Project description:To elucidate the role of S6K1 in human brain development, we performed next-generation sequencing-based genomweide analysis of S6K1 knockout (KO) human embryonic stem cells (ESCs) and brain organoids. Development/differentiation-related genes were highly enriched in DEGs of S6K1 KO hESCs compared to WT hESCs. Single cell transcriptomic analysis showed unusual retinal cell development in S6K1-depleted brain organoids, thereby reducing neural populations. Furthermore, we generated brain organoids containing both WT and S6K1 KO cells and then isolated them after completing differentiation to compare the feature of each portion grown in mixed condition. ATAC sequencing analysis of each portion in mixed brain organoids displayed no significant differences in retinal cell marker gene transcriptomes between WT and S6K1 KO portions, while chromatin accessibility of neural-specific genes were lower in S6K1 KO portion than WT. Collectively, this study revealed that S6K1 plays dual role in human brain development; suppression of retinal lineage specification and production of mature neurons through non-cell autonomous and cell autonomous action, respectively.

Project description:To elucidate the role of S6K1 in human brain development, we performed next-generation sequencing-based genomweide analysis of S6K1 knockout (KO) human embryonic stem cells (ESCs) and brain organoids. Development/differentiation-related genes were highly enriched in DEGs of S6K1 KO hESCs compared to WT hESCs. Single cell transcriptomic analysis showed unusual retinal cell development in S6K1-depleted brain organoids, thereby reducing neural populations. Furthermore, we generated brain organoids containing both WT and S6K1 KO cells and then isolated them after completing differentiation to compare the feature of each portion grown in mixed condition. ATAC sequencing analysis of each portion in mixed brain organoids displayed no significant differences in retinal cell marker gene transcriptomes between WT and S6K1 KO portions, while chromatin accessibility of neural-specific genes were lower in S6K1 KO portion than WT. Collectively, this study revealed that S6K1 plays dual role in human brain development; suppression of retinal lineage specification and production of mature neurons through non-cell autonomous and cell autonomous action, respectively.

Project description:Gb5 is a divergent, evolutionarily-conserved, member of the heterotrimeric G protein b subunit family that is expressed principally in brain and neuronal tissue. Among Gb isoforms, Gb5 is unique in its ability to heterodimerize with members of the R7 subfamily of the regulator of G protein signaling (RGS) proteins that contain G protein-g like (GGL) domains. Previous studies employing Gb5 knockout mice have shown that Gb5 is an essential stabilizer of GGL domain-containing RGS proteins and regulates the deactivation of retinal phototransduction and the proper functioning of retinal bipolar cells. The purpose of this study is to better understand the functions of Gb5 in the brain outside the visual system by employing molecular biology, immunohistochemistry and confocal imaging technologies. We show here that mice lacking Gb5 have a markedly abnormal neurologic phenotype that includes neurobehavioral developmental delay, wide-based gait, motor learning and coordination deficiencies, and hyperactivity. Using immunohistochemical analysis and a green fluorescent reporter of Purkinje cell maturation we show that the phenotype of Gb5-deficient mice includes, in part, delayed development of the cerebellar cortex, an abnormality that likely contributes to the neurobehavioral phenotype. Multiple neuronally-expressed genes are dysregulated in non-cerebellar portion of Gb5 KO mice. Brain tissues(non-cerebellar portion of brain) from WT and KO with three biological replications of mice were collected, frozen in liquid nitrogen, and stored at -70 °C

Project description:This study utilized human stem cell derived retinal organoids to characterize two models of Leber Congenital Amaurosis. Using CRISPR/Cas9, we generated CRB1 and RPGRIP1 KO cell lines and differentiated WT and KO lines into retinal organoids. Single cell capture was performed using Dropseq at days 70, 90, 120, 150, 190, and 225 of differentiation. We report upregulation of DDIT3 in both KO organoids relative to WT and confirm DDIT3 induction at the protein level by immunohistochemistry. These results indicate that these genetically different models of disease converge on endoplasmic reticulum stress and DDIT3 induction as a shared degenerative pathway. Therapeutic targeting of ER stress could help alleviate the degenerative phenotype in cases where diseased photorececeptors suffer ER stress.

Project description:RNA-seq analysis of five retinoblastoma tumor samples to compare expression signature with retinal organoids generated from hESCs in vitro and modelling retinoblastoma

Project description:ES/iPS-retinal sheet transplantation, which supplies photoreceptors as well as other retinal cells, has been shown able to restore visual function in mice with end-stage retinal degeneration. Here, we introduce a novel type of genetically engineered mouse ES/iPS-retinal sheet with reduced numbers of secondary retinal neurons but intact photoreceptor cell layer structure (Bhlhb4 knockout and Islet1 knockout). We show that this KO grafts can differentiate into retinal organoids with similar potency as wildtype retinal organoids. The data set contains data from 3 cell  lines: wildtype (WT, specified as ‘NCT’), B4KO (Bhlhb4 knock-out), and Isl1KO(Islet-1 knockout) across 3 differential days (DDs, DD10, DD16, and DD23) along the early differentiation of retinal tissue. 

Project description:The macula of the retina has a high ratio of cones to rods and is critical for central vision and visual acuity. Here we report the generation, transcriptome profiling, and functional validation of single cells from cone-enriched human retinal organoids differentiated from hESCs. Single-cell RNA-seq of 8-month retinal organoids identified clusters of cone and rod photoreceptors and confirmed the cone enrichment initially revealed by immunostaining. Collectively, we have established cone-enriched retinal organoids and a reference of transcriptomes that are rich resources for retinal studies.

Project description:To study the effect of GLI3 knockout in brain organoids, we collected scRNA-seq data from 45 day old brain organoids with GLI3 KO

Project description:The macula of the retina has a high ratio of cones to rods and is critical for central vision and visual acuity. Macula degenerations affect vision the most and are incurable. Here we report the generation, transcriptome profiling, and functional validation of cone-enriched human retinal organoids differentiated from hESCs. Transcriptome profiling using bulk RNA-seq demonstrated that retinal differentiation in vitro recapitulated retinogenesis in vivo in the temporal expression of cell differentiation markers and retinal disease genes, as well as in mRNA alternative splicing. Single-cell RNA-seq of 8-month retinal organoids identified clusters of cone and rod photoreceptors and confirmed the cone enrichment initially revealed by immunostaining. Notably, comparisons of single-cell transcriptomes demonstrated the similarity between retinal organoids and human macula in cones and rods. Cones in retinal organoids exhibited electrophysiological functions. Collectively, we have established cone-enriched retinal organoids and a reference of transcriptomes that are rich resources for retinal studies.

Project description:We reported loss of ARID1A promoted neurogenesis and inhibited cardiogenesis. Under microscopy, we observed that spontaneously differentiated cells were induced in ARID1A KO H9 hESCs cultured in mTesR medium. After cardiac differentiation for 10 days, we also observed the cell types were totally different between WT and ARID1A KO cells. We did not know what cells types were. Here scRNA-seq were used to identify the cell types in WT H9 hESCs and ARID1A KO H9 hESCs.