Das Leibniz-Institut zur Analyse des Biodiversitätswandels

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COGNATE: comparative gene annotation characterizer

Erscheinungsjahr: 
2017
Vollständiger Titel: 
Wilbrandt J, Misof B, and Niehuis O: COGNATE: comparative gene annotation characterizer. BMC Genomics 18(1): 535
ZFMK-Autorinnen / ZFMK-Autoren: 
Publiziert in: 
BMC Genomics
Publikationstyp: 
Populärwissenschaftliche Veröffentlichung
Bibliographische Angaben: 
Wilbrandt J, Misof B, and Niehuis O: COGNATE: comparative gene annotation characterizer. BMC Genomics 18(1): 535
Abstract: 

Background: The comparison of gene and genome structures across species has the potential to reveal major trends of genome evolution. However, such a comparative approach is currently hampered by a lack of standardization (e.g., Elliott TA, Gregory TR, Philos Trans Royal Soc B: Biol Sci 370:20140331, 2015). For example, testing the hypothesis that the total amount of coding sequences is a reliable measure of potential proteome diversity (Wang M, Kurland CG, Caetano-Anollés G, PNAS 108:11954, 2011) requires the application of standardized definitions of coding sequence and genes to create both comparable and comprehensive data sets and corresponding summary statistics. However, such standard definitions either do not exist or are not consistently applied. These circumstances call for a  standard at the descriptive level using a minimum of parameters as well as an undeviating use of standardized terms, and for software that infers the required data under these strict definitions. The acquisition of a comprehensive, descriptive, and standardized set of parameters and summary statistics for genome publications and further analyses can thus greatly benefit from the availability of an easy to use standard tool.

Results: We developed a new open-source command-line tool, COGNATE (Comparative Gene Annotation Characterizer), which uses a given genome assembly and its annotation of protein-coding genes for a detailed description of the respective gene and genome structure parameters. Additionally, we revised the standard definitions of gene and genome structures and provide the definitions used by COGNATE as a working draft suggestion for further reference. Complete parameter lists and summary statistics are inferred using this set of definitions to allow down-stream analyses and to provide an overview of the genome and gene repertoire characteristics. COGNATE is written in Perl and freely available at the ZFMK homepage (https://bonn.leibniz-lib.de/en/COGNATE) and on github (https://github.com/ZFMK/COGNATE).

Conclusion: The tool COGNATE allows comparing genome assemblies and structural elements on multiples levels (e.g., scaffold or contig sequence, gene). It clearly enhances comparability between analyses. Thus, COGNATE can provide the important standardization of both genome and gene structure parameter disclosure as well as data acquisition for future comparative analyses. With the establishment of comprehensive descriptive standards and the extensive availability of genomes, an encompassing database will become possible.