Na Sun

The neural fate commitment of pluripotent stem cells requires the repression of extrinsic inhibitory signals and the activation of intrinsic positive transcription factors. However, how these two events are integrated to ensure appropriate neural conversion remains unclear. In this study, we showed that Pou3f1 is essential for the neural differentiation of mouse embryonic stem cells (ESCs), specifically during the transition from epiblast stem cells (EpiSCs) to neural progenitor cells (NPCs). Chimeric analysis showed that Pou3f1 knockdown leads to a markedly decreased incorporation of ESCs in the neuroectoderm. By contrast, Pou3f1-overexpressing ESC derivatives preferentially contribute to the neuroectoderm. Genome-wide ChIP-seq and RNA-seq analyses indicated that Pou3f1 is an upstream activator of neural lineage genes, and also is a repressor of BMP and Wnt signaling. Our results established that Pou3f1 promotes the neural fate commitment of pluripotent stem cells through a dual role, activating internal neural induction programs and antagonizing extrinsic neural inhibitory signals.

progenitors upstream of PRDM1 to regulate the expression of SOX17. This serves to protect hPGCLCs from crossing the Weismann's barrier to adopt somatic cell fates and, therefore, is an essential mechanism for successfully initiating in vitro gametogenesis.

Heat shock transcription factorA2 (HsfA2) is a key regulator in response to heat stress in Arabidopsis (Arabidopsis thaliana), and its heat shock (HS)-induced transcription regulation has been extensively studied. Recently, alternative splicing, a critical posttranscriptional event, has been shown to regulate HS-inducible expression of HsfA2; however, the molecular mechanism remains largely unknown. Here, we demonstrate a new heat stress-induced splice variant, HsfA2-III, is involved in the self-regulation of HsfA2 transcription in Arabidopsis. HsfA2-III is generated through a cryptic 5' splice site in the intron, which is activated by severe heat (42°C-45°C). We confirmed that HsfA2-III encodes a small truncated HsfA2 isoform (S-HsfA2) by an immunoblot assay with anti-S-HsfA2 antiserum. S-HsfA2 has an extra leucine-rich motif next to its carboxyl-terminal truncated DNA-binding domain. The biological significance of S-HsfA2 was further demonstrated by its nuclear localization and heat shock element (HSE)-binding ability. In yeast (Saccharomyces cerevisiae), the leucine-rich motif can inhibit the transcriptional activation activity of S-HsfA2, while it appears not to be required for the truncated DNA-binding domain-mediated binding ability of S-HsfA2-HSE. Further results reveal that S-HsfA2 could bind to the TATA box-proximal clusters of HSE in the HsfA2 promoter to activate its own transcription. This S-HsfA2-modulated HsfA2 transcription is not mediated through homodimer or heterodimer formation with HsfA1d or HsfA1e, which are known transcriptional activators of HsfA2. Altogether, our findings provide new insights into how HS posttranscriptionally regulates HsfA2 expression. Severe HS-induced alternative splicing also occurs in four other HS-inducible Arabidopsis Hsf genes, suggesting that it is a common feature among Arabidopsis Hsfs.