Your search keyword '"Moxon, Sierra"' showing total 41 results

1. MapperGPT: Large Language Models for Linking and Mapping Entities

Author

Matentzoglu, Nicolas, Caufield, J. Harry, Hegde, Harshad B., Reese, Justin T., Moxon, Sierra, Kim, Hyeongsik, Harris, Nomi L., Haendel, Melissa A, and Mungall, Christopher J.

Subjects

Computer Science - Computation and Language, Computer Science - Artificial Intelligence

Abstract

Aligning terminological resources, including ontologies, controlled vocabularies, taxonomies, and value sets is a critical part of data integration in many domains such as healthcare, chemistry, and biomedical research. Entity mapping is the process of determining correspondences between entities across these resources, such as gene identifiers, disease concepts, or chemical entity identifiers. Many tools have been developed to compute such mappings based on common structural features and lexical information such as labels and synonyms. Lexical approaches in particular often provide very high recall, but low precision, due to lexical ambiguity. As a consequence of this, mapping efforts often resort to a labor intensive manual mapping refinement through a human curator. Large Language Models (LLMs), such as the ones employed by ChatGPT, have generalizable abilities to perform a wide range of tasks, including question-answering and information extraction. Here we present MapperGPT, an approach that uses LLMs to review and refine mapping relationships as a post-processing step, in concert with existing high-recall methods that are based on lexical and structural heuristics. We evaluated MapperGPT on a series of alignment tasks from different domains, including anatomy, developmental biology, and renal diseases. We devised a collection of tasks that are designed to be particularly challenging for lexical methods. We show that when used in combination with high-recall methods, MapperGPT can provide a substantial improvement in accuracy, beating state-of-the-art (SOTA) methods such as LogMap.

Published

2023

2. Structured Prompt Interrogation and Recursive Extraction of Semantics (SPIRES): a method for populating knowledge bases using zero-shot learning

Author

Caufield, J Harry, Hegde, Harshad, Emonet, Vincent, Harris, Nomi L, Joachimiak, Marcin P, Matentzoglu, Nicolas, Kim, HyeongSik, Moxon, Sierra, Reese, Justin T, Haendel, Melissa A, Robinson, Peter N, and Mungall, Christopher J

Subjects

Data Management and Data Science, Information and Computing Sciences, Networking and Information Technology R&D (NITRD), Generic health relevance, Semantics, Knowledge Bases, Databases, Factual, Mathematical Sciences, Biological Sciences, Bioinformatics, Biological sciences, Information and computing sciences, Mathematical sciences

Abstract

MotivationCreating knowledge bases and ontologies is a time consuming task that relies on manual curation. AI/NLP approaches can assist expert curators in populating these knowledge bases, but current approaches rely on extensive training data, and are not able to populate arbitrarily complex nested knowledge schemas.ResultsHere we present Structured Prompt Interrogation and Recursive Extraction of Semantics (SPIRES), a Knowledge Extraction approach that relies on the ability of Large Language Models (LLMs) to perform zero-shot learning and general-purpose query answering from flexible prompts and return information conforming to a specified schema. Given a detailed, user-defined knowledge schema and an input text, SPIRES recursively performs prompt interrogation against an LLM to obtain a set of responses matching the provided schema. SPIRES uses existing ontologies and vocabularies to provide identifiers for matched elements. We present examples of applying SPIRES in different domains, including extraction of food recipes, multi-species cellular signaling pathways, disease treatments, multi-step drug mechanisms, and chemical to disease relationships. Current SPIRES accuracy is comparable to the mid-range of existing Relation Extraction methods, but greatly surpasses an LLM's native capability of grounding entities with unique identifiers. SPIRES has the advantage of easy customization, flexibility, and, crucially, the ability to perform new tasks in the absence of any new training data. This method supports a general strategy of leveraging the language interpreting capabilities of LLMs to assemble knowledge bases, assisting manual knowledge curation and acquisition while supporting validation with publicly-available databases and ontologies external to the LLM.Availability and implementationSPIRES is available as part of the open source OntoGPT package: https://github.com/monarch-initiative/ontogpt.

Published

2024

3. The Monarch Initiative in 2024: an analytic platform integrating phenotypes, genes and diseases across species

Author

Putman, Tim E, Schaper, Kevin, Matentzoglu, Nicolas, Rubinetti, Vincent P, Alquaddoomi, Faisal S, Cox, Corey, Caufield, J Harry, Elsarboukh, Glass, Gehrke, Sarah, Hegde, Harshad, Reese, Justin T, Braun, Ian, Bruskiewich, Richard M, Cappelletti, Luca, Carbon, Seth, Caron, Anita R, Chan, Lauren E, Chute, Christopher G, Cortes, Katherina G, De Souza, Vinícius, Fontana, Tommaso, Harris, Nomi L, Hartley, Emily L, Hurwitz, Eric, Jacobsen, Julius OB, Krishnamurthy, Madan, Laraway, Bryan J, McLaughlin, James A, McMurry, Julie A, Moxon, Sierra AT, Mullen, Kathleen R, O’Neil, Shawn T, Shefchek, Kent A, Stefancsik, Ray, Toro, Sabrina, Vasilevsky, Nicole A, Walls, Ramona L, Whetzel, Patricia L, Osumi-Sutherland, David, Smedley, Damian, Robinson, Peter N, Mungall, Christopher J, Haendel, Melissa A, and Munoz-Torres, Monica C

Subjects

Biological Sciences, Genetics, Networking and Information Technology R&D (NITRD), Data Science, Good Health and Well Being, Humans, Phenotype, Internet, Databases, Factual, Software, Genes, Disease, Environmental Sciences, Information and Computing Sciences, Developmental Biology, Biological sciences, Chemical sciences, Environmental sciences

Abstract

Bridging the gap between genetic variations, environmental determinants, and phenotypic outcomes is critical for supporting clinical diagnosis and understanding mechanisms of diseases. It requires integrating open data at a global scale. The Monarch Initiative advances these goals by developing open ontologies, semantic data models, and knowledge graphs for translational research. The Monarch App is an integrated platform combining data about genes, phenotypes, and diseases across species. Monarch's APIs enable access to carefully curated datasets and advanced analysis tools that support the understanding and diagnosis of disease for diverse applications such as variant prioritization, deep phenotyping, and patient profile-matching. We have migrated our system into a scalable, cloud-based infrastructure; simplified Monarch's data ingestion and knowledge graph integration systems; enhanced data mapping and integration standards; and developed a new user interface with novel search and graph navigation features. Furthermore, we advanced Monarch's analytic tools by developing a customized plugin for OpenAI's ChatGPT to increase the reliability of its responses about phenotypic data, allowing us to interrogate the knowledge in the Monarch graph using state-of-the-art Large Language Models. The resources of the Monarch Initiative can be found at monarchinitiative.org and its corresponding code repository at github.com/monarch-initiative/monarch-app.

Published

2024

4. Structured prompt interrogation and recursive extraction of semantics (SPIRES): A method for populating knowledge bases using zero-shot learning

Author

Caufield, J. Harry, Hegde, Harshad, Emonet, Vincent, Harris, Nomi L., Joachimiak, Marcin P., Matentzoglu, Nicolas, Kim, HyeongSik, Moxon, Sierra A. T., Reese, Justin T., Haendel, Melissa A., Robinson, Peter N., and Mungall, Christopher J.

Subjects

Computer Science - Artificial Intelligence, Computer Science - Machine Learning

Abstract

Creating knowledge bases and ontologies is a time consuming task that relies on a manual curation. AI/NLP approaches can assist expert curators in populating these knowledge bases, but current approaches rely on extensive training data, and are not able to populate arbitrary complex nested knowledge schemas. Here we present Structured Prompt Interrogation and Recursive Extraction of Semantics (SPIRES), a Knowledge Extraction approach that relies on the ability of Large Language Models (LLMs) to perform zero-shot learning (ZSL) and general-purpose query answering from flexible prompts and return information conforming to a specified schema. Given a detailed, user-defined knowledge schema and an input text, SPIRES recursively performs prompt interrogation against GPT-3+ to obtain a set of responses matching the provided schema. SPIRES uses existing ontologies and vocabularies to provide identifiers for all matched elements. We present examples of use of SPIRES in different domains, including extraction of food recipes, multi-species cellular signaling pathways, disease treatments, multi-step drug mechanisms, and chemical to disease causation graphs. Current SPIRES accuracy is comparable to the mid-range of existing Relation Extraction (RE) methods, but has the advantage of easy customization, flexibility, and, crucially, the ability to perform new tasks in the absence of any training data. This method supports a general strategy of leveraging the language interpreting capabilities of LLMs to assemble knowledge bases, assisting manual knowledge curation and acquisition while supporting validation with publicly-available databases and ontologies external to the LLM. SPIRES is available as part of the open source OntoGPT package: https://github.com/ monarch-initiative/ontogpt., Comment: Updated 2023-12-22

Published

2023

5. KG-Hub—building and exchanging biological knowledge graphs

Author

Caufield, J Harry, Putman, Tim, Schaper, Kevin, Unni, Deepak R, Hegde, Harshad, Callahan, Tiffany J, Cappelletti, Luca, Moxon, Sierra AT, Ravanmehr, Vida, Carbon, Seth, Chan, Lauren E, Cortes, Katherina, Shefchek, Kent A, Elsarboukh, Glass, Balhoff, Jim, Fontana, Tommaso, Matentzoglu, Nicolas, Bruskiewich, Richard M, Thessen, Anne E, Harris, Nomi L, Munoz-Torres, Monica C, Haendel, Melissa A, Robinson, Peter N, Joachimiak, Marcin P, Mungall, Christopher J, and Reese, Justin T

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Networking and Information Technology R&D (NITRD), Machine Learning and Artificial Intelligence, Humans, Pattern Recognition, Automated, COVID-19, Biological Ontologies, Rare Diseases, Machine Learning, Mathematical Sciences, Information and Computing Sciences, Bioinformatics, Biological sciences, Information and computing sciences, Mathematical sciences

Abstract

MotivationKnowledge graphs (KGs) are a powerful approach for integrating heterogeneous data and making inferences in biology and many other domains, but a coherent solution for constructing, exchanging, and facilitating the downstream use of KGs is lacking.ResultsHere we present KG-Hub, a platform that enables standardized construction, exchange, and reuse of KGs. Features include a simple, modular extract-transform-load pattern for producing graphs compliant with Biolink Model (a high-level data model for standardizing biological data), easy integration of any OBO (Open Biological and Biomedical Ontologies) ontology, cached downloads of upstream data sources, versioned and automatically updated builds with stable URLs, web-browsable storage of KG artifacts on cloud infrastructure, and easy reuse of transformed subgraphs across projects. Current KG-Hub projects span use cases including COVID-19 research, drug repurposing, microbial-environmental interactions, and rare disease research. KG-Hub is equipped with tooling to easily analyze and manipulate KGs. KG-Hub is also tightly integrated with graph machine learning (ML) tools which allow automated graph ML, including node embeddings and training of models for link prediction and node classification.Availability and implementationhttps://kghub.org.

