The Plant Ontology Facilitates Comparisons of Plant Development Stages Across Species

Overview

Journal Front Plant Sci

Date 2019 Jun 20

PMID 31214208

Citations 13

Authors

Ramona L Walls

Laurel Cooper

Justin Elser

Maria Alejandra Gandolfo

Christopher J Mungall

Barry Smith

Dennis W Stevenson

Pankaj Jaiswal

Affiliations

Soon will be listed here.

Abstract

The Plant Ontology (PO) is a community resource consisting of standardized terms, definitions, and logical relations describing plant structures and development stages, augmented by a large database of annotations from genomic and phenomic studies. This paper describes the structure of the ontology and the design principles we used in constructing PO terms for plant development stages. It also provides details of the methodology and rationale behind our revision and expansion of the PO to cover development stages for all plants, particularly the land plants (bryophytes through angiosperms). As a case study to illustrate the general approach, we examine variation in gene expression across embryo development stages in Arabidopsis and maize, demonstrating how the PO can be used to compare patterns of expression across stages and in developmentally different species. Although many genes appear to be active throughout embryo development, we identified a small set of uniquely expressed genes for each stage of embryo development and also between the two species. Evaluating the different sets of genes expressed during embryo development in Arabidopsis or maize may inform future studies of the divergent developmental pathways observed in monocotyledonous versus dicotyledonous species. The PO and its annotation database (http://www.planteome.org) make plant data for any species more discoverable and accessible through common formats, thus providing support for applications in plant pathology, image analysis, and comparative development and evolution.

Citing Articles

Ontologies for increasing the FAIRness of plant research data.

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Cooper L, Elser J, Laporte M, Arnaud E, Jaiswal P Nucleic Acids Res. 2023; 52(D1):D1548-D1555.

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Comparative phenomics: a new approach to study heterochrony.

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