Kurinji Pandiyan

Cancer-Related Epigenome Changes Associated with Reprogramming to Induced Pluripotent Stem Cells

The ability to induce pluripotent stem cells from committed, somatic human cells provides tremendous potential for regenerative medicine. However, there is a defined neoplastic potential inherent to such reprogramming that must be understood and may provide a model for understanding key events in tumorigenesis. Using genome-wide assays, we identify cancer-related epigenetic abnormalities that arise early during reprogramming and persist in induced pluripotent stem cell (iPS) clones. These include hundreds of abnormal gene silencing events, patterns of aberrant responses to epigenetic-modifying drugs resembling those for cancer cells, and presence in iPS and partially reprogrammed cells of cancer-specific gene promoter DNA methylation alterations. Our findings suggest that by studying the process of induced reprogramming, we may gain significant insight into the origins of epigenetic gene silencing associated with human tumorigenesis, and add to means of assessing iPS for safety.

Functional DNA demethylation is accompanied by chromatin accessibility

DNA methylation inhibitors such as 5-aza-2′-deoxycytidine (5-Aza-CdR) are currently used for the treatment of myelodysplastic syndrome. Although global DNA demethylation has been observed after treatment, it is unclear to what extent demethylation induces changes in nucleosome occupancy, a key determinant of gene expression. We use the colorectal cancer cell line HCT116 as a model to address this question and determine that <2% of regions demethylated by 5-Aza-CdR treatment assume an open configuration. Consolidating our findings, we detect nucleosome retention at sites of global DNA methylation loss in DKO1, an HCT116-derived non-tumorigenic cell-line engineered for DNA methyltransferase disruption. Notably, regions that are open in both HCT116 cells after treatment and in DKO1 cells include promoters belonging to tumor suppressors and genes under-expressed in colorectal cancers. Our results indicate that only a minority of demethylated promoters are associated with nucleosome remodeling, and these could potentially be the epigenetic drivers causing the loss of tumorigenicity. Furthermore, we show that the chromatin opening induced by the histone deacetylase inhibitor suberoylanilide hydroxamic acid has strikingly distinct targets compared with those of 5-Aza-CdR, providing a mechanistic explanation for the importance of combinatorial therapy in eliciting maximal de-repression of the cancer epigenome.

SNF5 Is an Essential Executor of Epigenetic Regulation during Differentiation

Nucleosome occupancy controls the accessibility of the transcription machinery to DNA regulatory regions and serves an instructive role for gene expression. Chromatin remodelers, such as the BAF complexes, are responsible for establishing nucleosome occupancy patterns, which are key to epigenetic regulation along with DNA methylation and histone modifications. Some reports have assessed the roles of the BAF complex subunits and stemness in murine embryonic stem cells. However, the details of the relationships between remodelers and transcription factors in altering chromatin configuration, which ultimately affects gene expression during cell differentiation, remain unclear. Here for the first time we demonstrate that SNF5, a core subunit of the BAF complex, negatively regulates OCT4 levels in pluripotent cells and is essential for cell survival during differentiation. SNF5 is responsible for generating nucleosome-depleted regions (NDRs) at the regulatory sites of OCT4 repressed target genes such as PAX6 and NEUROG1, which are crucial for cell fate determination. Concurrently, SNF5 closes the NDRs at the regulatory regions of OCT4-activated target genes such as OCT4 itself and NANOG. Furthermore, using loss- and gain-of-function experiments followed by extensive genome-wide analyses including gene expression microarrays and ChIP-sequencing, we highlight that SNF5 plays dual roles during differentiation by antagonizing the expression of genes that were either activated or repressed by OCT4, respectively. Together, we demonstrate that SNF5 executes the switch between pluripotency and differentiation.

Identification of DNA Methylation–Independent Epigenetic Events Underlying Clear Cell Renal Cell Carcinoma

Alterations in chromatin accessibility independent of DNA methylation can affect cancer-related gene expression, but are often overlooked in conventional epigenomic profiling approaches. In this study, we describe a cost-effective and computationally simple assay called AcceSssIble to simultaneously interrogate DNA methylation and chromatin accessibility alterations in primary human clear cell renal cell carcinomas (ccRCC). Our study revealed significant perturbations to the ccRCC epigenome and identified gene expression changes that were specifically attributed to the chromatin accessibility status whether or not DNA methylation was involved. Compared with commonly mutated genes in ccRCC, such as the von Hippel-Lindau (VHL) tumor suppressor, the genes identified by AcceSssIble comprised distinct pathways and more frequently underwent epigenetic changes, suggesting that genetic and epigenetic alterations could be independent events in ccRCC. Specifically, we found unique DNA methylation-independent promoter accessibility alterations in pathways mimicking VHL deficiency. Overall, this study provides a novel approach for identifying new epigenetic-based therapeutic targets, previously undetectable by DNA methylation studies alone, that may complement current genetic-based treatment strategies. Cancer Res; 76(7); 1954-64. ©2016 AACR.