Published

2023

6. The Gene Ontology knowledgebase in 2023

Author

Aleksander, Suzi A, Balhoff, James, Carbon, Seth, Cherry, J Michael, Drabkin, Harold J, Ebert, Dustin, Feuermann, Marc, Gaudet, Pascale, Harris, Nomi L, Hill, David P, Lee, Raymond, Mi, Huaiyu, Moxon, Sierra, Mungall, Christopher J, Muruganugan, Anushya, Mushayahama, Tremayne, Sternberg, Paul W, Thomas, Paul D, Van Auken, Kimberly, Ramsey, Jolene, Siegele, Deborah A, Chisholm, Rex L, Fey, Petra, Aspromonte, Maria Cristina, Nugnes, Maria Victoria, Quaglia, Federica, Tosatto, Silvio, Giglio, Michelle, Nadendla, Suvarna, Antonazzo, Giulia, Attrill, Helen, dos Santos, Gil, Marygold, Steven, Strelets, Victor, Tabone, Christopher J, Thurmond, Jim, Zhou, Pinglei, Ahmed, Saadullah H, Asanitthong, Praoparn, Buitrago, Diana Luna, Erdol, Meltem N, Gage, Matthew C, Kadhum, Mohamed Ali, Li, Kan Yan Chloe, Long, Miao, Michalak, Aleksandra, Pesala, Angeline, Pritazahra, Armalya, Saverimuttu, Shirin CC, Su, Renzhi, Thurlow, Kate E, Lovering, Ruth C, Logie, Colin, Oliferenko, Snezhana, Blake, Judith, Christie, Karen, Corbani, Lori, Dolan, Mary E, Ni, Li, Sitnikov, Dmitry, Smith, Cynthia, Cuzick, Alayne, Seager, James, Cooper, Laurel, Elser, Justin, Jaiswal, Pankaj, Gupta, Parul, Naithani, Sushma, Lera-Ramirez, Manuel, Rutherford, Kim, Wood, Valerie, De Pons, Jeffrey L, Dwinell, Melinda R, Hayman, G Thomas, Kaldunski, Mary L, Kwitek, Anne E, Laulederkind, Stanley JF, Tutaj, Marek A, Vedi, Mahima, Wang, Shur-Jen, D’Eustachio, Peter, Aimo, Lucila, Axelsen, Kristian, Bridge, Alan, Hyka-Nouspikel, Nevila, Morgat, Anne, Engel, Stacia R, Karra, Kalpana, Miyasato, Stuart R, Nash, Robert S, Skrzypek, Marek S, Weng, Shuai, Wong, Edith D, Bakker, Erika, and Berardini, Tanya Z

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, 1.1 Normal biological development and functioning, Underpinning research, Gene Ontology, Proteins, Molecular Sequence Annotation, Databases, Genetic, Computational Biology, gene annotation, gene function, knowledgebase, knowledge graphs, Gene Ontology Consortium, Developmental Biology, Biochemistry and cell biology

Abstract

The Gene Ontology (GO) knowledgebase (http://geneontology.org) is a comprehensive resource concerning the functions of genes and gene products (proteins and noncoding RNAs). GO annotations cover genes from organisms across the tree of life as well as viruses, though most gene function knowledge currently derives from experiments carried out in a relatively small number of model organisms. Here, we provide an updated overview of the GO knowledgebase, as well as the efforts of the broad, international consortium of scientists that develops, maintains, and updates the GO knowledgebase. The GO knowledgebase consists of three components: (1) the GO-a computational knowledge structure describing the functional characteristics of genes; (2) GO annotations-evidence-supported statements asserting that a specific gene product has a particular functional characteristic; and (3) GO Causal Activity Models (GO-CAMs)-mechanistic models of molecular "pathways" (GO biological processes) created by linking multiple GO annotations using defined relations. Each of these components is continually expanded, revised, and updated in response to newly published discoveries and receives extensive QA checks, reviews, and user feedback. For each of these components, we provide a description of the current contents, recent developments to keep the knowledgebase up to date with new discoveries, and guidance on how users can best make use of the data that we provide. We conclude with future directions for the project.

Published

2023

7. An approach for collaborative development of a federated biomedical knowledge graph-based question-answering system: Question-of-the-Month challenges

Author

Fecho, Karamarie, Bizon, Chris, Issabekova, Tursynay, Moxon, Sierra, Thessen, Anne E, Abdollahi, Shervin, Baranzini, Sergio E, Belhu, Basazin, Byrd, William E, Chung, Lawrence, Crouse, Andrew, Duby, Marc P, Ferguson, Stephen, Foksinska, Aleksandra, Forero, Laura, Friedman, Jennifer, Gardner, Vicki, Glusman, Gwênlyn, Hadlock, Jennifer, Hanspers, Kristina, Hinderer, Eugene, Hobbs, Charlotte, Hyde, Gregory, Huang, Sui, Koslicki, David, Mease, Philip, Muller, Sandrine, Mungall, Christopher J, Ramsey, Stephen A, Roach, Jared, Rubin, Irit, Schurman, Shepherd H, Shalev, Anath, Smith, Brett, Soman, Karthik, Stemann, Sarah, Su, Andrew I, Ta, Casey, Watkins, Paul B, Williams, Mark D, Wu, Chunlei, Xu, Colleen H, and Consortium, The Biomedical Data Translator

Subjects

Data Management and Data Science, Information and Computing Sciences, Artificial Intelligence, Translational research, team science, knowledge graphs, bioinformatics, semantic technology, Biomedical Data Translator Consortium

Abstract

Knowledge graphs have become a common approach for knowledge representation. Yet, the application of graph methodology is elusive due to the sheer number and complexity of knowledge sources. In addition, semantic incompatibilities hinder efforts to harmonize and integrate across these diverse sources. As part of The Biomedical Translator Consortium, we have developed a knowledge graph-based question-answering system designed to augment human reasoning and accelerate translational scientific discovery: the Translator system. We have applied the Translator system to answer biomedical questions in the context of a broad array of diseases and syndromes, including Fanconi anemia, primary ciliary dyskinesia, multiple sclerosis, and others. A variety of collaborative approaches have been used to research and develop the Translator system. One recent approach involved the establishment of a monthly "Question-of-the-Month (QotM) Challenge" series. Herein, we describe the structure of the QotM Challenge; the six challenges that have been conducted to date on drug-induced liver injury, cannabidiol toxicity, coronavirus infection, diabetes, psoriatic arthritis, and ATP1A3-related phenotypes; the scientific insights that have been gleaned during the challenges; and the technical issues that were identified over the course of the challenges and that can now be addressed to foster further development of the prototype Translator system. We close with a discussion on Large Language Models such as ChatGPT and highlight differences between those models and the Translator system.

Published

2023

8. Unifying the identification of biomedical entities with the Bioregistry

Author

Hoyt, Charles Tapley, Balk, Meghan, Callahan, Tiffany J, Domingo-Fernández, Daniel, Haendel, Melissa A, Hegde, Harshad B, Himmelstein, Daniel S, Karis, Klas, Kunze, John, Lubiana, Tiago, Matentzoglu, Nicolas, McMurry, Julie, Moxon, Sierra, Mungall, Christopher J, Rutz, Adriano, Unni, Deepak R, Willighagen, Egon, Winston, Donald, and Gyori, Benjamin M

Subjects

Networking and Information Technology R&D (NITRD)

Abstract

The standardized identification of biomedical entities is a cornerstone of interoperability, reuse, and data integration in the life sciences. Several registries have been developed to catalog resources maintaining identifiers for biomedical entities such as small molecules, proteins, cell lines, and clinical trials. However, existing registries have struggled to provide sufficient coverage and metadata standards that meet the evolving needs of modern life sciences researchers. Here, we introduce the Bioregistry, an integrative, open, community-driven metaregistry that synthesizes and substantially expands upon 23 existing registries. The Bioregistry addresses the need for a sustainable registry by leveraging public infrastructure and automation, and employing a progressive governance model centered around open code and open data to foster community contribution. The Bioregistry can be used to support the standardized annotation of data, models, ontologies, and scientific literature, thereby promoting their interoperability and reuse. The Bioregistry can be accessed through https://bioregistry.io and its source code and data are available under the MIT and CC0 Licenses at https://github.com/biopragmatics/bioregistry .

