PoGO: Prediction of Gene Ontology terms for fungal proteins

Automated protein function prediction methods are the only practical approach for assigning functions to genes obtained from model organisms. Many of the previously reported function annotation methods are of limited utility for fungal protein annotation. They are often trained only to one species,...

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Bibliographic Details
Published in:BMC bioinformatics 2010-04, Vol.11 (1), p.215-215, Article 215
Main Authors: Jung, Jaehee, Yi, Gangman, Sukno, Serenella A, Thon, Michael R
Format: Article
Language:English
Subjects:
Databases, Protein
DNA microarrays
DNA sequencing
Fungal Proteins - chemistry
Fungal Proteins - genetics
Fungi
Gene expression
Genetic aspects
Genome, Fungal
Genomics - methods
Nucleotide sequencing
Physiological aspects
Protein Conformation
Sequence Alignment
Sequence Analysis, Protein
Software
Structure-Activity Relationship
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Summary:Automated protein function prediction methods are the only practical approach for assigning functions to genes obtained from model organisms. Many of the previously reported function annotation methods are of limited utility for fungal protein annotation. They are often trained only to one species, are not available for high-volume data processing, or require the use of data derived by experiments such as microarray analysis. To meet the increasing need for high throughput, automated annotation of fungal genomes, we have developed a tool for annotating fungal protein sequences with terms from the Gene Ontology. We describe a classifier called PoGO (Prediction of Gene Ontology terms) that uses statistical pattern recognition methods to assign Gene Ontology (GO) terms to proteins from filamentous fungi. PoGO is organized as a meta-classifier in which each evidence source (sequence similarity, protein domains, protein structure and biochemical properties) is used to train independent base-level classifiers. The outputs of the base classifiers are used to train a meta-classifier, which provides the final assignment of GO terms. An independent classifier is trained for each GO term, making the system amenable to updating, without having to re-train the whole system. The resulting system is robust. It provides better accuracy and can assign GO terms to a higher percentage of unannotated protein sequences than other methods that we tested. Our annotation system overcomes many of the shortcomings that we found in other methods. We also provide a web server where users can submit protein sequences to be annotated.
ISSN:1471-2105
1471-2105
DOI:10.1186/1471-2105-11-215