A multi-omics integrative analysis based on CRISPR screens re-defines the pluripotency regulatory network in ESCs.

A comprehensive and precise definition of the pluripotency gene regulatory network (PGRN) is crucial for clarifying the regulatory mechanisms in embryonic stem cells (ESCs). Here, after a CRISPR/Cas9-based functional genomics screen and integrative analysis with other functional genomes, transcriptomes, proteomes and epigenome data, an expanded pluripotency-associated gene set is obtained, and a new PGRN with nine sub-classes is constructed. By integrating the DNA binding, epigenetic modification, chromatin conformation, and RNA expression profiles, the PGRN is resolved to six functionally independent transcriptional modules (CORE, MYC, PAF, PRC, PCGF and TBX). Spatiotemporal transcriptomics reveal activated CORE/MYC/PAF module activity and repressed PRC/PCGF/TBX module activity in both mouse ESCs (mESCs) and pluripotent cells of early embryos. Moreover, this module activity pattern is found to be shared by human ESCs (hESCs) and cancers. Thus, our results provide novel insights into elucidating the molecular basis of ESC pluripotency.

Genome-Wide CRISPR Screen Identifies Puf60 as a Novel Stemness Gene of Mouse Embryonic Stem Cells.

The mechanisms underlying self-renewal of embryonic stem cells (ESCs) hold great value in the clinical translation of stem cell biology and regenerative medicine research. To study the mechanisms in ESC self-renewal, screening and identification of key genes maintaining ESC self-renewal were performed by a genome-wide CRISPR-Cas9 knockout virus library. The mouse ESC R1 were infected with CRISPR-Cas9 knockout virus library and cultured for 14 days. The variation of single guide RNA (sgRNA) ratio was analyzed by high-throughput sequencing, followed by bioinformatics analysis to profile the altered genes. Our results showed 1375 genes with increased sgRNA ratio were found to be mainly involved in signal transduction, cell differentiation, and cell apoptosis; 2929 genes with decreased sgRNA ratio were mainly involved in cell cycle regulation, RNA splicing, and biological metabolic processes. We further confirmed our screen specificity by identifying Puf60, U2af2, Wdr75, and Usp16 as novel positive regulators in mESC self-renewal. Meanwhile, further analysis showed the relevance between Puf60 expression and tumor. In conclusion, our study screened key genes maintaining ESC self-renewal and successfully identified Puf60, U2af2, Wdr75, and Usp16 as novel positive regulators in mESC self-renewal, which provided theoretical basis and research clues for a better understanding of ESC self-renewal regulation.

Identification and functional comparison of Bcl2 splicing isoforms in mouse embryonic stem cells.

Embryonic stem cells (ESCs) provide an ideal model for investigating developmental processes and are great sources for developing regenerative medicine. Harnessing apoptosis facilitates accurate recapitulation of signalling events during embryogenesis and allows efficient expansion of the ESCs during differentiation. Bcl2, a key regulator of intrinsic anti-apoptotic pathway, encodes two splicing isoforms. However, the identification and functional comparison of Bcl2 splicing isoforms in mouse ESCs (mESCs) remains to be elucidated. Here, we provide the evidence that both Bcl2 splicing variants are expressed in mESCs. Despite the structural difference, they have similar subcellular localisation. Both Bcl2α and Bcl2ß enhance differentiation efficiency of the ESCs and effectively improve the survival and growth of ESCs under serum-free conditions. However, the functional effect of Bcl2α was more potent than that of Bcl2ß. Moreover, only Bcl2α could maintain the long-term expansion and pluripotency of ESCs cultured in serum-free medium. Taken together, our results demonstrate previously unknown functional differences in Bcl2 alternative splicing isoforms in ESCs, and lay the foundation for future efforts to engineer ESCs for regenerative medicine.

Nac1 promotes self-renewal of embryonic stem cells through direct transcriptional regulation of c-Myc.

The pluripotency transcriptional network in embryonic stem cells (ESCs) is composed of distinct functional units including the core and Myc units. It is hoped that dissection of the cellular functions and interconnections of network factors will aid our understanding of ESC and cancer biology. Proteomic and genomic approaches have identified Nac1 as a member of the core pluripotency network. However, previous studies have predominantly focused on the role of Nac1 in psychomotor stimulant response and cancer pathogenesis. In this study, we report that Nac1 is a self-renewal promoting factor, but is not required for maintaining pluripotency of ESCs. Loss of function of Nac1 in ESCs results in a reduced proliferation rate and an enhanced differentiation propensity. Nac1 overexpression promotes ESC proliferation and delays ESC differentiation in the absence of leukemia inhibitory factor (LIF). Furthermore, we demonstrated that Nac1 directly binds to the c-Myc promoter and regulates c-Myc transcription. The study also revealed that the function of Nac1 in promoting ESC self-renewal appears to be partially mediated by c-Myc. These findings establish a functional link between the core and c-Myc-centered networks and provide new insights into mechanisms of stemness regulation in ESCs and cancer.