Published

2022

9. Biolink Model: A Universal Schema for Knowledge Graphs in Clinical, Biomedical, and Translational Science

Author

Unni, Deepak R., Moxon, Sierra A. T., Bada, Michael, Brush, Matthew, Bruskiewich, Richard, Clemons, Paul, Dancik, Vlado, Dumontier, Michel, Fecho, Karamarie, Glusman, Gustavo, Hadlock, Jennifer J., Harris, Nomi L., Joshi, Arpita, Putman, Tim, Qin, Guangrong, Ramsey, Stephen A., Shefchek, Kent A., Solbrig, Harold, Soman, Karthik, Thessen, Anne T., Haendel, Melissa A., Bizon, Chris, Mungall, Christopher J., and Consortium, the Biomedical Data Translator

Subjects

Computer Science - Databases

Abstract

Within clinical, biomedical, and translational science, an increasing number of projects are adopting graphs for knowledge representation. Graph-based data models elucidate the interconnectedness between core biomedical concepts, enable data structures to be easily updated, and support intuitive queries, visualizations, and inference algorithms. However, knowledge discovery across these "knowledge graphs" (KGs) has remained difficult. Data set heterogeneity and complexity; the proliferation of ad hoc data formats; poor compliance with guidelines on findability, accessibility, interoperability, and reusability; and, in particular, the lack of a universally-accepted, open-access model for standardization across biomedical KGs has left the task of reconciling data sources to downstream consumers. Biolink Model is an open source data model that can be used to formalize the relationships between data structures in translational science. It incorporates object-oriented classification and graph-oriented features. The core of the model is a set of hierarchical, interconnected classes (or categories) and relationships between them (or predicates), representing biomedical entities such as gene, disease, chemical, anatomical structure, and phenotype. The model provides class and edge attributes and associations that guide how entities should relate to one another. Here, we highlight the need for a standardized data model for KGs, describe Biolink Model, and compare it with other models. We demonstrate the utility of Biolink Model in various initiatives, including the Biomedical Data Translator Consortium and the Monarch Initiative, and show how it has supported easier integration and interoperability of biomedical KGs, bringing together knowledge from multiple sources and helping to realize the goals of translational science.

Published

2022

10. Recommendations for extending the GFF3 specification for improved interoperability of genomic data

Author

Saha, Surya, Cain, Scott, Cannon, Ethalinda K. S., Dunn, Nathan, Farmer, Andrew, Hu, Zhi-Liang, Maslen, Gareth, Moxon, Sierra, Mungall, Christopher J, Nelson, Rex, and Poelchau, Monica F.

Subjects

Quantitative Biology - Other Quantitative Biology

Abstract

The GFF3 format is a common, flexible tab-delimited format representing the structure and function of genes or other mapped features (https://github.com/The-Sequence-Ontology/Specifications/blob/master/gff3.md). However, with increasing re-use of annotation data, this flexibility has become an obstacle for standardized downstream processing. Common software packages that export annotations in GFF3 format model the same data and metadata in different notations, which puts the burden on end-users to interpret the data model. The AgBioData consortium is a group of genomics, genetics and breeding databases and partners working towards shared practices and standards. Providing concrete guidelines for generating GFF3, and creating a standard representation of the most common biological data types would provide a major increase in efficiency for AgBioData databases and the genomics research community that use the GFF3 format in their daily operations. The AgBioData GFF3 working group has developed recommendations to solve common problems in the GFF3 format. We suggest improvements for each of the GFF3 fields, as well as the special cases of modeling functional annotations, and standard protein-coding genes. We welcome further discussion of these recommendations. We request the genomics and bioinformatics community to utilize the github repository (https://github.com/NAL-i5K/AgBioData_GFF3_recommendation) to provide feedback via issues or pull requests., Comment: 23 pages

Published

2022

11. Biolink Model: A universal schema for knowledge graphs in clinical, biomedical, and translational science

Author

Unni, Deepak R, Moxon, Sierra AT, Bada, Michael, Brush, Matthew, Bruskiewich, Richard, Caufield, J Harry, Clemons, Paul A, Dancik, Vlado, Dumontier, Michel, Fecho, Karamarie, Glusman, Gustavo, Hadlock, Jennifer J, Harris, Nomi L, Joshi, Arpita, Putman, Tim, Qin, Guangrong, Ramsey, Stephen A, Shefchek, Kent A, Solbrig, Harold, Soman, Karthik, Thessen, Anne E, Haendel, Melissa A, Bizon, Chris, Mungall, Christopher J, Consortium, The Biomedical Data Translator, Acevedo, Liliana, Ahalt, Stanley C, Alden, John, Alkanaq, Ahmed, Amin, Nada, Avila, Ricardo, Balhoff, Jim, Baranzini, Sergio E, Baumgartner, Andrew, Baumgartner, William, Belhu, Basazin, Brandes, MacKenzie, Brandon, Namdi, Burtt, Noel, Byrd, William, Callaghan, Jackson, Cano, Marco Alvarado, Carrell, Steven, Celebi, Remzi, Champion, James, Chen, Zhehuan, Chen, Mei‐Jan, Chung, Lawrence, Cohen, Kevin, Conlin, Tom, Corkill, Dan, Costanzo, Maria, Cox, Steven, Crouse, Andrew, Crowder, Camerron, Crumbley, Mary E, Dai, Cheng, Dančík, Vlado, De Miranda Azevedo, Ricardo, Deutsch, Eric, Dougherty, Jennifer, Duby, Marc P, Duvvuri, Venkata, Edwards, Stephen, Emonet, Vincent, Fehrmann, Nathaniel, Flannick, Jason, Foksinska, Aleksandra M, Gardner, Vicki, Gatica, Edgar, Glen, Amy, Goel, Prateek, Gormley, Joseph, Greyber, Alon, Haaland, Perry, Hanspers, Kristina, He, Kaiwen, Henrickson, Jeff, Hinderer, Eugene W, Hoatlin, Maureen, Hoffman, Andrew, Huang, Sui, Huang, Conrad, Hubal, Robert, Huellas‐Bruskiewicz, Kenneth, Huls, Forest B, Hunter, Lawrence, Hyde, Greg, Issabekova, Tursynay, Jarrell, Matthew, Jenkins, Lindsay, Johs, Adam, Kang, Jimin, Kanwar, Richa, Kebede, Yaphet, Kim, Keum Joo, Kluge, Alexandria, Knowles, Michael, and Koesterer, Ryan

Subjects

Pharmacology and Pharmaceutical Sciences, Biomedical and Clinical Sciences, Cardiovascular Medicine and Haematology, Networking and Information Technology R&D (NITRD), Data Science, 2.6 Resources and infrastructure (aetiology), Aetiology, Generic health relevance, Knowledge, Pattern Recognition, Automated, Translational Science, Biomedical, Biomedical Data Translator Consortium, Cardiorespiratory Medicine and Haematology, Oncology and Carcinogenesis, Other Medical and Health Sciences, General Clinical Medicine, Cardiovascular medicine and haematology, Pharmacology and pharmaceutical sciences

Abstract

Within clinical, biomedical, and translational science, an increasing number of projects are adopting graphs for knowledge representation. Graph-based data models elucidate the interconnectedness among core biomedical concepts, enable data structures to be easily updated, and support intuitive queries, visualizations, and inference algorithms. However, knowledge discovery across these "knowledge graphs" (KGs) has remained difficult. Data set heterogeneity and complexity; the proliferation of ad hoc data formats; poor compliance with guidelines on findability, accessibility, interoperability, and reusability; and, in particular, the lack of a universally accepted, open-access model for standardization across biomedical KGs has left the task of reconciling data sources to downstream consumers. Biolink Model is an open-source data model that can be used to formalize the relationships between data structures in translational science. It incorporates object-oriented classification and graph-oriented features. The core of the model is a set of hierarchical, interconnected classes (or categories) and relationships between them (or predicates) representing biomedical entities such as gene, disease, chemical, anatomic structure, and phenotype. The model provides class and edge attributes and associations that guide how entities should relate to one another. Here, we highlight the need for a standardized data model for KGs, describe Biolink Model, and compare it with other models. We demonstrate the utility of Biolink Model in various initiatives, including the Biomedical Data Translator Consortium and the Monarch Initiative, and show how it has supported easier integration and interoperability of biomedical KGs, bringing together knowledge from multiple sources and helping to realize the goals of translational science.

Published

2022

12. A Simple Standard for Sharing Ontological Mappings (SSSOM)

Author

Matentzoglu, Nicolas, Balhoff, James P., Bello, Susan M., Bizon, Chris, Brush, Matthew, Callahan, Tiffany J., Chute, Christopher G, Duncan, William D., Evelo, Chris T., Gabriel, Davera, Graybeal, John, Gray, Alasdair, Gyori, Benjamin M., Haendel, Melissa, Harmse, Henriette, Harris, Nomi L., Harrow, Ian, Hegde, Harshad, Hoyt, Amelia L., Hoyt, Charles T., Jiao, Dazhi, Jiménez-Ruiz, Ernesto, Jupp, Simon, Kim, Hyeongsik, Koehler, Sebastian, Liener, Thomas, Long, Qinqin, Malone, James, McLaughlin, James A., McMurry, Julie A., Moxon, Sierra, Munoz-Torres, Monica C., Osumi-Sutherland, David, Overton, James A., Peters, Bjoern, Putman, Tim, Queralt-Rosinach, Núria, Shefchek, Kent, Solbrig, Harold, Thessen, Anne, Tudorache, Tania, Vasilevsky, Nicole, Wagner, Alex H., and Mungall, Christopher J.

