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1. Saturation genome editing of BAP1 functionally classifies somatic and germline variants

Author

Waters, Andrew J., Brendler-Spaeth, Timothy, Smith, Danielle, Offord, Victoria, Tan, Hong Kee, Zhao, Yajie, Obolenski, Sofia, Nielsen, Maartje, van Doorn, Remco, Murphy, Jo-Ellen, Gupta, Prashant, Rowlands, Charlie F., Hanson, Helen, Delage, Erwan, Thomas, Mark, Radford, Elizabeth J., Gerety, Sebastian S., Turnbull, Clare, Perry, John R. B., Hurles, Matthew E., and Adams, David J.

Published
2024
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2. Saturation genome editing of DDX3X clarifies pathogenicity of germline and somatic variation

Author

Radford, Elizabeth J., Tan, Hong-Kee, Andersson, Malin H. L., Stephenson, James D., Gardner, Eugene J., Ironfield, Holly, Waters, Andrew J., Gitterman, Daniel, Lindsay, Sarah, Abascal, Federico, Martincorena, Iñigo, Kolesnik-Taylor, Anna, Ng-Cordell, Elise, Firth, Helen V., Baker, Kate, Perry, John R. B., Adams, David J., Gerety, Sebastian S., and Hurles, Matthew E.

Published
2023
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5. Rare loss-of-function variants in SETD1A are associated with schizophrenia and developmental disorders

Author

Singh, Tarjinder, Kurki, Mitja I, Curtis, David, Purcell, Shaun M, Crooks, Lucy, McRae, Jeremy, Suvisaari, Jaana, Chheda, Himanshu, Blackwood, Douglas, Breen, Gerome, Pietiläinen, Olli, Gerety, Sebastian S, Ayub, Muhammad, Blyth, Moira, Cole, Trevor, Collier, David, Coomber, Eve L, Craddock, Nick, Daly, Mark J, Danesh, John, DiForti, Marta, Foster, Alison, Freimer, Nelson B, Geschwind, Daniel, Johnstone, Mandy, Joss, Shelagh, Kirov, Georg, Körkkö, Jarmo, Kuismin, Outi, Holmans, Peter, Hultman, Christina M, Iyegbe, Conrad, Lönnqvist, Jouko, Männikkö, Minna, McCarroll, Steve A, McGuffin, Peter, McIntosh, Andrew M, McQuillin, Andrew, Moilanen, Jukka S, Moore, Carmel, Murray, Robin M, Newbury-Ecob, Ruth, Ouwehand, Willem, Paunio, Tiina, Prigmore, Elena, Rees, Elliott, Roberts, David, Sambrook, Jennifer, Sklar, Pamela, Clair, David St, Veijola, Juha, Walters, James TR, Williams, Hywel, Sullivan, Patrick F, Hurles, Matthew E, O'Donovan, Michael C, Palotie, Aarno, Owen, Michael J, and Barrett, Jeffrey C

Subjects
Biological Psychology, Pharmacology and Pharmaceutical Sciences, Biomedical and Clinical Sciences, Psychology, Genetics, Serious Mental Illness, Human Genome, Schizophrenia, Biotechnology, Brain Disorders, Mental Health, 2.1 Biological and endogenous factors, Aetiology, Mental health, Case-Control Studies, Cohort Studies, Female, Finland, Genetic Association Studies, Genetic Predisposition to Disease, Genetic Variation, Histone-Lysine N-Methyltransferase, Humans, Male, Neurodevelopmental Disorders, Swedish Schizophrenia Study, INTERVAL Study, DDD Study, UK10 K Consortium, Neurosciences, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology
Abstract

By analyzing the whole-exome sequences of 4,264 schizophrenia cases, 9,343 controls and 1,077 trios, we identified a genome-wide significant association between rare loss-of-function (LoF) variants in SETD1A and risk for schizophrenia (P = 3.3 × 10(-9)). We found only two heterozygous LoF variants in 45,376 exomes from individuals without a neuropsychiatric diagnosis, indicating that SETD1A is substantially depleted of LoF variants in the general population. Seven of the ten individuals with schizophrenia carrying SETD1A LoF variants also had learning difficulties. We further identified four SETD1A LoF carriers among 4,281 children with severe developmental disorders and two more carriers in an independent sample of 5,720 Finnish exomes, both with notable neuropsychiatric phenotypes. Together, our observations indicate that LoF variants in SETD1A cause a range of neurodevelopmental disorders, including schizophrenia. Combining these data with previous common variant evidence, we suggest that epigenetic dysregulation, specifically in the histone H3K4 methylation pathway, is an important mechanism in the pathogenesis of schizophrenia.

