Your search keyword '"Schriml, Lynn M"' showing total 5 results

1. COVID-19 pandemic reveals the peril of ignoring metadata standards.

Author

Schriml LM, Chuvochina M, Davies N, Eloe-Fadrosh EA, Finn RD, Hugenholtz P, Hunter CI, Hurwitz BL, Kyrpides NC, Meyer F, Mizrachi IK, Sansone SA, Sutton G, Tighe S, and Walls R

Subjects

Betacoronavirus, COVID-19, Coronavirus Infections genetics, Datasets as Topic, Humans, Pandemics, Pneumonia, Viral genetics, SARS-CoV-2, Coronavirus Infections epidemiology, Genomics standards, Metadata standards, Pneumonia, Viral epidemiology

Published

2020

2. A Practical Approach to Using the Genomic Standards Consortium MIxS Reporting Standard for Comparative Genomics and Metagenomics

Author

Eloe-Fadrosh, Emiley A, Mungall, Christopher J, Miller, Mark Andrew, Smith, Montana, Patil, Sujay Sanjeev, Kelliher, Julia M, Johnson, Leah YD, Rodriguez, Francisca E, Chain, Patrick SG, Hu, Bin, Thornton, Michael B, McCue, Lee Ann, McHardy, Alice Carolyn, Harris, Nomi L, Reddy, TBK, Mukherjee, Supratim, Hunter, Christopher I, Walls, Ramona, and Schriml, Lynn M

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Human Genome, Biotechnology, Metagenomics, Genomics, Metagenome, Databases, Genetic, Soil Microbiology, Genome, Metadata, Schema, Validation, Standards, Other Chemical Sciences, Biochemistry and Cell Biology, Developmental Biology, Biochemistry and cell biology, Medicinal and biomolecular chemistry

Abstract

Comparative analysis of (meta)genomes necessitates aggregation, integration, and synthesis of well-annotated data using standards. The Genomic Standards Consortium (GSC) collaborates with the research community to develop and maintain the Minimum Information about any (x) Sequence (MIxS) reporting standard for genomic data. To facilitate the use of the GSC's MIxS reporting standard, we provide a description of the structure and terminology, how to navigate ontologies for required terms in MIxS, and demonstrate practical usage through a soil metagenome example.

Published

2024

3. OBO Foundry in 2021: operationalizing open data principles to evaluate ontologies

Author

Jackson, Rebecca, Matentzoglu, Nicolas, Overton, James A, Vita, Randi, Balhoff, James P, Buttigieg, Pier Luigi, Carbon, Seth, Courtot, Melanie, Diehl, Alexander D, Dooley, Damion M, Duncan, William D, Harris, Nomi L, Haendel, Melissa A, Lewis, Suzanna E, Natale, Darren A, Osumi-Sutherland, David, Ruttenberg, Alan, Schriml, Lynn M, Smith, Barry, Stoeckert, Christian J, Vasilevsky, Nicole A, Walls, Ramona L, Zheng, Jie, Mungall, Christopher J, and Peters, Bjoern

Subjects

Information and Computing Sciences, Biological Sciences, Bioinformatics and Computational Biology, Data Science, Networking and Information Technology R&D (NITRD), Biological Ontologies, Databases, Factual, Metadata, Data Format, Library and Information Studies, Bioinformatics and computational biology, Data management and data science

Abstract

Biological ontologies are used to organize, curate and interpret the vast quantities of data arising from biological experiments. While this works well when using a single ontology, integrating multiple ontologies can be problematic, as they are developed independently, which can lead to incompatibilities. The Open Biological and Biomedical Ontologies (OBO) Foundry was created to address this by facilitating the development, harmonization, application and sharing of ontologies, guided by a set of overarching principles. One challenge in reaching these goals was that the OBO principles were not originally encoded in a precise fashion, and interpretation was subjective. Here, we show how we have addressed this by formally encoding the OBO principles as operational rules and implementing a suite of automated validation checks and a dashboard for objectively evaluating each ontology's compliance with each principle. This entailed a substantial effort to curate metadata across all ontologies and to coordinate with individual stakeholders. We have applied these checks across the full OBO suite of ontologies, revealing areas where individual ontologies require changes to conform to our principles. Our work demonstrates how a sizable, federated community can be organized and evaluated on objective criteria that help improve overall quality and interoperability, which is vital for the sustenance of the OBO project and towards the overall goals of making data Findable, Accessible, Interoperable, and Reusable (FAIR). Database URL http://obofoundry.org/.

