Systems biology analysis of human genomes points to key pathways conferring spina bifida risk

Vanessa Aguiar-Pulido; Paul Wolujewicz; Alexander Martinez-Fundichely; Eran Elhaik; Gaurav Thareja; Alice Abdel Aleem; Nader Chalhoub; Tawny Cuykendall; Jamel Al-Zamer; Yunping Lei; Haitham El-Bashir; James M. Musser; Abdulla Al-Kaabi; Gary M. Shaw; Ekta Khurana; Karsten Suhre; Christopher E. Mason; Olivier Elemento; Richard H. Finnell; M. Elizabeth Ross

doi:10.1073/pnas.2106844118

Systems biology analysis of human genomes points to key pathways conferring spina bifida risk

Vanessa Aguiar-Pulido, Paul Wolujewicz, Alexander Martinez-Fundichely, Eran Elhaik, Gaurav Thareja, Alice Abdel Aleem, Nader Chalhoub, Tawny Cuykendall, Jamel Al-Zamer, Yunping Lei, Haitham El-Bashir, James M. Musser, Abdulla Al-Kaabi, Gary M. Shaw, Ekta Khurana, Karsten Suhre, Christopher E. Mason, Olivier Elemento, Richard H. Finnell, M. Elizabeth Ross

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6 Scopus citations

Abstract

Spina bifida (SB) is a debilitating birth defect caused by multiple gene and environment interactions. Though SB shows non-Mendelian inheritance, genetic factors contribute to an estimated 70% of cases. Nevertheless, identifying human mutations conferring SB risk is challenging due to its relative rarity, genetic heterogeneity, incomplete penetrance, and environmental influences that hamper genome-wide association studies approaches to untargeted discovery. Thus, SB genetic studies may suffer from population substructure and/or selection bias introduced by typical candidate gene searches. We report a population based, ancestry-matched whole-genome sequence analysis of SB genetic predisposition using a systems biology strategy to interrogate 298 case-control subject genomes (149 pairs). Genes that were enriched in likely gene disrupting (LGD), rare protein-coding variants were subjected to machine learning analysis to identify genes in which LGD variants occur with a different frequency in cases versus controls and so discriminate between these groups. Those genes with high discriminatory potential for SB significantly enriched pathways pertaining to carbon metabolism, inflammation, innate immunity, cytoskeletal regulation, and essential transcriptional regulation consistent with their having impact on the pathogenesis of human SB. Additionally, an interrogation of conserved noncoding sequences identified robust variant enrichment in regulatory regions of several transcription factors critical to embryonic development. This genome-wide perspective offers an effective approach to the interrogation of coding and noncoding sequence variant contributions to rare complex genetic disorders.

Original language	English (US)
Article number	e2106844118
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	118
Issue number	51
DOIs	https://doi.org/10.1073/pnas.2106844118
State	Published - Dec 21 2021

Keywords

Myelomeningocele
Neural tube defects
Pathway analysis
Rare variant enrichment
Whole-genome sequence

ASJC Scopus subject areas

General

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10.1073/pnas.2106844118

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Aguiar-Pulido, V., Wolujewicz, P., Martinez-Fundichely, A., Elhaik, E., Thareja, G., Aleem, A. A., Chalhoub, N., Cuykendall, T., Al-Zamer, J., Lei, Y., El-Bashir, H., Musser, J. M., Al-Kaabi, A., Shaw, G. M., Khurana, E., Suhre, K., Mason, C. E., Elemento, O., Finnell, R. H., & Elizabeth Ross, M. (2021). Systems biology analysis of human genomes points to key pathways conferring spina bifida risk. Proceedings of the National Academy of Sciences of the United States of America, 118(51), Article e2106844118. https://doi.org/10.1073/pnas.2106844118

Systems biology analysis of human genomes points to key pathways conferring spina bifida risk. / Aguiar-Pulido, Vanessa; Wolujewicz, Paul; Martinez-Fundichely, Alexander et al.
In: Proceedings of the National Academy of Sciences of the United States of America, Vol. 118, No. 51, e2106844118, 21.12.2021.