Published
2016

6. Quantifying the contribution of recessive coding variation to developmental disorders

Author

Deciphering Developmental Disorders Study, Martin, Hilary C., Jones, Wendy D., McIntyre, Rebecca, Sanchez-Andrade, Gabriela, Sanderson, Mark, Stephenson, James D., Jones, Carla P., Handsaker, Juliet, Gallone, Giuseppe, Bruntraeger, Michaela, McRae, Jeremy F., Prigmore, Elena, Short, Patrick, Niemi, Mari, Kaplanis, Joanna, Radford, Elizabeth J., Akawi, Nadia, Balasubramanian, Meena, Dean, John, Horton, Rachel, Hulbert, Alice, Johnson, Diana S., Johnson, Katie, Kumar, Dhavendra, Lynch, Sally Ann, Mehta, Sarju G., Morton, Jenny, Parker, Michael J., Splitt, Miranda, Turnpenny, Peter D., Vasudevan, Pradeep C., Wright, Michael, Bassett, Andrew, Gerety, Sebastian S., Wright, Caroline F., FitzPatrick, David R., Firth, Helen V., Hurles, Matthew E., and Barrett, Jeffrey C.

Published
2018

7. Loss of ADAMTS19 causes progressive non-syndromic heart valve disease

Author

Wünnemann, Florian, Ta-Shma, Asaf, Preuss, Christoph, Leclerc, Severine, van Vliet, Patrick Piet, Oneglia, Andrea, Thibeault, Maryse, Nordquist, Emily, Lincoln, Joy, Scharfenberg, Franka, Becker-Pauly, Christoph, Hofmann, Philipp, Hoff, Kirstin, Audain, Enrique, Kramer, Hans-Heiner, Makalowski, Wojciech, Nir, Amiram, Gerety, Sebastian S., Hurles, Matthew, Comes, Johanna, Fournier, Anne, Osinska, Hanna, Robins, Jeffrey, Pucéat, Michel, Elpeleg, Orly, Hitz, Marc-Phillip, and Andelfinger, Gregor

Published
2020
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8. Saturation genome editing of BAP1functionally classifies somatic and germline variants

Author

Waters, Andrew J., Brendler-Spaeth, Timothy, Smith, Danielle, Offord, Victoria, Tan, Hong Kee, Zhao, Yajie, Obolenski, Sofia, Nielsen, Maartje, van Doorn, Remco, Murphy, Jo-Ellen, Gupta, Prashant, Rowlands, Charlie F., Hanson, Helen, Delage, Erwan, Thomas, Mark, Radford, Elizabeth J., Gerety, Sebastian S., Turnbull, Clare, Perry, John R. B., Hurles, Matthew E., and Adams, David J.

Abstract

Many variants that we inherit from our parents or acquire de novo or somatically are rare, limiting the precision with which we can associate them with disease. We performed exhaustive saturation genome editing (SGE) of BAP1, the disruption of which is linked to tumorigenesis and altered neurodevelopment. We experimentally characterized 18,108 unique variants, of which 6,196 were found to have abnormal functions, and then used these data to evaluate phenotypic associations in the UK Biobank. We also characterized variants in a large population-ascertained tumor collection, in cancer pedigrees and ClinVar, and explored the behavior of cancer-associated variants compared to that of variants linked to neurodevelopmental phenotypes. Our analyses demonstrated that disruptive germline BAP1variants were significantly associated with higher circulating levels of the mitogen IGF-1, suggesting a possible pathological mechanism and therapeutic target. Furthermore, we built a variant classifier with >98% sensitivity and specificity and quantify evidence strengths to aid precision variant interpretation.

Published
2024
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9. Optimized whole-genome CRISPR interference screens identify ARID1A-dependent growth regulators in human induced pluripotent stem cells

Author

Usluer, Sunay, primary, Hallast, Pille, additional, Crepaldi, Luca, additional, Zhou, Yan, additional, Urgo, Katie, additional, Dincer, Cansu, additional, Su, Jing, additional, Noell, Guillaume, additional, Alasoo, Kaur, additional, El Garwany, Omar, additional, Gerety, Sebastian S., additional, Newman, Ben, additional, Dovey, Oliver M., additional, and Parts, Leopold, additional

Published
2023
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10. Models of KPTN-related disorder implicate mTOR signalling in cognitive and overgrowth phenotypes

Author

Levitin, Maria O., Rawlins, Lettie E., Sanchez-Andrade, Gabriela, Arshad, Osama A., Collins, Stephan C., Sawiak, Stephen J., Iffland, Phillip H., Andersson, Malin H.L., Bupp, Caleb, Cambridge, Emma L., Coomber, Eve L., Ellis, Ian, Herkert, Johanna C., Ironfield, Holly, Jory, Logan, Kretz, Perrine F., Kant, Sarina G., Neaverson, Alexandra, Nibbeling, Esther, Rowley, Christine, Relton, Emily, Sanderson, Mark, Scott, Ethan M., Stewart, Helen, Shuen, Andrew Y., Schreiber, John, Tuck, Liz, Tonks, James, Terkelsen, Thorkild, van Ravenswaaij-Arts, Conny, Vasudevan, Pradeep, Wenger, Olivia, Wright, Michael, Day, Andrew, Hunter, Adam, Patel, Minal, Lelliott, Christopher J., Crino, Peter B., Yalcin, Binnaz, Crosby, Andrew H., Baple, Emma L., Logan, Darren W., Hurles, Matthew E., Gerety, Sebastian S., Levitin, Maria O., Rawlins, Lettie E., Sanchez-Andrade, Gabriela, Arshad, Osama A., Collins, Stephan C., Sawiak, Stephen J., Iffland, Phillip H., Andersson, Malin H.L., Bupp, Caleb, Cambridge, Emma L., Coomber, Eve L., Ellis, Ian, Herkert, Johanna C., Ironfield, Holly, Jory, Logan, Kretz, Perrine F., Kant, Sarina G., Neaverson, Alexandra, Nibbeling, Esther, Rowley, Christine, Relton, Emily, Sanderson, Mark, Scott, Ethan M., Stewart, Helen, Shuen, Andrew Y., Schreiber, John, Tuck, Liz, Tonks, James, Terkelsen, Thorkild, van Ravenswaaij-Arts, Conny, Vasudevan, Pradeep, Wenger, Olivia, Wright, Michael, Day, Andrew, Hunter, Adam, Patel, Minal, Lelliott, Christopher J., Crino, Peter B., Yalcin, Binnaz, Crosby, Andrew H., Baple, Emma L., Logan, Darren W., Hurles, Matthew E., and Gerety, Sebastian S.

