ChIP-seq of plasma cell-free nucleosomes identifies gene expression programs of the cells of origin

Sadeh, Ronen; Sharkia, Israa; Fialkoff, Gavriel; Rahat, Ayelet; Gutin, Jenia; Chappleboim, Alon; Nitzan, Mor; Fox-Fisher, Ilana; Neiman, Daniel; Meler, Guy; Kamari, Zahala; Yaish, Dayana; Peretz, Tamar; Hubert, Ayala; Cohen, Jonathan; Salah, Azzam; Temper, Mark; Grinshpun, Albert; Maoz, Myriam; Abu‐Gazala, Samir; Ya’acov, Ami Ben; Shteyer, Eyal; Safadi, Rifaat; Kaplan, Tommy; Shemer, Ruth; Planer, David; Galun, Eithan; Gläser, Benjamin; Zick, Aviad; Dor, Yuval; Friedman, Nir

doi:10.1038/s41587-020-00775-6

Cited by 90 publications

(134 citation statements)

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“…S5C). The predominant cell types and their respective proportions we observe are generally consistent with recently published estimates for serum cfRNA 1 and plasma cfDNA 16 . We also observed small fractional contributions from endothelial cells, pancreatic cells, intestinal enterocytes, kidney epithelia, club cells, goblet cells, pancreatic acinar cells, and other pancreatic cells (Fig.…”

Section: Deconvolution Of Cell Type Specific Signals In the Healthy Cell Free Transcriptomesupporting

confidence: 91%

Cell Types of Origin in the Cell Free Transcriptome in Human Health and Disease

2021

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Liquid biopsies using cell-free RNA (cfRNA) can noninvasively measure dynamic physiological changes throughout the body. While there is much effort in the liquid biopsy field to determine disease tissue-of-origin, pathophysiology occurs at the cellular level. Here, we show that it is possible to determine cell type-of-origin from cfRNA by leveraging single cell transcriptomic atlases to perform computational deconvolution. We derived cell type gene signatures by combining the whole-body single cell atlas Tabula Sapiens, individual tissue single cell atlases, and bulk tissue atlases. Using deconvolution, we identified cell types-of-origin in the healthy human cell-free transcriptome, including contributions from multiple cell types in the brain, liver, lung, intestine, kidney, and pancreas in addition to hematopoietic cell types. We further showed that it is possible not only to detect cell types implicated in the pathology of chronic kidney disease (CKD) and Alzheimer’s disease (AD), but also to measure changes in these cell types as a function of disease state. Altogether, our results show that cfRNA measurements reflect cellular contributions in health and disease from diverse tissue-specific cell types. These findings underscore the resolution at which one can monitor pathophysiological changes and the broad potential prognostic utility afforded by non-invasive transcriptomic measurement.

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Section: Deconvolution Of Cell Type Specific Signals In the Healthy Cell Free Transcriptomesupporting

confidence: 91%

Cell Types of Origin in the Cell Free Transcriptome in Human Health and Disease

2021

Preprint

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“…Such regions could offer biomarkers which may inform appropriate lifestyle interventions to reduce risk of IR-related disease. More recently, Sadeh et al developed a method to identify liver-specific histone modification signatures in plasma cell-free nucleosomes using ChIP-seq (249). Despite the relatively small sample size and patient heterogeneity, the authors were able to detect liverdisease associated changes in histone modification enrichment at specific loci (249).…”

Section: Epigenetic Biomarkersmentioning

confidence: 99%

“…More recently, Sadeh et al developed a method to identify liver-specific histone modification signatures in plasma cell-free nucleosomes using ChIP-seq (249). Despite the relatively small sample size and patient heterogeneity, the authors were able to detect liverdisease associated changes in histone modification enrichment at specific loci (249). This methodology is expected to be taken up in the future to facilitate the high-throughput interrogation of disease signatures in patient blood samples.…”

Section: Epigenetic Biomarkersmentioning

confidence: 99%

“…Due to higher associated costs and technical challenges, the profiling of histone modifications has not really matched the pace of methylome-wide studies. Nevertheless, exciting research has recently demonstrated the potential to once more harness the correlation between liver and blood epigenomic profiles, this time by performing ChIP-seq on circulating cell-free DNA (249). Future studies are expected to leverage on this new technology to identify additional biomarkers of hepatic IR, assisting in the prevention of NAFLD, T2D and other cardiometabolic diseases, which together have an enormous health, societal and economic impact.…”

