Epigenetic Regulation of miR-302 by JMJD1C Inhibits Neural Differentiation of Human Embryonic Stem Cells

It has been recently reported that the regulatory circuitry formed by OCT4, miR-302, and NR2F2 controls both pluripotency and neural differentiation of human embryonic stem cells (hESCs). We show here that JMJD1C, a histone 3 lysine 9 (H3K9) demethylase expressed in hESCs, directly interacts with this circuitry. hESCs with stable knockdown of JMJD1C remain pluripotent while having reduced miR-302 expression, decreased BMP signaling, and enhanced TGFβ signaling. JMJD1C binds to the miR-302 promoter and reduces H3K9 methylation. Withdrawal of basic fibroblast growth factor (bFGF) from the culture induces neural differentiation of the knockdown, but not the control, cells within 3 days, accompanied by elevated NR2F2 expression. This can be attenuated with miR-302 mimics or an H3K9 methytransferase inhibitor. Together, our findings suggest that JMJD1C represses neural differentiation of hESCs at least partially by epigenetically sustaining miR-302 expression and that JMJD1C knockdown is sufficient to trigger neural differentiation upon withdrawal of exogenous bFGF.     

The regulatory role of histone deacetylase inhibitors in Fgf4 expression is dependent on the differentiation state of pluripotent stem cells

The identity of embryonic stem cells (ESCs) is controlled by a set of pluripotency genes, including Oct4, Sox2, Nanog, and Fgf4. How their expression is repressed during differentiation and reactivated during reprogramming is largely unknown. Here, using mouse ESCs as well as F9 and P19 cells (mouse embryonal carcinoma cell lines, P19 being considered further differentiated than F9 cells) as models, we found that HDAC inhibitors elevated Fgf4 expression in P19 cells, but reduced it in F9 cells. We also observed that HDAC inhibitors enhanced the expression of Fgf4 and a subset of pluripotency genes in differentiated ESCs, but reduced their expression in undifferentiated and less differentiated ESCs. Mechanistically, we observed more HDAC1 recruitment and a weaker association of histone 4 lysine 5 acetylation at the Fgf4 enhancer in P19 cells compared to F9 cells. Additionally, we demonstrated the interaction between Sox2 and HDAC1 both in vitro and in vivo, implicating a possible role for Sox2 in the recruitment of HDAC1 to the Fgf4 enhancer. We also found that Nanog bound to the Fgf4 enhancer, and this binding was stronger in F9 cells, indicating the involvement of Nanog in the regulation of Fgf4 expression in undifferentiated and less differentiated pluripotent stem cells. This study uncovers an important role of HDAC1 and histone modifications in the repression of Fgf4 and perhaps other pluripotency genes during ESC differentiation. Our results also suggest that HDAC inhibitors may promote reprogramming partially through activating pluripotency genes at some intermediate stages.     

HDAC1 and HDAC3 underlie dynamic H3K9 acetylation during embryonic neurogenesis and in schizophrenia‐like animals

Although histone acetylation is one of the most widely studied epigenetic modifications, there is still a lack of information regarding how the acetylome is regulated during brain development and pathophysiological processes. We demonstrate that the embryonic brain (E15) is characterized by an increase in H3K9 acetylation as well as decreases in the levels of HDAC1 and HDAC3. Moreover, experimental induction of H3K9 hyperacetylation led to the overexpression of NCAM in the embryonic cortex and depletion of Sox2 in the subventricular ependyma, which mimicked the differentiation processes. Inducing differentiation in HDAC1‐deficient mouse ESCs resulted in early H3K9 deacetylation, Sox2 downregulation, and enhanced astrogliogenesis, whereas neuro‐differentiation was almost suppressed. Neuro‐differentiation of (wt) ESCs was characterized by H3K9 hyperacetylation that was associated with HDAC1 and HDAC3 depletion. Conversely, the hippocampi of schizophrenia‐like animals showed H3K9 deacetylation that was regulated by an increase in both HDAC1 and HDAC3. The hippocampi of schizophrenia‐like brains that were treated with the cannabinoid receptor‐1 inverse antagonist AM251 expressed H3K9ac at the level observed in normal brains. Together, the results indicate that co‐regulation of H3K9ac by HDAC1 and HDAC3 is important to both embryonic brain development and neuro‐differentiation as well as the pathophysiology of a schizophrenia‐like phenotype.     