Abstract

Models

Published
2023

11. Contribution of retrotransposition to developmental disorders

Author

Gardner, Eugene J., Prigmore, Elena, Gallone, Giuseppe, Danecek, Petr, Samocha, Kaitlin E., Handsaker, Juliet, Gerety, Sebastian S., Ironfield, Holly, Short, Patrick J., Sifrim, Alejandro, Singh, Tarjinder, Chandler, Kate E., Clement, Emma, Lachlan, Katherine L., Prescott, Katrina, Rosser, Elisabeth, FitzPatrick, David R., Firth, Helen V., and Hurles, Matthew E.

Published
2019
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12. Differentiation of human induced pluripotent stem cells into cortical neural stem cells

Author

Neaverson, Alexandra, primary, Andersson, Malin H. L., additional, Arshad, Osama A., additional, Foulser, Luke, additional, Goodwin-Trotman, Mary, additional, Hunter, Adam, additional, Newman, Ben, additional, Patel, Minal, additional, Roth, Charlotte, additional, Thwaites, Tristan, additional, Kilpinen, Helena, additional, Hurles, Matthew E., additional, Day, Andrew, additional, and Gerety, Sebastian S., additional

Published
2023
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13. Differentiation of human induced pluripotent stem cells into cortical neural stem cells

Author

Neaverson, Alexandra, primary, Andersson, Malin H. L., additional, Arshad, Osama A., additional, Foulser, Luke, additional, Goodwin-Trotman, Mary, additional, Hunter, Adam, additional, Newman, Ben, additional, Patel, Minal, additional, Roth, Charlotte, additional, Thwaites, Tristan, additional, Kilpinen, Helena, additional, Hurles, Matthew E., additional, Day, Andrew, additional, and Gerety, Sebastian S., additional

Published
2022
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14. Mouse and cellular models of KPTN-related disorder implicate mTOR signalling in cognitive and progressive overgrowth phenotypes

Author

Levitin, Maria O., primary, Rawlins, Lettie E, additional, Sanchez-Andrade, Gabriela, additional, Arshad, Osama A., additional, Collins, Stephan C., additional, Sawiak, Stephen J., additional, Iffland, Phillip H., additional, Andersson, Malin H.L., additional, Bupp, Caleb, additional, Cambridge, Emma L., additional, Coomber, Eve L., additional, Ellis, Ian, additional, Herkert, Johanna C., additional, Ironfield, Holly, additional, Jory, Logan, additional, Kretz, Perrine F., additional, Kant, Sarina G., additional, Neaverson, Alexandra, additional, Nibbeling, Esther, additional, Rowley, Christine, additional, Relton, Emily, additional, Sanderson, Mark, additional, Scott, Ethan M., additional, Stewart, Helen, additional, Shuen, Andrew Y., additional, Schreiber, John, additional, Tuck, Liz, additional, Tonks, James, additional, Terkelsen, Thorkild, additional, van Ravenswaaij-Arts, Conny, additional, Vasudevan, Pradeep, additional, Wenger, Olivia, additional, Wright, Michael, additional, Day, Andrew, additional, Hunter, Adam, additional, Patel, Minal, additional, Lelliott, Christopher J., additional, Crino, Peter B., additional, Yalcin, Binnaz, additional, Crosby, Andrew, additional, Baple, Emma L., additional, Logan, Darren W., additional, Hurles, Matthew E., additional, and Gerety, Sebastian S., additional

Published
2022
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16. An STS-Based Map of the Human Genome

Author

Hudson, Thomas J., Stein, Lincoln D., Gerety, Sebastian S., Ma, Junli, Castle, Andrew B., Silva, James, Slonim, Donna K., Baptista, Rafael, Kruglyak, Leonid, Xu, Shu-Hua, Hu, Xintong, Rosenberg, Carl, Reeve-Daly, Mary Pat, Rozen, Steve, Hui, Lester, Wu, Xiaoyun, Vestergaard, Christina, Wilson, Kimberly M., Bae, Jane S., Maitra, Shanak, Ganiatsas, Soula, Evans, Cheryl A., DeAngelis, Margaret M., Ingalls, Kimberly A., Nahf, Robert W., Horton, Lloyd T., Anderson, Michele Oskin, Collymore, Alville J., Ye, Wenjuan, Kouyoumjian, Vardouhie, Zemsteva, Irena S., Tam, James, Devine, Richard, Courtney, Dorothy F., Renaud, Michelle Turner, Nguyen, Huy, O'Connor, Tara J., Fizames, Cécile, Fauré, Sabine, Gyapay, Gabor, Dib, Colette, Morissette, Jean, Orlin, James B., Birren, Bruce W., Goodman, Nathan, Weissenbach, Jean, Hawkins, Trevor L., Foote, Simon, Page, David C., and Lander, Eric S.

