Active and Repressed Chromatin Domains Exhibit Distinct Nucleosome Segregation during DNA Replication.

Chromatin domains and their associated structures must be faithfully inherited through cellular division to maintain cellular identity. However, accessing the localized strategies preserving chromatin domain inheritance, specifically the transfer of parental, pre-existing nucleosomes with their associated post-translational modifications (PTMs) during DNA replication, is challenging in living cells. We devised an inducible, proximity-dependent labeling system to irreversibly mark replication-dependent H3.1 and H3.2 histone-containing nucleosomes at desired loci in mouse embryonic stem cells so that their fate after DNA replication could be followed. Strikingly, repressed chromatin domains are preserved through local re-deposition of parental nucleosomes. In contrast, nucleosomes decorating active chromatin domains do not exhibit such preservation. Notably, altering cell fate leads to an adjustment of the positional inheritance of parental nucleosomes that reflects the corresponding changes in chromatin structure. These findings point to important mechanisms that contribute to parental nucleosome segregation to preserve cellular identity.

Increased incidence of non-alcoholic fatty liver disease in male rat offspring exposed to fluoxetine during fetal and neonatal life involves the NLRP3 inflammasome and augmented de novo hepatic lipogenesis.

Up to 10% of women take selective serotonin reuptake inhibitors (SSRI) during pregnancy. Children exposed to SSRIs in utero have an increased risk of being overweight suggesting that fetal exposure to SSRIs can cause permanent metabolic changes. We have previously shown in rats that fetal and neonatal exposure to the SSRI antidepressant fluoxetine results in metabolic perturbations including increased hepatic triglyceride content; a hallmark of non-alcoholic fatty liver disease (NAFLD). Therefore, the aim of this study was to identify the mechanism(s) underlying the fluoxetine-induced increase in intrahepatic triglyceride content. Female nulliparous Wistar rats were given vehicle or fluoxetine (10 mg/kg/day) orally for 2 weeks prior to mating until weaning. At 6 months of age, we assessed whether SSRI exposure altered components of the hepatic triglyceride biosynthesis pathway in the offspring and examined the molecular mechanisms underlying these changes. Male SSRI-exposed offspring had a significant increase in the steady-state mRNA levels of Elovl6 and Dgat1 and core components of the NLRP3 inflammasome (apoptosis-associated speck-like protein containing a caspase activation recruitment domain [ASC] and caspase-1). Augmented expression of Asc in the SSRI-exposed offspring coincided with increased histone acetylation in the proximal promoter region. Given that we have previously demonstrated that antenatal exposure to SSRIs can lead to fatty liver in the offspring, this raises concerns regarding the long-term metabolic sequelae of fetal SSRI exposure. Moreover, this study suggests that elevated hepatic triglyceride levels observed in the SSRI-exposed offspring may be due, in part, to activation of the NLRP3 inflammasome and augmentation of de novo lipogenesis.

Targeting 'histone mark': Advanced approaches in epigenetic regulation of telomere dynamics in cancer.

Telomere integrity is required for the maintenance of genome stability and prevention of oncogenic transformation of cells. Recent evidence suggests the presence of epigenetic modifications as an important regulator of mammalian telomeres. Telomeric and subtelomeric regions are rich in epigenetic marks that regulate telomere length majorly through DNA methylation and post-translational histone modifications. Specific histone modifying enzymes play an integral role in establishing telomeric histone codes necessary for the maintenance of structural integrity. Alterations of crucial histone moieties and histone modifiers cause deregulations in the telomeric chromatin leading to carcinogenic manifestations. This review delves into the significance of histone modifications and their influence on telomere dynamics concerning cancer. Additionally, it highlights the existing research gaps that hold the potential to drive the development of therapeutic interventions targeting the telomere epigenome.

Supplementation of l-arginine in pregnant gilts affects the protein abundance of DNMT1 in 35-day fetuses.

Maternal nutrition is one of the main environmental factors regulating gene expression during fetal development through epigenetic modifications. Some nutrients, such as the amino acid l-arginine, are added to maternal diets to modulate gene expression, improve the reproductive performance of females, and enhance conceptus development. This study investigated the hypothesis that supplementation of pregnant gilts with l-arginine regulates gene expression in conceptuses through epigenetic mechanisms. For this, fetal programming phenotypic markers, the expression of key epigenetic genes, and the abundance of DNA methylation proteins (DNMT3A and DNMT1) were evaluated in 25- and 35-day conceptuses from gilts supplemented (ARG) or not (CON) with 1.0 % l-arginine during early gestation. At 25 days, there were no significant differences in phenotypic markers between CON and ARG embryos (P > 0.05). Similarly, no differences were found between CON and ARG fetuses at 35 days (P > 0.05). Maternal supplementation with l-arginine did not influence the expression of the evaluated key epigenetic genes in pig embryos or fetuses, nor DNMT3A protein abundance (P > 0.05); on the other hand, DNMT1 protein abundance was lower in ARG fetuses (P = 0.002). It is concluded that supplementation of l-arginine in pregnant gilts affects epigenetic mechanisms, such as DNA methylation, in 35-day fetuses through regulation of DNMT1 levels. Further studies using transcriptomic and proteomic analysis could reveal additional epigenetic modifications in embryos and fetuses following maternal supplementation with l-arginine.

