Microbiota-sensitive epigenetic signature predicts inflammation in Crohn’s disease

Kelly, Daniel; Kotliar, Michael; Woo, Vivienne; Jagannathan, Srinivasan; Whitt, Jordan; Moncivaiz, Jessica; Aronow, Bruce J.; Dubinsky, Marla; Hyams, Jeffrey S.; Markowitz, James; Baldassano, Robert N.; Stephens, Michael C.; Walters, Thomas D.; Kugathasan, Subra; Haberman, Yael; Sundaram, Nambirajan; Rosen, Michael J.; Helmrath, Michael A.; Karns, Rebekah; Barski, Artem; Denson, Lee A.; Alenghat, Theresa

doi:10.1172/jci.insight.122104

Cited by 49 publications

(32 citation statements)

References 72 publications

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“…Host DNA methylation and gene expression both displayed more pronounced gradients of inflammation than what was observed with the microbiota, suggesting that epigenetic factors mediate interactions between colonic microbiota and host gene expression. Microbiota-sensitive epigenetic signatures were recently observed for histone methylation in CD 48 . While the largest difference in methylation patterns was attributed to inflammation, as expected due to disproportionate composition of inflammatory cells 49 , we did observe significant epigenome-wide differences between CD and control groups (visualized by principal component 6 in Fig.…”

Section: Discussionmentioning

confidence: 98%

Colonic microbiota is associated with inflammation and host epigenomic alterations in inflammatory bowel disease

et al. 2020

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Studies of inflammatory bowel disease (IBD) have been inconclusive in relating microbiota with distribution of inflammation. We report microbiota, host transcriptomics, epigenomics and genetics from matched inflamed and non-inflamed colonic mucosa [50 Crohn's disease (CD); 80 ulcerative colitis (UC); 31 controls]. Changes in community-wide and within-patient microbiota are linked with inflammation, but we find no evidence for a distinct microbial diagnostic signature, probably due to heterogeneous host-microbe interactions, and show only marginal microbiota associations with habitual diet. Epithelial DNA methylation improves disease classification and is associated with both inflammation and microbiota composition. Microbiota sub-groups are driven by dominant Enterbacteriaceae and Bacteroides species, representative strains of which are pro-inflammatory in vitro, are also associated with immune-related epigenetic markers. In conclusion, inflamed and non-inflamed colonic segments in both CD and UC differ in microbiota composition and epigenetic profiles.

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Section: Discussionmentioning

confidence: 98%

Colonic microbiota is associated with inflammation and host epigenomic alterations in inflammatory bowel disease

et al. 2020

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“…Kelly and colleagues [94] also recently identified a connection between the gut microbiome and certain histone modifications. Specifically, the location of histones with a H3K4 methylation mark was shown to be modified by the presence of gut microbes.…”

Section: The Gut Microbiome and Chromatin Structurementioning

confidence: 99%

“…This analysis revealed an abundance of genes that belonged to pathways associated with inflammatory bowel disease. Importantly, many of these genes and pathways are also associated with cancer (that is, genes involved in maintaining the innate mucosal barrier, reactive oxygen species generation, or ephrin signaling), so although the authors did not highlight a link to cancer in their findings, their results can be readily applied to better understand how gut microbes affect histone methylation at genes that are known to be dysregulated in CRC [94].…”

Section: The Gut Microbiome and Chromatin Structurementioning

confidence: 99%

“…Notably, many of the studies that identified CRC-related genes or pathways that are modified by the gut microbiome were not designed to examine CRC-related effects specifically. For example, Kelly and colleagues [94] sought to identify genes altered by the gut microbiome that showed different patterns of H3K4 methylation in individuals with inflammatory bowel disease, but these genes also relate to CRC because similar biological processes are disrupted in the two diseases. Similar to the computational analysis conducted by Liang and colleagues [119], in which microarray data (from a single laboratory) were reanalyzed to look for lncRNA changes induced by the gut microbiome, or the meta-analysis conducted by Drewes and colleagues [7], in which combined data from several groups were reanalyzed through a single computational pipeline, studies examining the impact of the gut microbiome on the epigenome should be reanalyzed to probe for CRC-related alterations that were not explored in the original analyses.…”

Section: Mechanistic Insightsmentioning

confidence: 99%

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Impact of the gut microbiome on the genome and epigenome of colon epithelial cells: contributions to colorectal cancer development

