Class of 1923: looking back at the authors of JEB's first issue.

Journal of Experimental Biology was launched in 1923 as The British Journal of Experimental Biology, with a single issue being published in the October of that year. As we celebrate our centenary, we look back at that first issue and the zoologists publishing their work in the new journal, and draw comparisons to the JEB that we know today. Much has changed since the publication of the first issue of JEB, in the worlds of both science and publishing, and we eagerly anticipate the next 100 years of discovery.

Histone modifications form a cell-type-specific chromosomal bar code that persists through the cell cycle.

Chromatin configuration influences gene expression in eukaryotes at multiple levels, from individual nucleosomes to chromatin domains several Mb long. Post-translational modifications (PTM) of core histones seem to be involved in chromatin structural transitions, but how remains unclear. To explore this, we used ChIP-seq and two cell types, HeLa and lymphoblastoid (LCL), to define how changes in chromatin packaging through the cell cycle influence the distributions of three transcription-associated histone modifications, H3K9ac, H3K4me3 and H3K27me3. We show that chromosome regions (bands) of 10-50 Mb, detectable by immunofluorescence microscopy of metaphase (M) chromosomes, are also present in G1 and G2. They comprise 1-5 Mb sub-bands that differ between HeLa and LCL but remain consistent through the cell cycle. The same sub-bands are defined by H3K9ac and H3K4me3, while H3K27me3 spreads more widely. We found little change between cell cycle phases, whether compared by 5 Kb rolling windows or when analysis was restricted to functional elements such as transcription start sites and topologically associating domains. Only a small number of genes showed cell-cycle related changes: at genes encoding proteins involved in mitosis, H3K9 became highly acetylated in G2M, possibly because of ongoing transcription. In conclusion, modified histone isoforms H3K9ac, H3K4me3 and H3K27me3 exhibit a characteristic genomic distribution at resolutions of 1 Mb and below that differs between HeLa and lymphoblastoid cells but remains remarkably consistent through the cell cycle. We suggest that this cell-type-specific chromosomal bar-code is part of a homeostatic mechanism by which cells retain their characteristic gene expression patterns, and hence their identity, through multiple mitoses.

Efficient translation of Dnmt1 requires cytoplasmic polyadenylation and Musashi binding elements.

Regulation of DNMT1 is critical for epigenetic control of many genes and for genome stability. Using phylogenetic analysis we characterized a block of 27 nucleotides in the 3'UTR of Dnmt1 mRNA identical between humans and Xenopus and investigated the role of the individual elements contained within it. This region contains a cytoplasmic polyadenylation element (CPE) and a Musashi binding element (MBE), with CPE binding protein 1 (CPEB1) known to bind to the former in mouse oocytes. The presence of these elements usually indicates translational control by elongation and shortening of the poly(A) tail in the cytoplasm of the oocyte and in some somatic cell types. We demonstrate for the first time cytoplasmic polyadenylation of Dnmt1 during periods of oocyte growth in mouse and during oocyte activation in Xenopus. Furthermore we show by RNA immunoprecipitation that Musashi1 (MSI1) binds to the MBE and that this element is required for polyadenylation in oocytes. As well as a role in oocytes, site-directed mutagenesis and reporter assays confirm that mutation of either the MBE or CPE reduce DNMT1 translation in somatic cells, but likely act in the same pathway: deletion of the whole conserved region has more severe effects on translation in both ES and differentiated cells. In adult cells lacking MSI1 there is a greater dependency on the CPE, with depletion of CPEB1 or CPEB4 by RNAi resulting in substantially reduced levels of endogenous DNMT1 protein and concurrent upregulation of the well characterised CPEB target mRNA cyclin B1. Our findings demonstrate that CPE- and MBE-mediated translation regulate DNMT1 expression, representing a novel mechanism of post-transcriptional control for this gene.

Ontogeny, conservation and functional significance of maternally inherited DNA methylation at two classes of non-imprinted genes.