Published
1995

17. Variant Library Annotation Tool (VaLiAnT): an oligonucleotide library design and annotation tool for saturation genome editing and other deep mutational scanning experiments.

Author

Barbon, Luca, Offord, Victoria, Radford, Elizabeth J, Butler, Adam P, Gerety, Sebastian S, Adams, David J, Tan, Hong Kee, and Waters, Andrew J

Subjects
PROTEIN-protein interactions, OLIGONUCLEOTIDES, GENOME editing, SYNTHETIC biology, PYTHON programming language, SINGLE nucleotide polymorphisms, OLIGONUCLEOTIDE synthesis, GENETIC variation
Abstract

Motivation CRISPR/Cas9-based technology allows for the functional analysis of genetic variants at single nucleotide resolution whilst maintaining genomic context. This approach, known as saturation genome editing (SGE), a form of deep mutational scanning, systematically alters each position in a target region to explore its function. SGE experiments require the design and synthesis of oligonucleotide variant libraries which are introduced into the genome. This technology is applicable to diverse fields such as disease variant identification, drug development, structure–function studies, synthetic biology, evolutionary genetics and host–pathogen interactions. Here, we present the Variant Library Annotation Tool (VaLiAnT) which can be used to generate variant libraries from user-defined genomic coordinates and standard input files. The software can accommodate user-specified species, reference sequences and transcript annotations. Results Coordinates for a genomic range are provided by the user to retrieve a corresponding oligonucleotide reference sequence. A user-specified range within this sequence is then subject to systematic, nucleotide and/or amino acid saturating mutator functions. VaLiAnT provides a novel way to retrieve, mutate and annotate genomic sequences for oligonucleotide library generation. Specific features for SGE library generation can be employed. In addition, VaLiAnT is configurable, allowing for cDNA and prime editing saturation library generation, with other diverse applications possible. Availability and implementation VaLiAnT is a command line tool written in Python. Source code, testing data, example input and output files and executables are available (https://github.com/cancerit/VaLiAnT) in addition to a detailed user manual (https://github.com/cancerit/VaLiAnT/wiki). VaLiAnT is licensed under AGPLv3. Supplementary information Supplementary data are available at Bioinformatics online. [ABSTRACT FROM AUTHOR]

Published
2022
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18. Discovery of four recessive developmental disorders using probabilistic genotype and phenotype matching among 4,125 families

Author

Akawi, Nadia, McRae, Jeremy, Ansari, Morad, Balasubramanian, Meena, Blyth, Moira, Brady, Angela F, Clayton, Stephen, Cole, Trevor, Deshpande, Charu, Fitzgerald, Tomas W, Foulds, Nicola, Francis, Richard, Gabriel, George, Gerety, Sebastian S, Goodship, Judith, Hobson, Emma, Jones, Wendy D, Joss, Shelagh, King, Daniel, Klena, Nikolai, Kumar, Ajith, Lees, Melissa, Lelliott, Chris, Lord, Jenny, McMullan, Dominic, O'Regan, Mary, Osio, Deborah, Piombo, Virginia, Prigmore, Elena, Rajan, Diana, Rosser, Elisabeth, Sifrim, Alejandro, Smith, Audrey, Swaminathan, Ganesh J, Turnpenny, Peter, Whitworth, James, Wright, Caroline F, Firth, Helen V, Barrett, Jeffrey C, Lo, Cecilia W, FitzPatrick, David R, Hurles, Matthew E, DDD Study, Kumar, Ajith [0000-0003-3878-2856], Lelliott, Chris [0000-0001-8087-4530], Barrett, Jeffrey C [0000-0002-1152-370X], and Apollo - University of Cambridge Repository

Subjects
Family Health, Male, Protein-Arginine N-Methyltransferases, Genotype, Developmental Disabilities, Ubiquitin-Protein Ligases, Genetic Variation, Cell Cycle Proteins, Genes, Recessive, Sequence Analysis, DNA, United Kingdom, Pedigree, Phenotype, Matrix Metalloproteinases, Secreted, Humans, Exome, Female, Genetic Predisposition to Disease, human activities, Genetic Association Studies
Abstract

Discovery of most autosomal recessive disease-associated genes has involved analysis of large, often consanguineous multiplex families or small cohorts of unrelated individuals with a well-defined clinical condition. Discovery of new dominant causes of rare, genetically heterogeneous developmental disorders has been revolutionized by exome analysis of large cohorts of phenotypically diverse parent-offspring trios1,2. Here we analyzed 4,125 families with diverse, rare and genetically heterogeneous developmental disorders and identified four new autosomal recessive disorders. These four disorders were identified by integrating Mendelian filtering (selecting probands with rare, biallelic and putatively damaging variants in the same gene) with statistical assessments of (i) the likelihood of sampling the observed genotypes from the general population and (ii) the phenotypic similarity of patients with recessive variants in the same candidate gene. This new paradigm promises to catalyze the discovery of novel recessive disorders, especially those with less consistent or nonspecific clinical presentations and those caused predominantly by compound heterozygous genotypes.