Histone h1 depletion impairs embryonic stem cell differentiation

Pluripotent embryonic stem cells (ESCs) are known to possess a relatively open chromatin structure; yet, despite efforts to characterize the chromatin signatures of ESCs, the role of chromatin compaction in stem cell fate and function remains elusive. Linker histone H1 is important for higher-order chromatin folding and is essential for mammalian embryogenesis. To investigate the role of H1 and chromatin compaction in stem cell pluripotency and differentiation, we examine the differentiation of embryonic stem cells that are depleted of multiple H1 subtypes. H1c/H1d/H1e triple null ESCs are more resistant to spontaneous differentiation in adherent monolayer culture upon removal of leukemia inhibitory factor. Similarly, the majority of the triple-H1 null embryoid bodies (EBs) lack morphological structures representing the three germ layers and retain gene expression signatures characteristic of undifferentiated ESCs. Furthermore, upon neural differentiation of EBs, triple-H1 null cell cultures are deficient in neurite outgrowth and lack efficient activation of neural markers. Finally, we discover that triple-H1 null embryos and EBs fail to fully repress the expression of the pluripotency genes in comparison with wild-type controls and that H1 depletion impairs DNA methylation and changes of histone marks at promoter regions necessary for efficiently silencing pluripotency gene Oct4 during stem cell differentiation and embryogenesis. In summary, we demonstrate that H1 plays a critical role in pluripotent stem cell differentiation, and our results suggest that H1 and chromatin compaction may mediate pluripotent stem cell differentiation through epigenetic repression of the pluripotency genes.     

Histone deacetylase 9 deficiency protects against effector T cell-mediated systemic autoimmunity

Co-repressor histone deacetylase 9 (HDAC9) plays a key role in the development and differentiation of many types of cells, including regulatory T cells. However, the biological function of HDAC9 in T effector cells is unknown. Systemic autoimmune diseases like lupus, diabetes, and rheumatoid arthritis have dysfunctional effector T cells. To determine the role of HDAC9 in systemic autoimmunity, we created MRL/lpr mice with HDAC9 deficiency that have aberrant effector T cell function. HDAC9 deficiency led to decreased lympho-proliferation, inflammation, autoantibody production, and increased survival in MRL/lpr mice. HDAC9-deficient mice manifested Th2 polarization, decreased T effector follicular cells positive for inducible co-stimulator, and activated T cells in vivo compared with HDAC9-intact MRL/lpr mice. HDAC9 deficiency also resulted in increased GATA3 and roquin and decreased BCL6 gene expression. HDAC9 deficiency was associated with increased site-specific lysine histone acetylation at H3 (H3K9, H3K14, and H3K18) globally that was localized to IL-4, roquin, and peroxisome proliferator-activated receptor-γ promoters with increased gene expression, respectively. In kidney and spleen, HDAC9 deficiency decreased inflammation and cytokine and chemokine production due to peroxisome proliferator-activated receptor γ overexpression. These findings suggest that HDAC9 acts as an epigenetic switch in effector T cell-mediated systemic autoimmunity.     

A Combined Epigenetic and Non-Genetic Approach for Reprogramming Human Somatic Cells

Reprogramming of somatic cells to different extents has been reported using different methods. However, this is normally accompanied by the use of exogenous materials, and the overall reprogramming efficiency has been low. Chemicals and small molecules have been used to improve the reprogramming process during somatic cell nuclear transfer (SCNT) and induced pluripotent stem (iPS) cell generation. We report here the first application of a combined epigenetic and non-genetic approach for reprogramming somatic cells, i.e., DNA methyltransferase (DNMT) and histone deacetylase (HDAC) inhibitors, and human embryonic stem cell (hESC) extracts. When somatic cells were pretreated with these inhibitors before exposure to hESC (MEL1) extracts, morphological analysis revealed a higher rate of hESC-like colony formation than without pretreatment. Quantitative PCR (qPCR) demonstrated that pluripotency genes were upregulated when compared to those of somatic cells or treated with hESC extracts alone. Overall changes in methylation and acetylation levels of pretreated somatic cells suggests that epigenetic states of the cells have an effect on reprogramming efficiency induced by hESC extracts. KnockOutserum replacement (KOSR™) medium (KO-SR) played a positive role in inducing expression of the pluripotency genes. hESC extracts could be an alternative approach to reprogram somatic cells without introducing exogenous materials. The epigenetic pre-treatment of somatic cells could be used to improve the efficiency of reprogramming process. Under differentiation conditions, the reprogrammed cells exhibited differentiation ability into neurons suggesting that, although fully reprogramming was not achieved, the cells could be transdifferentiated after reprogramming.     

