Project description:Microarray anlaysis was performed to investigate gene expression patterns of other transcription factors involved in early retinal and/or forebrain development using human embryonic stem cell-derived retinal and forebrain progenitor cells. After 20 days of differentiation, vesicular neurospheres selectively expressed multiple retinal transcription factor genes appropriate for the OV stage of retinogenesis, whereas nonvesicular neurospheres expressed transcription factors indicative of the embryonic forebrain. Many transcription factor genes associated with retinal development were present at higher levels in vesicular vs. nonvesicular neurospheres. Nonvesicular neurospheres, on the other hand, expressed higher levels of transcription factors implicated in early forebrain development. Taken together, results indicated that the vesicular and nonvesicular neurospheres harbored retinal progenitor cells and early forebrain populations, respectively. Compare the global gene expression of retinal progenitor cells and forebrain progenitor cells derived from human embryonic stem cells

Project description:Vaccinia Virus Copenhagen Transcription Anlaysis

Project description:E2F4 wild and knockout type neurospheres from E12.5 forebrain. E2F4 transcription factor regulates the expression of the genes which are required for neural stem cell expansion in the developing mouse brain. The results of microarray analysis will help to identify the signaling pathways affected by E2F4 deletion and refine the neural stem cell regulatory mechanism. Keywords: other

Project description:Whole genome profiling of histone methylation (H3K4me3, H3K27me3 and RNA Pol II) in Ciliary derived stem/progenitor cells and differentiated cells. In the present study we focus on the cellular differentiation that involves loss of pluripotency and gain of lineage and cell type-specific characteristics and we show developments from adult ciliary derived stem/progenitor cells to differentiated retinal neurons/glial cells of human cadaveric eyes in vitro. Ciliary pigment epithelial cells isolated from human cadaveric eye balls were cultured in the presence of mitogens like Epidermal Growth Factor (EGF) and Fibroblast Growth Factors (FGF) to generate neurospheres (Stem/progenitor population). The generated neurospheres were plated on laminin and poly-D-lysine-coated cover slips in the presence of the Brain derived neurotrophic factor (BDNF), Retinoic acid (RA) and 10% FBS for the differentiation (Retinal neuron/glial cells). Global Methylation patterns of histone H3K4me3, RNA Pol II and H3K27me3 were analysed in the present study. This work would provide an outline of epigenetic modifications in ciliary derived stem/progenitor cells and the progeny that underwent differentiation into retinal neurons/glial cells and present that specific histone methylations are involved in gene expression reprogramming during the process of differentiation.

Project description:E2F4 wild and knockout type neurospheres from E12.5 forebrain. E2F4 transcription factor regulates the expression of the genes which are required for neural stem cell expansion in the developing mouse brain. The results of microarray analysis will help to identify the signaling pathways affected by E2F4 deletion and refine the neural stem cell regulatory mechanism. Experiment Overall Design: This experiment include 2 samples on 2 platforms for a total of 4 Samples.

Project description:The early retinal progenitor-expressed gene Sox11 regulates the timing of the differentiation of retinal cells. Sry-related HMG box (Sox) proteins play diverse and critical roles in a variety of morphogenetic processes during embryonic development. Sox11 and Sox4 are members of the SoxC subtype, and we found that Sox11 was strongly expressed in early retinal progenitor cells, and that when expression of Sox11 subsided around birth, Sox4 expression began. To analyze the role of Sox11 and Sox4 in retinal development, we perturbed their expression pattern by expressing them ectopically in retinal explant culture. Overexpression of Sox11 or Sox4 in retinal progenitors resulted in similar phenotypes, that is, increased cone cells and decreased Muller glia. Sox11-knockout retinas showed delayed onset and progress of differentiation of early-born retinal cells during the embryonic period. After birth, retinal differentiation took place relatively normally, probably because of the redundant activity of Sox4, which starts to differentiate around birth. Neither overexpression nor loss-of-function analysis gave any evidence that Sox11 and Sox4 directly regulate transcription of genes critical to early-born retinal cells. However, histone H3 acetylation status of the early neurogenic genes was lowered in knockout retinas, suggesting that Sox11 regulates the timing of differentiation in early-born retinas by creating an epigenetic state that helps to establish the competency to differentiate. We also found that the unique expression patterns of Sox11 and Sox4 may be achieved by the Notch signaling pathway and by epigenetic regulation. Taking our findings together, we propose that the precise regulation of Sox11 and Sox4 expression during retinogenesis by multiple mechanisms leads to the fine adjustment of retinal differentiation. To delineate the molecular mechanisms underlying the retinal action of Sox11, we performed microarray analysis of E18 retinas from wild-type and Sox11 knockout mice. Total RNA was obtained from each one retina of Sox11 knockout and wild-type littermate embryos at E18.

