Summary Mammalian genomes contain long domains with distinct average compositions of A/T versus G/C base pairs. In a screen for proteins that might interpret base composition by binding to AT-rich motifs, we identified the stem cell factor SALL4, which contains multiple zinc fingers. Mutation of the domain responsible for AT binding drastically reduced SALL4 genome occupancy and prematurely upregulated genes in proportion to their AT content. Inactivation of this single AT-binding zinc-finger cluster mimicked defects seen in Sall4 null cells, including precocious differentiation of embryonic stem cells (ESCs) and embryonic lethality in mice. In contrast, deletion of two other zinc-finger clusters was phenotypically neutral. Our data indicate that loss of pluripotency is triggered by downregulation of SALL4, leading to de-repression of a set of AT-rich genes that promotes neuronal differentiation. We conclude that base composition is not merely a passive byproduct of genome evolution and constitutes a signal that aids control of cell fate.
Tet1, Tet2, and Tet3 encode DNA demethylases that play critical roles during stem cell differentiation and reprogramming to pluripotency. Although all three genes are transcribed in pluripotent cells, little is known about the expression of the corresponding proteins. Here, we tagged all the endogenous Tet family alleles using CRISPR/Cas9, and characterised TET protein expression in distinct pluripotent cell culture conditions. Whereas TET1 is abundantly expressed in both naïve and primed pluripotent cells, TET2 expression is restricted to the naïve state. Moreover, TET2 is expressed heterogeneously in embryonic stem cells (ESCs) cultured in serum/leukemia inhibitory factor, with expression correlating with naïve pluripotency markers. FACS-sorting of ESCs carrying a Tet2Flag-IRES-EGFP reporter demonstrated that TET2-negative cells have lost the ability to form undifferentiated ESC colonies. We further show that TET2 binds to the transcription factor NANOG. We hypothesize that TET2 and NANOG co-localise on chromatin to regulate enhancers associated with naïve pluripotency genes.
Deletion of Sox2 from mouse embryonic stem cells (ESCs) causes trophectodermal differentiation. While this can be prevented by enforced expression of the related SOXB1 proteins, SOX1 or SOX3, the roles of SOXB1 proteins in epiblast stem cell (EpiSC) pluripotency are unknown. Here, we show that Sox2 can be deleted from EpiSCs with impunity. This is due to a shift in the balance of SoxB1 expression in EpiSCs, which have decreased Sox2 and increased Sox3 compared to ESCs. Consistent with functional redundancy, Sox3 can also be deleted from EpiSCs without eliminating self-renewal. However, deletion of both Sox2 and Sox3 prevents self-renewal. The overall SOXB1 levels in ESCs affect differentiation choices: neural differentiation of Sox2 heterozygous ESCs is compromised, while increased SOXB1 levels divert the ESC to EpiSC transition towards neural differentiation. Therefore, optimal SOXB1 levels are critical for each pluripotent state and for cell fate decisions during exit from naïve pluripotency.
Spalt-like 4 (SALL4) maintains vertebrate embryonic stem cell identity and is required for the development of multiple organs, including limbs. Mutations in SALL4 are associated with Okihiro syndrome, and SALL4 is also a known target of thalidomide. SALL4 protein has a distinct preference for AT-rich sequences, recognised by a pair of zinc fingers at the C-terminus. However, unlike many characterised zinc finger proteins, SALL4 shows flexible recognition with many different combinations of AT-rich sequences being targeted. SALL4 interacts with the NuRD corepressor complex which potentially mediates repression of AT-rich genes. We present a crystal structure of SALL4 C-terminal zinc fingers with an AT-rich DNA sequence, which shows that SALL4 uses small hydrophobic and polar side chains to provide flexible recognition in the major groove. Missense mutations reported in patients that lie within the C-terminal zinc fingers reduced overall binding to DNA but not the preference for AT-rich sequences. Furthermore, these mutations altered association of SALL4 with AT-rich genomic sites, providing evidence that these mutations are likely pathogenic.
Correlative evidence has suggested that DNA methylation promotes the formation of transcriptionally silent heterochromatin. Accordingly, the methyl-CpG binding domain protein MeCP2 is often portrayed as a constituent of heterochromatin. This interpretation has been reinforced by the use of mouse cells as an experimental system for studying the mammalian epigenome, as heterochromatin, DNA methylation and MeCP2 colocalise in prominent foci. The findings presented here revise this view. We show that focal localisation of MeCP2 in mice is independent of heterochromatin, as DNA methylation-dependent MeCP2 foci persist even when the signature heterochromatin histone mark H3K9me3 is absent and heterochromatin protein HP1 is diffuse. Contrary to the proposal that MeCP2 forms condensates at mouse heterochromatic foci via liquid-liquid phase transition, the short methyl-CpG binding domain, which lacks the disordered domains thought to be required for condensation, is sufficient to target foci in mouse cells. Importantly, we find that the formation of MeCP2 foci in mice is highly atypical, as they are indetectable in 14 out of 16 other mammalian species, including humans. Notably, MeCP2 foci are absent in Mus spretus which can interbreed with Mus musculus but lacks its highly methylated pericentric satellite DNA repeats. We conclude that MeCP2 has no intrinsic tendency to form nuclear condensates and its localisation is independent of heterochromatin formation. Instead, the distribution of MeCP2 in the nucleus is primarily determined by global DNA methylation patterns and is typically euchromatic.
Sin3a is a central component of a class of histone deacetylase‐containing transcriptional co‐regulatory complexes. In this issue of The EMBO Journal, Streubel et al () purify Sin3a and identify a variant Sin3a complex containing Fam60a in undifferentiated embryonic stem cells (ESCs). Fam60a is a critical component of the ESC Sin3a complex since Fam60a knockdown leads to an extended G1 cell cycle phase and reduced ESC self‐renewal. These exciting results open up new questions about how biochemical differences between variant Sin3a complexes may facilitate alterations in cell‐specific function.
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