Integrative Genomics Analysis Identifies <i>ACVR1B</i> as a Candidate Causal Gene of Emphysema Distribution

Boueiz, Adel; Pham, Brandon; Chase, Robert; Lamb, Andrew; Lee, Sool; Naing, Zun Zar Chi; Cho, Michael H.; Parker, Margaret M.; Sakornsakolpat, Phuwanat; Hersh, Craig P.; Crapo, James D.; Stergachis, Andrew B.; Tal‐Singer, Ruth; DeMeo, Dawn L.; Silverman, Edwin K.; Zhou, Xiaobo; Castaldi, Peter J.

doi:10.1165/rcmb.2018-0110oc

Cited by 16 publications

(12 citation statements)

References 40 publications

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“…With respect to the lung, TGF-β family proteins participate in normal lung development and are dysregulated in COPD, emphysema, asthma, and pulmonary fibrosis (Verhamme et al, 2015; Morris et al, 2003; Thomas et al, 2016). Genetic variants near TGF-β superfamily members TGFB2 (Castaldi et al, 2014; Cho et al, 2014), ACVR1B (Boueiz et al, 2019), LTBP4 (Wain et al, 2017), and BMP6 (Loth et al, 2014) have been identified in GWAS for lung function and COPD, but prior to this study the region near ACVR1B was the only one linked to a gene in the TGF-β pathway through functional studies (Boueiz et al, 2019). Our findings demonstrate that the emphysema-associated variant rs1690789 is located in an active gene regulatory region in human lung fibroblasts that interacts with the promoter region of TGFB2 and regulates TGFB2 expression.…”

Section: Discussionmentioning

confidence: 99%

Identification of an emphysema-associated genetic variant near TGFB2 with regulatory effects in lung fibroblasts

Parker

Hao

Guo

et al. 2019

eLife

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Murine studies have linked TGF-β signaling to emphysema, and human genome-wide association studies (GWAS) studies of lung function and COPD have identified associated regions near genes in the TGF-β superfamily. However, the functional regulatory mechanisms at these loci have not been identified. We performed the largest GWAS of emphysema patterns to date, identifying 10 GWAS loci including an association peak spanning a 200 kb region downstream from TGFB2. Integrative analysis of publicly available eQTL, DNaseI, and chromatin conformation data identified a putative functional variant, rs1690789, that may regulate TGFB2 expression in human fibroblasts. Using chromatin conformation capture, we confirmed that the region containing rs1690789 contacts the TGFB2 promoter in fibroblasts, and CRISPR/Cas-9 targeted deletion of a ~ 100 bp region containing rs1690789 resulted in decreased TGFB2 expression in primary human lung fibroblasts. These data provide novel mechanistic evidence linking genetic variation affecting the TGF-β pathway to emphysema in humans.

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Section: Discussionmentioning

confidence: 99%

Identification of an emphysema-associated genetic variant near TGFB2 with regulatory effects in lung fibroblasts

Parker

Hao

Guo

et al. 2019

eLife

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“…Most common have been GWAS of lung function, the largest of which included over 400,000 subjects and identified 279 genetic loci [55]. GWAS have been performed for hyperinflation [56] and emphysema distribution [57,58], two phenotypes that are relevant for lung volume reduction therapies. Although exacerbations are an important outcome in clinical trials, no GWAS for COPD exacerbations have been published.…”

Section: Genome-wide Association Studies In Copd Pharmacogenomicsmentioning

confidence: 99%

“…Emphysema can be assessed based on quantitative analysis of chest CT scans [67]. GWAS have identified genome-wide significant associations with quantitative measures of emphysema [68,69], emphysema patterns [70], and emphysema distribution [57,58]. Some of the emphysema associations overlap with COPD GWAS findings, including genes such as HHIP and FAM13A, which have been demonstrated to influence emphysema in mouse smoking models [71,72].…”