Project description:PAX6 is essential for eye and forebrain development but how PAX6 instructs retinal versus neuroectoderm specification remains unknown. We found that the paired-less PAX6, PAX6D, is uniquely expressed in retinal cells during human eye development and along human embryonic stem cell (hESC) differentiation to retinal cells. HESCs with deletion of PAX6D failed to enter retinal differentiation. Induced expression of PAX6D but not PAX6A under the PAX6-null background restored the retinal differentiation capacity. ChIP-Seq, confirmed by functional assays, revealed a set of retinal genes and neural genes that are targets of PAX6D, including WNT8B. Inhibition of WNTs restored the retinal differentiation capacity of neuroepithelia with PAX6D knockout whereas activation of WNTs blocks retinal differentiation even when PAX6D is induced. Thus, PAX6D specifies neuroepithelia to retinal cells, partly via regulation of WNTs.

Project description:PAX6 is essential for eye and forebrain development but how PAX6 instructs retinal versus neuroectoderm specification remains unknown. We found that the paired-less PAX6, PAX6D, is uniquely expressed in retinal cells during human eye development and along human embryonic stem cell (hESC) differentiation to retinal cells. HESCs with deletion of PAX6D failed to enter retinal differentiation. Induced expression of PAX6D but not PAX6A under the PAX6-null background restored the retinal differentiation capacity. ChIP-Seq, confirmed by functional assays, revealed a set of retinal genes and neural genes that are targets of PAX6D, including WNT8B. Inhibition of WNTs restored the retinal differentiation capacity of neuroepithelia with PAX6D knockout whereas activation of WNTs blocks retinal differentiation even when PAX6D is induced. Thus, PAX6D specifies neuroepithelia to retinal cells, partly via regulation of WNTs.

Project description:How the diverse neural cell types emerge from multipotent neural progenitor cells during central nervous system development remains poorly understood. Recent scRNA-seq studies have delineated the developmental trajectories of individual neural cell types in many neural systems including the neural retina. Further understanding of the formation of neural cell diversity requires knowledge about how the epigenetic landscape shifts along individual cell lineages and how key transcription factors regulate these changes. In this study, we dissect the changes in the epigenetic landscape during early retinal cell differentiation by scATAC-seq and identify globally the enhancers, enriched motifs, and potential interacting transcription factors underlying the cell state/type specific gene expression in individual lineages. Using CUT&Tag-seq, we further identify the enhancers bound directly by four key transcription factors, Otx2, Atoh7, Pou4f2, and Isl1, and uncover their roles in shaping the epigenetic landscape and controlling gene expression in a sequential and combinatorial fashion along individual retinal cell lineages such as retinal ganglion cells (RGCs). Our results reveal a general paradigm in which transcription factors collaborate and compete to regulate the emergence of distinct retinal cell types such as RGCs from multipotent retinal progenitor cells (RPCs).

Project description:The early retinal progenitor-expressed gene Sox11 regulates the timing of the differentiation of retinal cells. Sry-related HMG box (Sox) proteins play diverse and critical roles in a variety of morphogenetic processes during embryonic development. Sox11 and Sox4 are members of the SoxC subtype, and we found that Sox11 was strongly expressed in early retinal progenitor cells, and that when expression of Sox11 subsided around birth, Sox4 expression began. To analyze the role of Sox11 and Sox4 in retinal development, we perturbed their expression pattern by expressing them ectopically in retinal explant culture. Overexpression of Sox11 or Sox4 in retinal progenitors resulted in similar phenotypes, that is, increased cone cells and decreased Muller glia. Sox11-knockout retinas showed delayed onset and progress of differentiation of early-born retinal cells during the embryonic period. After birth, retinal differentiation took place relatively normally, probably because of the redundant activity of Sox4, which starts to differentiate around birth. Neither overexpression nor loss-of-function analysis gave any evidence that Sox11 and Sox4 directly regulate transcription of genes critical to early-born retinal cells. However, histone H3 acetylation status of the early neurogenic genes was lowered in knockout retinas, suggesting that Sox11 regulates the timing of differentiation in early-born retinas by creating an epigenetic state that helps to establish the competency to differentiate. We also found that the unique expression patterns of Sox11 and Sox4 may be achieved by the Notch signaling pathway and by epigenetic regulation. Taking our findings together, we propose that the precise regulation of Sox11 and Sox4 expression during retinogenesis by multiple mechanisms leads to the fine adjustment of retinal differentiation.