Subjects

Computer Science - Databases

Abstract

Despite progress in the development of standards for describing and exchanging scientific information, the lack of easy-to-use standards for mapping between different representations of the same or similar objects in different databases poses a major impediment to data integration and interoperability. Mappings often lack the metadata needed to be correctly interpreted and applied. For example, are two terms equivalent or merely related? Are they narrow or broad matches? Are they associated in some other way? Such relationships between the mapped terms are often not documented, leading to incorrect assumptions and making them hard to use in scenarios that require a high degree of precision (such as diagnostics or risk prediction). Also, the lack of descriptions of how mappings were done makes it hard to combine and reconcile mappings, particularly curated and automated ones. The Simple Standard for Sharing Ontological Mappings (SSSOM) addresses these problems by: 1. Introducing a machine-readable and extensible vocabulary to describe metadata that makes imprecision, inaccuracy and incompleteness in mappings explicit. 2. Defining an easy to use table-based format that can be integrated into existing data science pipelines without the need to parse or query ontologies, and that integrates seamlessly with Linked Data standards. 3. Implementing open and community-driven collaborative workflows designed to evolve the standard continuously to address changing requirements and mapping practices. 4. Providing reference tools and software libraries for working with the standard. In this paper, we present the SSSOM standard, describe several use cases, and survey some existing work on standardizing the exchange of mappings, with the goal of making mappings Findable, Accessible, Interoperable, and Reusable (FAIR). The SSSOM specification is at http://w3id.org/sssom/spec., Comment: Corresponding author: Christopher J. Mungall

Published

2021

13. A Simple Standard for Sharing Ontological Mappings (SSSOM)

Author

Matentzoglu, Nicolas, Balhoff, James P, Bello, Susan M, Bizon, Chris, Brush, Matthew, Callahan, Tiffany J, Chute, Christopher G, Duncan, William D, Evelo, Chris T, Gabriel, Davera, Graybeal, John, Gray, Alasdair, Gyori, Benjamin M, Haendel, Melissa, Harmse, Henriette, Harris, Nomi L, Harrow, Ian, Hegde, Harshad B, Hoyt, Amelia L, Hoyt, Charles T, Jiao, Dazhi, Jiménez-Ruiz, Ernesto, Jupp, Simon, Kim, Hyeongsik, Koehler, Sebastian, Liener, Thomas, Long, Qinqin, Malone, James, McLaughlin, James A, McMurry, Julie A, Moxon, Sierra, Munoz-Torres, Monica C, Osumi-Sutherland, David, Overton, James A, Peters, Bjoern, Putman, Tim, Queralt-Rosinach, Núria, Shefchek, Kent, Solbrig, Harold, Thessen, Anne, Tudorache, Tania, Vasilevsky, Nicole, Wagner, Alex H, and Mungall, Christopher J

Subjects

Data Management and Data Science, Information and Computing Sciences, Data Science, Networking and Information Technology R&D (NITRD), Data Management, Databases, Factual, Metadata, Semantic Web, Workflow, Data Format, Library and Information Studies, Bioinformatics and computational biology, Data management and data science

Abstract

Despite progress in the development of standards for describing and exchanging scientific information, the lack of easy-to-use standards for mapping between different representations of the same or similar objects in different databases poses a major impediment to data integration and interoperability. Mappings often lack the metadata needed to be correctly interpreted and applied. For example, are two terms equivalent or merely related? Are they narrow or broad matches? Or are they associated in some other way? Such relationships between the mapped terms are often not documented, which leads to incorrect assumptions and makes them hard to use in scenarios that require a high degree of precision (such as diagnostics or risk prediction). Furthermore, the lack of descriptions of how mappings were done makes it hard to combine and reconcile mappings, particularly curated and automated ones. We have developed the Simple Standard for Sharing Ontological Mappings (SSSOM) which addresses these problems by: (i) Introducing a machine-readable and extensible vocabulary to describe metadata that makes imprecision, inaccuracy and incompleteness in mappings explicit. (ii) Defining an easy-to-use simple table-based format that can be integrated into existing data science pipelines without the need to parse or query ontologies, and that integrates seamlessly with Linked Data principles. (iii) Implementing open and community-driven collaborative workflows that are designed to evolve the standard continuously to address changing requirements and mapping practices. (iv) Providing reference tools and software libraries for working with the standard. In this paper, we present the SSSOM standard, describe several use cases in detail and survey some of the existing work on standardizing the exchange of mappings, with the goal of making mappings Findable, Accessible, Interoperable and Reusable (FAIR). The SSSOM specification can be found at http://w3id.org/sssom/spec. Database URL: http://w3id.org/sssom/spec.

Published

2022

14. Harmonizing model organism data in the Alliance of Genome Resources

Author

Agapite, Julie, Albou, Laurent-Philippe, Aleksander, Suzanne A, Alexander, Micheal, Anagnostopoulos, Anna V, Antonazzo, Giulia, Argasinska, Joanna, Arnaboldi, Valerio, Attrill, Helen, Becerra, Andrés, Bello, Susan M, Blake, Judith A, Blodgett, Olin, Bradford, Yvonne M, Bult, Carol J, Cain, Scott, Calvi, Brian R, Carbon, Seth, Chan, Juancarlos, Chen, Wen J, Cherry, J Michael, Cho, Jaehyoung, Christie, Karen R, Crosby, Madeline A, Davis, Paul, da Veiga Beltrame, Eduardo, De Pons, Jeffrey L, D’Eustachio, Peter, Diamantakis, Stavros, Dolan, Mary E, dos Santos, Gilberto, Douglass, Eric, Dunn, Barbara, Eagle, Anne, Ebert, Dustin, Engel, Stacia R, Fashena, David, Foley, Saoirse, Frazer, Ken, Gao, Sibyl, Gibson, Adam C, Gondwe, Felix, Goodman, Josh, Gramates, L Sian, Grove, Christian A, Hale, Paul, Harris, Todd, Hayman, G Thomas, Hill, David P, Howe, Douglas G, Howe, Kevin L, Hu, Yanhui, Jha, Sagar, Kadin, James A, Kaufman, Thomas C, Kalita, Patrick, Karra, Kalpana, Kishore, Ranjana, Kwitek, Anne E, Laulederkind, Stanley JF, Lee, Raymond, Longden, Ian, Luypaert, Manuel, MacPherson, Kevin A, Martin, Ryan, Marygold, Steven J, Matthews, Beverley, McAndrews, Monica S, Millburn, Gillian, Miyasato, Stuart, Motenko, Howie, Moxon, Sierra, Muller, Hans-Michael, Mungall, Christopher J, Muruganujan, Anushya, Mushayahama, Tremayne, Nalabolu, Harika S, Nash, Robert S, Ng, Patrick, Nuin, Paulo, Paddock, Holly, Paulini, Michael, Perrimon, Norbert, Pich, Christian, Quinton-Tulloch, Mark, Raciti, Daniela, Ramachandran, Sridhar, Richardson, Joel E, Gelbart, Susan Russo, Ruzicka, Leyla, Schaper, Kevin, Schindelman, Gary, Shimoyama, Mary, Simison, Matt, Shaw, David R, Shrivatsav, Ajay, Singer, Amy, Skrzypek, Marek, Smith, Constance M, and Smith, Cynthia L

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Biotechnology, Human Genome, Underpinning research, 1.5 Resources and infrastructure (underpinning), Alleles, Animals, Caenorhabditis elegans, Databases, Genetic, Drosophila, Gene Ontology, Humans, Internet, Mice, Molecular Sequence Annotation, Rats, Saccharomycetales, Zebrafish, Alliance of Genome Resources Consortium, biocuration, data mining, gene expression, gene function, gene interaction, genome, knowledgebase, phenotype, variants, Developmental Biology, Biochemistry and cell biology

Abstract

The Alliance of Genome Resources (the Alliance) is a combined effort of 7 knowledgebase projects: Saccharomyces Genome Database, WormBase, FlyBase, Mouse Genome Database, the Zebrafish Information Network, Rat Genome Database, and the Gene Ontology Resource. The Alliance seeks to provide several benefits: better service to the various communities served by these projects; a harmonized view of data for all biomedical researchers, bioinformaticians, clinicians, and students; and a more sustainable infrastructure. The Alliance has harmonized cross-organism data to provide useful comparative views of gene function, gene expression, and human disease relevance. The basis of the comparative views is shared calls of orthology relationships and the use of common ontologies. The key types of data are alleles and variants, gene function based on gene ontology annotations, phenotypes, association to human disease, gene expression, protein-protein and genetic interactions, and participation in pathways. The information is presented on uniform gene pages that allow facile summarization of information about each gene in each of the 7 organisms covered (budding yeast, roundworm Caenorhabditis elegans, fruit fly, house mouse, zebrafish, brown rat, and human). The harmonized knowledge is freely available on the alliancegenome.org portal, as downloadable files, and by APIs. We expect other existing and emerging knowledge bases to join in the effort to provide the union of useful data and features that each knowledge base currently provides.

Published

2022

15. Phenomics Assistant: An Interface for LLM-based Biomedical Knowledge Graph Exploration

Author

O’Neil, Shawn T, primary, Schaper, Kevin, additional, Elsarboukh, Glass, additional, Reese, Justin T, additional, Moxon, Sierra A T, additional, Harris, Nomi L, additional, Munoz-Torres, Monica C, additional, Robinson, Peter N, additional, Haendel, Melissa A, additional, and Mungall, Christopher J, additional

Published

2024

16. The Monarch Initiative in 2024: an analytic platform integrating phenotypes, genes and diseases across species

Author

Putman, Tim E, primary, Schaper, Kevin, additional, Matentzoglu, Nicolas, additional, Rubinetti, Vincent P, additional, Alquaddoomi, Faisal S, additional, Cox, Corey, additional, Caufield, J Harry, additional, Elsarboukh, Glass, additional, Gehrke, Sarah, additional, Hegde, Harshad, additional, Reese, Justin T, additional, Braun, Ian, additional, Bruskiewich, Richard M, additional, Cappelletti, Luca, additional, Carbon, Seth, additional, Caron, Anita R, additional, Chan, Lauren E, additional, Chute, Christopher G, additional, Cortes, Katherina G, additional, De Souza, Vinícius, additional, Fontana, Tommaso, additional, Harris, Nomi L, additional, Hartley, Emily L, additional, Hurwitz, Eric, additional, Jacobsen, Julius O B, additional, Krishnamurthy, Madan, additional, Laraway, Bryan J, additional, McLaughlin, James A, additional, McMurry, Julie A, additional, Moxon, Sierra A T, additional, Mullen, Kathleen R, additional, O’Neil, Shawn T, additional, Shefchek, Kent A, additional, Stefancsik, Ray, additional, Toro, Sabrina, additional, Vasilevsky, Nicole A, additional, Walls, Ramona L, additional, Whetzel, Patricia L, additional, Osumi-Sutherland, David, additional, Smedley, Damian, additional, Robinson, Peter N, additional, Mungall, Christopher J, additional, Haendel, Melissa A, additional, and Munoz-Torres, Monica C, additional

