Enhancer Sequence Variants and Transcription-Factor Deregulation Synergize to Construct Pathogenic Regulatory Circuits in B-Cell Lymphoma

Koues, Olivia I.; Kowalewski, Rodney; Chang, Li‐Wei; Pyfrom, Sarah C.; Schmidt, Jennifer A.; Luo, Hong; Sandoval, Luis; Hughes, Tyler B.; Bednarski, Jeffrey J.; Cashen, Amanda F.; Payton, Jacqueline E.; Oltz, Eugene M.

doi:10.1016/j.immuni.2014.12.021

Cited by 67 publications

(104 citation statements)

References 52 publications

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“…Interestingly, we did not observe overt changes of transcript levels driven by the top 2,000 RACK7 bound promoters in the RACK7 null cells (Figure S2J), suggesting RACK7 functions mainly at enhancers. Using an established, enhancer activity reporter assay (Koues et al, 2015; Outchkourov et al, 2013), we were able to confirm that 10 out of 10 candidate active enhancers bound by RACK7 and KDM5C indeed possess enhancer activities and most, if not all, of them are regulated by RACK7 and KDM5C (Figure S3). Together with the finding discussed in Figure 3, we conclude that RACK7 or KDM5C loss both lead to hyper-activation of these enhancers and higher transcriptional activities.…”

Section: Resultsmentioning

confidence: 79%

Suppression of Enhancer Overactivation by a RACK7-Histone Demethylase Complex

Shen

Guo

et al. 2016

Cell

149

191

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Summary Regulation of enhancer activity is important for controlling gene expression programs. Here we report that a biochemical complex that contains a potential chromatin reader, RACK7 and the histone lysine 4 tri-methyl (H3K4me3)-specific demethylase KDM5C occupies many active enhancers, including almost all super-enhancers. Loss of RACK7 or KDM5C results in overactivation of enhancers, characterized by the deposition of H3K4me3 and H3K27Ac, together with increased transcription of eRNAs and nearby genes. Furthermore, loss of RACK7 or KDM5C leads to de-repression of S100A oncogenes and various cancer-related phenotypes. Our findings reveal a RACK7/KDM5C-regulated, dynamic interchange between histone H3K4me1 and H3K4me3 at active enhancers, representing an additional layer of regulation of enhancer activity. We propose that RACK7/KDM5C functions as an enhancer “brake” to ensure appropriate enhancer activity, which, when compromised, could contribute to tumorigenesis.

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Section: Resultsmentioning

confidence: 79%

Suppression of Enhancer Overactivation by a RACK7-Histone Demethylase Complex

Shen

Guo

et al. 2016

Cell

149

191

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“…This approach led to the identification of genes with altered expression as a consequence of disrupted TF binding including several with known key roles in lymphomagenesis. Enhancer profiling by Koues et al in FL demonstrated that FL tumors not only suppress specific enhancers so as to shed nonessential components of the GC transcriptional circuitry but additionally hijacked critical enhancers from other lineages to acquire specific advantageous tumorigenic functions [66]. Taken together, these recent studies highlight the contribution of the noncoding genome future science group Epigenetic dysregulation in follicular lymphoma Special Report and earmark the importance of this exciting new chapter in FL pathogenesis.…”

Section: Noncoding Regulatory Regionsmentioning

confidence: 97%

Epigenetic Dysregulation in Follicular Lymphoma

et al. 2015

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The adoption of next-generation sequencing technologies has led to a remarkable shift in our understanding of the genetic landscape of follicular lymphoma. While the disease has been synonymous with the t(14;18), the prevalence of alterations in genes that regulate the epigenome has been established as a pivotal hallmark of these lymphomas. Giant strides are being made in unraveling the biological consequences of these alterations in tumorigenesis opening up new opportunities for directed therapies.

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“…For example, many disease-associated SNPs identified by genome-wide association studies are in the enhancer regions [44,51]. They can abolish known or create novelbinding motifs of transcription factors, thus altering their binding to enhancers [49,65]. Using ChIP-seq of H3K27ac and GATA3 transcription factor, Oldridge et al found that the risk SNP rs2168101 associated with neuroblastoma overlapped the GATA3-binding motif within the enhancer of LMO1 oncogene.…”

Section: H3k27ac and H3k4me1/2mentioning

confidence: 99%

“…Consistency of narrow peaks called from replicates can be assessed using the irreproducible discovery rate, by which high-quality peaks can be extracted at a user-defined irreproducible discovery rate cutoff (like 1%) [2]. The functionality of peaks can be validated through chromatin interaction analysis by paired-end tag sequencing or chromosome conformation capture (3C)-based chromatin interaction mapping methods [25,86], reporter assays [16,49,86] or using genomeediting tools like CRISPR (clustered regularly interspaced short palindromic repeats)/Cas9 [86]. Three major aspects of data analysis are critical for future success of ChIP-seq applications in the clinic.…”

Section: Key Experimental Considerationsmentioning

confidence: 99%

“…The ideal approach would be to generate ChIP-seq data from both diseased and normal tissues of the same individual at the same time [88], which will bypass biases and help identify disease specific epigenetic signature. Quite often, normal epigenome reference is generated using tissues from normal individuals [13,44,[49][50]54]. In both scenarios, the question remains to be answered is how many patients and normal controls are needed in order to confidently identify the disease epigenetic signature.…”

Section: Differential-binding Analysismentioning

confidence: 99%

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ChIP-seq in Studying Epigenetic Mechanisms of Disease and Promoting Precision Medicine: Progresses and Future Directions

et al. 2016

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Chromatin immunoprecipitation followed by sequencing (ChIP-seq) is widely used for mapping histone modifications, histone proteins, chromatin regulators, transcription factors and other DNA-binding proteins. It has played a significant role in our understanding of disease mechanisms and in exploring epigenetic changes for potential clinical applications. However, the conventional protocol requires large amounts of starting material and does not quantify the actual occupancy, limiting its applications in clinical settings. Herein we summarize the latest progresses in utilizing ChIP-seq to link epigenetic alterations to disease initiation and progression, and the implications in precision medicine. We provide an update on the newly developed ChIP-seq protocols, especially those suitable for scare clinical samples. Technical and analytical challenges are outlined together with recommendations for improvement. Finally, future directions in expediting ChIP-seq use in clinic are discussed.

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Enhancer Sequence Variants and Transcription-Factor Deregulation Synergize to Construct Pathogenic Regulatory Circuits in B-Cell Lymphoma

Cited by 67 publications

References 52 publications

Suppression of Enhancer Overactivation by a RACK7-Histone Demethylase Complex

Suppression of Enhancer Overactivation by a RACK7-Histone Demethylase Complex

Epigenetic Dysregulation in Follicular Lymphoma

ChIP-seq in Studying Epigenetic Mechanisms of Disease and Promoting Precision Medicine: Progresses and Future Directions

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