Published
2015

19. Rare Variants in NR2F2 Cause Congenital Heart Defects in Humans

Author

Al Turki, Saeed, primary, Manickaraj, Ashok K., additional, Mercer, Catherine L., additional, Gerety, Sebastian S., additional, Hitz, Marc-Phillip, additional, Lindsay, Sarah, additional, D’Alessandro, Lisa C.A., additional, Swaminathan, G. Jawahar, additional, Bentham, Jamie, additional, Arndt, Anne-Karin, additional, Louw, Jacoba, additional, Breckpot, Jeroen, additional, Gewillig, Marc, additional, Thienpont, Bernard, additional, Abdul-Khaliq, Hashim, additional, Harnack, Christine, additional, Hoff, Kirstin, additional, Kramer, Hans-Heiner, additional, Schubert, Stephan, additional, Siebert, Reiner, additional, Toka, Okan, additional, Cosgrove, Catherine, additional, Watkins, Hugh, additional, Lucassen, Anneke M., additional, O’Kelly, Ita M., additional, Salmon, Anthony P., additional, Bu’Lock, Frances A., additional, Granados-Riveron, Javier, additional, Setchfield, Kerry, additional, Thornborough, Chris, additional, Brook, J. David, additional, Mulder, Barbara, additional, Klaassen, Sabine, additional, Bhattacharya, Shoumo, additional, Devriendt, Koen, additional, FitzPatrick, David R., additional, Wilson, David I., additional, Mital, Seema, additional, and Hurles, Matthew E., additional

Published
2016
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20. Pathogenicity and selective constraint on variation near splice sites

Author

Lord, Jenny, Gallone, Giuseppe, Short, Patrick J., McRae, Jeremy F., Ironfield, Holly, Wynn, Elizabeth H., Gerety, Sebastian S., He, Liu, Kerr, Bronwyn, Johnson, Diana S., McCann, Emma, Kinning, Esther, Flinter, Frances, Temple, I. Karen, Clayton-Smith, Jill, McEntagart, Meriel, Lynch, Sally Ann, Joss, Shelagh, Douzgou, Sofia, Dabir, Tabib, Clowes, Virginia, McConnell, Vivienne P.M., Lam, Wayne, Wright, Caroline F., FitzPatrick, David R., Firth, Helen V., Barrett, Jeffrey C., and Hurles, Matthew E.

Abstract

Mutations that perturb normal pre-mRNA splicing are significant contributors to human disease. We used exome sequencing data from 7833 probands with developmental disorders (DDs) and their unaffected parents, as well as more than 60,000 aggregated exomes from the Exome Aggregation Consortium, to investigate selection around the splice sites and quantify the contribution of splicing mutations to DDs. Patterns of purifying selection, a deficit of variants in highly constrained genes in healthy subjects, and excess de novo mutations in patients highlighted particular positions within and around the consensus splice site of greater functional relevance. By using mutational burden analyses in this large cohort of proband–parent trios, we could estimate in an unbiased manner the relative contributions of mutations at canonical dinucleotides (73%) and flanking noncanonical positions (27%), and calculate the positive predictive value of pathogenicity for different classes of mutations. We identified 18 patients with likely diagnostic de novo mutations in dominant DD-associated genes at noncanonical positions in splice sites. We estimate 35%–40% of pathogenic variants in noncanonical splice site positions are missing from public databases.

Published
2019
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21. Rare Variants in NR2F2 Cause Congenital Heart Defects in Humans

Author

Al Turki, Saeed, primary, Manickaraj, Ashok K., additional, Mercer, Catherine L., additional, Gerety, Sebastian S., additional, Hitz, Marc-Phillip, additional, Lindsay, Sarah, additional, D’Alessandro, Lisa C.A., additional, Swaminathan, G. Jawahar, additional, Bentham, Jamie, additional, Arndt, Anne-Karin, additional, Low, Jacoba, additional, Breckpot, Jeroen, additional, Gewillig, Marc, additional, Thienpont, Bernard, additional, Abdul-Khaliq, Hashim, additional, Harnack, Christine, additional, Hoff, Kirstin, additional, Kramer, Hans-Heiner, additional, Schubert, Stephan, additional, Siebert, Reiner, additional, Toka, Okan, additional, Cosgrove, Catherine, additional, Watkins, Hugh, additional, Lucassen, Anneke M., additional, O’Kelly, Ita M., additional, Salmon, Anthony P., additional, Bu’Lock, Frances A., additional, Granados-Riveron, Javier, additional, Setchfield, Kerry, additional, Thornborough, Chris, additional, Brook, J. David, additional, Mulder, Barbara, additional, Klaassen, Sabine, additional, Bhattacharya, Shoumo, additional, Devriendt, Koen, additional, FitzPatrick, David R., additional, Wilson, David I., additional, Mital, Seema, additional, and Hurles, Matthew E., additional

Published
2014
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25. Discovery of four recessive developmental disorders using probabilistic genotype and phenotype matching among 4,125 families.