A functional role for DNA methylation has been well-established at imprinted loci, which inherit methylation uniparentally, most commonly from the mother via the oocyte. Many CpG islands not associated with imprinting also inherit methylation from the oocyte, although the functional significance of this, and the common features of the genes affected, are unclear. We identify two major subclasses of genes associated with these gametic differentially methylated regions (gDMRs), namely those important for brain and for testis function. The gDMRs at these genes retain the methylation acquired in the oocyte through preimplantation development, but become fully methylated postimplantation by de novo methylation of the paternal allele. Each gene class displays unique features, with the gDMR located at the promoter of the testis genes but intragenically for the brain genes. Significantly, demethylation using knockout, knockdown or pharmacological approaches in mouse stem cells and fibroblasts resulted in transcriptional derepression of the testis genes, indicating that they may be affected by environmental exposures, in either mother or offspring, that cause demethylation. Features of the brain gene group suggest that they might represent a pool from which many imprinted genes have evolved. The locations of the gDMRs, as well as methylation levels and repression effects, were also conserved in human cells.

The histone deacetylase inhibitor sodium valproate causes limited transcriptional change in mouse embryonic stem cells but selectively overrides Polycomb-mediated Hoxb silencing.

BACKGROUND: Histone deacetylase inhibitors (HDACi) cause histone hyperacetylation and H3K4 hypermethylation in various cell types. They find clinical application as anti-epileptics and chemotherapeutic agents, but the pathways through which they operate remain unclear. Surprisingly, changes in gene expression caused by HDACi are often limited in extent and can be positive or negative. Here we have explored the ability of the clinically important HDACi valproic acid (VPA) to alter histone modification and gene expression, both globally and at specific genes, in mouse embryonic stem (ES) cells. RESULTS: Microarray expression analysis of ES cells exposed to VPA (1 mM, 8 h), showed that only 2.4% of genes showed a significant, >1.5-fold transcriptional change. Of these, 33% were down-regulated. There was no correlation between gene expression and VPA-induced changes in histone acetylation or H3K4 methylation at gene promoters, which were usually minimal. In contrast, all Hoxb genes showed increased levels of H3K9ac after exposure to VPA, but much less change in other modifications showing bulk increases. VPA-induced changes were lost within 24 h of inhibitor removal. VPA significantly increased the low transcription of Hoxb4 and Hoxb7, but not other Hoxb genes. Expression of Hoxb genes increased in ES cells lacking functional Polycomb silencing complexes PRC1 and PRC2. Surprisingly, VPA caused no further increase in Hoxb transcription in these cells, except for Hoxb1, whose expression increased several fold. Retinoic acid (RA) increased transcription of all Hoxb genes in differentiating ES cells within 24 h, but thereafter transcription remained the same, increased progressively or fell progressively in a locus-specific manner. CONCLUSIONS: Hoxb genes in ES cells are unusual in being sensitive to VPA, with effects on both cluster-wide and locus-specific processes. VPA increases H3K9ac at all Hoxb loci but significantly overrides PRC-mediated silencing only at Hoxb4 and Hoxb7. Hoxb1 is the only Hoxb gene that is further up-regulated by VPA in PRC-deficient cells. Our results demonstrate that VPA can exert both cluster-wide and locus-specific effects on Hoxb regulation.

DNA methylation plays an important role in promoter choice and protein production at the mouse Dnmt3L locus.

The DNA methyltransferase 3-like (Dnmt3L) protein is a crucial cofactor in the germ line for the de novo methyltransferase Dnmt3a, which establishes imprints and represses transposable elements. We have previously shown that Dnmt3L transcription is regulated via three different promoters in mice, producing transcripts we term Dnmt3L(s) (stem cell), Dnmt3L(o) (oocyte) and Dnmt3L(at) (adult testis). Here we show that both Dnmt3L(s) and Dnmt3L(o) produce full-length proteins but that the Dnmt3L(at) transcripts are not translated. Although not a canonical CpG island, the Dnmt3L(s) promoter is silenced by methylation during somatic differentiation in parallel with germ-cell-specific genes. During oocyte growth, Dnmt3L(s) also becomes heavily methylated and silenced and this requires its own gene product, since there is complete loss of methylation and derepression of transcription from this promoter in oocytes derived from Dnmt3L(-/-) mice. Methylation of the Dnmt3L(s) promoter is established prior to the completion of imprinting and explains the requirement in mouse oocytes for the Dnmt3L(o) promoter, located in an intron of the neighboring unmethylated Aire gene. Overall these results give insight into how and why promoter switching at the mouse Dnmt3L locus occurs and provide one of the first examples of a non-imprinted locus where methylation plays a role in promoter choice. The derepression of the Dnmt3L(s) promoter in the knockout oocytes also suggests that other non-imprinted loci may be dysregulated in these cells and contribute to the phenotype of the resultant mice.