Suzanne E de Bruijn, Daan M Panneman, Nicole Weisschuh, Elizabeth L Cadena, Erica G M Boonen, Lara K Holtes, Galuh D N Astuti, Frans P M Cremers, Nico Leijsten, Jordi Corominas, Christian Gilissen, Anna Skowronska, Jessica Woodley, Andrew D Beggs, Vasileios Toulis, Di Chen, Michael E Cheetham, Alison J Hardcastle, Terri L McLaren, Tina M Lamey, Jennifer A Thompson, Fred K Chen, John N de Roach, Isabella R Urwin, Lori S Sullivan, Susanne Roosing
{"title":"通过多步骤和高通量方法鉴定 17 型视网膜色素变性的新型三维基因组改变和复杂结构变异。","authors":"Suzanne E de Bruijn, Daan M Panneman, Nicole Weisschuh, Elizabeth L Cadena, Erica G M Boonen, Lara K Holtes, Galuh D N Astuti, Frans P M Cremers, Nico Leijsten, Jordi Corominas, Christian Gilissen, Anna Skowronska, Jessica Woodley, Andrew D Beggs, Vasileios Toulis, Di Chen, Michael E Cheetham, Alison J Hardcastle, Terri L McLaren, Tina M Lamey, Jennifer A Thompson, Fred K Chen, John N de Roach, Isabella R Urwin, Lori S Sullivan, Susanne Roosing","doi":"10.3389/fgene.2024.1469686","DOIUrl":null,"url":null,"abstract":"<p><strong>Introduction: </strong>Autosomal dominant retinitis pigmentosa type 17 (adRP, type RP17) is caused by complex structural variants (SVs) affecting a locus on chromosome 17 (chr17q22). The SVs disrupt the 3D regulatory landscape by altering the topologically associating domain (TAD) structure of the locus, creating novel TAD structures (neo-TADs) and ectopic enhancer-gene contacts. Currently, screening for RP17-associated SVs is not included in routine diagnostics given the complexity of the variants and a lack of cost-effective detection methods. The aim of this study was to accurately detect novel RP17-SVs by establishing a systematic and efficient workflow.</p><p><strong>Methods: </strong>Genetically unexplained probands diagnosed with adRP (n = 509) from an international cohort were screened using a smMIPs or genomic qPCR-based approach tailored for the RP17 locus. Suspected copy number changes were validated using high-density SNP-array genotyping, and SV breakpoint characterization was performed by mutation-specific breakpoint PCR, genome sequencing and, if required, optical genome mapping. <i>In silico</i> modeling of novel SVs was performed to predict the formation of neo-TADs and whether ectopic contacts between the retinal enhancers and the <i>GDPD1</i>-promoter could be formed.</p><p><strong>Results: </strong>Using this workflow, potential RP17-SVs were detected in eight probands of which seven were confirmed. Two novel SVs were identified that are predicted to cause TAD rearrangement and retinal enhancer-<i>GDPD1</i> contact, one from Germany (DE-SV9) and three with the same SV from the United States (US-SV10). Previously reported RP17-SVs were also identified in three Australian probands, one with UK-SV2 and two with SA-SV3.</p><p><strong>Discussion: </strong>In summary, we describe a validated multi-step pipeline for reliable and efficient RP17-SV discovery and expand the range of disease-associated SVs. Based on these data, RP17-SVs can be considered a frequent cause of adRP which warrants the inclusion of RP17-screening as a standard diagnostic test for this disease.</p>","PeriodicalId":12750,"journal":{"name":"Frontiers in Genetics","volume":null,"pages":null},"PeriodicalIF":2.8000,"publicationDate":"2024-10-23","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11537883/pdf/","citationCount":"0","resultStr":"{\"title\":\"Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach.\",\"authors\":\"Suzanne E de Bruijn, Daan M Panneman, Nicole Weisschuh, Elizabeth L Cadena, Erica G M Boonen, Lara K Holtes, Galuh D N Astuti, Frans P M Cremers, Nico Leijsten, Jordi Corominas, Christian Gilissen, Anna Skowronska, Jessica Woodley, Andrew D Beggs, Vasileios Toulis, Di Chen, Michael E Cheetham, Alison J Hardcastle, Terri L McLaren, Tina M Lamey, Jennifer A Thompson, Fred K Chen, John N de Roach, Isabella R Urwin, Lori S Sullivan, Susanne Roosing\",\"doi\":\"10.3389/fgene.2024.1469686\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Introduction: </strong>Autosomal dominant retinitis pigmentosa type 17 (adRP, type RP17) is caused by complex structural variants (SVs) affecting a locus on chromosome 17 (chr17q22). The SVs disrupt the 3D regulatory landscape by altering the topologically associating domain (TAD) structure of the locus, creating novel TAD structures (neo-TADs) and ectopic enhancer-gene contacts. Currently, screening for RP17-associated SVs is not included in routine diagnostics given the complexity of the variants and a lack of cost-effective detection methods. The aim of this study was to accurately detect novel RP17-SVs by establishing a systematic and efficient workflow.