Gene expression profiling of gilthead sea bream during early development and detection of stress-related genes by the application of cDNA microarray technology
Title | Gene expression profiling of gilthead sea bream during early development and detection of stress-related genes by the application of cDNA microarray technology |
Publication Type | Journal Article |
Year of Publication | 2005 |
Authors | Sarropoulou, E, Kotoulas G, Power DM, Geisler R |
Journal | Physiol Genomics |
Volume | 23 |
Pages | 182-91 |
Keywords | *Gene Expression Profiling, *Oligonucleotide Array Sequence Analysis, Animals, Cluster Analysis, Embryo, Nonmammalian/anatomy & histology/embryology/metabolism, Fish Proteins/*genetics, Genes, Developmental/genetics, Molecular Sequence Data, Sea Bream/anatomy & histology/embryology/*genetics/*growth & development, Stress/*genetics, Time Factors |
Abstract | Large-scale gene expression studies were performed for one of the main European aquaculture species, the gilthead sea bream Sparus auratus L. For this purpose, a cDNA microarray containing 10,176 clones from a cDNA library of mixed embryonic and larval stages was constructed. In addition to its importance for aquaculture, the taxonomic position and the relatively small genome size of sea bream makes it a prospective model for evolutionary biology and comparative genomics. However, so far, no large-scale analysis of gene expression exists for this species. In the present study, gene expression was analyzed in gilthead sea bream during early development, a significant period in the determination of quantitative traits and therefore of considerable interest for aquaculture. Synexpression groups expressed primarily early and late in development were determined and were composed of both known and novel genes. Furthermore, it was possible to identify stress response genes induced by cortisol injections using the cDNA microarray generated. The creation of gene expression profiles for sea bream by microarray hybridization will accelerate identification of candidate genes involved in multifactorial traits and certain regulatory pathways and will also contribute to a better understanding of the genetic background of fish physiology, which may help to improve aquaculture practices. |
URL | http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&dopt=Citation&list_uids=16046618 |