Genetic Association and Differential RNA Expression of Histone (De)Acetylation-Related Genes in Pemphigus Foliaceus-A Possible Epigenetic Effect in the Autoimmune Response.

Pemphigus foliaceus (PF) is an autoimmune skin blistering disease characterized by antidesmoglein-1 IgG production, with an endemic form (EPF) in Brazil. Genetic and epigenetic factors have been associated with EPF, but its etiology is still not fully understood. To evaluate the genetic association of histone (de)acetylation-related genes with EPF susceptibility, we evaluated 785 polymorphisms from 144 genes, for 227 EPF patients and 194 controls. Carriers of HDAC4_rs4852054*A were more susceptible (OR = 1.79, p = 0.0038), whereas those with GSE1_rs13339618*A (OR = 0.57, p = 0.0011) and homozygotes for PHF21A_rs4756055*A (OR = 0.39, p = 0.0006) were less susceptible to EPF. These variants were not associated with sporadic PF (SPF) in German samples of 75 SPF patients and 150 controls, possibly reflecting differences in SPF and EPF pathophysiology. We further evaluated the expression of histone (de)acetylation-related genes in CD4+ T lymphocytes, using RNAseq. In these cells, we found a higher expression of KAT2B, PHF20, and ZEB2 and lower expression of KAT14 and JAD1 in patients with active EPF without treatment compared to controls from endemic regions. The encoded proteins cause epigenetic modifications related to immune cell differentiation and cell death, possibly affecting the immune response in patients with PF.

Present and future challenges for the investigation of transgenerational epigenetic inheritance.

Epigenetic pathways are essential in different biological processes and in phenotype-environment interactions in response to different stressors and they can induce phenotypic plasticity. They encompass several processes that are mitotically and, in some cases, meiotically heritable, so they can be transferred to subsequent generations via the germline. Transgenerational Epigenetic Inheritance (TEI) describes the phenomenon that phenotypic traits, such as changes in fertility, metabolic function, or behavior, induced by environmental factors (e.g., parental care, pathogens, pollutants, climate change), can be transferred to offspring generations via epigenetic mechanisms. Investigations on TEI contribute to deciphering the role of epigenetic mechanisms in adaptation, adversity, and evolution. However, molecular mechanisms underlying the transmission of epigenetic changes between generations, and the downstream chain of events leading to persistent phenotypic changes, remain unclear. Therefore, inter-, (transmission of information between parental and offspring generation via direct exposure) and transgenerational (transmission of information through several generations with disappearance of the triggering factor) consequences of epigenetic modifications remain major issues in the field of modern biology. In this article, we review and describe the major gaps and issues still encountered in the TEI field: the general challenges faced in epigenetic research; deciphering the key epigenetic mechanisms in inheritance processes; identifying the relevant drivers for TEI and implement a collaborative and multi-disciplinary approach to study TEI. Finally, we provide suggestions on how to overcome these challenges and ultimately be able to identify the specific contribution of epigenetics in transgenerational inheritance and use the correct tools for environmental science investigation and biomarkers identification.

Tunable, division-independent control of gene activation timing by a polycomb switch.

During development, progenitors often differentiate many cell generations after receiving signals. These delays must be robust yet tunable for precise population size control. Polycomb repressive mechanisms, involving histone H3 lysine-27 trimethylation (H3K27me3), restrain the expression of lineage-specifying genes in progenitors and may delay their activation and ensuing differentiation. Here, we elucidate an epigenetic switch controlling the T cell commitment gene Bcl11b that holds its locus in a heritable inactive state for multiple cell generations before activation. Integrating experiments and modeling, we identify a mechanism where H3K27me3 levels at Bcl11b, regulated by methyltransferase and demethylase activities, set the time delay at which the locus switches from a compacted, silent state to an extended, active state. This activation delay robustly spans many cell generations, is tunable by chromatin modifiers and transcription factors, and is independent of cell division. With their regulatory flexibility, such timed epigenetic switches may broadly control timing in development.

Selective transcriptional regulation by Myc: Experimental design and computational analysis of high-throughput sequencing data.