Epigenetic landscape change analysis during human EMT sheds light on a key EMT mediator TRIM29

Epithelial to mesenchymal transition (EMT) is a key trans-differentiation process, which plays a critical role in physiology and pathology. Although gene expression changes in EMT have been scrutinized, study of epigenome is in its infancy. To understand epigenetic changes during TWIST-driven EMT, we used the AcceSssIble assay to study DNA methylation and chromatin accessibility in human mammary epithelial cells (HMECs). The DNA methylation changes were found to have functional significance in EMT – i.e. methylated genes were enriched for E-box motifs that can be recognized by TWIST, at the promoters suggesting a potential targeting phenomenon, whereas the demethylated regions were enriched for pro-metastatic genes, supporting the role of EMT in metastasis. TWIST-induced EMT triggers alterations in chromatin accessibility both independent of and dependent on DNA methylation changes, primarily resulting in closed chromatin conformation. By overlapping the genes, whose chromatin structure is changed during early EMT and a known “core EMT signature”, we identified 18 driver candidate genes during EMT, 14 upregulated and 4 downregulated genes with corresponding chromatin structure changes. Among 18 genes, we focused on TRIM29 as a novel marker of EMT. Although loss of TRIM29 is insufficient to suppress CDH, it is enough to induce CDH2 and VIM. Gene functional annotation analysis shows the involvement of TRIM29 in epidermal development, cell differentiation and cell migration. Taken together, our results provide a robust snapshot of chromatin state during human EMT and identify TRIM29 as a core mediator of EMT.

Abstract B03: Identification of epigenetic regulated genes through simultaneous analysis of DNA methylation and chromatin structure in uncultured tumors

The contribution of promoter DNA methylation to the alteration of caner related gene expression has been well studied, however, these genes can also potentially be altered by chromatin accessibility without involvement of DNA methylation and can be epigenetically inherited. In this study, we used an assay developed in our laboratory (AcceSssIble) that can simultaneously interrogate DNA methylation and chromatin accessibility allowing us to investigate the epigenetic changes in uncultured clear cell renal cell carcinoma (ccRCC) tumors and normal tissue to uncover genes that contribute to ccRCC tumorigenesis. AcceSssIble is both cost-effective and easily analyzed using simple and straightforward computational analysis. Our study revealed significant changes to the epigenome of ccRCC, especially identifying epigenetically up- (160) or down-regulated genes (180), which are dependent on accessibility changes with (30%) or without (70%) DNA methylation involvement, and which were validated by a cross-correlation of the identified genes with RNA-seq and DNA methylation data from larger cohorts of ccRCC samples from The Cancer Genome Atlas (TCGA). In addition, our findings also revealed these sets of genes not found to be commonly mutated in ccRCC and undergo epigenetic changes at higher frequencies than common ccRCC mutations. In addition, pathway analysis suggests that genetic and epigenetic alterations are independent events, and one such example includes a set of changes in HIF1α signaling pathway genes that are independent of the Von Hippel-Lindau (VHL) status. This suggests a novel epigenetic basis for HIF1αs role during tumorigenesis that may be a common occurrence in ccRCC. Thus, the AcceSssIble analysis on ccRCC samples revealed novel candidates for epigenetic driver genes which were previously undetectable by widely used methylation studies. Overall, this study provides a novel approach that can help identify new epigenetic therapeutic targets and treatment strategies complementing current approaches based primarily on the genetic makeup of primary tumors. Citation Format: Elinne Becket, Sameer Chopra, Christopher Duymich, Lin J. Justin, Jueng Soo You, Kurinji Pandiyan, Peter W. Nichols, Kimberly D. Siegmund, Peter A. Jones, Gangning Liang. Identification of epigenetic regulated genes through simultaneous analysis of DNA methylation and chromatin structure in uncultured tumors. [abstract]. In: Proceedings of the AACR Special Conference on Chromatin and Epigenetics in Cancer; Sep 24-27, 2015; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2016;76(2 Suppl):Abstract nr B03.

