Integration of ChIP-seq and machine learning reveals enhancers and a predictive regulatory sequence vocabulary in melanocytes

Gorkin, David U.; Lee, Dongwon; Reed, Xylena; Fletez-Brant, Christopher; Bessling, Seneca L.; Loftus, Stacie K.; Beer, M; Pavan, William J.; McCallion, Andrew S.

doi:10.1101/gr.139360.112

Cited by 69 publications

(73 citation statements)

References 70 publications

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“…We found that these predictions were cell type-specific in K562 cells and could accurately distinguish enhancer sequences from non-enhancer sequences. Our results suggest that combinations of TF-binding preferences, not histone modifications alone, are most predictive of actively expressing genomic sequences, a result supported by other attempts to define the sequence features of enhancers (Heinz et al 2010;Lee et al 2011;Arvey et al 2012;Gorkin et al 2012;Smith et al 2013). These results support a model where TF binding and subsequent tran- (Struhl and Segal 2013), leading to the constellation of histone modifications observed in segments with high cis-regulatory activity.…”

Section: Discussionsupporting

confidence: 82%

High-throughput functional testing of ENCODE segmentation predictions

et al. 2014

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The histone modification state of genomic regions is hypothesized to reflect the regulatory activity of the underlying genomic DNA. Based on this hypothesis, the ENCODE Project Consortium measured the status of multiple histone modifications across the genome in several cell types and used these data to segment the genome into regions with different predicted regulatory activities. We measured the cis-regulatory activity of more than 2000 of these predictions in the K562 leukemia cell line. We tested genomic segments predicted to be Enhancers, Weak Enhancers, or Repressed elements in K562 cells, along with other sequences predicted to be Enhancers specific to the H1 human embryonic stem cell line (H1-hESC). Both Enhancer and Weak Enhancer sequences in K562 cells were more active than negative controls, although surprisingly, Weak Enhancer segmentations drove expression higher than did Enhancer segmentations. Lower levels of the covalent histone modifications H3K36me3 and H3K27ac, thought to mark active enhancers and transcribed gene bodies, associate with higher expression and partly explain the higher activity of Weak Enhancers over Enhancer predictions. While DNase I hypersensitivity (HS) is a good predictor of active sequences in our assay, transcription factor (TF) binding models need to be included in order to accurately identify highly expressed sequences. Overall, our results show that a significant fraction (~26%) of the ENCODE enhancer predictions have regulatory activity, suggesting that histone modification states can reflect the cis-regulatory activity of sequences in the genome, but that specific sequence preferences, such as TF-binding sites, are the causal determinants of cis-regulatory activity.[Supplemental material is available for this article.]It is widely reported that specific combinations of covalent histone modifications reflect the regulatory function of underlying genomic DNA sequence (Strahl and Allis 2000). As part of the ENCODE Project, the genomic locations of a variety of covalent histone modifications were determined by chromatin immunoprecipitation sequencing (ChIP-seq) in a number of cell types and cell lines. Two studies used these data to train computational models that predict different functional regions of the human genome. These unsupervised learning algorithms, Segway (Hoffman et al. 2012) and ChromHMM Kellis 2010, 2012), take functional genomics data as input (DNase-seq; FAIRE-seq; and ChIP-seq of histone modifications, RNA polymerase II large subunit [POLR2A], and CTCF) and return segmentation classes, which are then assigned a hypothesized function using current knowledge of histone modification function. As part of the ENCODE Project, these two sets of predictions were consolidated to create a unified annotation of the entire human genome with seven functional classes in multiple cell types. These segmentations include Transcription Start Site, Promoter Flanking, Transcribed, CTCF-bound, Enhancer, Weak Enhancer, and Repressed or Inactive segments (The ENCODE Project ...

