Your search keyword '"Marc Hanauer"' showing total 20 results

1. Building Expertise on FAIR Through Evolving Bring Your Own Data (BYOD) Workshops: Describing the Data, Software, and Management-focused Approaches and Their Evolution

Author

César H. Bernabé, Lieze Thielemans, Rajaram Kaliyaperumal, Claudio Carta, Shuxin Zhang, Celia W.G. van Gelder, Nirupama Benis, Luiz Olavo Bonino da Silva Santos, Ronald Cornet, Bruna dos Santos Vieira, Nawel Lalout, Ines Henriques, Alberto Cámara Ballesteros, Kees Burger, Martijn G. Kersloot, Friederike Ehrhart, Esther van Enckevort, Chris T. Evelo, Alasdair J. G. Gray, Marc Hanauer, Kristina Hettne, Joep de Ligt, Arnaldo Pereira, Núria Queralt-Rosinach, Erik Schultes, Domenica Taruscio, Andra Waagmeester, Mark D. Wilkinson, Egon L. Willighagen, Mascha Jansen, Barend Mons, Marco Roos, and Annika Jacobsen

Subjects

Information technology, T58.5-58.64

Published

2024

2. Clinical, genetic, epidemiologic, evolutionary, and functional delineation of TSPEAR-related autosomal recessive ectodermal dysplasia 14

Author

Adam Jackson, Sheng-Jia Lin, Elizabeth A. Jones, Kate E. Chandler, David Orr, Celia Moss, Zahra Haider, Gavin Ryan, Simon Holden, Mike Harrison, Nigel Burrows, Wendy D. Jones, Mary Loveless, Cassidy Petree, Helen Stewart, Karen Low, Deirdre Donnelly, Simon Lovell, Konstantina Drosou, Gaurav K. Varshney, Siddharth Banka, J.C. Ambrose, P. Arumugam, R. Bevers, M. Bleda, F. Boardman-Pretty, C.R. Boustred, H. Brittain, M.A. Brown, M.J. Caulfield, G.C. Chan, A. Giess, J.N. Griffin, A. Hamblin, S. Henderson, T.J.P. Hubbard, R. Jackson, L.J. Jones, D. Kasperaviciute, M. Kayikci, A. Kousathanas, L. Lahnstein, A. Lakey, S.E.A. Leigh, I.U.S. Leong, F.J. Lopez, F. Maleady-Crowe, M. McEntagart, F. Minneci, J. Mitchell, L. Moutsianas, M. Mueller, N. Murugaesu, A.C. Need, P. O‘Donovan, C.A. Odhams, C. Patch, D. Perez-Gil, M.B. Pereira, J. Pullinger, T. Rahim, A. Rendon, T. Rogers, K. Savage, K. Sawant, R.H. Scott, A. Siddiq, A. Sieghart, S.C. Smith, A. Sosinsky, A. Stuckey, M. Tanguy, A.L. Taylor Tavares, E.R.A. Thomas, S.R. Thompson, A. Tucci, M.J. Welland, E. Williams, K. Witkowska, S.M. Wood, M. Zarowiecki, Olaf Riess, Tobias B. Haack, Holm Graessner, Birte Zurek, Kornelia Ellwanger, Stephan Ossowski, German Demidov, Marc Sturm, Julia M. Schulze-Hentrich, Rebecca Schüle, Christoph Kessler, Melanie Wayand, Matthis Synofzik, Carlo Wilke, Andreas Traschütz, Ludger Schöls, Holger Hengel, Peter Heutink, Han Brunner, Hans Scheffer, Nicoline Hoogerbrugge, Alexander Hoischen, Peter A.C. ’t Hoen, Lisenka E.L.M. Vissers, Christian Gilissen, Wouter Steyaert, Karolis Sablauskas, Richarda M. de Voer, Erik-Jan Kamsteeg, Bart van de Warrenburg, Nienke van Os, Iris te Paske, Erik Janssen, Elke de Boer, Marloes Steehouwer, Burcu Yaldiz, Tjitske Kleefstra, Anthony J. Brookes, Colin Veal, Spencer Gibson, Marc Wadsley, Mehdi Mehtarizadeh, Umar Riaz, Greg Warren, Farid Yavari Dizjikan, Thomas Shorter, Ana Töpf, Volker Straub, Chiara Marini Bettolo, Sabine Specht, Jill Clayton-Smith, Elizabeth Alexander, Laurence Faivre, Christel Thauvin, Antonio Vitobello, Anne-Sophie Denommé-Pichon, Yannis Duffourd, Emilie Tisserant, Ange-Line Bruel, Christine Peyron, Aurore Pélissier, Sergi Beltran, Ivo Glynne Gut, Steven Laurie, Davide Piscia, Leslie Matalonga, Anastasios Papakonstantinou, Gemma Bullich, Alberto Corvo, Carles Garcia, Marcos Fernandez-Callejo, Carles Hernández, Daniel Picó, Ida Paramonov, Hanns Lochmüller, Gulcin Gumus, Virginie Bros-Facer, Ana Rath, Marc Hanauer, Annie Olry, David Lagorce, Svitlana Havrylenko, Katia Izem, Fanny Rigour, Giovanni Stevanin, Alexandra Durr, Claire-Sophie Davoine, Léna Guillot-Noel, Anna Heinzmann, Giulia Coarelli, Gisèle Bonne, Teresinha Evangelista, Valérie Allamand, Isabelle Nelson, Rabah Ben Yaou, Corinne Metay, Bruno Eymard, Enzo Cohen, Antonio Atalaia, Tanya Stojkovic, Milan Macek, Jr., Marek Turnovec, Dana Thomasová, Radka Pourová Kremliková, Vera Franková, Markéta Havlovicová, Vlastimil Kremlik, Helen Parkinson, Thomas Keane, Dylan Spalding, Alexander Senf, Peter Robinson, Daniel Danis, Glenn Robert, Alessia Costa, Christine Patch, Mike Hanna, Henry Houlden, Mary Reilly, Jana Vandrovcova, Francesco Muntoni, Irina Zaharieva, Anna Sarkozy, Vincent Timmerman, Jonathan Baets, Liedewei Van de Vondel, Danique Beijer, Peter de Jonghe, Vincenzo Nigro, Sandro Banfi, Annalaura Torella, Francesco Musacchia, Giulio Piluso, Alessandra Ferlini, Rita Selvatici, Rachele Rossi, Marcella Neri, Stefan Aretz, Isabel Spier, Anna Katharina Sommer, Sophia Peters, Carla Oliveira, Jose Garcia Pelaez, Ana Rita Matos, Celina São José, Marta Ferreira, Irene Gullo, Susana Fernandes, Luzia Garrido, Pedro Ferreira, Fátima Carneiro, Morris A. Swertz, Lennart Johansson, Joeri K. van der Velde, Gerben van der Vries, Pieter B. Neerincx, Dieuwke Roelofs-Prins, Sebastian Köhler, Alison Metcalfe, Alain Verloes, Séverine Drunat, Caroline Rooryck, Aurelien Trimouille, Raffaele Castello, Manuela Morleo, Michele Pinelli, Alessandra Varavallo, Manuel Posada De la Paz, Eva Bermejo Sánchez, Estrella López Martín, Beatriz Martínez Delgado, F. Javier Alonso García de la Rosa, Andrea Ciolfi, Bruno Dallapiccola, Simone Pizzi, Francesca Clementina Radio, Marco Tartaglia, Alessandra Renieri, Elisa Benetti, Peter Balicza, Maria Judit Molnar, Ales Maver, Borut Peterlin, Alexander Münchau, Katja Lohmann, Rebecca Herzog, Martje Pauly, Alfons Macaya, Anna Marcé-Grau, Andres Nascimiento Osorio, Daniel Natera de Benito, Rachel Thompson, Kiran Polavarapu, David Beeson, Judith Cossins, Pedro M. Rodriguez Cruz, Peter Hackman, Mridul Johari, Marco Savarese, Bjarne Udd, Rita Horvath, Gabriel Capella, Laura Valle, Elke Holinski-Feder, Andreas Laner, Verena Steinke-Lange, Evelin Schröck, and Andreas Rump