Published

2023

17. Model organism data evolving in support of translational medicine

Author

Howe, Douglas G., Blake, Judith A., Bradford, Yvonne M., Bult, Carol J., Calvi, Brian R., Engel, Stacia R., Kadin, James A., Kaufman, Thomas C., Kishore, Ranjana, Laulederkind, Stanley J. F., Lewis, Suzanna E., Moxon, Sierra A. T., Richardson, Joel E., and Smith, Cynthia

Published

2018

18. The Gene Ontology knowledgebase in 2023.

Author

Gene Ontology Consortium, Baryshnikova, A1, Gene Ontology Consortium, Aleksander, Suzi A, Balhoff, James, Carbon, Seth, Cherry, J Michael, Drabkin, Harold J, Ebert, Dustin, Feuermann, Marc, Gaudet, Pascale, Harris, Nomi L, Hill, David P, Lee, Raymond, Mi, Huaiyu, Moxon, Sierra, Mungall, Christopher J, Muruganugan, Anushya, Mushayahama, Tremayne, Sternberg, Paul W, Thomas, Paul D, Van Auken, Kimberly, Ramsey, Jolene, Siegele, Deborah A, Chisholm, Rex L, Fey, Petra, Aspromonte, Maria Cristina, Nugnes, Maria Victoria, Quaglia, Federica, Tosatto, Silvio, Giglio, Michelle, Nadendla, Suvarna, Antonazzo, Giulia, Attrill, Helen, Dos Santos, Gil, Marygold, Steven, Strelets, Victor, Tabone, Christopher J, Thurmond, Jim, Zhou, Pinglei, Ahmed, Saadullah H, Asanitthong, Praoparn, Luna Buitrago, Diana, Erdol, Meltem N, Gage, Matthew C, Ali Kadhum, Mohamed, Li, Kan Yan Chloe, Long, Miao, Michalak, Aleksandra, Pesala, Angeline, Pritazahra, Armalya, Saverimuttu, Shirin CC, Su, Renzhi, Thurlow, Kate E, Lovering, Ruth C, Logie, Colin, Oliferenko, Snezhana, Blake, Judith, Christie, Karen, Corbani, Lori, Dolan, Mary E, Ni, Li, Sitnikov, Dmitry, Smith, Cynthia, Cuzick, Alayne, Seager, James, Cooper, Laurel, Elser, Justin, Jaiswal, Pankaj, Gupta, Parul, Naithani, Sushma, Lera-Ramirez, Manuel, Rutherford, Kim, Wood, Valerie, De Pons, Jeffrey L, Dwinell, Melinda R, Hayman, G Thomas, Kaldunski, Mary L, Kwitek, Anne E, Laulederkind, Stanley JF, Tutaj, Marek A, Vedi, Mahima, Wang, Shur-Jen, D'Eustachio, Peter, Aimo, Lucila, Axelsen, Kristian, Bridge, Alan, Hyka-Nouspikel, Nevila, Morgat, Anne, Engel, Stacia R, Karra, Kalpana, Miyasato, Stuart R, Nash, Robert S, Skrzypek, Marek S, Weng, Shuai, Wong, Edith D, Bakker, Erika, Gene Ontology Consortium, Baryshnikova, A1, Gene Ontology Consortium, Aleksander, Suzi A, Balhoff, James, Carbon, Seth, Cherry, J Michael, Drabkin, Harold J, Ebert, Dustin, Feuermann, Marc, Gaudet, Pascale, Harris, Nomi L, Hill, David P, Lee, Raymond, Mi, Huaiyu, Moxon, Sierra, Mungall, Christopher J, Muruganugan, Anushya, Mushayahama, Tremayne, Sternberg, Paul W, Thomas, Paul D, Van Auken, Kimberly, Ramsey, Jolene, Siegele, Deborah A, Chisholm, Rex L, Fey, Petra, Aspromonte, Maria Cristina, Nugnes, Maria Victoria, Quaglia, Federica, Tosatto, Silvio, Giglio, Michelle, Nadendla, Suvarna, Antonazzo, Giulia, Attrill, Helen, Dos Santos, Gil, Marygold, Steven, Strelets, Victor, Tabone, Christopher J, Thurmond, Jim, Zhou, Pinglei, Ahmed, Saadullah H, Asanitthong, Praoparn, Luna Buitrago, Diana, Erdol, Meltem N, Gage, Matthew C, Ali Kadhum, Mohamed, Li, Kan Yan Chloe, Long, Miao, Michalak, Aleksandra, Pesala, Angeline, Pritazahra, Armalya, Saverimuttu, Shirin CC, Su, Renzhi, Thurlow, Kate E, Lovering, Ruth C, Logie, Colin, Oliferenko, Snezhana, Blake, Judith, Christie, Karen, Corbani, Lori, Dolan, Mary E, Ni, Li, Sitnikov, Dmitry, Smith, Cynthia, Cuzick, Alayne, Seager, James, Cooper, Laurel, Elser, Justin, Jaiswal, Pankaj, Gupta, Parul, Naithani, Sushma, Lera-Ramirez, Manuel, Rutherford, Kim, Wood, Valerie, De Pons, Jeffrey L, Dwinell, Melinda R, Hayman, G Thomas, Kaldunski, Mary L, Kwitek, Anne E, Laulederkind, Stanley JF, Tutaj, Marek A, Vedi, Mahima, Wang, Shur-Jen, D'Eustachio, Peter, Aimo, Lucila, Axelsen, Kristian, Bridge, Alan, Hyka-Nouspikel, Nevila, Morgat, Anne, Engel, Stacia R, Karra, Kalpana, Miyasato, Stuart R, Nash, Robert S, Skrzypek, Marek S, Weng, Shuai, Wong, Edith D, and Bakker, Erika

Abstract

The Gene Ontology (GO) knowledgebase (http://geneontology.org) is a comprehensive resource concerning the functions of genes and gene products (proteins and noncoding RNAs). GO annotations cover genes from organisms across the tree of life as well as viruses, though most gene function knowledge currently derives from experiments carried out in a relatively small number of model organisms. Here, we provide an updated overview of the GO knowledgebase, as well as the efforts of the broad, international consortium of scientists that develops, maintains, and updates the GO knowledgebase. The GO knowledgebase consists of three components: (1) the GO-a computational knowledge structure describing the functional characteristics of genes; (2) GO annotations-evidence-supported statements asserting that a specific gene product has a particular functional characteristic; and (3) GO Causal Activity Models (GO-CAMs)-mechanistic models of molecular "pathways" (GO biological processes) created by linking multiple GO annotations using defined relations. Each of these components is continually expanded, revised, and updated in response to newly published discoveries and receives extensive QA checks, reviews, and user feedback. For each of these components, we provide a description of the current contents, recent developments to keep the knowledgebase up to date with new discoveries, and guidance on how users can best make use of the data that we provide. We conclude with future directions for the project.

Published

2023

19. An approach for collaborative development of a federated biomedical knowledge graph-based question-answering system: Question-of-the-Month challenges.

Author

Belhu, Basazin, Belhu, Basazin, Byrd, William, Chung, Lawrence, Crouse, Andrew, Duby, Marc, Ferguson, Stephen, Foksinska, Aleksandra, Forero, Laura, Friedman, Jennifer, Gardner, Vicki, Glusman, Gwênlyn, Hadlock, Jennifer, Hanspers, Kristina, Hinderer, Eugene, Hobbs, Charlotte, Hyde, Gregory, Huang, Sui, Koslicki, David, Mease, Philip, Muller, Sandrine, Ramsey, Stephen, Roach, Jared, Rubin, Irit, Schurman, Shepherd, Shalev, Anath, Smith, Brett, Soman, Karthik, Stemann, Sarah, Su, Andrew, Ta, Casey, Watkins, Paul, Williams, Mark, Wu, Chunlei, Xu, Colleen, Fecho, Karamarie, Bizon, Chris, Issabekova, Tursynay, Moxon, Sierra, Thessen, Anne, Abdollahi, Shervin, Baranzini, Sergio, Mungall, Chris, Belhu, Basazin, Belhu, Basazin, Byrd, William, Chung, Lawrence, Crouse, Andrew, Duby, Marc, Ferguson, Stephen, Foksinska, Aleksandra, Forero, Laura, Friedman, Jennifer, Gardner, Vicki, Glusman, Gwênlyn, Hadlock, Jennifer, Hanspers, Kristina, Hinderer, Eugene, Hobbs, Charlotte, Hyde, Gregory, Huang, Sui, Koslicki, David, Mease, Philip, Muller, Sandrine, Ramsey, Stephen, Roach, Jared, Rubin, Irit, Schurman, Shepherd, Shalev, Anath, Smith, Brett, Soman, Karthik, Stemann, Sarah, Su, Andrew, Ta, Casey, Watkins, Paul, Williams, Mark, Wu, Chunlei, Xu, Colleen, Fecho, Karamarie, Bizon, Chris, Issabekova, Tursynay, Moxon, Sierra, Thessen, Anne, Abdollahi, Shervin, Baranzini, Sergio, and Mungall, Chris

Abstract

Knowledge graphs have become a common approach for knowledge representation. Yet, the application of graph methodology is elusive due to the sheer number and complexity of knowledge sources. In addition, semantic incompatibilities hinder efforts to harmonize and integrate across these diverse sources. As part of The Biomedical Translator Consortium, we have developed a knowledge graph-based question-answering system designed to augment human reasoning and accelerate translational scientific discovery: the Translator system. We have applied the Translator system to answer biomedical questions in the context of a broad array of diseases and syndromes, including Fanconi anemia, primary ciliary dyskinesia, multiple sclerosis, and others. A variety of collaborative approaches have been used to research and develop the Translator system. One recent approach involved the establishment of a monthly Question-of-the-Month (QotM) Challenge series. Herein, we describe the structure of the QotM Challenge; the six challenges that have been conducted to date on drug-induced liver injury, cannabidiol toxicity, coronavirus infection, diabetes, psoriatic arthritis, and ATP1A3-related phenotypes; the scientific insights that have been gleaned during the challenges; and the technical issues that were identified over the course of the challenges and that can now be addressed to foster further development of the prototype Translator system. We close with a discussion on Large Language Models such as ChatGPT and highlight differences between those models and the Translator system.

