Integrating phenotype ontologies with PhenomeNET

Miguel Ángel Rodríguez-García; Georgios V Gkoutos; Paul N Schofield; Robert Hoehndorf

doi:10.1186/s13326-017-0167-4

Integrating phenotype ontologies with PhenomeNET

Miguel Ángel Rodríguez-García, Georgios V Gkoutos, Paul N Schofield, Robert Hoehndorf

Cancer and Genomic Sciences

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

143 Downloads (Pure)

Abstract

BACKGROUND: Integration and analysis of phenotype data from humans and model organisms is a key challenge in building our understanding of normal biology and pathophysiology. However, the range of phenotypes and anatomical details being captured in clinical and model organism databases presents complex problems when attempting to match classes across species and across phenotypes as diverse as behaviour and neoplasia. We have previously developed PhenomeNET, a system for disease gene prioritization that includes as one of its components an ontology designed to integrate phenotype ontologies. While not applicable to matching arbitrary ontologies, PhenomeNET can be used to identify related phenotypes in different species, including human, mouse, zebrafish, nematode worm, fruit fly, and yeast.

RESULTS: Here, we apply the PhenomeNET to identify related classes from two phenotype and two disease ontologies using automated reasoning. We demonstrate that we can identify a large number of mappings, some of which require automated reasoning and cannot easily be identified through lexical approaches alone. Combining automated reasoning with lexical matching further improves results in aligning ontologies.

CONCLUSIONS: PhenomeNET can be used to align and integrate phenotype ontologies. The results can be utilized for biomedical analyses in which phenomena observed in model organisms are used to identify causative genes and mutations underlying human disease.

Original language	English
Pages (from-to)	58
Journal	Journal of Biomedical Semantics
Volume	8
DOIs	https://doi.org/10.1186/s13326-017-0167-4
Publication status	Published - 19 Dec 2017

Keywords

Phenotype
PhenomeNET
Disease gene prioritization
OWL
Automated reasoning

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1186/s13326-017-0167-4Licence: Creative Commons: Attribution (CC BY)

Rodriguez-Garcia_et_al_Integrating_phenotype_Journal_of_Biomedical_Semantics_2017
Checked for eligibility: 10/01/2018
Final published version, 721 KBLicence: Creative Commons: Attribution (CC BY)

Cite this

@article{09d00d4a9cbc4b7182dc36d46e963227,

title = "Integrating phenotype ontologies with PhenomeNET",

abstract = "BACKGROUND: Integration and analysis of phenotype data from humans and model organisms is a key challenge in building our understanding of normal biology and pathophysiology. However, the range of phenotypes and anatomical details being captured in clinical and model organism databases presents complex problems when attempting to match classes across species and across phenotypes as diverse as behaviour and neoplasia. We have previously developed PhenomeNET, a system for disease gene prioritization that includes as one of its components an ontology designed to integrate phenotype ontologies. While not applicable to matching arbitrary ontologies, PhenomeNET can be used to identify related phenotypes in different species, including human, mouse, zebrafish, nematode worm, fruit fly, and yeast.RESULTS: Here, we apply the PhenomeNET to identify related classes from two phenotype and two disease ontologies using automated reasoning. We demonstrate that we can identify a large number of mappings, some of which require automated reasoning and cannot easily be identified through lexical approaches alone. Combining automated reasoning with lexical matching further improves results in aligning ontologies.CONCLUSIONS: PhenomeNET can be used to align and integrate phenotype ontologies. The results can be utilized for biomedical analyses in which phenomena observed in model organisms are used to identify causative genes and mutations underlying human disease.",

keywords = "Phenotype, PhenomeNET, Disease gene prioritization, OWL, Automated reasoning",

author = "Rodr{\'i}guez-Garc{\'i}a, {Miguel {\'A}ngel} and Gkoutos, {Georgios V} and Schofield, {Paul N} and Robert Hoehndorf",

year = "2017",

month = dec,

day = "19",

doi = "10.1186/s13326-017-0167-4",

language = "English",

volume = "8",

pages = "58",

journal = "Journal of Biomedical Semantics",

issn = "2041-1480",

publisher = "BioMed Central Ltd",

}

TY - JOUR

T1 - Integrating phenotype ontologies with PhenomeNET

AU - Rodríguez-García, Miguel Ángel

AU - Gkoutos, Georgios V

AU - Schofield, Paul N

AU - Hoehndorf, Robert

PY - 2017/12/19

Y1 - 2017/12/19

N2 - BACKGROUND: Integration and analysis of phenotype data from humans and model organisms is a key challenge in building our understanding of normal biology and pathophysiology. However, the range of phenotypes and anatomical details being captured in clinical and model organism databases presents complex problems when attempting to match classes across species and across phenotypes as diverse as behaviour and neoplasia. We have previously developed PhenomeNET, a system for disease gene prioritization that includes as one of its components an ontology designed to integrate phenotype ontologies. While not applicable to matching arbitrary ontologies, PhenomeNET can be used to identify related phenotypes in different species, including human, mouse, zebrafish, nematode worm, fruit fly, and yeast.RESULTS: Here, we apply the PhenomeNET to identify related classes from two phenotype and two disease ontologies using automated reasoning. We demonstrate that we can identify a large number of mappings, some of which require automated reasoning and cannot easily be identified through lexical approaches alone. Combining automated reasoning with lexical matching further improves results in aligning ontologies.CONCLUSIONS: PhenomeNET can be used to align and integrate phenotype ontologies. The results can be utilized for biomedical analyses in which phenomena observed in model organisms are used to identify causative genes and mutations underlying human disease.

AB - BACKGROUND: Integration and analysis of phenotype data from humans and model organisms is a key challenge in building our understanding of normal biology and pathophysiology. However, the range of phenotypes and anatomical details being captured in clinical and model organism databases presents complex problems when attempting to match classes across species and across phenotypes as diverse as behaviour and neoplasia. We have previously developed PhenomeNET, a system for disease gene prioritization that includes as one of its components an ontology designed to integrate phenotype ontologies. While not applicable to matching arbitrary ontologies, PhenomeNET can be used to identify related phenotypes in different species, including human, mouse, zebrafish, nematode worm, fruit fly, and yeast.RESULTS: Here, we apply the PhenomeNET to identify related classes from two phenotype and two disease ontologies using automated reasoning. We demonstrate that we can identify a large number of mappings, some of which require automated reasoning and cannot easily be identified through lexical approaches alone. Combining automated reasoning with lexical matching further improves results in aligning ontologies.CONCLUSIONS: PhenomeNET can be used to align and integrate phenotype ontologies. The results can be utilized for biomedical analyses in which phenomena observed in model organisms are used to identify causative genes and mutations underlying human disease.

KW - Phenotype

KW - PhenomeNET

KW - Disease gene prioritization

KW - OWL

KW - Automated reasoning

U2 - 10.1186/s13326-017-0167-4

DO - 10.1186/s13326-017-0167-4

M3 - Article

C2 - 29258588

SN - 2041-1480

VL - 8

SP - 58

JO - Journal of Biomedical Semantics

JF - Journal of Biomedical Semantics

ER -

Integrating phenotype ontologies with PhenomeNET

Abstract

Keywords

UN SDGs

Access to Document

Fingerprint

Cite this