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Comparative and Functional Genomics logoLink to Comparative and Functional Genomics
. 2005 Oct-Dec;6(7-8):373–378. doi: 10.1002/cfg.498

Using Multiple Ontologies to Integrate Complex Biological Data

Mary Shimoyama 1,2,, Victoria Petri 1, Dean Pasko 1, Susan Bromberg 1, Wenhua Wu 1, Jiali Chen 1, Nataliya Nenasheva 1, Anne Kwitek 1, Simon Twigger 1, Howard Jacob 1
PMCID: PMC2447497  PMID: 18629202

Abstract

The strength of the rat as a model organism lies in its utility in pharmacology, biochemistry and physiology research. Data resulting from such studies is difficult to represent in databases and the creation of user-friendly data mining tools has proved difficult. The Rat Genome Database has developed a comprehensive ontology-based data structure and annotation system to integrate physiological data along with environmental and experimental factors, as well as genetic and genomic information. RGD uses multiple ontologies to integrate complex biological information from the molecular level to the whole organism, and to develop data mining and presentation tools. This approach allows RGD to indicate not only the phenotypes seen in a strain but also the specific values under each diet and atmospheric condition, as well as gender differences. Harnessing the power of ontologies in this way allows the user to gather and filter data in a customized fashion, so that a researcher can retrieve all phenotype readings for which a high hypoxia is a factor. Utilizing the same data structure for expression data, pathways and biological processes, RGD will provide a comprehensive research platform which allows users to investigate the conditions under which biological processes are altered and to elucidate the mechanisms of disease.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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