De novo variants in the PABP domain of PABPC1 lead to developmental delay

Meret Wegler; Xiangbin Jia; Marielle Alders; Arjan Bouman; Jia Chen; Xinyu Duan; Julie L. Lauzon; Inge B. Mathijssen; Heinrich Sticht; Steffen Syrbe; Senwei Tan; Hui Guo; Rami Abou Jamra

doi:https://doi.org/10.1016/j.gim.2022.04.013

De novo variants in the PABP domain of PABPC1 lead to developmental delay

Meret Wegler, Xiangbin Jia, Marielle Alders, Arjan Bouman, Jia Chen, Xinyu Duan, Julie L. Lauzon, Inge B. Mathijssen, Heinrich Sticht, Steffen Syrbe, Senwei Tan, Hui Guo, Rami Abou Jamra

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

2 Citations (Scopus)

Abstract

Purpose: The study aimed to investigate the role of PABPC1 in developmental delay (DD). Methods: Children were examined by geneticists and pediatricians. Variants were identified using exome sequencing and standard downstream bioinformatics pipelines. We performed in silico molecular modeling and coimmunoprecipitation to test if the variants affect the interaction between PABPC1 and PAIP2. We performed in utero electroporation of mouse embryo brains to enlighten the function of PABPC1. Results: We describe 4 probands with an overlapping phenotype of DD, expressive speech delay, and autistic features and heterozygous de novo variants that cluster in the PABP domain of PABPC1. Further symptoms were seizures and behavioral disorders. Molecular modeling predicted that the variants are pathogenic and would lead to decreased binding affinity to messenger RNA metabolism-related proteins, such as PAIP2. Coimmunoprecipitation confirmed this because it showed a significant weakening of the interaction between mutant PABPC1 and PAIP2. Electroporation of mouse embryo brains showed that Pabpc1 knockdown decreases the proliferation of neural progenitor cells. Wild-type Pabpc1 could rescue this disturbance, whereas 3 of the 4 variants did not. Conclusion: Pathogenic variants in the PABP domain lead to DD, possibly because of interference with the translation initiation and subsequently an impaired neurogenesis in cortical development.

Original language	English
Pages (from-to)	1761-1773
Number of pages	13
Journal	Genetics in medicine
Volume	24
Issue number	8
Early online date	2022
DOIs	https://doi.org/10.1016/j.gim.2022.04.013
Publication status	Published - Aug 2022

Keywords

Epilepsy
Exome
Intellectual disability
Neural progenitor cells
Neurodevelopmental disorder

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https://doi.org/10.1016/j.gim.2022.04.013

Cite this

@article{f73a38dfef464c8ab9588959afa3eef2,

title = "De novo variants in the PABP domain of PABPC1 lead to developmental delay",

abstract = "Purpose: The study aimed to investigate the role of PABPC1 in developmental delay (DD). Methods: Children were examined by geneticists and pediatricians. Variants were identified using exome sequencing and standard downstream bioinformatics pipelines. We performed in silico molecular modeling and coimmunoprecipitation to test if the variants affect the interaction between PABPC1 and PAIP2. We performed in utero electroporation of mouse embryo brains to enlighten the function of PABPC1. Results: We describe 4 probands with an overlapping phenotype of DD, expressive speech delay, and autistic features and heterozygous de novo variants that cluster in the PABP domain of PABPC1. Further symptoms were seizures and behavioral disorders. Molecular modeling predicted that the variants are pathogenic and would lead to decreased binding affinity to messenger RNA metabolism-related proteins, such as PAIP2. Coimmunoprecipitation confirmed this because it showed a significant weakening of the interaction between mutant PABPC1 and PAIP2. Electroporation of mouse embryo brains showed that Pabpc1 knockdown decreases the proliferation of neural progenitor cells. Wild-type Pabpc1 could rescue this disturbance, whereas 3 of the 4 variants did not. Conclusion: Pathogenic variants in the PABP domain lead to DD, possibly because of interference with the translation initiation and subsequently an impaired neurogenesis in cortical development.",

keywords = "Epilepsy, Exome, Intellectual disability, Neural progenitor cells, Neurodevelopmental disorder",

author = "Meret Wegler and Xiangbin Jia and Marielle Alders and Arjan Bouman and Jia Chen and Xinyu Duan and Lauzon, {Julie L.} and Mathijssen, {Inge B.} and Heinrich Sticht and Steffen Syrbe and Senwei Tan and Hui Guo and {Abou Jamra}, Rami",