Subjects

TSPEAR, Ectodermal dysplasia, Enamel knot, WNT10A, Hypodontia, Conical teeth, Genetics, QH426-470

Abstract

Summary: TSPEAR variants cause autosomal recessive ectodermal dysplasia (ARED) 14. The function of TSPEAR is unknown. The clinical features, the mutation spectrum, and the underlying mechanisms of ARED14 are poorly understood. Combining data from new and previously published individuals established that ARED14 is primarily characterized by dental anomalies such as conical tooth cusps and hypodontia, like those seen in individuals with WNT10A-related odontoonychodermal dysplasia. AlphaFold-predicted structure-based analysis showed that most of the pathogenic TSPEAR missense variants likely destabilize the β-propeller of the protein. Analysis of 100000 Genomes Project (100KGP) data revealed multiple founder TSPEAR variants across different populations. Mutational and recombination clock analyses demonstrated that non-Finnish European founder variants likely originated around the end of the last ice age, a period of major climatic transition. Analysis of gnomAD data showed that the non-Finnish European population TSPEAR gene-carrier rate is ∼1/140, making it one of the commonest AREDs. Phylogenetic and AlphaFold structural analyses showed that TSPEAR is an ortholog of drosophila Closca, an extracellular matrix-dependent signaling regulator. We, therefore, hypothesized that TSPEAR could have a role in enamel knot, a structure that coordinates patterning of developing tooth cusps. Analysis of mouse single-cell RNA sequencing (scRNA-seq) data revealed highly restricted expression of Tspear in clusters representing enamel knots. A tspeara−/−;tspearb−/− double-knockout zebrafish model recapitulated the clinical features of ARED14 and fin regeneration abnormalities of wnt10a knockout fish, thus suggesting interaction between tspear and wnt10a. In summary, we provide insights into the role of TSPEAR in ectodermal development and the evolutionary history, epidemiology, mechanisms, and consequences of its loss of function variants.

Published

2023

3. The ELIXIR Human Copy Number Variations Community: building bioinformatics infrastructure for research [version 1; peer review: 2 approved]

Author

David Salgado, Irina M. Armean, Michael Baudis, Sergi Beltran, Salvador Capella-Gutierrez, Denise Carvalho-Silva, Victoria Dominguez Del Angel, Joaquin Dopazo, Laura I. Furlong, Bo Gao, Leyla Garcia, Dietlind Gerloff, Ivo Gut, Attila Gyenesei, Nina Habermann, John M. Hancock, Marc Hanauer, Eivind Hovig, Lennart F. Johansson, Thomas Keane, Jan Korbel, Katharina B. Lauer, Steve Laurie, Brane Leskošek, David Lloyd, Tomas Marques-Bonet, Hailiang Mei, Katalin Monostory, Janet Piñero, Krzysztof Poterlowicz, Ana Rath, Pubudu Samarakoon, Ferran Sanz, Gary Saunders, Daoud Sie, Morris A. Swertz, Kirill Tsukanov, Alfonso Valencia, Marko Vidak, Cristina Yenyxe González, Bauke Ylstra, and Christophe Béroud

