Genome-Wide Mapping of Bivalent Histone Modifications in Hepatic Stem/Progenitor Cells

Expression and significance of histone methyltransferase SET domain containing 2 with histone H3 lysine 36 trimethylation in mouse hepatic oval cells differentiated into bile duct epithelial cells in vitro

The present study aimed to identify the function and expression of trimethylated protein histone H3 lysine 36 (H3K36)me3 and the upstream specific enzyme histone methyltransferase SET domain containing 2 (SETD2), during the differentiation of hepatic oval cells (HOCs) into cholangiocytes in mice following partial liver resection and fed with 2‑acetamidofluorene. HOCs were isolated from Kunming male mice fed with 2‑acetamidofluorene for 10 days. Their liver tissues were then isolated following partial liver resection and another week of 2‑acetamidofluorene treatment. HOCs were collected following a two‑step enzyme digestion procedure involving protease E and collagenase 4. The target cells were cultured in DMEM/F12 supplemented with 10 µg/ml EGF, 5 µg/ml stem cell growth factor and 5 µg/ml leukemia inhibitory factor. Target cells using the markers OV‑6, CK‑19, SETD2, H3K36me3, were detected with flow cytometry and immunofluorescence microscopy; reverse transcription‑quantitative PCR and western blotting were used to quantify the protein levels of SETD2 and H3K36me3. The retrieved primary hepatocytes developed into cholangiocytes with increasing CK‑19 and decreasing OV‑6 expression in each subsequent passage, whereas the SETD2 and H3K36me3 levels gradually increased, suggesting the possible involvement of both of these factors in differentiation.

P14AS upregulates gene expression in the CDKN2A/2B locus through competitive binding to PcG protein CBX7

Background: It is well known that P16 ^INK4A , P14 ^ARF , P15 ^INK4B mRNAs, and ANRIL lncRNA are transcribed from the CDKN2A/2B locus. LncRNA P14AS is a lncRNA transcribed from antisense strand of P14 ^ARF promoter to intron-1. Our previous study showed that P14AS could upregulate the expression level of ANRIL and P16 ^INK4A and promote the proliferation of cancer cells. Because polycomb group protein CBX7 could repress P16 ^INK4A expression and bind ANRIL, we wonder whether the P14AS-upregulated ANRIL and P16 ^INK4A expression is mediated with CBX7. Results: In this study, we found that the upregulation of P16 ^INK4A , P14 ^ARF , P15 ^INK4B and ANRIL expression was induced by P14AS overexpression only in HEK293T and HCT116 cells with active endogenous CBX7 expression, but not in MGC803 and HepG2 cells with weak CBX7 expression. Further studies showed that the stable shRNA-knockdown of CBX7 expression abolished the P14AS-induced upregulation of these P14AS target genes in HEK293T and HCT116 cells whereas enforced CBX7 overexpression enabled P14AS to upregulate expression of these target genes in MGC803 and HepG2 cells. Moreover, a significant association between the expression levels of P14AS and its target genes were observed only in human colon cancer tissue samples with high level of CBX7 expression (n = 38, p < 0.05), but not in samples (n = 37) with low level of CBX7 expression, nor in paired surgical margin tissues. In addition, the results of RNA immunoprecipitation (RIP)- and chromatin immunoprecipitation (ChIP)-PCR analyses revealed that lncRNA P14AS could competitively bind to CBX7 protein which prevented the bindings of CBX7 to both lncRNA ANRIL and the promoters of P16 ^INK4A , P14 ^ARF and P15 ^INK4B genes. The amounts of repressive histone modification H3K9m3 was also significantly decreased at the promoters of these genes by P14AS in CBX7 actively expressing cells. Conclusions: CBX7 expression is essential for P14AS to upregulate the expression of P16 ^INK4A , P14 ^ARF , P15 ^INK4B and ANRIL genes in the CDKN2A/2Blocus. P14AS may upregulate these genes' expression through competitively blocking CBX7-binding to ANRIL lncRNA and target gene promoters.

Bivalent Regulation and Related Mechanisms of H3K4/27/9me3 in Stem Cells

The "bivalent domain" is a unique histone modification region consisting of two histone tri-methylation modifications. Over the years, it has been revealed that the maintenance and dynamic changes of the bivalent domains play a vital regulatory role in the differentiation of various stem cell systems, as well as in other cells, such as immunomodulation. Tri-methylation modifications involved in the formation of the bivalent domains are interrelated and mutually regulated, thus regulating many life processes of cells. Tri-methylation of histone H3 at lysine 4 (H3K4me3), tri-methylation of histone H3 at lysine 9 (H3K9me3) and tri-methylation of histone H3 at lysine 27 (H3K27me3) are the main tri-methylation modifications involved in the formation of bivalent domains. The three form different bivalent domains in pairs. Furthermore, it is equally clear that H3K4me3 is a positive regulator of transcription and that H3K9me3/H3K27me3 are negative regulators. Enzymes related to the regulation of histone methylation play a significant role in the "homeostasis" and "breaking homeostasis" of the bivalent domains. Bivalent domains regulate target genes, upstream transcription, downstream targeting regulation and related cytokines during the establishment and breakdown of homeostasis, and exert the specific regulation of stem cells. Indeed, a unified mechanism to explain the bivalent modification in all stem cells has been difficult to define, and whether the bivalent modification is antagonistic in inducing the differentiation of homologous stem cells is controversial. In this review, we focus on the different bivalent modifications in several key stem cells and explore the main mechanisms and effects of these modifications involved. Finally, we discussed the close relationship between bivalent domains and immune cells, and put forward the prospect of the application of bivalent domains in the field of stem cells.

ASH2L drives proliferation and sensitivity to bleomycin and other genotoxins in Hodgkin's lymphoma and testicular cancer cells

It is of clinical importance to identify biomarkers predicting the efficacy of DNA damaging drugs (genotoxins) so that nonresponders are not unduly exposed to the deleterious effects of otherwise inefficient drugs. Here, we initially focused on the bleomycin genotoxin because of the limited information about the genes implicated in the sensitivity or resistance to this compound. Using a whole-genome CRISPR/Cas9 gene knockout approach, we identified ASH2L, a core component of the H3K4 methyl transferase complex, as a protein required for bleomycin sensitivity in L1236 Hodgkin lymphoma. Knocking down ASH2L in these cells and in the NT2D1 testicular cancer cell line rendered them resistant to bleomycin, etoposide, and cisplatin but did not affect their sensitivity toward ATM or ATR inhibitors. ASH2L knockdown decreased cell proliferation and facilitated DNA repair via homologous recombination and nonhomologous end-joining mechanisms. Data from the Tumor Cancer Genome Atlas indicate that patients with testicular cancer carrying alterations in the ASH2L gene are more likely to relapse than patients with unaltered ASH2L genes. The cell models we have used are derived from cancers currently treated either partially (Hodgkin’s lymphoma), or entirely (testicular cancer) with genotoxins. For such cancers, ASH2L levels could be used as a biomarker to predict the response to genotoxins. In situations where tumors are expressing low levels of ASH2L, which may allow them to resist genotoxic treatment, the use of ATR or ATM inhibitors may be more efficacious as our data indicate that ASH2L knockdown does not affect sensitivity to these inhibitors.