</p><p><strong>Methods: </strong>Genetically unexplained probands diagnosed with adRP (n = 509) from an international cohort were screened using a smMIPs or genomic qPCR-based approach tailored for the RP17 locus. Suspected copy number changes were validated using high-density SNP-array genotyping, and SV breakpoint characterization was performed by mutation-specific breakpoint PCR, genome sequencing and, if required, optical genome mapping. <i>In silico</i> modeling of novel SVs was performed to predict the formation of neo-TADs and whether ectopic contacts between the retinal enhancers and the <i>GDPD1</i>-promoter could be formed.</p><p><strong>Results: </strong>Using this workflow, potential RP17-SVs were detected in eight probands of which seven were confirmed. Two novel SVs were identified that are predicted to cause TAD rearrangement and retinal enhancer-<i>GDPD1</i> contact, one from Germany (DE-SV9) and three with the same SV from the United States (US-SV10). Previously reported RP17-SVs were also identified in three Australian probands, one with UK-SV2 and two with SA-SV3.</p><p><strong>Discussion: </strong>In summary, we describe a validated multi-step pipeline for reliable and efficient RP17-SV discovery and expand the range of disease-associated SVs. 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Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach.
Introduction: Autosomal dominant retinitis pigmentosa type 17 (adRP, type RP17) is caused by complex structural variants (SVs) affecting a locus on chromosome 17 (chr17q22). The SVs disrupt the 3D regulatory landscape by altering the topologically associating domain (TAD) structure of the locus, creating novel TAD structures (neo-TADs) and ectopic enhancer-gene contacts. Currently, screening for RP17-associated SVs is not included in routine diagnostics given the complexity of the variants and a lack of cost-effective detection methods. The aim of this study was to accurately detect novel RP17-SVs by establishing a systematic and efficient workflow.
Methods: Genetically unexplained probands diagnosed with adRP (n = 509) from an international cohort were screened using a smMIPs or genomic qPCR-based approach tailored for the RP17 locus. Suspected copy number changes were validated using high-density SNP-array genotyping, and SV breakpoint characterization was performed by mutation-specific breakpoint PCR, genome sequencing and, if required, optical genome mapping. In silico modeling of novel SVs was performed to predict the formation of neo-TADs and whether ectopic contacts between the retinal enhancers and the GDPD1-promoter could be formed.
Results: Using this workflow, potential RP17-SVs were detected in eight probands of which seven were confirmed. Two novel SVs were identified that are predicted to cause TAD rearrangement and retinal enhancer-GDPD1 contact, one from Germany (DE-SV9) and three with the same SV from the United States (US-SV10). Previously reported RP17-SVs were also identified in three Australian probands, one with UK-SV2 and two with SA-SV3.
Discussion: In summary, we describe a validated multi-step pipeline for reliable and efficient RP17-SV discovery and expand the range of disease-associated SVs. Based on these data, RP17-SVs can be considered a frequent cause of adRP which warrants the inclusion of RP17-screening as a standard diagnostic test for this disease.
Frontiers in GeneticsBiochemistry, Genetics and Molecular Biology-Molecular Medicine
CiteScore
5.50
自引率
8.10%
发文量
3491
审稿时长
14 weeks
期刊介绍:
Frontiers in Genetics publishes rigorously peer-reviewed research on genes and genomes relating to all the domains of life, from humans to plants to livestock and other model organisms. Led by an outstanding Editorial Board of the world’s leading experts, this multidisciplinary, open-access journal is at the forefront of communicating cutting-edge research to researchers, academics, clinicians, policy makers and the public.
The study of inheritance and the impact of the genome on various biological processes is well documented. However, the majority of discoveries are still to come. A new era is seeing major developments in the function and variability of the genome, the use of genetic and genomic tools and the analysis of the genetic basis of various biological phenomena.