Integrating role of T antigen,Rb2/p130, CTCF and BORIS in mediating non-canonical endoplasmic reticulum-dependent death pathways triggered by chronic ER stress in mouse medulloblastoma

Distinct molecular pathways could be constitutively active in mouse T-Antigen positive and T-Antigen negative medulloblastoma cell lines, contributing to their phenotypic differences as well as to cellular responses, cell cycle progression, cell death and survival. The diversity of these responses may be due, at least in part, to distinct activities of Rb2/p130, CTCF and BORIS proteins in response to an altered network of signaling evoked by the T-Ag presence. Here, we provided evidence supporting a role for the T-Antigen in causing chronic endoplasmic reticulum (ER) stress and aberrant Caspase-12 expression and activation, subsequently driving to both massive cell death, and perhaps selection of cells with a higher malignant phenotype. Furthermore, we observed that the endoplasmic stress, either chronically caused by T-Ag or transiently induced by glucose deprivation, is accompanied by the formation of complexes between the retinoblastoma related protein Rb2/p130 and the chromatin insulator CCCTC-binding factor CTCF, or the CTCF-paralogue BORIS. Our study represents the first evidence supporting a role of the T-Antigen in inducing/maintaining chronic ER-stress, as well as, indicating a role of Rb2/p130, CTCF and BORIS as potential mediators of non-canonical ER-dependent death pathway in mouse medulloblastoma.     

Coordinate Regulation of the Gel-forming Mucin Genes at Chromosome 11p15.5

Four of the genes that encode gel-forming mucins, which are major components of the mucus layer protecting many epithelial surfaces, are clustered at chromosome 11p15.5 and show both cell- and tissue-specific expression patterns. We aimed to determine whether the individual genes were coordinately regulated by mechanisms involving higher order chromatin structure. CCCTC-binding factor (CTCF) sites were predicted in silico and CTCF occupancy then evaluated by chromatin immunoprecipitation. CTCF was found at many sites across the gene cluster, and its binding was correlated with mucin gene expression. Next, siRNA-mediated depletion of CTCF was shown to increase MUC2 expression in A549 lung carcinoma cells and both MUC6 and MUC5AC expression in LS180 colon carcinoma cells. These changes correlated with loss of CTCF binding at multiple sites, although others retained occupancy. In cells actively expressing the mucins, the gene cluster was shown by chromosome conformation capture to form looped three-dimensional structures with direct interactions between the MUC2 promoter region, regions 30 kb 5′ to it, close to the MUC6 promoter and others near the 3′ end of MUC5AC, >170 kb away. Finally, to demonstrate the importance of CTCF binding to mucin gene expression, Calu-3 lung carcinoma cells were exposed to lipopolysaccharide (LPS). LPS increased the expression of MUC2 and MUC5AC and reduced MUC5B. CTCF occupancy was concurrently depleted at specific binding sites close to these genes. These data suggest that CTCF binding and cell type-specific long-range interactions across the 11p15.5 gene cluster are critical mechanisms for coordinating gel-forming mucin gene expression.     

Poly(ADP-ribosyl)ation associated changes in CTCF-chromatin binding and gene expression in breast cells

CTCF is an evolutionarily conserved and ubiquitously expressed architectural protein regulating a plethora of cellular functions via different molecular mechanisms. CTCF can undergo a number of post-translational modifications which change its properties and functions. One such modifications linked to cancer is poly(ADP-ribosyl)ation (PARylation). The highly PARylated CTCF form has an apparent molecular mass of 180?kDa (referred to as CTCF180), which can be distinguished from hypo- and non-PARylated CTCF with the apparent molecular mass of 130?kDa (referred to as CTCF130). The existing data accumulated so far have been mainly related to CTCF130. However, the properties of CTCF180 are not well understood despite its abundance in a number of primary tissues. In this study we performed ChIP-seq and RNA-seq analyses in human breast cells 226LDM, which display predominantly CTCF130 when proliferating, but CTCF180 upon cell cycle arrest. We observed that in the arrested cells the majority of sites lost CTCF, whereas fewer sites gained CTCF or remain bound (i.e. common sites). The classical CTCF binding motif was found in the lost and common, but not in the gained sites. The changes in CTCF occupancies in the lost and common sites were associated with increased chromatin densities and altered expression from the neighboring genes. Based on these results we propose a model integrating the CTCF130/180 transition with CTCF-DNA binding and gene expression changes. This study also issues an important cautionary note concerning the design and interpretation of any experiments using cells and tissues where CTCF180 may be present.     

BAT3 and SET1A form a complex with CTCFL/BORIS to modulate H3K4 histone dimethylation and gene expression

Chromatin status is characterized in part by covalent posttranslational modifications of histones that regulate chromatin dynamics and direct gene expression. BORIS (brother of the regulator of imprinted sites) is an insulator DNA-binding protein that is thought to play a role in chromatin organization and gene expression. BORIS is a cancer-germ line gene; these are genes normally present in male germ cells (testis) that are also expressed in cancer cell lines as well as primary tumors. This work identifies SET1A, an H3K4 methyltransferase, and BAT3, a cochaperone recruiter, as binding partners for BORIS, and these proteins bind to the upstream promoter regions of two well-characterized procarcinogenic genes, Myc and BRCA1. RNA interference (RNAi) knockdown of BAT3, as well as SET1A, decreased Myc and BRCA1 gene expression but did not affect the binding properties of BORIS, but RNAi knockdown of BORIS prevented the assembly of BAT3 and SET1A at the Myc and BRCA1 promoters. Finally, chromatin analysis suggested that BORIS and BAT3 exert their effects on gene expression by recruiting proteins such as SET1A that are linked to changes in H3K4 dimethylation. Thus, we propose that BORIS acts as a platform upon which BAT3 and SET1A assemble and exert effects upon chromatin structure and gene expression.     

BORIS-mediated generation of circular RNAs induces inflammation

Circular RNAs (circRNAs), which are more stable than linear mRNAs and long non-coding RNAs (LncRNAs), are detected in body fluids such as plasma, serum, and exosomes. Disease-associated circRNAs have significant clinical roles due to their diagnostic and prognostic values. Brother of regulator of imprinting site (BORIS) promotes cancer progression and is specifically highly expressed in the majority of carcinoma. However, the mechanism underlying the regulation of circRNAs by the oncoprotein BORIS and their role in regulating inflammation and immunity remain to be further explored. Vaccines prepared from circRNAs extracted from cancer cells showed that circRNAs induced inflammation and prevented cancer progression. Serum from animals injected with cancer cell-derived circRNAs vigorously reacted with cells that expressed cancer-specific antigen BORIS or cancer extracted circRNAs. It has been implicated that cancer-related circRNAs could be used as antigens to activate immune responses to prevent cancers and stimulate NF-κB signaling pathway by up-regulating and inducing TLR3. In the study we also found that BORIS regulated the expression of circRNAs and interacted with RNA motifs and the CCCTC binding factor (CTCF) motif adjacent to circRNA splicing sites to enhance the formation of circRNAs. Thus, our study delineated the novel mechanism by which cancer-specific antigen BORIS regulated circRNAs and identified that circRNAs could serve as a vaccine for cancer prevention.