Published

2023

20. The Gene Ontology knowledgebase in 2023

Author

Consortium, Gene Ontology, Aleksander, Suzi A, Balhoff, James, Carbon, Seth, Cherry, J Michael, Drabkin, Harold J, Ebert, Dustin, Feuermann, Marc, Gaudet, Pascale, Harris, Nomi L, Hill, David P, Lee, Raymond, Mi, Huaiyu, Moxon, Sierra, Mungall, Christopher J, Muruganugan, Anushya, Mushayahama, Tremayne, Sternberg, Paul W, Thomas, Paul D, Van Auken, Kimberly, Ramsey, Jolene, Siegele, Deborah A, Chisholm, Rex L, Fey, Petra, Aspromonte, Maria Cristina, Nugnes, Maria Victoria, Quaglia, Federica, Tosatto, Silvio, Giglio, Michelle, Nadendla, Suvarna, Antonazzo, Giulia, Attrill, Helen, Dos Santos, Gil, Marygold, Steven, Strelets, Victor, Tabone, Christopher J, Thurmond, Jim, Zhou, Pinglei, Ahmed, Saadullah H, Asanitthong, Praoparn, Buitrago, Diana Luna, Erdol, Meltem N, Gage, Matthew C, Kadhum, Mohamed Ali, Li, Kan Yan Chloe, Long, Miao, Michalak, Aleksandra, Pesala, Angeline, Pritazahra, Armalya, Saverimuttu, Shirin CC, Su, Renzhi, Thurlow, Kate E, Lovering, Ruth C, Logie, Colin, Oliferenko, Snezhana, Blake, Judith, Christie, Karen, Corbani, Lori, Dolan, Mary E, Ni, Li, Sitnikov, Dmitry, Smith, Cynthia, Cuzick, Alayne, Seager, James, Cooper, Laurel, Elser, Justin, Jaiswal, Pankaj, Gupta, Parul, Naithani, Sushma, Lera-Ramirez, Manuel, Rutherford, Kim, Wood, Valerie, De Pons, Jeffrey L, Dwinell, Melinda R, Hayman, G Thomas, Kaldunski, Mary L, Kwitek, Anne E, Laulederkind, Stanley JF, Tutaj, Marek A, Vedi, Mahima, Wang, Shur-Jen, D'Eustachio, Peter, Aimo, Lucila, Axelsen, Kristian, Bridge, Alan, Hyka-Nouspikel, Nevila, Morgat, Anne, Engel, Stacia R, Karra, Kalpana, Miyasato, Stuart R, Nash, Robert S, Skrzypek, Marek S, Weng, Shuai, Wong, Edith D, Bakker, Erika, Berardini, Tanya Z, Reiser, Leonore, Auchincloss, Andrea, Argoud-Puy, Ghislaine, Blatter, Marie-Claude, Boutet, Emmanuel, Breuza, Lionel, Casals-Casas, Cristina, Coudert, Elisabeth, Estreicher, Anne, Famiglietti, Maria Livia, Gos, Arnaud, Gruaz-Gumowski, Nadine, Hulo, Chantal, Jungo, Florence, Le Mercier, Philippe, Lieberherr, Damien, Masson, Patrick, Pedruzzi, Ivo, Pourcel, Lucille, Poux, Sylvain, Rivoire, Catherine, Sundaram, Shyamala, Bateman, Alex, Bowler-Barnett, Emily, Bye-A-Jee, Hema, Denny, Paul, Ignatchenko, Alexandr, Ishtiaq, Rizwan, Lock, Antonia, Lussi, Yvonne, Magrane, Michele, Martin, Maria J, Orchard, Sandra, Raposo, Pedro, Speretta, Elena, Tyagi, Nidhi, Warner, Kate, Zaru, Rossana, Diehl, Alexander D, Chan, Juancarlos, Diamantakis, Stavros, Raciti, Daniela, Zarowiecki, Magdalena, Fisher, Malcolm, James-Zorn, Christina, Ponferrada, Virgilio, Zorn, Aaron, Ramachandran, Sridhar, Ruzicka, Leyla, and Westerfield, Monte

Subjects

Ecology,Evolution & Ethology, Cell Cycle & Chromosomes, Cell Biology

Abstract

The Gene Ontology (GO) knowledgebase (http://geneontology.org) is a comprehensive resource concerning the functions of genes and gene products (proteins and noncoding RNAs). GO annotations cover genes from organisms across the tree of life as well as viruses, though most gene function knowledge currently derives from experiments carried out in a relatively small number of model organisms. Here, we provide an updated overview of the GO knowledgebase, as well as the efforts of the broad, international consortium of scientists that develops, maintains, and updates the GO knowledgebase. The GO knowledgebase consists of three components: (1) the GO-a computational knowledge structure describing the functional characteristics of genes; (2) GO annotations-evidence-supported statements asserting that a specific gene product has a particular functional characteristic; and (3) GO Causal Activity Models (GO-CAMs)-mechanistic models of molecular "pathways" (GO biological processes) created by linking multiple GO annotations using defined relations. Each of these components is continually expanded, revised, and updated in response to newly published discoveries and receives extensive QA checks, reviews, and user feedback. For each of these components, we provide a description of the current contents, recent developments to keep the knowledgebase up to date with new discoveries, and guidance on how users can best make use of the data that we provide. We conclude with future directions for the project.

Published

2023

21. Unifying the Identification of Biomedical Entities with the Bioregistry

Author

Hoyt, Charles Tapley, primary, Balk, Meghan, additional, Callahan, Tiffany J., additional, Domingo-Fernández, Daniel, additional, Haendel, Melissa A., additional, Hegde, Harshad B., additional, Himmelstein, Daniel S., additional, Karis, Klas, additional, Kunze, John, additional, Lubiana, Tiago, additional, Matentzoglu, Nicolas, additional, McMurry, Julie, additional, Moxon, Sierra, additional, Mungall, Christopher J., additional, Rutz, Adriano, additional, Unni, Deepak R., additional, Willighagen, Egon, additional, Winston, Donald, additional, and Gyori, Benjamin M., additional

Published

2022

22. A Simple Standard for Sharing Ontological Mappings (SSSOM)

Author

Matentzoglu, Nicolas, primary, Balhoff, James P, additional, Bello, Susan M, additional, Bizon, Chris, additional, Brush, Matthew, additional, Callahan, Tiffany J, additional, Chute, Christopher G, additional, Duncan, William D, additional, Evelo, Chris T, additional, Gabriel, Davera, additional, Graybeal, John, additional, Gray, Alasdair, additional, Gyori, Benjamin M, additional, Haendel, Melissa, additional, Harmse, Henriette, additional, Harris, Nomi L, additional, Harrow, Ian, additional, Hegde, Harshad B, additional, Hoyt, Amelia L, additional, Hoyt, Charles T, additional, Jiao, Dazhi, additional, Jiménez-Ruiz, Ernesto, additional, Jupp, Simon, additional, Kim, Hyeongsik, additional, Koehler, Sebastian, additional, Liener, Thomas, additional, Long, Qinqin, additional, Malone, James, additional, McLaughlin, James A, additional, McMurry, Julie A, additional, Moxon, Sierra, additional, Munoz-Torres, Monica C, additional, Osumi-Sutherland, David, additional, Overton, James A, additional, Peters, Bjoern, additional, Putman, Tim, additional, Queralt-Rosinach, Núria, additional, Shefchek, Kent, additional, Solbrig, Harold, additional, Thessen, Anne, additional, Tudorache, Tania, additional, Vasilevsky, Nicole, additional, Wagner, Alex H, additional, and Mungall, Christopher J, additional

