Computational identification of novel chitinase-like proteins in the Drosophila melanogaster genome

doi:10.1093/bioinformatics/bth020

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Vol. 20 no. 2 2004, pages 161-169
Bioinformatics © Oxford University Press 2004; all rights reserved.

PAG Meeting Original Paper

Computational identification of novel chitinase-like proteins in the Drosophila melanogaster genome

Qingsong Zhu ¹, Youping Deng ²^,*, Phaneendra Vanka ², Susan J. Brown ², Subbaratnam Muthukrishnan ¹ and Karl J. Kramer ³

¹ Department of Biochemistry, Kansas State University, Manhattan, KS 66506, USA, ² Bioinformatics Program, Division of Biology, Kansas State University, Manhattan, KS 66506, USA and ³ Grain Marketing and Production Research Center, ARS-USDA, Manhattan, KS 66502, USA

Received on November 9, 2003 ; accepted on November 11, 2003

Motivation: Multiple chitinases as well as lectins closely relatedto them have been characterized previously from many insectspecies and the corresponding genes/cDNAs have been cloned.However, the identification of the entire assortment of genesfor chitinase family proteins and their differences in biochemicalproperties have not been carried out in any individual insectspecies. The completion of the entire DNA sequence of Drosophilamelanogaster (fruit fly) genome and identification of open readingframes presents an opportunity to study the structures and functionsof chitinase-like proteins, and also to identify new membersof this family in Drosophila. We are, therefore, interestedin studying the functional genomics of chitinase-like gene familiesin insects.

Methods: We searched the Drosophila protein sequences databaseusing fully characterized insect chitinase sequences and BLASTPsoftware, identified all the putative chitinase-like proteinsencoded in Drosophila genome, and predicted their structuresusing domain analysis tools. A phylogenetic analysis of thechitinase-like proteins from Drosophila and several other insectspecies was carried out. The structures of these chitinaseswere modeled using homology modeling software.

Results: Our analysis revealed the presence of 18 chitinase-likeproteins in the Drosophila protein database. Among these areseven novel chitinase-like proteins that contain four signatureamino acid sequences of chitinases belonging to family 18 glycosylhydrolases,including both acidic and hydrophobic amino acid residues criticalfor enzyme activity. All the proteins contain at least one catalyticdomain with one having four catalytic domains. Phylogeneticanalysis of chitinase-like proteins from Drosophila and otherinsects revealed an evolutionary relationship among all theseproteins, which indicated gene duplication and domain shufflingto generate the observed diversity in the encoded proteins.Homology modeling showed that all the Drosophila chitinase-likeproteins contain one or more catalytic domains with a ( ${alpha}$ /ß)₈barrel-like structure. Our results suggest that insects utilizemultiple family 18 chitinolytic enzymes and also non-enzymaticchitinase-like proteins for degrading/remodeling/binding tochitin in different insect anatomical extracellular structures,such as the cuticle, peritrophic membrane, trachea and mouthparts during insect development, and possibly for other rolesincluding chitin synthesis.

Availability: Perl program and supplementary material are availableat http://www.ksu.edu/bioinformatics/supplementary.htm

Contact: ydeng{at}ksu.edu

^* To whom correspondence should be addressed.

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