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Section: Discussionsupporting

confidence: 82%

High-throughput functional testing of ENCODE segmentation predictions

et al. 2014

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“…The corresponding patterns of DNase I HS in these cell types suggest that IRF4 expression in lymphocytes and melanocytes are directed by distinct sets of regulatory elements (Figure 2b). In addition, the position orthologous to rs12203592 in the mouse genome directly overlaps a melanocyte enhancer (Gorkin et al, 2012) since it is occupied by p300 and marked by H3K4me1 in the melanocyte line melan-Ink4a-Arf (Sviderskaya et al, 2002) (Figure 2c). …”

Section: Resultsmentioning

confidence: 99%

“…c) UCSC genome browser view of 25 KB region around Irf4 (mm9 coordinates chr13:30,838,000–30,863,000). The ChIP-seq signals for EP300 (green) and H3K4me1 (blue) in the mouse melanocyte line melan-Ink4a-Arf from Gorkin et al, 2012.…”

Section: Figurementioning

confidence: 99%

A Polymorphism in IRF4 Affects Human Pigmentation through a Tyrosinase-Dependent MITF/TFAP2A Pathway

Praetorius

Grill

Stacey

et al. 2013

Cell

190

181

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Sequence polymorphisms linked to human diseases and phenotypes in genome-wide association studies often affect non-coding regions. A single nucleotide polymorphism (SNP) within an intron of the gene encoding Interferon Regulatory Factor 4 (IRF4), a transcription factor with no known role in melanocyte biology, is strongly associated with sensitivity of skin to sun exposure, freckles, blue eyes and brown hair color. Here we demonstrate that this SNP lies within an enhancer of IRF4 transcription in melanocytes. The allele associated with this pigmentation phenotype impairs binding of the TFAP2A transcription factor which together with the melanocyte master regulator MITF, regulates activity of the enhancer. Assays in zebrafish and mice reveal that IRF4 cooperates with MITF to activate expression of Tyrosinase (TYR), an essential enzyme in melanin synthesis. Our findings provide a clear example of a non-coding polymorphism that affects a phenotype by modulating a developmental gene regulatory network.

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“…2B). While MYC ChIPseq peaks were the most enriched feature for this analysis, we prioritized MITF due to its role as a master regulator (Steingrímsson et al 2004;Levy et al 2006), lineage-specific oncogene (Garraway et al 2005;Tsao et al 2012), and its association with MET regulation (McGill et al 2006;Beuret et al 2007) and enhancer function (Gorkin et al 2012). These results raised the possibility that MITF may utilize lineage-specific regulatory elements to control MET expression in melanoma downstream from BRAF inhibition.…”

Section: Resultsmentioning

confidence: 99%

Enhancer-targeted genome editing selectively blocks innate resistance to oncokinase inhibition

et al. 2014

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Thousands of putative enhancers are characterized in the human genome, yet few have been shown to have a functional role in cancer progression. Inhibiting oncokinases, such as EGFR, ALK, ERBB2, and BRAF, is a mainstay of current cancer therapy but is hindered by innate drug resistance mediated by up-regulation of the HGF receptor, MET. The mechanisms mediating such genomic responses to targeted therapy are unknown. Here, we identify lineage-specific enhancers at the MET locus for multiple common tumor types, including a melanoma lineage-specific enhancer 63 kb downstream from the MET TSS. This enhancer displays inducible chromatin looping with the MET promoter to up-regulate MET expression upon BRAF inhibition. Epigenomic analysis demonstrated that the melanocyte-specific transcription factor, MITF, mediates this enhancer function. Targeted genomic deletion (<7 bp) of the MITF motif within the MET enhancer suppressed inducible chromatin looping and innate drug resistance, while maintaining MITF-dependent, inhibitor-induced melanoma cell differentiation. Epigenomic analysis can thus guide functional disruption of regulatory DNA to decouple pro-and antioncogenic functions of a dominant transcription factor and block innate resistance to oncokinase therapy.

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Integration of ChIP-seq and machine learning reveals enhancers and a predictive regulatory sequence vocabulary in melanocytes

Cited by 69 publications

References 70 publications

High-throughput functional testing of ENCODE segmentation predictions

High-throughput functional testing of ENCODE segmentation predictions

A Polymorphism in IRF4 Affects Human Pigmentation through a Tyrosinase-Dependent MITF/TFAP2A Pathway

Enhancer-targeted genome editing selectively blocks innate resistance to oncokinase inhibition

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