Published

2022

23. Harmonizing model organism data in the Alliance of Genome Resources

Author

Agapite, Julie, Albou, Laurent-Philippe, Aleksander, Suzanne A., Alexander, Micheal, Anagnostopoulos, Anna V., Antonazzo, Giulia, Argasinska, Joanna, Arnaboldi, Valerio, Attrill, Helen, Becerra, Andrés, Bello, Susan M., Blake, Judith A., Blodgett, Olin, Bradford, Yvonne M., Bult, Carol J., Cain, Scott, Calvi, Brian R., Carbon, Seth, Chan, Juancarlos, Chen, Wen J., Cherry, J. Michael, Cho, Jaehyoung, Christie, Karen R., Crosby, Madeline A., Davis, Paul, da Veiga Beltrame, Eduardo, De Pons, Jeffrey L., D’Eustachio, Peter, Diamantakis, Stavros, Dolan, Mary E., dos Santos, Gilberto, Douglass, Eric, Dunn, Barbara, Eagle, Anne, Ebert, Dustin, Engel, Stacia R., Fashena, David, Foley, Saoirse, Frazer, Ken, Gao, Sibyl, Gibson, Adam C., Gondwe, Felix, Goodman, Josh, Gramates, L. Sian, Grove, Christian A., Hale, Paul, Harris, Todd, Thomas Hayman, G., Hill, David P., Howe, Douglas G., Howe, Kevin L., Hu, Yanhui, Jha, Sagar, Kadin, James A., Kaufman, Thomas C., Kalita, Patrick, Karra, Kalpana, Kishore, Ranjana, Kwitek, Anne E., Laulederkind, Stanley J. F., Lee, Raymond, Longden, Ian, Luypaert, Manuel, MacPherson, Kevin A., Martin, Ryan, Marygold, Steven J., Matthews, Beverley, McAndrews, Monica S., Millburn, Gillian, Miyasato, Stuart, Motenko, Howie, Moxon, Sierra, Müller, Hans-Michael, Mungall, Christopher J., Muruganujan, Anushya, Mushayahama, Tremayne, Nalabolu, Harika S., Nash, Robert S., Ng, Patrick, Nuin, Paulo, Paddock, Holly, Paulini, Michael, Perrimon, Norbert, Pich, Christian, Quinton-Tulloch, Mark, Raciti, Daniela, Ramachandran, Sridhar, Richardson, Joel E., Russo Gelbart, Susan, Ruzicka, Leyla, Schaper, Kevin, Schindelman, Gary, Shimoyama, Mary, Simison, Matt, Shaw, David R., Shrivatsav, Ajay, Singer, Amy, Skrzypek, Marek, Smith, Constance M., Smith, Cynthia L., Smith, Jennifer R., Stein, Lincoln, Sternberg, Paul W., Tabone, Christopher J., Thomas, Paul D., Thorat, Ketaki, Thota, Jyothi, Toro, Sabrina, Tomczuk, Monika, Trovisco, Vitor, Tutaj, Marek A., Tutaj, Monika, Urbano, Jose-Maria, Van Auken, Kimberly, Van Slyke, Ceri E., Wang, Qinghua, Wang, Shur-Jen, Weng, Shuai, Westerfield, Monte, Williams, Gary, Wilming, Laurens G., Wong, Edith D., Wright, Adam, Yook, Karen, Zarowiecki, Magdalena, Zhou, Pinglei, and Zytkovicz, Mark

Subjects

Internet, Molecular Sequence Annotation, Rats, Mice, Gene Ontology, Databases, Genetic, Saccharomycetales, Genetics, Animals, Humans, Drosophila, Caenorhabditis elegans, Alleles, Zebrafish

Abstract

The Alliance of Genome Resources (the Alliance) is a combined effort of 7 knowledgebase projects: Saccharomyces Genome Database, WormBase, FlyBase, Mouse Genome Database, the Zebrafish Information Network, Rat Genome Database, and the Gene Ontology Resource. The Alliance seeks to provide several benefits: better service to the various communities served by these projects; a harmonized view of data for all biomedical researchers, bioinformaticians, clinicians, and students; and a more sustainable infrastructure. The Alliance has harmonized cross-organism data to provide useful comparative views of gene function, gene expression, and human disease relevance. The basis of the comparative views is shared calls of orthology relationships and the use of common ontologies. The key types of data are alleles and variants, gene function based on gene ontology annotations, phenotypes, association to human disease, gene expression, protein–protein and genetic interactions, and participation in pathways. The information is presented on uniform gene pages that allow facile summarization of information about each gene in each of the 7 organisms covered (budding yeast, roundworm Caenorhabditis elegans, fruit fly, house mouse, zebrafish, brown rat, and human). The harmonized knowledge is freely available on the alliancegenome.org portal, as downloadable files, and by APIs. We expect other existing and emerging knowledge bases to join in the effort to provide the union of useful data and features that each knowledge base currently provides.

Published

2021

24. ZFIN, the Zebrafish Model Organism Database: increased support for mutants and transgenics

Author

Howe, Douglas G., Bradford, Yvonne M., Conlin, Tom, Eagle, Anne E., Fashena, David, Frazer, Ken, Knight, Jonathan, Mani, Prita, Martin, Ryan, Moxon, Sierra A. Taylor, Paddock, Holly, Pich, Christian, Ramachandran, Sridhar, Ruef, Barbara J., Ruzicka, Leyla, Schaper, Kevin, Shao, Xiang, Singer, Amy, Sprunger, Brock, Van Slyke, Ceri E., and Westerfield, Monte

Published

2013

25. ZFIN: enhancements and updates to the zebrafish model organism database

Author

Bradford, Yvonne, Conlin, Tom, Dunn, Nathan, Fashena, David, Frazer, Ken, Howe, Douglas G., Knight, Jonathan, Mani, Prita, Martin, Ryan, Moxon, Sierra A. T., Paddock, Holly, Pich, Christian, Ramachandran, Sridhar, Ruef, Barbara J., Ruzicka, Leyla, Bauer Schaper, Holle, Schaper, Kevin, Shao, Xiang, Singer, Amy, Sprague, Judy, Sprunger, Brock, Van Slyke, Ceri, and Westerfield, Monte

Published

2011

26. The Zebrafish Information Network: major gene page and home page updates

Author

Howe, Douglas G, primary, Ramachandran, Sridhar, additional, Bradford, Yvonne M, additional, Fashena, David, additional, Toro, Sabrina, additional, Eagle, Anne, additional, Frazer, Ken, additional, Kalita, Patrick, additional, Mani, Prita, additional, Martin, Ryan, additional, Moxon, Sierra Taylor, additional, Paddock, Holly, additional, Pich, Christian, additional, Ruzicka, Leyla, additional, Schaper, Kevin, additional, Shao, Xiang, additional, Singer, Amy, additional, Van Slyke, Ceri E, additional, and Westerfield, Monte, additional

Published

2020

27. The Zebrafish Information Network: the zebrafish model organism database provides expanded support for genotypes and phenotypes

Author

Sprague, Judy, Bayraktaroglu, Leyla, Bradford, Yvonne, Conlin, Tom, Dunn, Nathan, Fashena, David, Frazer, Ken, Haendel, Melissa, Howe, Douglas G., Knight, Jonathan, Mani, Prita, Moxon, Sierra A.T., Pich, Christian, Ramachandran, Sridhar, Schaper, Kevin, Segerdell, Erik, Shao, Xiang, Singer, Amy, Song, Peiran, Sprunger, Brock, Van Slyke, Ceri E., and Westerfield, Monte

Published

2008

28. The Zebrafish Information Network: new support for non-coding genes, richer Gene Ontology annotations and the Alliance of Genome Resources

Author

Ruzicka, Leyla, primary, Howe, Douglas G, additional, Ramachandran, Sridhar, additional, Toro, Sabrina, additional, Van Slyke, Ceri E, additional, Bradford, Yvonne M, additional, Eagle, Anne, additional, Fashena, David, additional, Frazer, Ken, additional, Kalita, Patrick, additional, Mani, Prita, additional, Martin, Ryan, additional, Moxon, Sierra Taylor, additional, Paddock, Holly, additional, Pich, Christian, additional, Schaper, Kevin, additional, Shao, Xiang, additional, Singer, Amy, additional, and Westerfield, Monte, additional

Published

2018

29. Zebrafish Models of Human Disease: Gaining Insight into Human Disease at ZFIN

Author

Bradford, Yvonne M., primary, Toro, Sabrina, additional, Ramachandran, Sridhar, additional, Ruzicka, Leyla, additional, Howe, Douglas G., additional, Eagle, Anne, additional, Kalita, Patrick, additional, Martin, Ryan, additional, Taylor Moxon, Sierra A., additional, Schaper, Kevin, additional, and Westerfield, Monte, additional

Published

2017

30. ZFIN, the Zebrafish Model Organism Database: updates and new directions

Author

Ruzicka, Leyla, Bradford, Yvonne M., Frazer, Ken, Howe, Douglas G., Paddock, Holly, Ramachandran, Sridhar, Singer, Amy, Toro, Sabrina, Van Slyke, Ceri E., Eagle, Anne E., Fashena, David, Kalita, Patrick, Knight, Jonathan, Mani, Prita, Martin, Ryan, Moxon, Sierra A. T., Pich, Christian, Schaper, Kevin, Shao, Xiang, and Westerfield, Monte

Subjects

Internet, fungi, Databases, Genetic, Models, Animal, Animals, Computational Biology, Genomics, Zebrafish Proteins, Article, Data Curation, Genetic Association Studies, Zebrafish

Abstract

The Zebrafish Model Organism Database (ZFIN; http://zfin.org) is the central resource for genetic and genomic data from zebrafish (Danio rerio) research. ZFIN staff curate detailed information about genes, mutants, genotypes, reporter lines, sequences, constructs, antibodies, knockdown reagents, expression patterns, phenotypes, gene product function, and orthology from publications. Researchers can submit mutant, transgenic, expression, and phenotype data directly to ZFIN and use the ZFIN Community Wiki to share antibody and protocol information. Data can be accessed through topic-specific searches, a new site-wide search, and the data-mining resource ZebrafishMine (http://zebrafishmine.org). Data download and web service options are also available. ZFIN collaborates with major bioinformatics organizations to verify and integrate genomic sequence data, provide nomenclature support, establish reciprocal links, and participate in the development of standardized structured vocabularies (ontologies) used for data annotation and searching. ZFIN-curated gene, function, expression, and phenotype data are available for comparative exploration at several multi-species resources. The use of zebrafish as a model for human disease is increasing. ZFIN is supporting this growing area with three major projects: adding easy access to computed orthology data from gene pages, curating details of the gene expression pattern changes in mutant fish, and curating zebrafish models of human diseases.