Subjects

Medicine, Science

Abstract

Copy number variations (CNVs) are major causative contributors both in the genesis of genetic diseases and human neoplasias. While “High-Throughput” sequencing technologies are increasingly becoming the primary choice for genomic screening analysis, their ability to efficiently detect CNVs is still heterogeneous and remains to be developed. The aim of this white paper is to provide a guiding framework for the future contributions of ELIXIR’s recently established human CNV Community, with implications beyond human disease diagnostics and population genomics. This white paper is the direct result of a strategy meeting that took place in September 2018 in Hinxton (UK) and involved representatives of 11 ELIXIR Nodes. The meeting led to the definition of priority objectives and tasks, to address a wide range of CNV-related challenges ranging from detection and interpretation to sharing and training. Here, we provide suggestions on how to align these tasks within the ELIXIR Platforms strategy, and on how to frame the activities of this new ELIXIR Community in the international context.

Published

2020

4. Privacy-Preserving Linkage of Distributed Pseudonymised Datasets in a Virtual European Rare Disease Platform.

Author

Dieter Hayn, Emanuel Sandner, Abishaa Vengadeswaran, Mark Wilkinson, Marc Hanauer, Karl Kreiner, and Günter Schreier 0001

Published

2024

5. Enabling FAIR Discovery of Rare Disease Digital Resources.

Author

Rajaram Kaliyaperumal, Núria Queralt Rosinach, Kees Burger, Luiz Olavo Bonino da Silva Santos, Marc Hanauer, and Marco Roos

Published

2021

6. The Human Phenotype Ontology in 2021.

Author

Sebastian Köhler 0001, Michael A. Gargano, Nicolas Matentzoglu, Leigh Carmody, David Lewis-Smith, Nicole A. Vasilevsky, Daniel Danis, Ganna Balagura, Gareth Baynam, Amy M. Brower, Tiffany J. Callahan, Christopher G. Chute, Johanna L. Est, Peter D. Galer, Shiva Ganesan, Matthias Griese, Matthias Haimel, Julia Pazmandi, Marc Hanauer, Nomi L. Harris, Michael Hartnett, Maximilian Hastreiter, Fabian Hauck, Yongqun He, Tim Jeske, Hugh Kearney, Gerhard Kindle, Christoph Klein 0001, Katrin Knoflach, Roland Krause, David Lagorce, Julie A. McMurry, Jillian A. Miller, Monica C. Munoz-Torres, Rebecca L. Peters, Christina K. Rapp, Ana Rath, Shahmir A. Rind, Avi Z. Rosenberg, Michael M. Segal, Markus G. Seidel, Damian Smedley, Tomer Talmy, Yarlalu Thomas, Samuel A. Wiafe, Julie Xian, Zafer Yüksel, Ingo Helbig, Christopher J. Mungall, Melissa A. Haendel, and Peter N. Robinson

Published

2021

7. The ELIXIR Core Data Resources: fundamental infrastructure for the life sciences.

Author

Rachel Drysdale, Charles E. Cook, Robert Petryszak, Vivienne Baillie Gerritsen, Mary Barlow, Elisabeth Gasteiger, Franziska Gruhl, Jürgen Haas, Jerry Lanfear, Rodrigo Lopez, Nicole Redaschi, Heinz Stockinger, Daniel Teixeira, Aravind Venkatesan, Alex Bateman, Alan J. Bridge, Guy Cochrane, Robert D. Finn, Frank Oliver Glöckner, Marc Hanauer, Thomas M. Keane, Andrew Leach, Luana Licata, Per Oksvold, Sandra E. Orchard, Christine A. Orengo, Helen E. Parkinson, Bengt Persson, Pablo Porras, Jordi Rambla, Ana Rath, Charlotte Rodwell, Ugis Sarkans, Dietmar Schomburg, Ian Sillitoe, J. Dylan Spalding, Mathias Uhlén, Sameer Velankar, Juan Antonio Vizcaíno, Kalle von Feilitzen, Christian von Mering, Andrew D. Yates, Niklas Blomberg, Christine Durinx, and Johanna R. McEntyre

Published

2020

8. Expansion of the Human Phenotype Ontology (HPO) knowledge base and resources.

Author

Sebastian Köhler 0001, Leigh Carmody, Nicole A. Vasilevsky, Julius O. B. Jacobsen, Daniel Danis, Jean-Philippe F. Gourdine, Michael A. Gargano, Nomi L. Harris, Nicolas Matentzoglu, Julie A. McMurry, David Osumi-Sutherland, Valentina Cipriani, James P. Balhoff, Tom Conlin, Hannah Blau, Gareth Baynam, Richard Palmer, Dylan Gratian, Hugh J. S. Dawkins, Michael Segal 0002, Anna C. Jansen, Ahmed Muaz, Willie H. Chang, Jenna Bergerson, Stanley J. F. Laulederkind, Zafer Yüksel, Sergi Beltran, Alexandra F. Freeman, Panagiotis I. Sergouniotis, Daniel Durkin, Andrea L. Storm, Marc Hanauer, Michael Brudno, Susan M. Bello, Murat Sincan, Kayli Rageth, Matthew T. Wheeler, Renske Oegema, Halima Lourghi, Maria G. Della Rocca, Rachel Thompson, Francisco Castellanos, James Priest, Charlotte Cunningham-Rundles, Ayushi Hegde, Ruth C. Lovering, Catherine Hajek, Annie Olry, Luigi Notarangelo, Morgan Similuk, Xingmin Aaron Zhang, David Gómez-Andrés, Hanns Lochmüller, Hélène Dollfus, Sergio Rosenzweig, Shruti Marwaha, Ana Rath, Kathleen Sullivan, Cynthia L. Smith, Joshua D. Milner, Dorothée Leroux, Cornelius F. Boerkoel, Amy Klion, Melody C. Carter, Tudor Groza, Damian Smedley, Melissa A. Haendel, Chris Mungall, and Peter N. Robinson

