Comparative analysis of in-silico tools in identifying pathogenic variants in dominant inherited retinal diseases

Daniel C. Brock; Meng Wang; Hafiz Muhammad Jafar Hussain; David E. Rauch; Molly Marra; Mark E. Pennesi; Paul Yang; Lesley Everett; Radwan S. Ajlan; Jason Colbert; Fernanda Belga Ottoni Porto; Anna Matynia; Michael B. Gorin; Robert K. Koenekoop; Irma Lopez; Ruifang Sui; Gang Zou; Yumei Li; Rui Chen

doi:10.1093/hmg/ddae028

Comparative analysis of in-silico tools in identifying pathogenic variants in dominant inherited retinal diseases

Daniel C. Brock, Meng Wang, Hafiz Muhammad Jafar Hussain, David E. Rauch, Molly Marra, Mark E. Pennesi, Paul Yang, Lesley Everett, Radwan S. Ajlan, Jason Colbert, Fernanda Belga Ottoni Porto, Anna Matynia, Michael B. Gorin, Robert K. Koenekoop, Irma Lopez, Ruifang Sui, Gang Zou, Yumei Li, Rui Chen

Ophthalmology

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

2 Scopus citations

Abstract

Inherited retinal diseases (IRDs) are a group of rare genetic eye conditions that cause blindness. Despite progress in identifying genes associated with IRDs, improvements are necessary for classifying rare autosomal dominant (AD) disorders. AD diseases are highly heterogenous, with causal variants being restricted to specific amino acid changes within certain protein domains, making AD conditions difficult to classify. Here, we aim to determine the top-performing in-silico tools for predicting the pathogenicity of AD IRD variants. We annotated variants from ClinVar and benchmarked 39 variant classifier tools on IRD genes, split by inheritance pattern. Using area-under-the-curve (AUC) analysis, we determined the top-performing tools and defined thresholds for variant pathogenicity. Top-performing tools were assessed using genome sequencing on a cohort of participants with IRDs of unknown etiology. MutScore achieved the highest accuracy within AD genes, yielding an AUC of 0.969. When filtering for AD gain-of-function and dominant negative variants, BayesDel had the highest accuracy with an AUC of 0.997. Five participants with variants in NR2E3, RHO, GUCA1A, and GUCY2D were confirmed to have dominantly inherited disease based on pedigree, phenotype, and segregation analysis. We identified two uncharacterized variants in GUCA1A (c.428T>A, p.Ile143Thr) and RHO (c.631C>G, p.His211Asp) in three participants. Our findings support using a multi-classifier approach comprised of new missense classifier tools to identify pathogenic variants in participants with AD IRDs. Our results provide a foundation for improved genetic diagnosis for people with IRDs.

Original language	English (US)
Pages (from-to)	945-957
Number of pages	13
Journal	Human molecular genetics
Volume	33
Issue number	11
DOIs	https://doi.org/10.1093/hmg/ddae028
State	Published - Jun 1 2024

Keywords

autosomal dominant
genetic diagnosis
inherited retinal diseases
next-generation sequencing
variant classification

ASJC Scopus subject areas

Molecular Biology
Genetics
Genetics(clinical)

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10.1093/hmg/ddae028

Cite this

Brock, D. C., Wang, M., Hussain, H. M. J., Rauch, D. E., Marra, M., Pennesi, M. E., Yang, P., Everett, L., Ajlan, R. S., Colbert, J., Porto, F. B. O., Matynia, A., Gorin, M. B., Koenekoop, R. K., Lopez, I., Sui, R., Zou, G., Li, Y., & Chen, R. (2024). Comparative analysis of in-silico tools in identifying pathogenic variants in dominant inherited retinal diseases. Human molecular genetics, 33(11), 945-957. https://doi.org/10.1093/hmg/ddae028

Brock, DC, Wang, M, Hussain, HMJ, Rauch, DE, Marra, M, Pennesi, ME, Yang, P , Everett, L, Ajlan, RS, Colbert, J, Porto, FBO, Matynia, A, Gorin, MB, Koenekoop, RK, Lopez, I, Sui, R, Zou, G, Li, Y & Chen, R 2024, 'Comparative analysis of in-silico tools in identifying pathogenic variants in dominant inherited retinal diseases', Human molecular genetics, vol. 33, no. 11, pp. 945-957. https://doi.org/10.1093/hmg/ddae028

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title = "Comparative analysis of in-silico tools in identifying pathogenic variants in dominant inherited retinal diseases",