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

Aguiar-Pulido, V, Wolujewicz, P, Martinez-Fundichely, A, Elhaik, E, Thareja, G, Aleem, AA, Chalhoub, N, Cuykendall, T, Al-Zamer, J, Lei, Y, El-Bashir, H, Musser, JM, Al-Kaabi, A, Shaw, GM, Khurana, E, Suhre, K, Mason, CE, Elemento, O, Finnell, RH & Elizabeth Ross, M 2021, 'Systems biology analysis of human genomes points to key pathways conferring spina bifida risk', Proceedings of the National Academy of Sciences of the United States of America, vol. 118, no. 51, e2106844118. https://doi.org/10.1073/pnas.2106844118

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title = "Systems biology analysis of human genomes points to key pathways conferring spina bifida risk",

abstract = "Spina bifida (SB) is a debilitating birth defect caused by multiple gene and environment interactions. Though SB shows non-Mendelian inheritance, genetic factors contribute to an estimated 70% of cases. Nevertheless, identifying human mutations conferring SB risk is challenging due to its relative rarity, genetic heterogeneity, incomplete penetrance, and environmental influences that hamper genome-wide association studies approaches to untargeted discovery. Thus, SB genetic studies may suffer from population substructure and/or selection bias introduced by typical candidate gene searches. We report a population based, ancestry-matched whole-genome sequence analysis of SB genetic predisposition using a systems biology strategy to interrogate 298 case-control subject genomes (149 pairs). Genes that were enriched in likely gene disrupting (LGD), rare protein-coding variants were subjected to machine learning analysis to identify genes in which LGD variants occur with a different frequency in cases versus controls and so discriminate between these groups. Those genes with high discriminatory potential for SB significantly enriched pathways pertaining to carbon metabolism, inflammation, innate immunity, cytoskeletal regulation, and essential transcriptional regulation consistent with their having impact on the pathogenesis of human SB. Additionally, an interrogation of conserved noncoding sequences identified robust variant enrichment in regulatory regions of several transcription factors critical to embryonic development. This genome-wide perspective offers an effective approach to the interrogation of coding and noncoding sequence variant contributions to rare complex genetic disorders.",

keywords = "Myelomeningocele, Neural tube defects, Pathway analysis, Rare variant enrichment, Whole-genome sequence",

author = "Vanessa Aguiar-Pulido and Paul Wolujewicz and Alexander Martinez-Fundichely and Eran Elhaik and Gaurav Thareja and Aleem, {Alice Abdel} and Nader Chalhoub and Tawny Cuykendall and Jamel Al-Zamer and Yunping Lei and Haitham El-Bashir and Musser, {James M.} and Abdulla Al-Kaabi and Shaw, {Gary M.} and Ekta Khurana and Karsten Suhre and Mason, {Christopher E.} and Olivier Elemento and Finnell, {Richard H.} and {Elizabeth Ross}, M.",

note = "Funding Information: ACKNOWLEDGMENTS. We thank Ms. Amira Assad, Project Coordinator at Weill Cornell Medicine-Qatar, for invaluable efforts toward patient enrollment. We thank the California Department of Public Health Maternal Child and Adolescent Health Division for providing data. The findings and conclusions herein are ours and do not necessarily represent the official position of the California Department of Public Health. This project was supported by the NIH (Grants P01HD067244, R01NS076465, R01HD081216, and T32HD060600) and the Qatar Foundation (Grant NPRP4-149-3-049; the Biomedical Research Program at Weill Cornell Medicine-Qatar). Publisher Copyright: {\textcopyright} 2021 National Academy of Sciences. All rights reserved.",

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doi = "10.1073/pnas.2106844118",

language = "English (US)",

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T1 - Systems biology analysis of human genomes points to key pathways conferring spina bifida risk

AU - Aguiar-Pulido, Vanessa

AU - Wolujewicz, Paul

AU - Martinez-Fundichely, Alexander

AU - Elhaik, Eran

AU - Thareja, Gaurav

AU - Aleem, Alice Abdel

AU - Chalhoub, Nader

AU - Cuykendall, Tawny

AU - Al-Zamer, Jamel

AU - Lei, Yunping

AU - El-Bashir, Haitham

AU - Musser, James M.