note = "Funding Information: The authors would like to thank the families for their support and consent to publish this study. This work was supported by doctoral scholarship from the Faculty of Medicine at the University of Leipzig , the National Natural Science Foundation of China (81871079), and the grants from Hunan Provincial Government (2019RS2005, 2021jj10070) to H.G. H.G. was also supported by the Innovation-Driven Project of Central South University (2020CX042). S.S. received funding from the Dietmar Hopp Stiftung (grant 23011236). This work was partially supported by the High Performance Computing Center of Central South University. Funding Information: The authors would like to thank the families for their support and consent to publish this study. This work was supported by doctoral scholarship from the Faculty of Medicine at the University of Leipzig, the National Natural Science Foundation of China (81871079), and the grants from Hunan Provincial Government (2019RS2005, 2021jj10070) to H.G. H.G. was also supported by the Innovation-Driven Project of Central South University (2020CX042). S.S. received funding from the Dietmar Hopp Stiftung (grant 23011236). This work was partially supported by the High Performance Computing Center of Central South University. Conceptualization: M.W. X.J. R.A.J. H.G.; Data Curation: M.W. X.J. R.A.J. H.G.; Formal Analysis: M.W. X.J. R.A.J. H.G. H.S. S.T. X.D. J.C.; Investigation: A.B. S.S. J.L.L. I.B.M. M.A. H.S. S.T. X.D. J.C.; Resources: M.W. R.A.J, A.B, S.S. J.L.L. I.B.M. M.A.; Visualization: H.S. X.J. M.W.; Supervision: H.G. R.A.J.; Writing-original draft: M.W. X.J. R.A.J. H.G; Writing-review and editing: A.B. S.S. J.L.L. I.B.M. M.A. H.S. S.T. X.D. J.C. All probands were clinically examined by experienced pediatricians and/or human geneticists and were enrolled and sampled according to standard local practice in approved human subjects{\textquoteright} protocols as part of routine clinical care at the respective institutes. The project was approved by the ethics committee of the University of Leipzig, Germany (224/16-ek and 402/16-ek) and was conducted in concordance to the Declaration of Helsinki. Written informed consent of all examined probands or their legal representatives was obtained for the publication of findings and photos after advice and informing about the risks and benefits of the study. University of Washington. CADD v1.4. Accessed October 25, 2021. http://cadd.gs.washington.edu/, National Center for Biotechnology Information. Index of /pub/clinvar/vcf_GRCh38. Accessed October 25, 2021. https://ftp.ncbi.nlm.nih.gov/pub/clinvar/vcf_GRCh38/, Wellcome Sanger Institute. DECIPHER. Accessed October 25, 2021. https://decipher.sanger.ac.uk/, BHCMG Centers for Mendelian Genomics. GeneMatcher, Accessed November 1, 2021. https://genematcher.org/, Broad Institute of MIT and Harvard. gnomAD genome 3.0. Accessed November 01, 2021. http://gnomad.broadinstitute.org/downloads, Broad Institute of MIT and Harvard. GTEx v8. Accessed October 25, 2021. https://www.gtexportal.org/home/datasets, Radboudumc. MetaDome version 1.0.1. Accessed October 25, 2021. https://stuart.radboudumc.nl/metadome, Computational Biology Center, Memorial Sloan Kettering Cancer Center. MutationAssessor release 3. Accessed November 01, 2021. http://mutationassessor.org/, Berlin Institute of Health. MutationTaster 2, Accessed 2015. http://www.mutationtaster.org/, Johns Hopkins University. OMIM, Accessed October 25, 2021. https://omim.org/, String Consortium. STRING database. Accessed October 25, 2021. https://www.string-db.org/, National Library of Medicine. The National Center for Biotechnology Information (NCBI), Accessed October 25, 2021. https://www.ncbi.nlm.nih.gov/, University of California. UCSC Cell Browser (human cerebral cortex) v1.1.1. Accessed October 25, 2021. https://cells.ucsc.edu/, UniProt Consortium. UniProt database, Release 01.2019. Accessed October 25, 2021. https://www.uniprot.org/, Ensemble. Variant Effect Predictor (VEP) from ENSEMBL Release 104. Accessed November 01, 2021. https://www.ensembl.org/, University of Leipzig. WebAutoCasC version 1.0.1. Accessed October 25, 2021. https://autocasc.uni-leipzig.de/ Publisher Copyright: {\textcopyright} 2022 American College of Medical Genetics and Genomics",