abstract = "Inherited retinal diseases (IRDs) are a group of rare genetic eye conditions that cause blindness. Despite progress in identifying genes associated with IRDs, improvements are necessary for classifying rare autosomal dominant (AD) disorders. AD diseases are highly heterogenous, with causal variants being restricted to specific amino acid changes within certain protein domains, making AD conditions difficult to classify. Here, we aim to determine the top-performing in-silico tools for predicting the pathogenicity of AD IRD variants. We annotated variants from ClinVar and benchmarked 39 variant classifier tools on IRD genes, split by inheritance pattern. Using area-under-the-curve (AUC) analysis, we determined the top-performing tools and defined thresholds for variant pathogenicity. Top-performing tools were assessed using genome sequencing on a cohort of participants with IRDs of unknown etiology. MutScore achieved the highest accuracy within AD genes, yielding an AUC of 0.969. When filtering for AD gain-of-function and dominant negative variants, BayesDel had the highest accuracy with an AUC of 0.997. Five participants with variants in NR2E3, RHO, GUCA1A, and GUCY2D were confirmed to have dominantly inherited disease based on pedigree, phenotype, and segregation analysis. We identified two uncharacterized variants in GUCA1A (c.428T>A, p.Ile143Thr) and RHO (c.631C>G, p.His211Asp) in three participants. Our findings support using a multi-classifier approach comprised of new missense classifier tools to identify pathogenic variants in participants with AD IRDs. Our results provide a foundation for improved genetic diagnosis for people with IRDs.",

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author = "Brock, {Daniel C.} and Meng Wang and Hussain, {Hafiz Muhammad Jafar} and Rauch, {David E.} and Molly Marra and Pennesi, {Mark E.} and Paul Yang and Lesley Everett and Ajlan, {Radwan S.} and Jason Colbert and Porto, {Fernanda Belga Ottoni} and Anna Matynia and Gorin, {Michael B.} and Koenekoop, {Robert K.} and Irma Lopez and Ruifang Sui and Gang Zou and Yumei Li and Rui Chen",

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AU - Brock, Daniel C.

AU - Wang, Meng

AU - Hussain, Hafiz Muhammad Jafar

AU - Rauch, David E.

AU - Marra, Molly

AU - Pennesi, Mark E.

AU - Yang, Paul

AU - Everett, Lesley

AU - Ajlan, Radwan S.

AU - Colbert, Jason

AU - Porto, Fernanda Belga Ottoni

AU - Matynia, Anna

AU - Gorin, Michael B.

AU - Koenekoop, Robert K.

AU - Lopez, Irma

AU - Sui, Ruifang

AU - Zou, Gang

AU - Li, Yumei

AU - Chen, Rui

PY - 2024/6/1

Y1 - 2024/6/1

N2 - Inherited retinal diseases (IRDs) are a group of rare genetic eye conditions that cause blindness. Despite progress in identifying genes associated with IRDs, improvements are necessary for classifying rare autosomal dominant (AD) disorders. AD diseases are highly heterogenous, with causal variants being restricted to specific amino acid changes within certain protein domains, making AD conditions difficult to classify. Here, we aim to determine the top-performing in-silico tools for predicting the pathogenicity of AD IRD variants. We annotated variants from ClinVar and benchmarked 39 variant classifier tools on IRD genes, split by inheritance pattern. Using area-under-the-curve (AUC) analysis, we determined the top-performing tools and defined thresholds for variant pathogenicity. Top-performing tools were assessed using genome sequencing on a cohort of participants with IRDs of unknown etiology. MutScore achieved the highest accuracy within AD genes, yielding an AUC of 0.969. When filtering for AD gain-of-function and dominant negative variants, BayesDel had the highest accuracy with an AUC of 0.997. Five participants with variants in NR2E3, RHO, GUCA1A, and GUCY2D were confirmed to have dominantly inherited disease based on pedigree, phenotype, and segregation analysis. We identified two uncharacterized variants in GUCA1A (c.428T>A, p.Ile143Thr) and RHO (c.631C>G, p.His211Asp) in three participants. Our findings support using a multi-classifier approach comprised of new missense classifier tools to identify pathogenic variants in participants with AD IRDs. Our results provide a foundation for improved genetic diagnosis for people with IRDs.

AB - Inherited retinal diseases (IRDs) are a group of rare genetic eye conditions that cause blindness. Despite progress in identifying genes associated with IRDs, improvements are necessary for classifying rare autosomal dominant (AD) disorders. AD diseases are highly heterogenous, with causal variants being restricted to specific amino acid changes within certain protein domains, making AD conditions difficult to classify. Here, we aim to determine the top-performing in-silico tools for predicting the pathogenicity of AD IRD variants. We annotated variants from ClinVar and benchmarked 39 variant classifier tools on IRD genes, split by inheritance pattern. Using area-under-the-curve (AUC) analysis, we determined the top-performing tools and defined thresholds for variant pathogenicity. Top-performing tools were assessed using genome sequencing on a cohort of participants with IRDs of unknown etiology. MutScore achieved the highest accuracy within AD genes, yielding an AUC of 0.969. When filtering for AD gain-of-function and dominant negative variants, BayesDel had the highest accuracy with an AUC of 0.997. Five participants with variants in NR2E3, RHO, GUCA1A, and GUCY2D were confirmed to have dominantly inherited disease based on pedigree, phenotype, and segregation analysis. We identified two uncharacterized variants in GUCA1A (c.428T>A, p.Ile143Thr) and RHO (c.631C>G, p.His211Asp) in three participants. Our findings support using a multi-classifier approach comprised of new missense classifier tools to identify pathogenic variants in participants with AD IRDs. Our results provide a foundation for improved genetic diagnosis for people with IRDs.

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KW - next-generation sequencing

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Comparative analysis of in-silico tools in identifying pathogenic variants in dominant inherited retinal diseases

Abstract

Keywords

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