CHAPTER 10:Dosing – When Less is More

Epigenetic mechanisms control the expression of both canonical coding genes and non-coding regulatory RNA species. Such mechanisms include DNA methylation changes at predominantly CpG sites in humans, modification of histone tails, packaging of DNA into nucleosomes, and control of nucleosome positioning or nucleosome remodelling. These steps ultimately impact upon gene expression and therefore cell state definition. It has been established that a variety of epigenetic aberrations seen in cancers can complement genetic abnormalities in tumorigenesis and some are almost certainly driving events for malignant potential. Epigenetic abnormalities are potentially reversible with respect to pharmacological intervention for cancer management. In this chapter we will discuss the evolution of epigenetic therapy over the last approximately 40 years, our current understanding of clinically available agents and future approaches towards drug development, regulatory studies and clinical efficacy assessment.

Abstract A1-05: Elucidation of epigenetic driver genes in clear cell renal cell carcinoma using a newly developed assay, AcceSssIble

Background: While many studies have uncovered genetic mutations that drive tumorigenesis, far fewer have described epigenetic changes, such as nucleosome positioning and DNA methylation, which lead to the development of cancer. Therefore, accurately mapping these changes between normal and tumor tissue will provide novel information to identify genes that undergo epigenetic changes that drive tumorigenesis (“epigenetic driver genes”). In this study, we used an assay developed in our laboratory to investigate the epigenetic changes between clear cell renal cell carcinoma (ccRCC, the most common subtype of renal carcinoma) tumors and normal tissue to uncover genes that contribute to ccRCC tumorigenesis. Methods: Current methods to investigate epigenomic changes in clinical samples are expensive and require abundant biological sample material for analysis. We have developed a novel assay (“Acce SssI ble”) to simultaneously determine DNA methylation and chromatin accessibility in clinical samples. It is rapid and cost-effective, only requiring 20 mg of tissue, the Infinium HumanMethylation450 BeadChip platform, and the CpG methyltransferase M.SssI. We used this method to measure the changes in DNA methylation and chromatin accessibility in 9 matched pairs of ccRCC tumors and adjacent normal tissue from different patients, and intersected this data with RNA-seq data of 72 matched ccRCC samples and DNA methylation data of 160 matched ccRCC samples from The Cancer Genome Atlas (TCGA). Genes that were revealed to have the most changes in chromatin structure and expression were then targeted by siRNA knockdown for functional validation in ccRCC. Results: From the Acce SssI ble assay on 9 pairs of ccRCC patient tumor/normal samples, we uncovered 438 genes whose promoters change in chromatin accessibility in at least 2 ccRCC samples, both dependent and independent of DNA methylation changes, and have an accompanying change in gene expression in TCGA RNA-seq data. The results produce a striking figure in which chromatin accessibility changes are inversely correlated with DNA methylation but directly correlated with gene expression changes. Interestingly, loss of (DNA methylation change-dependent) accessibility preferentially occurred within CpG islands, while gain of (DNA methylation change-dependent) accessibility was strongly biased towards non-CpG islands. Meanwhile, chromatin accessibility changes independent of DNA methylation changes do not show preference in CpG content. Furthermore, pathway analyses reveal involvement of HIF1α signaling, cAMP-mediated signaling, and G-protein Coupled Receptor Signaling in the development of ccRCC. Lastly, we performed siRNA knockdown experiments on several top genes most changing in expression and accessibility, which revealed two genes, encoding type IV collagen and an RNA-binding protein, whose knockdown resulted in a significant increase in proliferation in normal kidney epithelial cells. Conclusions: Our study revealed a vast number of chromatin accessibility and accompanying gene expression changes that occur in gene promoters in the development of ccRCC, both dependent and independent of DNA methylation changes. Each individual tumor has a unique profile of epigenetic alterations. Moreover, almost none of the genes that were found to undergo epigenetic and resulting gene expression changes overlap with TCGA9s findings of commonly mutated genes in ccRCC. Overall, these studies represent novel approaches that can help identify new therapeutic target genes and treatment strategies for ccRCC, including personalized approaches. Citation Format: Elinne Coral Becket, Christopher Duymich, Yin-Wei Chang, Kurinji Pandiyan, Peter Nichols, Peter Jones, Inderbir Gill, Gangning Liang. Elucidation of epigenetic driver genes in clear cell renal cell carcinoma using a newly developed assay, AcceSssIble. [abstract]. In: Proceedings of the AACR Special Conference on Translation of the Cancer Genome; Feb 7-9, 2015; San Francisco, CA. Philadelphia (PA): AACR; Cancer Res 2015;75(22 Suppl 1):Abstract nr A1-05.

