Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach

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

Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach

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

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

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.

Original language	English
Article number	1469686
Journal	Frontiers in Genetics
Volume	15
DOIs	https://doi.org/10.3389/fgene.2024.1469686
Publication status	Published - 2024
Externally published	Yes

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de Bruijn, S. E., Panneman, D. M., Weisschuh, N., Cadena, E. L., Boonen, E. G. M., Holtes, L. K., Astuti, G. D. N., Cremers, F. P. M., Leijsten, N., Corominas, J., Gilissen, C., Skowronska, A., Woodley, J., Beggs, A. D., Toulis, V., Chen, D., Cheetham, M. E., Hardcastle, A. J., McLaren, T. L., ... Roosing, S. (2024). Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach. Frontiers in Genetics, 15, Article 1469686. https://doi.org/10.3389/fgene.2024.1469686

@article{d3d59893a53341b39ad7b4d2cf7b4e7c,

title = "Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach",

abstract = "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.",

author = "\{de Bruijn\}, \{Suzanne E\} and Panneman, \{Daan M\} and Nicole Weisschuh and Cadena, \{Elizabeth L\} and Boonen, \{Erica G M\} and Holtes, \{Lara K\} and Astuti, \{Galuh D N\} and Cremers, \{Frans P M\} and Nico Leijsten and Jordi Corominas and Christian Gilissen and Anna Skowronska and Jessica Woodley and Beggs, \{Andrew D\} and Vasileios Toulis and Di Chen and Cheetham, \{Michael E\} and Hardcastle, \{Alison J\} and McLaren, \{Terri L\} and Lamey, \{Tina M\} and Thompson, \{Jennifer A\} and Chen, \{Fred K\} and \{de Roach\}, \{John N\} and Urwin, \{Isabella R\} and Sullivan, \{Lori S\} and Susanne Roosing",

note = "Publisher Copyright: Copyright {\textcopyright} 2024 de Bruijn, Panneman, Weisschuh, Cadena, Boonen, Holtes, Astuti, Cremers, Leijsten, Corominas, Gilissen, Skowronska, Woodley, Beggs, Toulis, Chen, Cheetham, Hardcastle, McLaren, Lamey, Thompson, Chen, de Roach, Urwin, Sullivan, Roosing.",

year = "2024",

doi = "10.3389/fgene.2024.1469686",

language = "English",

volume = "15",

journal = "Frontiers in Genetics",

issn = "1664-8021",

publisher = "Frontiers Media S. A.",

}

de Bruijn, SE, Panneman, DM, Weisschuh, N, Cadena, EL, Boonen, EGM, Holtes, LK, Astuti, GDN, Cremers, FPM, Leijsten, N, Corominas, J, Gilissen, C, Skowronska, A, Woodley, J, Beggs, AD, Toulis, V, Chen, D, Cheetham, ME, Hardcastle, AJ, McLaren, TL, Lamey, TM, Thompson, JA, Chen, FK, de Roach, JN, Urwin, IR, Sullivan, LS & Roosing, S 2024, 'Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach', Frontiers in Genetics, vol. 15, 1469686. https://doi.org/10.3389/fgene.2024.1469686

TY - JOUR

T1 - Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach

AU - de Bruijn, Suzanne E

AU - Panneman, Daan M

AU - Weisschuh, Nicole

AU - Cadena, Elizabeth L

AU - Boonen, Erica G M

AU - Holtes, Lara K

AU - Astuti, Galuh D N

AU - Cremers, Frans P M

AU - Leijsten, Nico

AU - Corominas, Jordi

AU - Gilissen, Christian

AU - Skowronska, Anna

AU - Woodley, Jessica

AU - Beggs, Andrew D

AU - Toulis, Vasileios

AU - Chen, Di

AU - Cheetham, Michael E

AU - Hardcastle, Alison J

AU - McLaren, Terri L

AU - Lamey, Tina M

AU - Thompson, Jennifer A

AU - Chen, Fred K

AU - de Roach, John N

AU - Urwin, Isabella R

AU - Sullivan, Lori S

AU - Roosing, Susanne

N1 - Publisher Copyright: Copyright © 2024 de Bruijn, Panneman, Weisschuh, Cadena, Boonen, Holtes, Astuti, Cremers, Leijsten, Corominas, Gilissen, Skowronska, Woodley, Beggs, Toulis, Chen, Cheetham, Hardcastle, McLaren, Lamey, Thompson, Chen, de Roach, Urwin, Sullivan, Roosing.

PY - 2024

Y1 - 2024

N2 - 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.

AB - 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.

U2 - 10.3389/fgene.2024.1469686

DO - 10.3389/fgene.2024.1469686

M3 - Article

C2 - 39507620

SN - 1664-8021

VL - 15

JO - Frontiers in Genetics

JF - Frontiers in Genetics

M1 - 1469686

ER -

Identification of novel 3D-genome altering and complex structural variants underlying retinitis pigmentosa type 17 through a multistep and high-throughput approach

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