Published

2019

9. Projet OrphaOnto - Première étape de l'ontologisation des bases de connaissances d'Orphanet.

Author

Ferdinand Dhombres, Pierre-Yves Vandenbussche, Ana Rath, Marc Hanauer, Annie Olry, Bruno Urbero, and Jean Charlet

Published

2011

10. Mondo: Unifying diseases for the world, by the world

Author

Nicole A Vasilevsky, Nicolas A Matentzoglu, Sabrina Toro, Joseph E Flack, Harshad Hegde, Deepak R Unni, Gioconda F Alyea, Joanna S Amberger, Larry Babb, James P Balhoff, Taylor I Bingaman, Gully A Burns, Orion J Buske, Tiffany J Callahan, Leigh C Carmody, Paula Carrio Cordo, Lauren E Chan, George S Chang, Sean L Christiaens, Michel Dumontier, Laura E Failla, May J Flowers, H. Alpha Garrett, Jennifer L Goldstein, Dylan Gration, Tudor Groza, Marc Hanauer, Nomi L Harris, Jason A Hilton, Daniel S Himmelstein, Charles Tapley Hoyt, Megan S Kane, Sebastian Köhler, David Lagorce, Abbe Lai, Martin Larralde, Antonia Lock, Irene López Santiago, Donna R Maglott, Adriana J Malheiro, Birgit H M Meldal, Monica C Munoz-Torres, Tristan H Nelson, Frank W Nicholas, David Ochoa, Daniel P Olson, Tudor I Oprea, David Osumi-Sutherland, Helen Parkinson, Zoë May Pendlington, Ana Rath, Heidi L Rehm, Lyubov Remennik, Erin R Riggs, Paola Roncaglia, Justyne E Ross, Marion F Shadbolt, Kent A Shefchek, Morgan N Similuk, Nicholas Sioutos, Damian Smedley, Rachel Sparks, Ray Stefancsik, Ralf Stephan, Andrea L Storm, Doron Stupp, Gregory S Stupp, Jagadish Chandrabose Sundaramurthi, Imke Tammen, Darin Tay, Courtney L Thaxton, Eloise Valasek, Jordi Valls-Margarit, Alex H Wagner, Danielle Welter, Patricia L Whetzel, Lori L Whiteman, Valerie Wood, Colleen H Xu, Andreas Zankl, Xingmin Aaron Zhang, Christopher G Chute, Peter N Robinson, Christopher J Mungall, Ada Hamosh, and Melissa A Haendel

Abstract

There are thousands of distinct disease entities and concepts, each of which are known by different and sometimes contradictory names. The lack of a unified system for managing these entities poses a major challenge for both machines and humans that need to harmonize information to better predict causes and treatments for disease. The Mondo Disease Ontology is an open, community-driven ontology that integrates key medical and biomedical terminologies, supporting disease data integration to improve diagnosis, treatment, and translational research. Mondo records the sources of all data and is continually updated, making it suitable for research and clinical applications that require up-to-date disease knowledge.

Published

2022

11. OntoOrpha: An Ontology to Support Edition and Audit of Knowledge of Rare Diseases in ORPHANET.

Author

Ferdinand Dhombres, Pierre-Yves Vandenbussche, Ana Rath, Marc Hanauer, Annie Olry, Bruno Urbero, Rémy Choquet, and Jean Charlet

Published

2011

12. Enabling FAIR Discovery of Rare Disease Digital Resources

Author

Rajaram, Kaliyaperumal, Núria, Queralt Rosinach, Kees, Burger, Luiz Olavo, Bonino da Silva Santos, Marc, Hanauer, and Marco, Roos

Subjects

Internet, Metadata, Rare Diseases, Databases, Factual, Humans, Software, Semantics

Abstract

Integration of heterogenous resources is key for Rare Disease research. Within the EJP RD, common Application Programming Interface specifications are proposed for discovery of resources and data records. This is not sufficient for automated processing between RD resources and meeting the FAIR principles.To design a solution to improve FAIR for machines for the EJP RD API specification.A FAIR Data Point is used to expose machine-actionable metadata of digital resources and it is configured to store its content to a semantic database to be FAIR at the source.A solution was designed based on grlc server as middleware to implement the EJP RD API specification on top of the FDP.grlc reduces potential API implementation overhead faced by maintainers who use FAIR at the source.

Published

2021

13. The Human Phenotype Ontology in 2021

Author

Christopher J. Mungall, Matthias Haimel, Fabian Hauck, Marc Hanauer, Nicolas Matentzoglu, Ganna Balagura, Ingo Helbig, Julie A. McMurry, Avi Z. Rosenberg, Amy Brower, Johanna L. Est, Julia Pazmandi, Maximilian Hastreiter, Melissa A. Haendel, Peter D. Galer, Nomi L. Harris, Gerhard Kindle, Michael Hartnett, Daniel Danis, Hugh Kearney, Shiva Ganesan, Yongqun He, Michael A. Gargano, Rebecca L. Peters, Matthias Griese, Roland Krause, Damian Smedley, Shahmir A. Rind, Katrin Knoflach, Tim Jeske, Gareth Baynam, Peter N. Robinson, Michael M. Segal, Leigh C. Carmody, David Lagorce, Monica Munoz-Torres, Christopher G. Chute, Christoph Klein, Zafer Yüksel, Jillian A. Miller, Tomer Talmy, Christina K Rapp, Julie Xian, Tiffany J. Callahan, Samuel A. Wiafe, David Lewis-Smith, Ana Rath, Nicole Vasilevsky, Yarlalu Thomas, Markus G. Seidel, and Sebastian Köhler