Genome-Wide Studies Reveal that H3K4me3 Modification in Bivalent Genes Is Dynamically Regulated during the Pluripotent Cell Cycle and Stabilized upon Differentiation

Stem cell phenotypes are reflected by posttranslational histone modifications, and this chromatin-related memory must be mitotically inherited to maintain cell identity through proliferative expansion. In human embryonic stem cells (hESCs), bivalent genes with both activating (H3K4me3) and repressive (H3K27me3) histone modifications are essential to sustain pluripotency. Yet, the molecular mechanisms by which this epigenetic landscape is transferred to progeny cells remain to be established. By mapping genomic enrichment of H3K4me3/H3K27me3 in pure populations of hESCs in G₂, mitotic, and G₁ phases of the cell cycle, we found striking variations in the levels of H3K4me3 through the G₂-M-G₁ transition. Analysis of a representative set of bivalent genes revealed that chromatin modifiers involved in H3K4 methylation/demethylation are recruited to bivalent gene promoters in a cell cycle-dependent fashion. Interestingly, bivalent genes enriched with H3K4me3 exclusively during mitosis undergo the strongest upregulation after induction of differentiation. Furthermore, the histone modification signature of genes that remain bivalent in differentiated cells resolves into a cell cycle-independent pattern after lineage commitment. These results establish a new dimension of chromatin regulation important in the maintenance of pluripotency.     

Histone variants as emerging regulators of embryonic stem cell identity

Dynamic regulation of chromatin structure is an important mechanism for balancing the pluripotency and cell fate decision in embryonic stem cells (ESCs). Indeed ESCs are characterized by unusual chromatin packaging, and a wide variety of chromatin regulators have been implicated in control of pluripotency and differentiation. Genome-wide maps of epigenetic factors have revealed a unique epigenetic signature in pluripotent ESCs and have contributed models to explain their plasticity. In addition to the well known epigenetic regulation through DNA methylation, histone posttranslational modifications, chromatin remodeling, and non-coding RNA, histone variants are emerging as important regulators of ESC identity. In this review, we summarize and discuss the recent progress that has highlighted the central role of histone variants in ESC pluripotency and ESC fate, focusing, in particular, on H1 variants, H2A variants H2A.X, H2A.Z and macroH2A and H3 variant H3.3.     

Macro Histone Variants Are Critical for the Differentiation of Human Pluripotent Cells

We have previously shown that macro histone variants (macroH2A) are expressed at low levels in stem cells and are up-regulated during differentiation. Here we show that the knockdown of macro histone variants impaired the in vitro and in vivo differentiation of human pluripotent cells, likely through defects in the silencing of pluripotency-related genes. ChIP experiments showed that during differentiation macro histone variants are recruited to the regulatory regions of pluripotency and developmental genes marked with H3K27me3 contributing to the silencing of these genes.     

Coordinated expression of p300 and HDAC3 upregulates histone acetylation during dentinogenesis

Cellular differentiation is caused by highly controlled modifications in the gene expression but rarely involves a change in the DNA sequence itself. Histone acetylation is a major epigenetic factor that adds an acetyl group to histone proteins, thus altering their interaction with DNA and nuclear proteins. Illumination of the histone acetylation during dentinogenesis is important for odontoblast differentiation and dentinogenesis. In the current study, we aimed to discover the roles and regulation of acetylation at histone 3 lysine 9 (H3K9ac) and H3K27ac during dentinogenesis. We first found that both of these modifications were enhanced during odontoblast differentiation and dentinogenesis. These modifications are dynamically catalyzed by histone acetyltransferases (HATs) and deacetylases (HDACs), among which HDAC3 was decreased while p300 increased during odontoblast differentiation. Moreover, overexpression of HDAC3 or knockdown p300 inhibited odontoblast differentiation in vitro, and inhibition of HDAC3 and p300 with trichostatin A or C646 regulated odontoblast differentiation. Taken together, the results of our present study suggest that histone acetylation is involved in dentinogenesis and coordinated expression of p300- and HDAC3-regulated odontoblast differentiation through upregulating histone acetylation.