Author

Foulds, Nicola, Akawi, Nadia, McRae, Jeremy, Clayton, Stephen, Fitzgerald, Tomas W, Gerety, Sebastian S, Jones, Wendy D, King, Daniel, Lelliott, Chris, Lord, Jenny, Piombo, Virginia, Prigmore, Elena, Rajan, Diana, Sifrim, Alejandro, Swaminathan, Ganesh J, Wright, Caroline F, Barrett, Jeffrey C, Hurles, Matthew E, Joss, Shelagh, and O'Regan, Mary

Subjects
PHENOTYPES, GENOTYPES, PSEUDOHYPOPARATHYROIDISM, EMBRYOLOGY, DNA mutational analysis
Abstract

Discovery of most autosomal recessive disease-associated genes has involved analysis of large, often consanguineous multiplex families or small cohorts of unrelated individuals with a well-defined clinical condition. Discovery of new dominant causes of rare, genetically heterogeneous developmental disorders has been revolutionized by exome analysis of large cohorts of phenotypically diverse parent-offspring trios. Here we analyzed 4,125 families with diverse, rare and genetically heterogeneous developmental disorders and identified four new autosomal recessive disorders. These four disorders were identified by integrating Mendelian filtering (selecting probands with rare, biallelic and putatively damaging variants in the same gene) with statistical assessments of (i) the likelihood of sampling the observed genotypes from the general population and (ii) the phenotypic similarity of patients with recessive variants in the same candidate gene. This new paradigm promises to catalyze the discovery of novel recessive disorders, especially those with less consistent or nonspecific clinical presentations and those caused predominantly by compound heterozygous genotypes. [ABSTRACT FROM AUTHOR]

Published
2015
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27. Human Genome Anatomy: BACs Integrating the Genetic and Cytogenetic Maps for Bridging Genome and Biomedicine

Author

Korenberg, Julie R., primary, Chen, Xiao-Ning, additional, Sun, Zhiguang, additional, Shi, Zheng-Yang, additional, Ma, Shaowu, additional, Vataru, Eddy, additional, Yimlamai, Dean, additional, Weissenbach, Jean S., additional, Shizuya, Hiroaki, additional, Simon, Melvin I., additional, Gerety, Sebastian S., additional, Nguyen, Huy, additional, Zemsteva, Irina S., additional, Hui, Lester, additional, Silva, James, additional, Wu, Xiaoyun, additional, Birren, Bruce W., additional, and Hudson, Thomas J., additional

Published
1999
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29. Valproic acid silencing of ascl1b/Ascl1 results in the failure of serotonergic differentiation in a zebrafish model of fetal valproate syndrome

Author

Jacob, John, Ribes, Vanessa, Moore, Steven, Constable, Sean C., Sasai, Noriaki, Gerety, Sebastian S., Martin, Darren J., Sergeant, Chris P., Wilkinson, David G., and Briscoe, James

Abstract

Fetal valproate syndrome (FVS) is caused by in utero exposure to the drug sodium valproate. Valproate is used worldwide for the treatment of epilepsy, as a mood stabiliser and for its pain-relieving properties. In addition to birth defects, FVS is associated with an increased risk of autism spectrum disorder (ASD), which is characterised by abnormal behaviours. Valproate perturbs multiple biochemical pathways and alters gene expression through its inhibition of histone deacetylases. Which, if any, of these mechanisms is relevant to the genesis of its behavioural side effects is unclear. Neuroanatomical changes associated with FVS have been reported and, among these, altered serotonergic neuronal differentiation is a consistent finding. Altered serotonin homeostasis is also associated with autism. Here we have used a chemical-genetics approach to investigate the underlying molecular defect in a zebrafish FVS model. Valproate causes the selective failure of zebrafish central serotonin expression. It does so by downregulating the proneural gene ascl1b, an ortholog of mammalian Ascl1, which is a known determinant of serotonergic identity in the mammalian brainstem. ascl1b is sufficient to rescue serotonin expression in valproate-treated embryos. Chemical and genetic blockade of the histone deacetylase Hdac1 downregulates ascl1b, consistent with the Hdac1-mediated silencing of ascl1b expression by valproate. Moreover, tonic Notch signalling is crucial for ascl1b repression by valproate. Concomitant blockade of Notch signalling restores ascl1b expression and serotonin expression in both valproate-exposed and hdac1 mutant embryos. Together, these data provide a molecular explanation for serotonergic defects in FVS and highlight an epigenetic mechanism for genome-environment interaction in disease.