Subjects

endocrine system, Databases, Factual, Genotype, AcademicSubjects/SCI00010, International Cooperation, Biology, 03 medical and health sciences, 0302 clinical medicine, Human disease, Neonatal Screening, Electronic health record, Terminology as Topic, Human Phenotype Ontology, Genetics, Database Issue, Animals, Humans, Disease, 030304 developmental biology, 0303 health sciences, Internet, Genome, Extramural, fungi, Infant, Newborn, Computational Biology, Biological Ontologies, equipment and supplies, Data science, body regions, Disease Models, Animal, Phenotype, Pharmacogenetics, Clinical validity, International league against epilepsy, 030217 neurology & neurosurgery, Software

Abstract

The Human Phenotype Ontology (HPO, https://hpo.jax.org) was launched in 2008 to provide a comprehensive logical standard to describe and computationally analyze phenotypic abnormalities found in human disease. The HPO is now a worldwide standard for phenotype exchange. The HPO has grown steadily since its inception due to considerable contributions from clinical experts and researchers from a diverse range of disciplines. Here, we present recent major extensions of the HPO for neurology, nephrology, immunology, pulmonology, newborn screening, and other areas. For example, the seizure subontology now reflects the International League Against Epilepsy (ILAE) guidelines and these enhancements have already shown clinical validity. We present new efforts to harmonize computational definitions of phenotypic abnormalities across the HPO and multiple phenotype ontologies used for animal models of disease. These efforts will benefit software such as Exomiser by improving the accuracy and scope of cross-species phenotype matching. The computational modeling strategy used by the HPO to define disease entities and phenotypic features and distinguish between them is explained in detail.We also report on recent efforts to translate the HPO into indigenous languages. Finally, we summarize recent advances in the use of HPO in electronic health record systems.

Published

2021

14. The ELIXIR Human Copy Number Variations Community: building bioinformatics infrastructure for research

Author

Joaquín Dopazo, Gary Saunders, Cristina Y. González, Ivo Gut, Michael Baudis, Dietlind Gerloff, Morris A. Swertz, Ana Rath, Katalin Monostory, Attila Gyenesei, Denise Carvalho-Silva, Jan O. Korbel, Tomas Marques-Bonet, Christophe Béroud, Thomas Keane, Daoud Sie, Marko Vidak, Brane Leskošek, Victoria Dominguez Del Angel, Steve Laurie, Hailiang Mei, Sergi Beltran, Lennart Johansson, Bo Gao, Eivind Hovig, Krzysztof Poterlowicz, John M. Hancock, Salvador Capella-Gutierrez, Kirill Tsukanov, Alfonso Valencia, Ferran Sanz, David Lloyd, Pubudu S. Samarakoon, Janet Piñero, David Salgado, Katharina B Lauer, Laura I. Furlong, Leyla Garcia, Nina Habermann, Bauke Ylstra, Irina M. Armean, Marc Hanauer, Groningen Institute for Gastro Intestinal Genetics and Immunology (3GI), Human genetics, CCA - Cancer biology and immunology, and Pathology

Subjects

Community building, DNA Copy Number Variations, Computer science, viruses, Data analysis, Context (language use), Oncogenetics, DNA Copy Number Variations/genetics, General Biochemistry, Genetics and Molecular Biology, Genomic screening, Population genomics, Common Diseases, White paper, Human disease, Humans, Copy-number variation, General Pharmacology, Toxicology and Pharmaceutics, computer.programming_language, whole genome sequencing, General Immunology and Microbiology, Computational Biology, High-Throughput Nucleotide Sequencing, Human Genetics, General Medicine, Articles, Opinion Article, Data science, Copy Number Variation, Genòmica, Malalties -- Diagnòstic, Malalties, next-generation sequencing, Elixir (programming language), Malalties congènites, computer, Federated Human Data

Abstract

Copy number variations (CNVs) are major causative contributors both in the genesis of genetic diseases and human neoplasias. While "High-Throughput" sequencing technologies are increasingly becoming the primary choice for genomic screening analysis, their ability to efficiently detect CNVs is still heterogeneous and remains to be developed. The aim of this white paper is to provide a guiding framework for the future contributions of ELIXIR's recently established h uman CNV Community, with implications beyond human disease diagnostics and population genomics. This white paper is the direct result of a strategy meeting that took place in September 2018 in Hinxton (UK) and involved representatives of 11 ELIXIR Nodes. The meeting led to the definition of priority objectives and tasks, to address a wide range of CNV-related challenges ranging from detection and interpretation to sharing and training. Here, we provide suggestions on how to align these tasks within the ELIXIR Platforms strategy, and on how to frame the activities of this new ELIXIR Community in the international context. The first ELIXIR hCNV Community meeting held in Hinxton (UK) was supported by ELIXIR. The authors declare that no grants were involved in supporting this work