Published

2021

4. Microbiome Metadata Standards: Report of the National Microbiome Data Collaborative’s Workshop and Follow-On Activities

Author

Vangay, Pajau, Burgin, Josephine, Johnston, Anjanette, Beck, Kristen L, Berrios, Daniel C, Blumberg, Kai, Canon, Shane, Chain, Patrick, Chandonia, John-Marc, Christianson, Danielle, Costes, Sylvain V, Damerow, Joan, Duncan, William D, Dundore-Arias, Jose Pablo, Fagnan, Kjiersten, Galazka, Jonathan M, Gibbons, Sean M, Hays, David, Hervey, Judson, Hu, Bin, Hurwitz, Bonnie L, Jaiswal, Pankaj, Joachimiak, Marcin P, Kinkel, Linda, Ladau, Joshua, Martin, Stanton L, McCue, Lee Ann, Miller, Kayd, Mouncey, Nigel, Mungall, Chris, Pafilis, Evangelos, Reddy, TBK, Richardson, Lorna, Roux, Simon, Schriml, Lynn M, Shaffer, Justin P, Sundaramurthi, Jagadish Chandrabose, Thompson, Luke R, Timme, Ruth E, Zheng, Jie, Wood-Charlson, Elisha M, and Eloe-Fadrosh, Emiley A

Subjects

Information and Computing Sciences, Biological Sciences, Library and Information Studies, Microbiome, data standards, metadata, microbiome, ontology

Abstract

Microbiome samples are inherently defined by the environment in which they are found. Therefore, data that provide context and enable interpretation of measurements produced from biological samples, often referred to as metadata, are critical. Important contributions have been made in the development of community-driven metadata standards; however, these standards have not been uniformly embraced by the microbiome research community. To understand how these standards are being adopted, or the barriers to adoption, across research domains, institutions, and funding agencies, the National Microbiome Data Collaborative (NMDC) hosted a workshop in October 2019. This report provides a summary of discussions that took place throughout the workshop, as well as outcomes of the working groups initiated at the workshop.

Published

2021

5. Standardized Metadata for Human Pathogen/Vector Genomic Sequences.

Author

Dugan, Vivien G., Emrich, Scott J., Giraldo-Calderón, Gloria I., Harb, Omar S., Newman, Ruchi M., Pickett, Brett E., Schriml, Lynn M., Stockwell, Timothy B., Stoeckert Jr, Christian J., Sullivan, Dan E., Singh, Indresh, Ward, Doyle V., Yao, Alison, Zheng, Jie, Barrett, Tanya, Birren, Bruce, Brinkac, Lauren, Bruno, Vincent M., Caler, Elizabet, and Chapman, Sinéad

Subjects

GENOMICS, METADATA, GENETIC polymorphisms, MOLECULAR biology, ENTOMOLOGY, COMPARATIVE genomics

Abstract

High throughput sequencing has accelerated the determination of genome sequences for thousands of human infectious disease pathogens and dozens of their vectors. The scale and scope of these data are enabling genotype-phenotype association studies to identify genetic determinants of pathogen virulence and drug/insecticide resistance, and phylogenetic studies to track the origin and spread of disease outbreaks. To maximize the utility of genomic sequences for these purposes, it is essential that metadata about the pathogen/vector isolate characteristics be collected and made available in organized, clear, and consistent formats. Here we report the development of the GSCID/BRC Project and Sample Application Standard, developed by representatives of the Genome Sequencing Centers for Infectious Diseases (GSCIDs), the Bioinformatics Resource Centers (BRCs) for Infectious Diseases, and the U.S. National Institute of Allergy and Infectious Diseases (NIAID), part of the National Institutes of Health (NIH), informed by interactions with numerous collaborating scientists. It includes mapping to terms from other data standards initiatives, including the Genomic Standards Consortium’s minimal information (MIxS) and NCBI’s BioSample/BioProjects checklists and the Ontology for Biomedical Investigations (OBI). The standard includes data fields about characteristics of the organism or environmental source of the specimen, spatial-temporal information about the specimen isolation event, phenotypic characteristics of the pathogen/vector isolated, and project leadership and support. By modeling metadata fields into an ontology-based semantic framework and reusing existing ontologies and minimum information checklists, the application standard can be extended to support additional project-specific data fields and integrated with other data represented with comparable standards. The use of this metadata standard by all ongoing and future GSCID sequencing projects will provide a consistent representation of these data in the BRC resources and other repositories that leverage these data, allowing investigators to identify relevant genomic sequences and perform comparative genomics analyses that are both statistically meaningful and biologically relevant. [ABSTRACT FROM AUTHOR]

Published

2014