year = "2022",

month = aug,

doi = "https://doi.org/10.1016/j.gim.2022.04.013",

language = "English",

volume = "24",

pages = "1761--1773",

journal = "Genetics in medicine",

issn = "1098-3600",

publisher = "Lippincott Williams and Wilkins",

number = "8",

}

TY - JOUR

T1 - De novo variants in the PABP domain of PABPC1 lead to developmental delay

AU - Wegler, Meret

AU - Jia, Xiangbin

AU - Alders, Marielle

AU - Bouman, Arjan

AU - Chen, Jia

AU - Duan, Xinyu

AU - Lauzon, Julie L.

AU - Mathijssen, Inge B.

AU - Sticht, Heinrich

AU - Syrbe, Steffen

AU - Tan, Senwei

AU - Guo, Hui

AU - Abou Jamra, Rami

N1 - Funding Information: The authors would like to thank the families for their support and consent to publish this study. This work was supported by doctoral scholarship from the Faculty of Medicine at the University of Leipzig , the National Natural Science Foundation of China (81871079), and the grants from Hunan Provincial Government (2019RS2005, 2021jj10070) to H.G. H.G. was also supported by the Innovation-Driven Project of Central South University (2020CX042). S.S. received funding from the Dietmar Hopp Stiftung (grant 23011236). This work was partially supported by the High Performance Computing Center of Central South University. Funding Information: The authors would like to thank the families for their support and consent to publish this study. This work was supported by doctoral scholarship from the Faculty of Medicine at the University of Leipzig, the National Natural Science Foundation of China (81871079), and the grants from Hunan Provincial Government (2019RS2005, 2021jj10070) to H.G. H.G. was also supported by the Innovation-Driven Project of Central South University (2020CX042). S.S. received funding from the Dietmar Hopp Stiftung (grant 23011236). This work was partially supported by the High Performance Computing Center of Central South University. Conceptualization: M.W. X.J. R.A.J. H.G.; Data Curation: M.W. X.J. R.A.J. H.G.; Formal Analysis: M.W. X.J. R.A.J. H.G. H.S. S.T. X.D. J.C.; Investigation: A.B. S.S. J.L.L. I.B.M. M.A. H.S. S.T. X.D. J.C.; Resources: M.W. R.A.J, A.B, S.S. J.L.L. I.B.M. M.A.; Visualization: H.S. X.J. M.W.; Supervision: H.G. R.A.J.; Writing-original draft: M.W. X.J. R.A.J. H.G; Writing-review and editing: A.B. S.S. J.L.L. I.B.M. M.A. H.S. S.T. X.D. J.C. All probands were clinically examined by experienced pediatricians and/or human geneticists and were enrolled and sampled according to standard local practice in approved human subjects’ protocols as part of routine clinical care at the respective institutes. The project was approved by the ethics committee of the University of Leipzig, Germany (224/16-ek and 402/16-ek) and was conducted in concordance to the Declaration of Helsinki. Written informed consent of all examined probands or their legal representatives was obtained for the publication of findings and photos after advice and informing about the risks and benefits of the study. University of Washington. CADD v1.4. Accessed October 25, 2021. http://cadd.gs.washington.edu/, National Center for Biotechnology Information. Index of /pub/clinvar/vcf_GRCh38. Accessed October 25, 2021. https://ftp.ncbi.nlm.nih.gov/pub/clinvar/vcf_GRCh38/, Wellcome Sanger Institute. DECIPHER. Accessed October 25, 2021. https://decipher.sanger.ac.uk/, BHCMG Centers for Mendelian Genomics. GeneMatcher, Accessed November 1, 2021. https://genematcher.org/, Broad Institute of MIT and Harvard. gnomAD genome 3.0. Accessed November 01, 2021. http://gnomad.broadinstitute.org/downloads, Broad Institute of MIT and Harvard. GTEx v8. Accessed October 25, 2021. https://www.gtexportal.org/home/datasets, Radboudumc. MetaDome version 1.0.1. Accessed October 25, 2021. https://stuart.radboudumc.nl/metadome, Computational Biology Center, Memorial Sloan Kettering Cancer Center. MutationAssessor release 3. Accessed November 01, 2021. http://mutationassessor.org/, Berlin Institute of Health. MutationTaster 2, Accessed 2015. http://www.mutationtaster.org/, Johns Hopkins University. OMIM, Accessed October 25, 2021. https://omim.org/, String Consortium. STRING database. Accessed October 25, 2021. https://www.string-db.org/, National Library of Medicine. The National Center for Biotechnology Information (NCBI), Accessed October 25, 2021. https://www.ncbi.nlm.nih.gov/, University of California. UCSC Cell Browser (human cerebral cortex) v1.1.1. Accessed October 25, 2021. https://cells.ucsc.edu/, UniProt Consortium. UniProt database, Release 01.2019. Accessed October 25, 2021. https://www.uniprot.org/, Ensemble. Variant Effect Predictor (VEP) from ENSEMBL Release 104. Accessed November 01, 2021. https://www.ensembl.org/, University of Leipzig. WebAutoCasC version 1.0.1. Accessed October 25, 2021. https://autocasc.uni-leipzig.de/ Publisher Copyright: © 2022 American College of Medical Genetics and Genomics

