project description:This experiment used RNA-Seq technology to explore gene expression in mouse Insm1GFP.Cre/+ controls and Insm1 (Insm1GFP.Cre/GFP.Cre), Neurod1 (Insm1GFP.Cre/+; Neurod1LacZ/LacZ), or Pax6 (Insm1GFP.Cre/+; Pax6fl/fl) knockout FACS sorted pancreatic endocrine cells at E15.5. Comparison of Insm1GFP.Cre+/- and knockout animals revealed sets of differentially expressed genes that are required for endocrine cell specification and development.