Published

2020

15. Expansion of the Human Phenotype Ontology (HPO) knowledge base and resources

Author

Kayli Rageth, Cynthia L. Smith, Renske Oegema, Julius O.B. Jacobsen, Xingmin Aaron Zhang, Kathleen E. Sullivan, James P. Balhoff, Ayushi Hegde, David Osumi-Sutherland, Gareth Baynam, Rachel Thompson, Matthew T. Wheeler, Cornelius F. Boerkoel, Hélène Dollfus, Nomi L. Harris, Daniel Durkin, Dorothée Leroux, Joshua D. Milner, Melissa A. Haendel, Annie Olry, Dylan Gratian, Nicolas Matentzoglu, Anna Jansen, David Gómez-Andrés, Zafer Yüksel, Hugh Dawkins, Peter N. Robinson, Ruth C. Lovering, Luigi D. Notarangelo, Michael M. Segal, Maria G. Della Rocca, Sergio Rosenzweig, Julie A. McMurry, Catherine Hajek, Francisco Castellanos, Valentina Cipriani, Willie H. Chang, Sergi Beltran, Ahmed Muaz, Leigh C. Carmody, Marc Hanauer, Jenna R.E. Bergerson, Hanns Lochmüller, Halima Lourghi, Tom Conlin, Charlotte Cunningham-Rundles, James R. Priest, Richard Palmer, Shruti Marwaha, Panagiotis I. Sergouniotis, Amy D. Klion, Alexandra F. Freeman, Morgan Similuk, Michael Brudno, Melody C. Carter, Stanley J. F. Laulederkind, Michael A. Gargano, Susan M. Bello, Tudor Groza, Christopher J. Mungall, Damian Smedley, Hannah Blau, Daniel Danis, Jean-Philippe F. Gourdine, Sebastian Köhler, Murat Sincan, Ana Rath, Nicole Vasilevsky, Andrea L. Storm, Public Health Sciences, Mental Health and Wellbeing research group, Neurogenetics, and Pediatrics

Subjects

Vocabulary, media_common.quotation_subject, Knowledge Bases, Interoperability, Biology, Ontology (information science), Congenital Abnormalities, World Wide Web, 03 medical and health sciences, 0302 clinical medicine, Rare Diseases, Information and Computing Sciences, Human Phenotype Ontology, Databases, Genetic, Genetics, Database Issue, Humans, Genetic Predisposition to Disease, 030304 developmental biology, media_common, 0303 health sciences, Internet, Whole Genome Sequencing, business.industry, Computational Biology, Genetic Variation, Biological Ontologies, Biological Sciences, 3. Good health, Phenotype, Knowledge base, The Internet, business, Environmental Sciences, 030217 neurology & neurosurgery, Developmental Biology, De facto standard

Abstract

National Institutes of Health (NIH), Monarch Initiative [OD #5R24OD011883]; Forums for Integrative Phenomics [U13 CA221044-01]; NCATS Data Translator [1OT3TR002019]; NCATS National Center for Digital Health Informatics Innovation [U24 TR002306];NIH Data Commons [1 OT3 OD02464-01 UNCCH]; Cost Action CA 16118 Neuro-MIG; British Heart Foundation Programme Grant [RG/13/5/30112]; Division of Intramural Research; NIAID; NIH; E-RARE project Hipbi-RD [01GM1608]; European Union's Horizon 2020 Research and Innovation Programme [779257]. Funding for open access charge: NIH; Donald A. Roux Family Fund (to P.N.R.). The Human Phenotype Ontology (HPO) - a standardized vocabulary of phenotypic abnormalities associated with 7000+ diseases - is used by thousands of researchers, clinicians, informaticians and electronic health record systems around the world. Its detailed descriptions of clinical abnormalities and computable disease definitions have made HPO the de facto standard for deep phenotyping in the field of rare disease. The HPO's interoperability with other ontologies has enabled it to be used to improve diagnostic accuracy by incorporating model organism data. It also plays a key role in the popular Exomiser tool, which identifies potential disease-causing variants from whole-exome or whole-genome sequencing data. Since the HPO was first introduced in 2008, its users have become both more numerous and more diverse. To meet these emerging needs, the project has added new content, language translations, mappings and computational tooling, as well as integrations with external community data. The HPO continues to collaborate with clinical adopters to improve specific areas of the ontology and extend standardized disease descriptions. The newly redesigned HPO website (www.human-phenotype-ontology.org) simplifies browsing terms and exploring clinical features, diseases, and human genes.

Published

2019

16. Improved Diagnosis and Care for Rare Diseases through Implementation of Precision Public Health Framework

Author

Gareth, Baynam, Faye, Bowman, Karla, Lister, Caroline E, Walker, Nicholas, Pachter, Jack, Goldblatt, Kym M, Boycott, William A, Gahl, Kenjiro, Kosaki, Takeya, Adachi, Ken, Ishii, Trinity, Mahede, Fiona, McKenzie, Sharron, Townshend, Jennie, Slee, Cathy, Kiraly-Borri, Anand, Vasudevan, Anne, Hawkins, Stephanie, Broley, Lyn, Schofield, Hedwig, Verhoef, Tudor, Groza, Andreas, Zankl, Peter N, Robinson, Melissa, Haendel, Michael, Brudno, John S, Mattick, Marcel E, Dinger, Tony, Roscioli, Mark J, Cowley, Annie, Olry, Marc, Hanauer, Fowzan S, Alkuraya, Domenica, Taruscio, Manuel, Posada de la Paz, Hanns, Lochmüller, Kate, Bushby, Rachel, Thompson, Victoria, Hedley, Paul, Lasko, Kym, Mina, John, Beilby, Cynthia, Tifft, Mark, Davis, Nigel G, Laing, Daria, Julkowska, Yann, Le Cam, Sharon F, Terry, Petra, Kaufmann, Iiro, Eerola, Irene, Norstedt, Ana, Rath, Makoto, Suematsu, Stephen C, Groft, Christopher P, Austin, Ruxandra, Draghia-Akli, Tarun S, Weeramanthri, Caron, Molster, and Hugh J S, Dawkins