PY - 2022/8

Y1 - 2022/8

N2 - Purpose: The study aimed to investigate the role of PABPC1 in developmental delay (DD). Methods: Children were examined by geneticists and pediatricians. Variants were identified using exome sequencing and standard downstream bioinformatics pipelines. We performed in silico molecular modeling and coimmunoprecipitation to test if the variants affect the interaction between PABPC1 and PAIP2. We performed in utero electroporation of mouse embryo brains to enlighten the function of PABPC1. Results: We describe 4 probands with an overlapping phenotype of DD, expressive speech delay, and autistic features and heterozygous de novo variants that cluster in the PABP domain of PABPC1. Further symptoms were seizures and behavioral disorders. Molecular modeling predicted that the variants are pathogenic and would lead to decreased binding affinity to messenger RNA metabolism-related proteins, such as PAIP2. Coimmunoprecipitation confirmed this because it showed a significant weakening of the interaction between mutant PABPC1 and PAIP2. Electroporation of mouse embryo brains showed that Pabpc1 knockdown decreases the proliferation of neural progenitor cells. Wild-type Pabpc1 could rescue this disturbance, whereas 3 of the 4 variants did not. Conclusion: Pathogenic variants in the PABP domain lead to DD, possibly because of interference with the translation initiation and subsequently an impaired neurogenesis in cortical development.

AB - Purpose: The study aimed to investigate the role of PABPC1 in developmental delay (DD). Methods: Children were examined by geneticists and pediatricians. Variants were identified using exome sequencing and standard downstream bioinformatics pipelines. We performed in silico molecular modeling and coimmunoprecipitation to test if the variants affect the interaction between PABPC1 and PAIP2. We performed in utero electroporation of mouse embryo brains to enlighten the function of PABPC1. Results: We describe 4 probands with an overlapping phenotype of DD, expressive speech delay, and autistic features and heterozygous de novo variants that cluster in the PABP domain of PABPC1. Further symptoms were seizures and behavioral disorders. Molecular modeling predicted that the variants are pathogenic and would lead to decreased binding affinity to messenger RNA metabolism-related proteins, such as PAIP2. Coimmunoprecipitation confirmed this because it showed a significant weakening of the interaction between mutant PABPC1 and PAIP2. Electroporation of mouse embryo brains showed that Pabpc1 knockdown decreases the proliferation of neural progenitor cells. Wild-type Pabpc1 could rescue this disturbance, whereas 3 of the 4 variants did not. Conclusion: Pathogenic variants in the PABP domain lead to DD, possibly because of interference with the translation initiation and subsequently an impaired neurogenesis in cortical development.

KW - Epilepsy

KW - Exome

KW - Intellectual disability

KW - Neural progenitor cells

KW - Neurodevelopmental disorder

UR - http://www.scopus.com/inward/record.url?scp=85129776878&partnerID=8YFLogxK

U2 - https://doi.org/10.1016/j.gim.2022.04.013

DO - https://doi.org/10.1016/j.gim.2022.04.013

M3 - Article

C2 - 35511136

SN - 1098-3600

VL - 24

SP - 1761

EP - 1773

JO - Genetics in medicine

JF - Genetics in medicine

IS - 8

ER -

De novo variants in the PABP domain of PABPC1 lead to developmental delay

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Keywords

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