TY - JOUR
T1 - Homology-based annotation yields 1,042 new candidate genes in the drosophila melanogaster genome
AU - Gopal, Shuba
AU - Schroeder, Mark
AU - Pieper, Ursula
AU - Sczyrba, Alexander
AU - Aytekin-Kurban, Gulriz
AU - Bekiranov, Stefan
AU - Eduardo Fajardo, J.
AU - Eswar, Narayanan
AU - Sanchez, Roberto
AU - Sali, Andrej
AU - Gaasterland, Terry
N1 - Funding Information:
We thank S. Burley, M. Vidal, J. Sorge, J. Goncalves, M. Ashburner, S. Lewis, M. Young and U. Gaul for insights and comments. This work was partially supported by the Mathers, Sinsheimer and Mallinkrodt Foundations, National Cancer Institute Health grant R33CA84699, National Institutes of Health grant P50GM62529, and the National Science Foundation grant DBI-9984882.
PY - 2001
Y1 - 2001
N2 - The approach to annotating a genome critically affects the number and accuracy of genes identified in the genome sequence. Genome annotation based on stringent gene identification is prone to underestimate the complement of genes encoded in a genome. In contrast, over-prediction of putative genes followed by exhaustive computational sequence, motif and structural homology search will find rarely expressed, possibly unique, new genes at the risk of including non-functional genes. We developed a two-stage approach that combines the merits of stringent genome annotation with the benefits of over-prediction. First we identify plausible genes regardless of matches with EST, cDNA or protein sequences from the organism (stage 1). In the second stage, proteins predicted from the plausible genes are compared at the protein level with EST, cDNA and protein sequences, and protein structures from other organisms (stage 2). Remote but biologically meaningful protein sequence or structure homologies provide supporting evidence for genuine genes. The method, applied to the Drosophila melanogaster genome, validated 1,042 novel candidate genes after filtering 19,410 plausible genes, of which 12,124 matched the original 13,601 annotated genes1. This annotation strategy is applicable to genomes of all organisms, including human.
AB - The approach to annotating a genome critically affects the number and accuracy of genes identified in the genome sequence. Genome annotation based on stringent gene identification is prone to underestimate the complement of genes encoded in a genome. In contrast, over-prediction of putative genes followed by exhaustive computational sequence, motif and structural homology search will find rarely expressed, possibly unique, new genes at the risk of including non-functional genes. We developed a two-stage approach that combines the merits of stringent genome annotation with the benefits of over-prediction. First we identify plausible genes regardless of matches with EST, cDNA or protein sequences from the organism (stage 1). In the second stage, proteins predicted from the plausible genes are compared at the protein level with EST, cDNA and protein sequences, and protein structures from other organisms (stage 2). Remote but biologically meaningful protein sequence or structure homologies provide supporting evidence for genuine genes. The method, applied to the Drosophila melanogaster genome, validated 1,042 novel candidate genes after filtering 19,410 plausible genes, of which 12,124 matched the original 13,601 annotated genes1. This annotation strategy is applicable to genomes of all organisms, including human.
UR - http://www.scopus.com/inward/record.url?scp=0035096629&partnerID=8YFLogxK
U2 - 10.1038/85922
DO - 10.1038/85922
M3 - Article
C2 - 11242120
AN - SCOPUS:0035096629
SN - 1061-4036
VL - 27
SP - 337
EP - 340
JO - Nature Genetics
JF - Nature Genetics
IS - 3
ER -