Subjects

Phenotype, Rare Diseases, Predictive Value of Tests, Health Policy, Humans, Genetic Predisposition to Disease, Genomics, Public Health, Precision Medicine, Program Development, Policy Making, Prognosis, Program Evaluation

Abstract

Public health relies on technologies to produce and analyse data, as well as effectively develop and implement policies and practices. An example is the public health practice of epidemiology, which relies on computational technology to monitor the health status of populations, identify disadvantaged or at risk population groups and thereby inform health policy and priority setting. Critical to achieving health improvements for the underserved population of people living with rare diseases is early diagnosis and best care. In the rare diseases field, the vast majority of diseases are caused by destructive but previously difficult to identify protein-coding gene mutations. The reduction in cost of genetic testing and advances in the clinical use of genome sequencing, data science and imaging are converging to provide more precise understandings of the 'person-time-place' triad. That is: who is affected (people); when the disease is occurring (time); and where the disease is occurring (place). Consequently we are witnessing a paradigm shift in public health policy and practice towards 'precision public health'.Patient and stakeholder engagement has informed the need for a national public health policy framework for rare diseases. The engagement approach in different countries has produced highly comparable outcomes and objectives. Knowledge and experience sharing across the international rare diseases networks and partnerships has informed the development of the Western Australian Rare Diseases Strategic Framework 2015-2018 (RD Framework) and Australian government health briefings on the need for a National plan.The RD Framework is guiding the translation of genomic and other technologies into the Western Australian health system, leading to greater precision in diagnostic pathways and care, and is an example of how a precision public health framework can improve health outcomes for the rare diseases population.Five vignettes are used to illustrate how policy decisions provide the scaffolding for translation of new genomics knowledge, and catalyze transformative change in delivery of clinical services. The vignettes presented here are from an Australian perspective and are not intended to be comprehensive, but rather to provide insights into how a new and emerging 'precision public health' paradigm can improve the experiences of patients living with rare diseases, their caregivers and families.The conclusion is that genomic public health is informed by the individual and family needs, and the population health imperatives of an early and accurate diagnosis; which is the portal to best practice care. Knowledge sharing is critical for public health policy development and improving the lives of people living with rare diseases.

Published

2017

17. Harmonising phenomics information for a better interoperability in the rare disease field

Author

Michael Brudno, Ana Rath, Helen Parkinson, Tudor Groza, Marc Hanauer, Sebastian Köhler, Simon Jupp, Charlotte Rodwell, Dominik Seelow, Halima Lourghi, Sylvie Maiella, Valérie Lanneau, Annie Olry, Peter N. Robinson, and Bruno Donadille

Subjects

0301 basic medicine, Databases, Factual, Interoperability, Computational Biology, Biological Ontologies, General Medicine, Ontology (information science), Data science, 3. Good health, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Resource (project management), Phenomics, Phenotype, Rare Diseases, Controlled vocabulary, Human Phenotype Ontology, Genetics, Humans, Exome, 030217 neurology & neurosurgery, Genetics (clinical), Software

Abstract

HIPBI-RD (Harmonising phenomics information for a better interoperability in the rare disease field) is a three-year project which started in 2016 funded via the E-Rare 3 ERA-NET program. This project builds on three resources largely adopted by the rare disease (RD) community: Orphanet, its ontology ORDO (the Orphanet Rare Disease Ontology), HPO (the Human Phenotype Ontology) as well as PhenoTips software for the capture and sharing of structured phenotypic data for RD patients. Our project is further supported by resources developed by the European Bioinformatics Institute and the Garvan Institute. HIPBI-RD aims to provide the community with an integrated, RD-specific bioinformatics ecosystem that will harmonise the way phenomics information is stored in databases and patient files worldwide, and thereby contribute to interoperability. This ecosystem will consist of a suite of tools and ontologies, optimized to work together, and made available through commonly used software repositories. The project workplan follows three main objectives: The HIPBI-RD ecosystem will contribute to the interpretation of variants identified through exome and full genome sequencing by harmonising the way phenotypic information is collected, thus improving diagnostics and delineation of RD. The ultimate goal of HIPBI-RD is to provide a resource that will contribute to bridging genome-scale biology and a disease-centered view on human pathobiology. Achievements in Year 1.

Published

2017

18. Improved Diagnosis and Care for Rare Diseases through Implementation of Precision Public Health Framework

Author

Michael Brudno, Victoria Hedley, Anne Hawkins, Anand Vasudevan, Cynthia J. Tifft, Ruxandra Draghia-Akli, Christopher P. Austin, Stephen C. Groft, Paul Lasko, Nigel G. Laing, Hedwig Verhoef, Iiro Eerola, Tudor Groza, Cathy Kiraly-Borri, Lyn Schofield, Melissa A. Haendel, Trinity Mahede, John S. Mattick, Stephanie Broley, Hugh Dawkins, Rachel Thompson, Yann Le Cam, Jack Goldblatt, Peter N. Robinson, Kate Bushby, Nicholas Pachter, Kenjiro Kosaki, Caroline E. Walker, Daria Julkowska, Gareth Baynam, Domenica Taruscio, Hanns Lochmüller, Marcel E. Dinger, Manuel Posada de la Paz, Caron Molster, Annie Olry, William A. Gahl, Jennie Slee, Sharron Townshend, Andreas Zankl, Fowzan S. Alkuraya, Fiona Haslam McKenzie, Faye L. Bowman, Makoto Suematsu, Tarun Weeramanthri, Ken Ishii, Takeya Adachi, Petra Kaufmann, Kym M. Boycott, Mark M. Davis, Kym Mina, Karla J. Lister, John Beilby, Irene Norstedt, Marc Hanauer, Tony Roscioli, Ana Rath, Mark J. Cowley, and Sharon F. Terry

