Early-life physical activity reverses metabolic and Foxo1 epigenetic misregulation induced by gestational sleep disturbance.

Sleep disorders are highly prevalent during late pregnancy and can impose adverse effects, such as preeclampsia and diabetes. However, the consequences of sleep fragmentation (SF) on offspring metabolism and epigenomic signatures are unclear. We report that physical activity during early life, but not later, reversed the increased body weight, altered glucose and lipid homeostasis, and increased visceral adipose tissue in offspring of mice subjected to gestational SF (SFo).

Metabolic dysfunction drives a mechanistically distinct proinflammatory phenotype in adipose tissue macrophages.

Adipose tissue macrophage (ATM)-driven inflammation plays a key role in insulin resistance; however, factors activating ATMs are poorly understood. Using a proteomics approach, we show that markers of classical activation are absent on ATMs from obese humans but are readily detectable on airway macrophages of patients with cystic fibrosis, a disease associated with chronic bacterial infection. Moreover, treating macrophages with glucose, insulin, and palmitate-conditions characteristic of the metabolic syndrome-produces a "metabolically activated" phenotype distinct from classical activation.

Sleep fragmentation during late gestation induces metabolic perturbations and epigenetic changes in adiponectin gene expression in male adult offspring mice.

Sleep fragmentation (SF) is a common condition among pregnant women, particularly during late gestation. Gestational perturbations promote the emergence of adiposity and metabolic disease risk in offspring, most likely through epigenetic modifications. Adiponectin (AdipoQ) expression inversely correlates with obesity and insulin resistance.

The human insulin gene is part of a large open chromatin domain specific for human islets.

Knowledge of how insulin (INS) gene expression is regulated will lead to better understanding of normal and abnormal pancreatic beta cell function. We have mapped histone modifications over the INS region, coupled with an expression profile, in freshly isolated islets from multiple human donors. Unlike many other human genes, in which active modifications tend to be concentrated within 1 kb around the transcription start site, these marks are distributed over the entire coding region of INS as well.

The human insulin gene displays transcriptionally active epigenetic marks in islet-derived mesenchymal precursor cells in the absence of insulin expression.

Human islet-derived precursor cells (hIPCs), mesenchymal cells derived in vitro from adult pancreas, proliferate freely and do not express insulin but can be differentiated to epithelial cells that express insulin. hIPCs have been studied with the goal of obtaining large quantities of insulin-producing cells suitable for transplantation into patients suffering from type 1 diabetes. It appeared that undifferentiated hIPCs are "committed" to a pancreatic endocrine phenotype through multiple cell divisions, suggesting that epigenetic modifications at the insulin locus could be responsible.

Silencing of transgene transcription precedes methylation of promoter DNA and histone H3 lysine 9.

Transgenes stably integrated into cells or animals in many cases are silenced rapidly, probably under the influence of surrounding endogenous condensed chromatin. This gene silencing correlates with repressed chromatin structure marked by histone hypoacetylation, loss of methylation at H3 lysine 4, increase of histone H3 lysine 9 methylation as well as CpG DNA methylation at the promoter. However, the order and the timing of these modifications and their impact on transcription inactivation are less well understood.

The insulation of genes from external enhancers and silencing chromatin.

Insulators are DNA sequence elements that can serve in some cases as barriers to protect a gene against the encroachment of adjacent inactive condensed chromatin. Some insulators also can act as blocking elements to protect against the activating influence of distal enhancers associated with other genes. Although most of the insulators identified so far derive from Drosophila, they also are found in vertebrates.

The barrier function of an insulator couples high histone acetylation levels with specific protection of promoter DNA from methylation.

Stably integrated transgenes flanked by the chicken beta-globin HS4 insulator are protected against chromosomal position effects and gradual extinction of expression during long-term propagation in culture. To investigate the mechanism of action of this insulator, we used bisulfite genomic sequencing to examine the methylation of individual CpG sites within insulated transgenes, and compared this with patterns of histone acetylation. Surprisingly, although the histones of the entire insulated transgene are highly acetylated, only a specific region in the promoter, containing binding sites for erythroid-specific transcription factors, is highly protected from DNA methylation.

Preferential interaction of the core histone tail domains with linker DNA.

Within chromatin, the core histone tail domains play critical roles in regulating the structure and accessibility of nucleosomal DNA within the chromatin fiber. Thus, many nuclear processes are facilitated by concomitant posttranslational modification of these domains. However, elucidation of the mechanisms by which the tails mediate such processes awaits definition of tail interactions within chromatin.

Control of the histone-acetyltransferase activity of Tip60 by the HIV-1 transactivator protein, Tat.

Tip60, a cellular histone-acetyltransferase, is known to interact with the HIV-1-encoded transactivator protein, Tat. In this work, we show that the interaction of Tat with Tip60 efficiently inhibits the Tip60 histone-acetyltransferase activity. Besides its histone-acetyltransferase activity, Tip60 can undergo an autoacetylation which is not affected by Tat interaction.

Persistent interactions of core histone tails with nucleosomal DNA following acetylation and transcription factor binding.

In this study, we examined the effect of acetylation of the NH2 tails of core histones on their binding to nucleosomal DNA in the absence or presence of bound transcription factors. To do this, we used a novel UV laser-induced protein-DNA cross-linking technique, combined with immunochemical and molecular biology approaches. Nucleosomes containing one or five GAL4 binding sites were reconstituted with hypoacetylated or hyperacetylated core histones.

A preparative method for crosslinking proteins to DNA in nuclei by single-pulse UV laser irradiation.

Photocrosslinking of proteins to DNA by single-pulse UV laser has been used only in analytical experiments, carried out with reconstituted complexes of a single DNA binding protein and a labeled target sequence. Here we propose a large-scale technique for irradiation of nuclei, generating preparative quantities of covalently linked protein-DNA complexes for further analysis of the partner molecules. The use of a flow cuvette allows a milligram of DNA in either nuclei or chromatin to be irradiated by a single pulse within few minutes.

Histones associated with non-nucleosomal rat ribosomal genes are acetylated while those bound to nucleosome-organized gene copies are not.

Acetylation of histones bound to rat rRNA genes has been studied relative to their organization in chromatin, either as canonical nucleosomes, containing the inactive copies, or as anucleosomal nonrepeating structures, corresponding to the transcribed genes (Conconi, A., Widmer, R. M.