Section: Genetics Of Copd Heterogeneity and Subtypesmentioning

confidence: 99%

Pharmacogenomics of chronic obstructive pulmonary disease

Hersh

2019

Expert Review of Respiratory Medicine

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Introduction: Chronic obstructive pulmonary disease (COPD) is a heterogeneous condition, which presents the opportunity for precision therapy based on genetics or other biomarkers. Areas covered: Alpha-1 antitrypsin deficiency, a genetic form of emphysema, provides an example of this precision approach to diagnosis and therapy. To date, research in COPD pharmacogenomics has been limited by small sample sizes, lack of accessible target tissue, failure to consider COPD subtypes, and different outcomes relevant for various medications. There have been several published genome-wide association studies and other omics studies in COPD pharmacogenomics; however, clinical implementation remains far away. There is a growing evidence base for precision prescription of inhaled corticosteroids in COPD, based on clinical phenotypes and blood biomarkers, but not yet based on pharmacogenomics. Expert opinion: At this time, there is insufficient evidence for clinical implementation of COPD pharmacogenomics. Additional genome-wide studies will be required to discover predictors of drug response and to identify genomic biomarkers of COPD subtypes, which could be targeted with subtype-directed therapies.

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“…As a result, expression quantitative trait locus (eQTL) studies that associate genetic variants to gene expression values have been used to identify functional gene targets of GWAS-identified loci. In COPD, this approach has identified putative causal variants affecting the expression of HHIP 2 , FAM13A 3 , TGFB2 4 , and ACVR1B 5 . However, eQTL studies do not capture all of the potentially relevant functional mechanisms through which causal variants may alter gene expression.…”

Section: Introductionmentioning

confidence: 99%

Characterization of a COPD-Associated NPNT Functional Splicing Genetic Variant in Human Lung Tissue via Long-Read Sequencing

Saferali

Sheynkman

Hersh

et al. 2020

Preprint

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Chronic obstructive pulmonary disease (COPD) is a leading cause of death worldwide. Genome-wide association studies (GWAS) have identified over 80 loci that are associated with COPD and emphysema, however for most of these loci the causal variant and gene are unknown. Here, we utilize lung splice quantitative trait loci (sQTL) data from the Genotype-Tissue Expression project (GTEx) and short read sequencing data from the Lung Tissue Research Consortium (LTRC) to characterize a locus in nephronectin (NPNT) associated with COPD case-control status and lung function. We found that the rs34712979 variant is associated with alternative splice junction use in NPNT , specifically for the junction connecting the 2nd and 4th exons (chr4:105898001-105927336) (p=4.02x10-38). This association colocalized with GWAS data for COPD and lung spirometry measures with a posterior probability of 94%, indicating that the same causal genetic variants in NPNT underlie the associations with COPD risk, spirometric measures of lung function, and splicing. Investigation of NPNT short read sequencing revealed that rs34712979 creates a cryptic splice acceptor site which results in the inclusion of a 3 nucleotide exon extension, coding for a serine residue near the N-terminus of the protein. Using Oxford Nanopore Technologies (ONT) long read sequencing we identified 13 NPNT isoforms, 6 of which are predicted to be protein coding. Two of these are full length isoforms which differ only in the 3 nucleotide exon extension whose occurrence differs by genotype. Overall, our data indicate that rs34712979 modulates COPD risk and lung function by creating a novel splice acceptor which results in the inclusion of a 3 nucelotide sequence coding for a serine in the nephronectin protein sequence. Our findings implicate NPNT splicing in contributing to COPD risk, and identify a novel serine insertion in the nephronectin protein that warrants further study.

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Integrative Genomics Analysis Identifies ACVR1B as a Candidate Causal Gene of Emphysema Distribution

Cited by 16 publications

References 40 publications

Identification of an emphysema-associated genetic variant near TGFB2 with regulatory effects in lung fibroblasts

Identification of an emphysema-associated genetic variant near TGFB2 with regulatory effects in lung fibroblasts

Pharmacogenomics of chronic obstructive pulmonary disease

Characterization of a COPD-Associated NPNT Functional Splicing Genetic Variant in Human Lung Tissue via Long-Read Sequencing

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