2019

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In recent years, the number of studies investigating the impact of the gut microbiome in colorectal cancer (CRC) has risen sharply. As a result, we now know that various microbes (and microbial communities) are found more frequently in the stool and mucosa of individuals with CRC than healthy controls, including in the primary tumors themselves, and even in distant metastases. We also know that these microbes induce tumors in various mouse models, but we know little about how they impact colon epithelial cells (CECs) directly, or about how these interactions might lead to modifications at the genetic and epigenetic levels that trigger and propagate tumor growth. Rates of CRC are increasing in younger individuals, and CRC remains the second most frequent cause of cancer-related deaths globally. Hence, a more in-depth understanding of the role that gut microbes play in CRC is needed. Here, we review recent advances in understanding the impact of gut microbes on the genome and epigenome of CECs, as it relates to CRC. Overall, numerous studies in the past few years have definitively shown that gut microbes exert distinct impacts on DNA damage, DNA methylation, chromatin structure and non-coding RNA expression in CECs. Some of the genes and pathways that are altered by gut microbes relate to CRC development, particularly those involved in cell proliferation and WNT signaling. We need to implement more standardized analysis strategies, collate data from multiple studies, and utilize CRC mouse models to better assess these effects, understand their functional relevance, and leverage this information to improve patient care.

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“…All biopsies were extracted and processed as previously described 14,15 with NEBNext Ultra RNA Library Prep Kit used for Illumina RNA sequencing library preparations by following set manufacturer's recommendations (NEB, Ipswich, MA, USA). Approximately 77% of the 274 CD ileal biopsies, n = 212, were used for our previous publication 10 .…”

Section: Rna-sequencingmentioning

confidence: 99%

Profiling Non-Coding RNA Levels With Clinical Classifiers in Pediatric Crohn’s Disease

Pelia

Venkateswaran

Matthews

et al. 2020

Preprint

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Background: Crohn’s disease (CD) is a heritable chronic inflammatory disorder. Non-coding RNAs (ncRNAs) play an important role in epigenetic regulation by affecting gene expression, but can also directly affect protein function, thus having a substantial impact on biological processes. We investigated whether non-coding RNAs (ncRNA) at diagnosis are dysregulated during CD at different CD locations and future disease behaviors to determine if ncRNA signatures can serve as an index to outcomes. Methods: Using subjects belonging to the RISK cohort, we analyzed ncRNA from the ileal biopsies of 345 CD and 71 non-IBD controls, and ncRNA from rectal biopsies of 329 CD and 61 non-IBD controls. Sequence alignment was done (STAR package) using Human Genome version 38 (hg38) as reference panel. The differential expression (DE) analysis was performed with EdgeR package and DE ncRNAs were identified with a threshold of fold change (FC) >2 and FDR < 0.05 after multiple test corrections. Results: In total, we identified 130 CD specific DE ncRNAs (89 in ileum and 41 in rectum) when compared to non-IBD controls. Similarly, 35 DE ncRNAs were identified between B1 and B2 in ileum, whereas no differences among CD disease behaviors were noticed in rectum. We also found inflammation specific ncRNAs between inflamed and non-inflamed groups in ileal biopsies. Overall, we observed that expression of mir1244-2, mir1244-3, mir1244-4, and RN7SL2 were increased during CD, regardless of disease behavior, location, or inflammatory status. Lastly, we tested ncRNA expression at baseline as potential tool to predict the disease status, disease behaviors and disease inflammation at 3-year follow up.Conclusions: We have identified ncRNAs that are specific to disease location, disease behavior, and disease inflammation in CD. Both ileal and rectal specific ncRNA are changing over the course of CD, specifically during the disease progression in the intestinal mucosa. Collectively, our findings show changes in ncRNA during CD and may have a clinical utility in early identification and characterization of disease progression.

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Microbiota-sensitive epigenetic signature predicts inflammation in Crohn’s disease

Cited by 49 publications

References 72 publications

Colonic microbiota is associated with inflammation and host epigenomic alterations in inflammatory bowel disease

Colonic microbiota is associated with inflammation and host epigenomic alterations in inflammatory bowel disease

Impact of the gut microbiome on the genome and epigenome of colon epithelial cells: contributions to colorectal cancer development

Profiling Non-Coding RNA Levels With Clinical Classifiers in Pediatric Crohn’s Disease

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