Published

2015

31. Cross-Organism Analysis Using InterMine

Author

Lyne, Rachel, Sullivan, Julie, Butano, Daniela, Contrino, Sergio, Heimbach, Josh, Hu, Fengyuan, Kalderimis, Alex, Lyne, Mike, Smith, Richard N., Štěpán, Radek, Balakrishnan, Rama, Binkley, Gail, Harris, Todd, Karra, Kalpana, Moxon, Sierra A. T., Motenko, Howie, Neuhauser, Steven, Ruzicka, Leyla, Cherry, Mike, Richardson, Joel, Stein, Lincoln, Westerfield, Monte, Worthey, Elizabeth, and Micklem, Gos

Subjects

Systems Integration, Internet, User-Computer Interface, Databases, Factual, Databases, Genetic, Animals, Computational Biology, Humans, Genomics, Article, Software

Abstract

InterMine is a data integration warehouse and analysis software system developed for large and complex biological data sets. Designed for integrative analysis, it can be accessed through a user-friendly web interface. For bioinformaticians, extensive web services as well as programming interfaces for most common scripting languages support access to all features. The web interface includes a useful identifier look-up system, and both simple and sophisticated search options. Interactive results tables enable exploration, and data can be filtered, summarized, and browsed. A set of graphical analysis tools provide a rich environment for data exploration including statistical enrichment of sets of genes or other entities. InterMine databases have been developed for the major model organisms, budding yeast, nematode worm, fruit fly, zebrafish, mouse, and rat together with a newly developed human database. Here, we describe how this has facilitated interoperation and development of cross-organism analysis tools and reports. InterMine as a data exploration and analysis tool is also described. All the InterMine-based systems described in this article are resources freely available to the scientific community.

Published

2015

32. The Zebrafish Information Network: new support for non-coding genes, richer Gene Ontology annotations and the Alliance of Genome Resources.

Author

Ruzicka, Leyla, Howe, Douglas G, Ramachandran, Sridhar, Toro, Sabrina, Van Slyke, Ceri E, Bradford, Yvonne M, Eagle, Anne, Fashena, David, Frazer, Ken, Kalita, Patrick, Mani, Prita, Martin, Ryan, Moxon, Sierra Taylor, Paddock, Holly, Pich, Christian, Schaper, Kevin, Shao, Xiang, Singer, Amy, and Westerfield, Monte

Published

2019

33. The Zebrafish Model Organism Database: new support for human disease models, mutation details, gene expression phenotypes and searching

Author

Howe, Douglas G., primary, Bradford, Yvonne M., additional, Eagle, Anne, additional, Fashena, David, additional, Frazer, Ken, additional, Kalita, Patrick, additional, Mani, Prita, additional, Martin, Ryan, additional, Moxon, Sierra Taylor, additional, Paddock, Holly, additional, Pich, Christian, additional, Ramachandran, Sridhar, additional, Ruzicka, Leyla, additional, Schaper, Kevin, additional, Shao, Xiang, additional, Singer, Amy, additional, Toro, Sabrina, additional, Van Slyke, Ceri, additional, and Westerfield, Monte, additional

Published

2016

34. ZFIN, The zebrafish model organism database: Updates and new directions

Author

Ruzicka, Leyla, primary, Bradford, Yvonne M., additional, Frazer, Ken, additional, Howe, Douglas G., additional, Paddock, Holly, additional, Ramachandran, Sridhar, additional, Singer, Amy, additional, Toro, Sabrina, additional, Van Slyke, Ceri E., additional, Eagle, Anne E., additional, Fashena, David, additional, Kalita, Patrick, additional, Knight, Jonathan, additional, Mani, Prita, additional, Martin, Ryan, additional, Moxon, Sierra A.T., additional, Pich, Christian, additional, Schaper, Kevin, additional, Shao, Xiang, additional, and Westerfield, Monte, additional

Published

2015

35. Cross-organism analysis using InterMine

Author

Lyne, Rachel, primary, Sullivan, Julie, additional, Butano, Daniela, additional, Contrino, Sergio, additional, Heimbach, Joshua, additional, Hu, Fengyuan, additional, Kalderimis, Alex, additional, Lyne, Mike, additional, N. Smith, Richard, additional, Štěpán, Radek, additional, Balakrishnan, Rama, additional, Binkley, Gail, additional, Harris, Todd, additional, Karra, Kalpana, additional, A. T. Moxon, Sierra, additional, Motenko, Howie, additional, Neuhauser, Steven, additional, Ruzicka, Leyla, additional, Cherry, Mike, additional, Richardson, Joel, additional, Stein, Lincoln, additional, Westerfield, Monte, additional, Worthey, Elizabeth, additional, and Micklem, Gos, additional

Published

2015

36. The Zebrafish Model Organism Database: new support for human disease models, mutation details, gene expression phenotypes and searching.

Author

Howe, Douglas G., Bradford, Yvonne M., Eagle, Anne, Fashena, David, Frazer, Ken, Kalita, Patrick, Mani, Prita, Martin, Ryan, Moxon, Sierra Taylor, Paddock, Holly, Pich, Christian, Ramachandran, Sridhar, Ruzicka, Leyla, Schaper, Kevin, Xiang Shao, Singer, Amy, Toro, Sabrina, Van Slyke, Ceri, and Westerfield, Monte

Published

2017

37. Correction: Corrigendum: InterMOD: integrated data and tools for the unification of model organism research

Author

Sullivan, Julie, primary, Karra, Kalpana, additional, Moxon, Sierra A. T., additional, Vallejos, Andrew, additional, Motenko, Howie, additional, Wong, J. D., additional, Aleksic, Jelena, additional, Balakrishnan, Rama, additional, Binkley, Gail, additional, Harris, Todd, additional, Hitz, Benjamin, additional, Jayaraman, Pushkala, additional, Lyne, Rachel, additional, Neuhauser, Steven, additional, Pich, Christian, additional, Smith, Richard N., additional, Trinh, Quang, additional, Cherry, J. Michael, additional, Richardson, Joel, additional, Stein, Lincoln, additional, Twigger, Simon, additional, Westerfield, Monte, additional, Worthey, Elizabeth, additional, and Micklem, Gos, additional

Published

2013

38. InterMOD: integrated data and tools for the unification of model organism research

Author

Sullivan, Julie, primary, Karra, Kalpana, additional, Moxon, Sierra A. T., additional, Vallejos, Andrew, additional, Motenko, Howie, additional, Wong, J. D., additional, Aleksic, Jelena, additional, Balakrishnan, Rama, additional, Binkley, Gail, additional, Harris, Todd, additional, Hitz, Benjamin, additional, Jayaraman, Pushkala, additional, Lyne, Rachel, additional, Neuhauser, Steven, additional, Pich, Christian, additional, Smith, Richard N., additional, Trinh, Quang, additional, Cherry, J. Michael, additional, Richardson, Joel, additional, Stein, Lincoln, additional, Twigger, Simon, additional, Westerfield, Monte, additional, Worthey, Elizabeth, additional, and Micklem, Gos, additional

Published

2013

39. ZFIN, the Zebrafish Model Organism Database: increased support for mutants and transgenics

Author

Howe, Douglas G., primary, Bradford, Yvonne M., additional, Conlin, Tom, additional, Eagle, Anne E., additional, Fashena, David, additional, Frazer, Ken, additional, Knight, Jonathan, additional, Mani, Prita, additional, Martin, Ryan, additional, Moxon, Sierra A. Taylor, additional, Paddock, Holly, additional, Pich, Christian, additional, Ramachandran, Sridhar, additional, Ruef, Barbara J., additional, Ruzicka, Leyla, additional, Schaper, Kevin, additional, Shao, Xiang, additional, Singer, Amy, additional, Sprunger, Brock, additional, Van Slyke, Ceri E., additional, and Westerfield, Monte, additional

Published

2012

40. Generating Biomedical Knowledge Graphs from Knowledge Bases, Registries, and Multiomic Data.

Author

Qin G, Narsinh K, Wei Q, Roach JC, Joshi A, Goetz SL, Moxon ST, Brush MH, Xu C, Yao Y, Glen AK, Morris ED, Ralevski A, Roper R, Belhu B, Zhang Y, Shmulevich I, Hadlock J, and Glusman G

Abstract

As large clinical and multiomics datasets and knowledge resources accumulate, they need to be transformed into computable and actionable information to support automated reasoning. These datasets range from laboratory experiment results to electronic health records (EHRs). Barriers to accessibility and sharing of such datasets include diversity of content, size and privacy. Effective transformation of data into information requires harmonization of stakeholder goals, implementation, enforcement of standards regarding quality and completeness, and availability of resources for maintenance and updates. Systems such as the Biomedical Data Translator leverage knowledge graphs (KGs), structured and machine learning readable knowledge representation, to encode knowledge extracted through inference. We focus here on the transformation of data from multiomics datasets and EHRs into compact knowledge, represented in a KG data structure. We demonstrate this data transformation in the context of the Translator ecosystem, including clinical trials, drug approvals, cancer, wellness, and EHR data. These transformations preserve individual privacy. We provide access to the five resulting KGs through the Translator framework. We show examples of biomedical research questions supported by our KGs, and discuss issues arising from extracting biomedical knowledge from multiomics data.

Published

2024

41. The Zebrafish Information Network: major gene page and home page updates.

Author

Howe DG, Ramachandran S, Bradford YM, Fashena D, Toro S, Eagle A, Frazer K, Kalita P, Mani P, Martin R, Moxon ST, Paddock H, Pich C, Ruzicka L, Schaper K, Shao X, Singer A, Van Slyke CE, and Westerfield M

Subjects

Animals, Animals, Genetically Modified, Data Mining methods, Gene Expression, Humans, Internet, Models, Animal, Mutation, Phenotype, Zebrafish Proteins genetics, Computational Biology methods, Databases, Genetic, Genome genetics, Genomics methods, Zebrafish genetics

Abstract

The Zebrafish Information Network (ZFIN) (https://zfin.org/) is the database for the model organism, zebrafish (Danio rerio). ZFIN expertly curates, organizes, and provides a wide array of zebrafish genetic and genomic data, including genes, alleles, transgenic lines, gene expression, gene function, mutant phenotypes, orthology, human disease models, gene and mutant nomenclature, and reagents. New features at ZFIN include major updates to the home page and the gene page, the two most used pages at ZFIN. Data including disease models, phenotypes, expression, mutants and gene function continue to be contributed to The Alliance of Genome Resources for integration with similar data from other model organisms., (© The Author(s) 2020. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2021