Jacqueline E. Mermoud

Histone H3 lysine 9 methylation is an epigenetic imprint of facultative heterochromatin

Post-translational modifications of histone amino termini are an important regulatory mechanism that induce transitions in chromatin structure, thereby contributing to epigenetic gene control and the assembly of specialized chromosomal subdomains. Methylation of histone H3 at lysine 9 (H3–Lys9) by site-specific histone methyltransferases (Suv39h HMTases) marks constitutive heterochromatin. Here, we show that H3–Lys9 methylation also occurs in facultative heterochromatin of the inactive X chromosome (Xi) in female mammals. H3–Lys9 methylation is retained through mitosis, indicating that it might provide an epigenetic imprint for the maintenance of the inactive state. Disruption of the two mouse Suv39h HMTases abolishes H3-Lys9 methylation of constitutive heterochromatin but not that of the Xi. In addition, HP1 proteins, which normally associate with heterochromatin, do not accumulate with the Xi. These observations suggest the existence of an Suv39h-HP1-independent pathway regulating H3-Lys9 methylation of facultative heterochromatin.

Regulation of mammalian spliceosome assembly by a protein phosphorylation mechanism.

Splicing of mRNA precursors (pre‐mRNA) is preceded by assembly of the pre‐mRNA with small nuclear ribonucleoprotein particles (snRNPs) and protein factors to form a splicesome. Here we show that stimulating Ser/Thr‐specific protein dephosphorylation selectively inhibits an early step during mammalian spliceosome assembly. Treatment of HeLa nuclear splicing extracts with human protein phosphatase 1 (PP1) expressed in Escherichia coli, or PP1 purified from rabbit skeletal muscle, prevents pre‐spliceosome E complex (early complex) formation and stable binding of U2 and U4/U6.U5 snRNPs to the pre‐mRNA. PP1 does not inhibit splicing catalysis if added after spliceosome assembly has taken place. Addition of purified SR protein splicing factors restores spliceosome formation and splicing to PP1‐inhibited extracts, consistent with SR proteins being targets regulated by phosphorylation. These data extend earlier observations showing that splicing catalysis, but not spliceosome assembly, is blocked by inhibiting protein phosphatases. It therefore appears that pre‐mRNA splicing, in common with other biological processes, can be regulated both positively and negatively by reversible protein phosphorylation.

Global hypomethylation of the genome in XX embryonic stem cells

Embryonic stem (ES) cells are important tools in the study of gene function and may also become important in cell therapy applications. Establishment of stable XX ES cell lines from mouse blastocysts is relatively problematic owing to frequent loss of one of the two X chromosomes. Here we show that DNA methylation is globally reduced in XX ES cell lines and that this is attributable to the presence of two active X chromosomes. Hypomethylation affects both repetitive and unique sequences, the latter including differentially methylated regions that regulate expression of parentally imprinted genes. Methylation of differentially methylated regions can be restored coincident with elimination of an X chromosome in early-passage parthenogenetic ES cells, suggesting that selection against loss of methylation may provide the basis for X-chromosome instability. Finally, we show that hypomethylation is associated with reduced levels of the de novo DNA methyltransferases Dnmt3a and Dnmt3b and that ectopic expression of these factors restores global methylation levels.

Histone H3 lysine 9 methylation occurs rapidly at the onset of random X chromosome inactivation.

In female mammals, a single X chromosome is stably and heritably silenced early in embryogenesis. The inactive X is characterized by asynchronous DNA replication and epigenetic chromatin modifications, including DNA methylation, histone H3/H4 hypoacetylation, and incorporation of a variant histone macroH2A. X inactivation is initiated by a cis-acting RNA molecule, the X-inactive specific transcript (Xist), which coats the chromosome. However, the mechanism by which Xist induces chromosome silencing is poorly understood. An important approach towards answering this question has been to determine the temporal order of epigenetic chromatin modifications in an in vitro model system, differentiating XX embryonic stem (ES) cells, and thereby to identify candidate targets for Xist RNA. To date, these studies have demonstrated that, following accumulation of Xist RNA, the transition to late replication of the X chromosome is the earliest detectable event. H4 hypoacetylation, macroH2A1.2 incorporation, and DNA methylation all occur subsequently. Recently, it has been shown that chromatin of the inactive X is also characterized by methylation of histone H3 at lysine 9 (H3-K9). Here we show that H3-K9 methylation is a very early event in the process of X inactivation, which closely parallels the onset of Xist RNA accumulation.

Maintenance of Silent Chromatin through Replication Requires SWI/SNF-like Chromatin Remodeler SMARCAD1

Epigenetic marks such as posttranslational histone modifications specify the functional states of underlying DNA sequences, though how they are maintained after their disruption during DNA replication remains a critical question. We identify the mammalian SWI/SNF-like protein SMARCAD1 as a key factor required for the re-establishment of repressive chromatin. The ATPase activity of SMARCAD1 is necessary for global deacetylation of histones H3/H4. In this way, SMARCAD1 promotes methylation of H3K9, the establishment of heterochromatin, and faithful chromosome segregation. SMARCAD1 associates with transcriptional repressors including KAP1, histone deacetylases HDAC1/2 and the histone methyltransferase G9a/GLP and modulates the interaction of HDAC1 and KAP1 with heterochromatin. SMARCAD1 directly interacts with PCNA, a central component of the replication machinery, and is recruited to sites of DNA replication. Our findings suggest that chromatin remodeling by SMARCAD1 ensures that silenced loci, such as pericentric heterochromatin, are correctly perpetuated.

Keeping chromatin quiet: How nucleosome remodeling restores heterochromatin after replication

Disruption of chromatin organization during replication poses a major challenge to the maintenance and integrity of genome organization. It creates the need to accurately reconstruct the chromatin landscape following DNA duplication but there is little mechanistic understanding of how chromatin based modifications are restored on newly synthesized DNA. ATP-dependent chromatin remodeling activities serve multiple roles during replication and recent work underscores their requirement in the maintenance of proper chromatin organization. A new component of chromatin replication, the SWI/SNF-like chromatin remodeler SMARCAD1, acts at replication sites to facilitate deacetylation of newly assembled histones. Deacetylation is a pre-requisite for the restoration of epigenetic signatures in heterochromatin regions following replication. In this way, SMARCAD1, in concert with histone modifying activities and transcriptional repressors, reinforces epigenetic instructions to ensure that silenced loci are correctly perpetuated in each replication cycle. The emerging concept is that remodeling of nucleosomes is an early event imperative to promote the re-establishment of histone modifications following DNA replication.

Neurite-like structures induced by mevalonate pathway blockade are due to the stability of cell adhesion foci and are enhanced by the presence of APP

J. Neurochem. (2010) 114, 832–842.

Epigenomes under scrutiny

A report on the 3rd UK Stem Cell Meeting Epigenetics & Differentiation, London, UK, 11 March 2008.