The gene expression programs regulated by the Myc transcription factor were evaluated by integrated genome-wide profiling of Myc binding sites, chromatin marks and RNA expression in several biological models. Our results indicate that Myc directly drives selective transcriptional regulation, which in certain physiological conditions may indirectly lead to RNA amplification. Here, we illustrate in detail the experimental design concerning the high-throughput sequencing data associated with our study (Sabò et al., Nature. (2014) 511:488-492) and the R scripts used for their computational analysis.

Re-print of "Histone extraction protocol from the two model diatoms Phaeodactylum tricornutum and Thalassiosira pseudonana".

Post-translational modifications of histones affect many biological processes by influencing higher order chromatin structure that affects gene and genome regulation. It is therefore important to develop methods for extracting histones while maintaining their native post-translational modifications. While histone extraction protocols have been developed in multicellular and single celled organisms such as yeast and Arabidopsis, they are inefficient in diatoms that have a silica cell wall that is likely to hinder histone extraction. We report in this work a rapid and reliable method for extraction of large amounts of high quality histones from the two model diatoms Phaeodactylum tricornutum and Thalassiosira pseudonana. The protocol is an important enabling step permitting downstream applications such as western blotting and mass spectrometry.

Histone extraction protocol from the two model diatoms Phaeodactylum tricornutum and Thalassiosira pseudonana.

Post-translational modifications of histones affect many biological processes by influencing higher order chromatin structure that affects gene and genome regulation. It is therefore important to develop methods for extracting histones while maintaining their native post-translational modifications. While histone extraction protocols have been developed in multicellular and single celled organisms such as yeast and Arabidopsis, they are inefficient in diatoms that have a silica cell wall that is likely to hinder histone extraction. We report in this work a rapid and reliable method for extraction of large amounts of high quality histones from the two model diatoms Phaeodactylum tricornutum and Thalassiosira pseudonana. The protocol is an important enabling step permitting downstream applications such as western blotting and mass spectrometry.

Epigenetics: the neglected key to minimize learning and memory deficits in Down syndrome.

Down syndrome (DS) is the most common genetic intellectual disability, caused by the triplication of the human chromosome 21 (HSA21). Although this would theoretically lead to a 1.5 fold increase in gene transcription, transcript levels of many genes significantly deviate. Surprisingly, the underlying cause of this gene expression variation has been largely neglected so far. Epigenetic mechanisms, including DNA methylation and post-translational histone modifications, regulate gene expression and as such might play a crucial role in the development of the cognitive deficits in DS. Various overexpressed HSA21 proteins affect epigenetic mechanisms and DS individuals are thus likely to present epigenetic aberrations. Importantly, epigenetic marks are reversible, offering a huge therapeutic potential to alleviate or cure certain genetic deficits. Current epigenetic therapies are already used for cancer and epilepsy, and might provide novel possibilities for cognition-enhancing treatment in DS as well. To that end, this review discusses the still limited knowledge on epigenetics in DS and describes the potential of epigenetic therapies to reverse dysregulated gene expression.

The localization of histone H3K27me3 demethylase Jmjd3 is dynamically regulated.

Jmjd3 is required for cellular differentiation and senescence, and inhibits the induction of pluripotent stem cells by demethylating histone 3 lysine 27 trimethylation (H3K27me3). Although recent studies reveal crucial biological roles for Jmjd3, it is unclear how its demethylase activity is controlled. Here, we show that nuclear localization of Jmjd3 is required for effective demethylation of H3K27me3. Our subcellular localization analysis of Jmjd3 shows that the N-terminal region of the protein is responsible for its nuclear placement, whereas the C-terminal region harboring the catalytic Jumonji C (JmjC) domain cannot situate into the nucleus. We identify two classical nuclear localization signals (cNLSs) in the N-terminal domain of Jmjd3. Forced nuclear emplacement of the catalytic domain of Jmjd3 by fusion with a heterologous cNLS significantly enhances its H3K27me3 demethylation activity. A dynamic nucleocytoplasmic shuttling of endogenous Jmjd3 occurs in mouse embryonic fibroblasts. Jmjd3 is localized both into the cytoplasm and the nucleus, and its nuclear export is dependent on Exportin-1, as treatment with leptomycin B triggers nuclear accumulation of Jmjd3. These results suggest that the subcellular localization of Jmjd3 is dynamically regulated and has pivotal roles for H3K27me3 status.

Radiation-induced alterations in histone modification patterns and their potential impact on short-term radiation effects.

Detection and repair of radiation-induced DNA damage occur in the context of chromatin. An intricate network of mechanisms defines chromatin structure, including DNA methylation, incorporation of histone variants, histone modifications, and chromatin remodeling. In the last years it became clear that the cellular response to radiation-induced DNA damage involves all of these mechanisms. Here we focus on the current knowledge on radiation-induced alterations in post-translational histone modification patterns and their effect on the chromatin accessibility, transcriptional regulation and chromosomal stability.