Subjects

0301 basic medicine, medicine.medical_specialty, medicine.diagnostic_test, business.industry, Public health, Disease, 030105 genetics & heredity, Public relations, Gene mutation, Disadvantaged, 03 medical and health sciences, Underserved Population, Epidemiology, medicine, Business, Health policy, Genetic testing

Abstract

Public health relies on technologies to produce and analyse data, as well as effectively develop and implement policies and practices. An example is the public health practice of epidemiology, which relies on computational technology to monitor the health status of populations, identify disadvantaged or at risk population groups and thereby inform health policy and priority setting. Critical to achieving health improvements for the underserved population of people living with rare diseases is early diagnosis and best care. In the rare diseases field, the vast majority of diseases are caused by destructive but previously difficult to identify protein-coding gene mutations. The reduction in cost of genetic testing and advances in the clinical use of genome sequencing, data science and imaging are converging to provide more precise understandings of the ‘person-time-place’ triad. That is: who is affected (people); when the disease is occurring (time); and where the disease is occurring (place). Consequently we are witnessing a paradigm shift in public health policy and practice towards ‘precision public health’.

Published

2017

19. Rare diseases knowledge curation in an ontology-based architecture in Orphanet

Author

Ferdinand Dhombres, Pierre-Yves Vandenbussche, Rémy Choquet, Jos de Roo, Ana Rath, Annie Olry, Marc Hanauer, Bruno Urbero, Ségolène Aymé, Jean Charlet, and Charlet, Jean

Subjects

[INFO.INFO-AI] Computer Science [cs]/Artificial Intelligence [cs.AI], ontology terminology knowledge organisation system knowledge base curation rare diseases OntoOrpha, terminology, rare diseases, ontology, knowledge organisation system, OntoOrpha, knowledge base curation

Abstract

ORPHANET is a reference information portal on rare diseases and orphan drugs for healthcare professionals and general audiences. After ten years of evolution, the current ORPHANET tools and knowledge representation cannot represent appropriately the constantly evolving knowledge on rare diseases. ORPHANET knowledge base has evolved from a simple thesaurus to a multi-classification terminology over the years, without refactoring the knowledge organization from the top (using a metamodel or/and an ontology). We propose in this paper to review the knowledge organization of ORPHANET by introducing a core ontology for rare diseases that has the specificity to also model classifications. We are conducting research to build and use a rare diseases knowledge base in an ontology-based architecture that complies with the W3C standards of the semantic web : OWL, RDF, SPARQL and SKOS. Using a specific knowledge cycle, we propose new edition, validation and sharing processes for rare diseases knowledge in ORPHANET. We show in this paper that ontologies are designed to manage the generation of multi-classifications into complex knowledge organization systems (KOS). We also demonstrate that the introduction of formal knowledge representation systems (OWL) improved ORPHANET knowledge base quality. This experiment highlights a continuity in the use of different knowledge organization systems. Nevertheless, the complex knowledge curation of this domain involves a formalization that can be appropriately supported only by the use of rules and an ontology.

Published

2011

20. New functionalities in Orphanet for orphan drugs, R&D and marketing authorisations to better serve the rare diseases community

Author

Marc Hanauer, Virginie Hivert, Natalia Martin, Ségolène Aymé, Orphanet - Plateforme maladies rares, Institut National de la Santé et de la Recherche Médicale (INSERM), and BMC, Ed.

Subjects

Medicine(all), Principal (computer security), Pharmacology toxicology, lcsh:R, Authorization, lcsh:Medicine, Listing (computer), General Medicine, [SDV.GEN] Life Sciences [q-bio]/Genetics, Trade name, Orphan drug, Poster Presentation, European market, Genetics(clinical), Pharmacology (medical), Business, Marketing, Genetics (clinical), ComputingMilieux_MISCELLANEOUS, Rare disease

Abstract

The data contained in the Orphanet "Orphan Drugs" database is extracted from official sources. This data includes a list of all substances which have been granted an orphan designation for a disease(s) considered as rare in Europe, whether further developed to become drugs with marketing authorisation (MA) or not. The Orphanet database also includes drugs without an orphan designation as long as they have been granted a MA with a specific indication for a rare disease. Orphanet also publishes a quarterly report ("Orphanet Report Series") listing orphan drugs on the European market with or without prior orphan designation. In order to improve access to Orphanet’s rich database of information and resources, the search engine has been recalibrated to render data more accessible. In addition to existing search options (by drug or disease), four new sub-tabs improve the visibility of information pertaining to orphan drugs, allowing users to search by a wider range of criteria. Several alphabetical lists of designated products, orphan-designated products with MA, substances and drug trade names are now available. New advanced search options allow users to refine their search by sponsor, MA holder and ATC (Anatomic, Therapeutic, Chemical) category. Substances are now clearly separated from trade names in the results pages: trade names are used solely for products granted MA, whereas substances with orphan designation status (prior to MA) are referred to by their active molecule. Additionally, each substance or trade name is linked to the "Clinical trials" sub-tab of the "Research and trials" tab. Users can retrieve clinical trial(s) that are (or have been) performed for a particular drug. These can also be searched by a wider range of criteria (disease concerned, principal investigator by country, sponsor or clinical trial category). These features are available in all five languages of the Orphanet website.

Published

2010