<i>Cis</i>-regulatory Element Hijacking by Structural Variants Overshadows Higher-Order Topological Changes in Prostate Cancer

Hawley, James R.; Zhou, Stanley; Arlidge, Christopher; Grillo, Giacomo; Kron, Ken J.; Hugh-White, Rupert; Kwast, Theodorus H. van der; Fraser, Michael; Boutros, Paul C.; Bristow, Robert G.; Lupien, Mathieu

doi:10.1101/2021.01.05.425333

Cited by 7 publications

(4 citation statements)

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“…Recent data suggest that the majority (>80%) of common loops identified in primary benign prostate tissue and prostate tumors are overlapping, further indicating that de novo looping is not a major driver of transcriptional differences in differentiated tissue. 41 While the current data suggest that loops are relatively static, more experiments across a wider variety of conditions are needed to understand the generalizability of these observations. We utilized high-resolution H3K27ac-HiChIP data in the LNCaP prostate cancer cell line, the most widely used in vitro model of prostate cancer, to identify links between target genes and PrCa risk loci.…”

Section: Introductionmentioning

confidence: 78%

H3K27ac HiChIP in prostate cell lines identifies risk genes for prostate cancer susceptibility

Giambartolomei

Seo

Schwarz

et al. 2021

The American Journal of Human Genetics

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Section: Introductionmentioning

confidence: 78%

H3K27ac HiChIP in prostate cell lines identifies risk genes for prostate cancer susceptibility

Giambartolomei

Seo

Schwarz

et al. 2021

The American Journal of Human Genetics

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“…Recent efforts ( Hawley et al, 2021 Preprint ) have characterized 3D genomic profiles in prostate tumor cohorts. These studies recapitulate our findings that the 3D genome organization between malignant and benign prostate tissues remains largely consistent.…”

Section: Discussionmentioning

confidence: 99%

Chromosome compartmentalization alterations in prostate cancer cell lines model disease progression

Martin

Das

Marques

et al. 2021

Journal of Cell Biology

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Prostate cancer aggressiveness and metastatic potential are influenced by gene expression and genomic aberrations, features that can be influenced by the 3D structure of chromosomes inside the nucleus. Using chromosome conformation capture (Hi-C), we conducted a systematic genome architecture comparison on a cohort of cell lines that model prostate cancer progression, from normal epithelium to bone metastasis. We describe spatial compartment identity (A-open versus B-closed) changes with progression in these cell lines and their relation to gene expression changes in both cell lines and patient samples. In particular, 48 gene clusters switch from the B to the A compartment, including androgen receptor, WNT5A, and CDK14. These switches are accompanied by changes in the structure, size, and boundaries of topologically associating domains (TADs). Further, compartment changes in chromosome 21 are exacerbated with progression and may explain, in part, the genesis of the TMPRSS2-ERG translocation. These results suggest that discrete 3D genome structure changes play a deleterious role in prostate cancer progression.

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“…The most significantly associated ARBS (p = 2 x 10 -8 ) was in an intergenic region that physically interacts with the FGFR2 promoter in LNCaP cells (Fig. 7E) and benign prostate tissue 75 . FGFR2 encodes a receptor highly expressed in prostate stroma that is implicated in the development of BPH 76 .…”

Section: Ar Cwas Identifies Genetic Mediators Of Diverse Androgen-dri...mentioning

confidence: 99%

Genetic determinants of chromatin reveal prostate cancer risk mediated by context-dependent gene regulation

et al. 2022

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Methods that link genetic variation to steady-state gene expression levels, such as expression quantitative trait loci (eQTLs), are widely used to functionally annotate traitassociated variants, but they are limited in identifying context-dependent effects on transcription. To address this challenge, we developed the cistrome-wide association study (CWAS), a framework for nominating variants that impact traits through their effects on chromatin state. CWAS associates the genetic determinants of cistromes (e.g., the genomewide profiles of transcription factor binding sites or histone modifications) with traits using summary statistics from genome-wide association studies (GWAS). We performed CWASs of prostate cancer and androgen-related traits, using a reference panel of 307 prostate cistromes from 165 individuals. CWAS nominated susceptibility regulatory elements or androgen receptor (AR) binding sites at 52 out of 98 known prostate cancer GWAS loci and implicated an additional 17 novel loci. We functionally validated a subset of our results using CRISPRi and in vitro reporter assays. At 28 of the 52 risk loci, CWAS identified regulatory mechanisms that are not observable via eQTLs, implicating genes with complex or context-specific regulation that are overlooked by current approaches that relying on steady-state transcript measurements. CWAS genes include transcription factors that govern prostate development such as NKX3-1, HOXB13, GATA2, and KLF5. Moreover, CWAS boosts discovery power in modestly sized GWAS, identifying novel genetic associations mediated through AR binding for androgenrelated phenotypes, including resistance to prostate cancer therapy. CWAS is a powerful and biologically interpretable paradigm for studying variants that influence traits by affecting contextdependent transcriptional regulation.

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Cis-regulatory Element Hijacking by Structural Variants Overshadows Higher-Order Topological Changes in Prostate Cancer

Cited by 7 publications

References 98 publications

H3K27ac HiChIP in prostate cell lines identifies risk genes for prostate cancer susceptibility

H3K27ac HiChIP in prostate cell lines identifies risk genes for prostate cancer susceptibility

Chromosome compartmentalization alterations in prostate cancer cell lines model disease progression

Genetic determinants of chromatin reveal prostate cancer risk mediated by context-dependent gene regulation

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