AU - Al-Kaabi, Abdulla

AU - Shaw, Gary M.

AU - Khurana, Ekta

AU - Suhre, Karsten

AU - Mason, Christopher E.

AU - Elemento, Olivier

AU - Finnell, Richard H.

AU - Elizabeth Ross, M.

N1 - Funding Information: ACKNOWLEDGMENTS. We thank Ms. Amira Assad, Project Coordinator at Weill Cornell Medicine-Qatar, for invaluable efforts toward patient enrollment. We thank the California Department of Public Health Maternal Child and Adolescent Health Division for providing data. The findings and conclusions herein are ours and do not necessarily represent the official position of the California Department of Public Health. This project was supported by the NIH (Grants P01HD067244, R01NS076465, R01HD081216, and T32HD060600) and the Qatar Foundation (Grant NPRP4-149-3-049; the Biomedical Research Program at Weill Cornell Medicine-Qatar). Publisher Copyright: © 2021 National Academy of Sciences. All rights reserved.

PY - 2021/12/21

Y1 - 2021/12/21

N2 - Spina bifida (SB) is a debilitating birth defect caused by multiple gene and environment interactions. Though SB shows non-Mendelian inheritance, genetic factors contribute to an estimated 70% of cases. Nevertheless, identifying human mutations conferring SB risk is challenging due to its relative rarity, genetic heterogeneity, incomplete penetrance, and environmental influences that hamper genome-wide association studies approaches to untargeted discovery. Thus, SB genetic studies may suffer from population substructure and/or selection bias introduced by typical candidate gene searches. We report a population based, ancestry-matched whole-genome sequence analysis of SB genetic predisposition using a systems biology strategy to interrogate 298 case-control subject genomes (149 pairs). Genes that were enriched in likely gene disrupting (LGD), rare protein-coding variants were subjected to machine learning analysis to identify genes in which LGD variants occur with a different frequency in cases versus controls and so discriminate between these groups. Those genes with high discriminatory potential for SB significantly enriched pathways pertaining to carbon metabolism, inflammation, innate immunity, cytoskeletal regulation, and essential transcriptional regulation consistent with their having impact on the pathogenesis of human SB. Additionally, an interrogation of conserved noncoding sequences identified robust variant enrichment in regulatory regions of several transcription factors critical to embryonic development. This genome-wide perspective offers an effective approach to the interrogation of coding and noncoding sequence variant contributions to rare complex genetic disorders.

AB - Spina bifida (SB) is a debilitating birth defect caused by multiple gene and environment interactions. Though SB shows non-Mendelian inheritance, genetic factors contribute to an estimated 70% of cases. Nevertheless, identifying human mutations conferring SB risk is challenging due to its relative rarity, genetic heterogeneity, incomplete penetrance, and environmental influences that hamper genome-wide association studies approaches to untargeted discovery. Thus, SB genetic studies may suffer from population substructure and/or selection bias introduced by typical candidate gene searches. We report a population based, ancestry-matched whole-genome sequence analysis of SB genetic predisposition using a systems biology strategy to interrogate 298 case-control subject genomes (149 pairs). Genes that were enriched in likely gene disrupting (LGD), rare protein-coding variants were subjected to machine learning analysis to identify genes in which LGD variants occur with a different frequency in cases versus controls and so discriminate between these groups. Those genes with high discriminatory potential for SB significantly enriched pathways pertaining to carbon metabolism, inflammation, innate immunity, cytoskeletal regulation, and essential transcriptional regulation consistent with their having impact on the pathogenesis of human SB. Additionally, an interrogation of conserved noncoding sequences identified robust variant enrichment in regulatory regions of several transcription factors critical to embryonic development. This genome-wide perspective offers an effective approach to the interrogation of coding and noncoding sequence variant contributions to rare complex genetic disorders.

KW - Myelomeningocele

KW - Neural tube defects

KW - Pathway analysis

KW - Rare variant enrichment

KW - Whole-genome sequence

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Systems biology analysis of human genomes points to key pathways conferring spina bifida risk

Abstract

Keywords

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