Published
2014
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30. Contribution of retrotransposition to developmental disorders

Author

Katherine Lachlan, Elena Prigmore, Emma Clement, Patrick J. Short, Katrina Prescott, David R. FitzPatrick, Petr Danecek, Kate Chandler, Holly Ironfield, Alejandro Sifrim, Helen V. Firth, Giuseppe Gallone, Matthew E. Hurles, Tarjinder Singh, Eugene J. Gardner, Sebastian S. Gerety, Kaitlin E. Samocha, Juliet Handsaker, Elisabeth Rosser, Gardner, Eugene J [0000-0001-9671-1533], Gerety, Sebastian S [0000-0002-6126-5040], Short, Patrick J [0000-0002-7626-6177], Singh, Tarjinder [0000-0003-0601-6815], and Apollo - University of Cambridge Repository

Subjects
Proband, 0301 basic medicine, Mutation rate, BROWSER, Retroelements, DATABASE, Science, Developmental Disabilities, Mutagenesis (molecular biology technique), General Physics and Astronomy, Retrotransposon, VARIANTS, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Germline, 03 medical and health sciences, Negative selection, 0302 clinical medicine, Mutation Rate, Genetic variation, ELEMENTS, Humans, lcsh:Science, Exome, Gene, 030304 developmental biology, Genetics, 0303 health sciences, Science & Technology, Multidisciplinary, Neurodevelopmental disorders, Genetic Variation, General Chemistry, FRAMEWORK, Multidisciplinary Sciences, GENOME, 030104 developmental biology, DE-NOVO MUTATIONS, Mutation, PATTERNS, Science & Technology - Other Topics, lcsh:Q, Structural variation, Mobile genetic elements, Medical genomics, 030217 neurology & neurosurgery
Abstract

Mobile genetic Elements (MEs) are segments of DNA which can copy themselves and other transcribed sequences through the process of retrotransposition (RT). In humans several disorders have been attributed to RT, but the role of RT in severe developmental disorders (DD) has not yet been explored. Here we identify RT-derived events in 9738 exome sequenced trios with DD-affected probands. We ascertain 9 de novo MEs, 4 of which are likely causative of the patient’s symptoms (0.04%), as well as 2 de novo gene retroduplications. Beyond identifying likely diagnostic RT events, we estimate genome-wide germline ME mutation rate and selective constraint and demonstrate that coding RT events have signatures of purifying selection equivalent to those of truncating mutations. Overall, our analysis represents a comprehensive interrogation of the impact of retrotransposition on protein coding genes and a framework for future evolutionary and disease studies., Retrotransposition events have been linked to some human disorders. Here, Gardner et al. systematically search for mobile genetic elements (ME) in trio whole exome-sequencing datasets and ascertain 9 de novo MEs and further estimate genome-wide germline ME burden and constraint.

Published
2019

31. Rare Variants in NR2F2 Cause Congenital Heart Defects in Humans.

Author

Turki, Saeed Al, Manickaraj, Ashok K., Mercer, Catherine L., Gerety, Sebastian S., Hitz, Marc-Phillip, Lindsay, Sarah, D'Alessandro, Lisa C. A., Swaminathan, G. Jawahar, Bentham, Jamie, Arndt, Anne-Karin, Low, Jacoba, Breckpot, Jeroen, Gewillig, Marc, Thienpont, Bernard, Abdul-Khaliq, Hashim, Harnack, Christine, Hoff, Kirstin, Kramer, Hans-Heiner, Schubert, Stephan, and Siebert, Reiner

Published
2014
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32. Models of KPTN-related disorder implicate mTOR signalling in cognitive and overgrowth phenotypes.

Author

Levitin MO, Rawlins LE, Sanchez-Andrade G, Arshad OA, Collins SC, Sawiak SJ, Iffland PH 2nd, Andersson MHL, Bupp C, Cambridge EL, Coomber EL, Ellis I, Herkert JC, Ironfield H, Jory L, Kretz PF, Kant SG, Neaverson A, Nibbeling E, Rowley C, Relton E, Sanderson M, Scott EM, Stewart H, Shuen AY, Schreiber J, Tuck L, Tonks J, Terkelsen T, van Ravenswaaij-Arts C, Vasudevan P, Wenger O, Wright M, Day A, Hunter A, Patel M, Lelliott CJ, Crino PB, Yalcin B, Crosby AH, Baple EL, Logan DW, Hurles ME, and Gerety SS

Subjects
Humans, Animals, Mice, Brain metabolism, Mechanistic Target of Rapamycin Complex 1 metabolism, Cognition, Microfilament Proteins genetics, Signal Transduction genetics, TOR Serine-Threonine Kinases metabolism
Abstract