Section: Open Questions and Future Directionsmentioning

confidence: 99%

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Epigenetics of Hepatic Insulin Resistance

2021

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Insulin resistance (IR) is largely recognized as a unifying feature that underlies metabolic dysfunction. Both lifestyle and genetic factors contribute to IR. Work from recent years has demonstrated that the epigenome may constitute an interface where different signals may converge to promote IR gene expression programs. Here, we review the current knowledge of the role of epigenetics in hepatic IR, focusing on the roles of DNA methylation and histone post-translational modifications. We discuss the broad epigenetic changes observed in the insulin resistant liver and its associated pathophysiological states and leverage on the wealth of ‘omics’ studies performed to discuss efforts in pinpointing specific loci that are disrupted by these changes. We envision that future studies, with increased genomic resolution and larger cohorts, will further the identification of biomarkers of early onset hepatic IR and assist the development of targeted interventions. Furthermore, there is growing evidence to suggest that persistent epigenetic marks may be acquired over prolonged exposure to disease or deleterious exposures, highlighting the need for preventative medicine and long-term lifestyle adjustments to avoid irreversible or long-term alterations in gene expression.

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“…However, signal abundance can be increased by leveraging signals from all cfDNA molecules rather than the smaller subset of fragments containing specific tumorrelated mutations (Figures 2A,C). This can be accomplished by targeting tumor-specific epigenetic changes that occur early on during carcinogenesis and thus are found at higher abundance in early stage cancers than tumor-related mutations (Snyder et al, 2016;Ulz et al, 2016;Wong et al, 2016;Leygo et al, 2017;Jiang et al, 2018Jiang et al, , 2019Cristiano et al, 2019;Gai and Sun, 2019;Ivanov et al, 2019;Panagopoulou et al, 2019;Sun et al, 2019;Van der pol and Mouliere, 2019;Sadeh et al, 2021). Further, combining tumor-cell derived signals with those from the surrounding host microenvironment can increase signal abundance (Hoadley et al, 2018;Liu et al, 2018;Haigis et al, 2019;Lam et al, 2019).…”

Section: Increased Signal Abundance From Leveraging Epigenetic Changes In Both Tumor and Non-tumor Cellsmentioning

confidence: 99%

Detection of Cell Types Contributing to Cancer From Circulating, Cell-Free Methylated DNA

et al. 2021

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Detection of cellular changes in tissue biopsies has been the basis for cancer diagnostics. However, tissue biopsies are invasive and limited by inaccuracies due to sampling locations, restricted sampling frequency, and poor representation of tissue heterogeneity. Liquid biopsies are emerging as a complementary approach to traditional tissue biopsies to detect dynamic changes in specific cell populations. Cell-free DNA (cfDNA) fragments released into the circulation from dying cells can be traced back to the tissues and cell types they originated from using DNA methylation, an epigenetic regulatory mechanism that is highly cell-type specific. Decoding changes in the cellular origins of cfDNA over time can reveal altered host tissue homeostasis due to local cancer invasion and metastatic spread to distant organs as well as treatment responses. In addition to host-derived cfDNA, changes in cancer cells can be detected from cell-free, circulating tumor DNA (ctDNA) by monitoring DNA mutations carried by cancer cells. Here, we will discuss computational approaches to identify and validate robust biomarkers of changed tissue homeostasis using cell-free, methylated DNA in the circulation. We highlight studies performing genome-wide profiling of cfDNA methylation and those that combine genetic and epigenetic markers to further identify cell-type specific signatures. Finally, we discuss opportunities and current limitations of these approaches for implementation in clinical oncology.

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ChIP-seq of plasma cell-free nucleosomes identifies gene expression programs of the cells of origin

Cited by 90 publications

References 91 publications

Cell Types of Origin in the Cell Free Transcriptome in Human Health and Disease

Cell Types of Origin in the Cell Free Transcriptome in Human Health and Disease

Epigenetics of Hepatic Insulin Resistance

Detection of Cell Types Contributing to Cancer From Circulating, Cell-Free Methylated DNA

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