Abstract LB-130: Simultaneous evaluation of chromatin accessibility and DNA methylation in clear cell renal cell carcinoma by a newly developed assay, AcceSssIble

Proceedings: AACR Annual Meeting 2014; April 5-9, 2014; San Diego, CA Background: Epigenetic changes, such as nucleosome positioning and DNA methylation, control gene expression and are altered in cancer. Therefore, accurately mapping these changes between normal and tumor tissue will provide novel information for identification of epigenetic driver genes, biomarker discovery, and anti-tumor therapy development for clear cell renal cell carcinoma (ccRCC), the most common subtype of renal carcinoma. Current methods are expensive and require a considerable amount of biological tissue. Methods: We have developed a novel assay (AcceSssIble) to determine DNA methylation and nucleosome occupancy in a single experiment. It is rapid and cost-effective, requiring the Infinium HumanMethylation450 BeadChip platform and the CpG methyltransferase M.SssI. Preliminary studies using fresh and frozen kidney tumors show that the epigenetic profile is maintained in frozen tissues, making this method suitable to interrogate archived clinical samples. Results: We have used AcceSssIble to assay the epigenomes of 5 fresh ccRCC tumors and their adjacent normal tissue, and have uncovered 257 genes that are associated with changes in chromatin accessibility in at least 4 ccRCC samples; 155 of these genes also show a change in endogenous DNA methylation levels in at least 4 tumors. These chromatin accessibility and DNA methylation changes occurred in the promoter regions, open reading frames, and the 3’ untranslated regions (UTRs) of the genes. Cross-referencing our results to the expression data of 72 matched ccRCC samples from The Cancer Genome Atlas (TCGA), we discovered that 29% (74/257) of these genes exhibited a significant change in gene expression, over half of which had been previously implicated in various cancers, including ccRCC. Furthermore, we observed chromatin accessibility changes in intergenic regions, including several which contain known transcription factor binding sites and ncRNA promoter regions. These sites might serve as potential enhancers for neighboring genes important to the development of ccRCC. Conclusions: In these studies, we were able to identify epigenetic changes in ccRCC samples associated with known oncogenes and tumor suppressor genes, as well as uncover novel targets. These targets, associated both within genes as well as in intergenic regions, undergo changes in chromatin structure and may be important in the development of ccRCC. Linking these findings to gene expression data revealed functionally relevant targets for ccRCC treatment. Expansion of these studies into a larger number of clinical samples across tumor grades will allow us to uncover biomarkers that can be used for personalized medicine. Citation Format: Elinne Becket, Christopher Duymich, Yin-Wei Chang, Kurinji Pandiyan, Peter A. Jones, Gangning Liang. Simultaneous evaluation of chromatin accessibility and DNA methylation in clear cell renal cell carcinoma by a newly developed assay, AcceSssIble. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr LB-130. doi:10.1158/1538-7445.AM2014-LB-130

Abstract PR07: SNF5 is an essential executor of epigenetic regulation during differentiation

Nucleosome occupancy controls the accessibility of the transcription machinery to DNA regulatory regions and serves an instructive role for gene expression. Chromatin remodelers, such as the BAF complexes, are responsible for establishing nucleosome occupancy patterns, which are key to epigenetic regulation along with DNA methylation and histone modifications. Some reports have assessed the roles of the BAF complex subunits and stemness in murine embryonic stem cells. However, the details of the relationships between remodelers and transcription factors in altering chromatin configuration, which ultimately affects gene expression during cell differentiation, remain unclear. Here for the first time we demonstrate that SNF5, a core subunit of the BAF complex, negatively regulates OCT4 levels in pluripotent cells and is essential for cell survival during differentiation. SNF5 is responsible for generating nucleosomedepleted regions (NDRs) at the regulatory sites of OCT4 repressed target genes such as PAX6 and NEUROG1, which are crucial for cell fate determination. Concurrently, SNF5 closes the NDRs at the regulatory regions of OCT4 activated target genes such as OCT4 itself and NANOG. Furthermore, using loss and gain of function experiments followed by extensive genome-wide analyses including gene expression microarrays and ChIP-sequencing, we highlight that SNF5 plays dual roles during differentiation by antagonizing the expression of genes that were either activated or repressed by OCT4, respectively. Together, we demonstrate that SNF5 executes the switch between pluripotency and differentiation. This abstract is also presented as Poster A39 . Citation Format: Jueng Soo You, Daniel D. De Carvalho, Chao Dai, Minmin Liu, Kurinji Pandiyan, Xianghong Zhou, Gangning Liang, Peter A. Jones. SNF5 is an essential executor of epigenetic regulation during differentiation. [abstract]. In: Proceedings of the AACR Special Conference on Chromatin and Epigenetics in Cancer; Jun 19-22, 2013; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2013;73(13 Suppl):Abstract nr PR07.