KPTN-related disorder is an autosomal recessive disorder associated with germline variants in KPTN (previously known as kaptin), a component of the mTOR regulatory complex KICSTOR. To gain further insights into the pathogenesis of KPTN-related disorder, we analysed mouse knockout and human stem cell KPTN loss-of-function models. Kptn -/- mice display many of the key KPTN-related disorder phenotypes, including brain overgrowth, behavioural abnormalities, and cognitive deficits. By assessment of affected individuals, we have identified widespread cognitive deficits (n = 6) and postnatal onset of brain overgrowth (n = 19). By analysing head size data from their parents (n = 24), we have identified a previously unrecognized KPTN dosage-sensitivity, resulting in increased head circumference in heterozygous carriers of pathogenic KPTN variants. Molecular and structural analysis of Kptn-/- mice revealed pathological changes, including differences in brain size, shape and cell numbers primarily due to abnormal postnatal brain development. Both the mouse and differentiated induced pluripotent stem cell models of the disorder display transcriptional and biochemical evidence for altered mTOR pathway signalling, supporting the role of KPTN in regulating mTORC1. By treatment in our KPTN mouse model, we found that the increased mTOR signalling downstream of KPTN is rapamycin sensitive, highlighting possible therapeutic avenues with currently available mTOR inhibitors. These findings place KPTN-related disorder in the broader group of mTORC1-related disorders affecting brain structure, cognitive function and network integrity., (© The Author(s) 2023. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2023
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33. Quantifying the contribution of recessive coding variation to developmental disorders.

Author

Martin HC, Jones WD, McIntyre R, Sanchez-Andrade G, Sanderson M, Stephenson JD, Jones CP, Handsaker J, Gallone G, Bruntraeger M, McRae JF, Prigmore E, Short P, Niemi M, Kaplanis J, Radford EJ, Akawi N, Balasubramanian M, Dean J, Horton R, Hulbert A, Johnson DS, Johnson K, Kumar D, Lynch SA, Mehta SG, Morton J, Parker MJ, Splitt M, Turnpenny PD, Vasudevan PC, Wright M, Bassett A, Gerety SS, Wright CF, FitzPatrick DR, Firth HV, Hurles ME, and Barrett JC

Subjects
Animals, Disease Models, Animal, Eukaryotic Initiation Factor-3 genetics, Europe, Genome-Wide Association Study, Humans, Jumonji Domain-Containing Histone Demethylases genetics, Mice, Nuclear Proteins genetics, Pakistan, Phylogeny, Repressor Proteins genetics, Developmental Disabilities genetics, Genes, Recessive, Genetic Code, Genetic Variation, Penetrance
Abstract

We estimated the genome-wide contribution of recessive coding variation in 6040 families from the Deciphering Developmental Disorders study. The proportion of cases attributable to recessive coding variants was 3.6% in patients of European ancestry, compared with 50% explained by de novo coding mutations. It was higher (31%) in patients with Pakistani ancestry, owing to elevated autozygosity. Half of this recessive burden is attributable to known genes. We identified two genes not previously associated with recessive developmental disorders, KDM5B and EIF3F , and functionally validated them with mouse and cellular models. Our results suggest that recessive coding variants account for a small fraction of currently undiagnosed nonconsanguineous individuals, and that the role of noncoding variants, incomplete penetrance, and polygenic mechanisms need further exploration., (Copyright © 2018 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published
2018
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34. Discovery of four recessive developmental disorders using probabilistic genotype and phenotype matching among 4,125 families.

Author

Akawi N, McRae J, Ansari M, Balasubramanian M, Blyth M, Brady AF, Clayton S, Cole T, Deshpande C, Fitzgerald TW, Foulds N, Francis R, Gabriel G, Gerety SS, Goodship J, Hobson E, Jones WD, Joss S, King D, Klena N, Kumar A, Lees M, Lelliott C, Lord J, McMullan D, O'Regan M, Osio D, Piombo V, Prigmore E, Rajan D, Rosser E, Sifrim A, Smith A, Swaminathan GJ, Turnpenny P, Whitworth J, Wright CF, Firth HV, Barrett JC, Lo CW, FitzPatrick DR, and Hurles ME

Subjects
Cell Cycle Proteins genetics, Developmental Disabilities classification, Exome genetics, Family Health, Female, Genetic Variation, Genotype, Humans, Male, Matrix Metalloproteinases, Secreted genetics, Pedigree, Phenotype, Protein-Arginine N-Methyltransferases genetics, Sequence Analysis, DNA methods, Ubiquitin-Protein Ligases genetics, United Kingdom, Developmental Disabilities genetics, Genes, Recessive, Genetic Association Studies methods, Genetic Predisposition to Disease genetics
Abstract

Discovery of most autosomal recessive disease-associated genes has involved analysis of large, often consanguineous multiplex families or small cohorts of unrelated individuals with a well-defined clinical condition. Discovery of new dominant causes of rare, genetically heterogeneous developmental disorders has been revolutionized by exome analysis of large cohorts of phenotypically diverse parent-offspring trios. Here we analyzed 4,125 families with diverse, rare and genetically heterogeneous developmental disorders and identified four new autosomal recessive disorders. These four disorders were identified by integrating Mendelian filtering (selecting probands with rare, biallelic and putatively damaging variants in the same gene) with statistical assessments of (i) the likelihood of sampling the observed genotypes from the general population and (ii) the phenotypic similarity of patients with recessive variants in the same candidate gene. This new paradigm promises to catalyze the discovery of novel recessive disorders, especially those with less consistent or nonspecific clinical presentations and those caused predominantly by compound heterozygous genotypes.

Published
2015
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