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| Main Authors: | , , |
|---|---|
| Format: | Artículo científico |
| Language: | en |
| Published: |
Current issues in molecular biology
2026
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| Online Access: | https://pubmed.ncbi.nlm.nih.gov/41899471/ |
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Table of Contents:
- Effects of Hybridization and Triploidization on Transcription of Core Metabolic and Stress Response Genes in Rainbow Trout () × Brook Trout () Hybrids-Preliminary Results. Kuciński, Marcin Rożyński, Rafał Ocalewicz, Konrad The transcriptomic effects of hybridization and triploidization were investigated in diploid and triploid rainbow trout, diploid brook trout, as well as triploid hybrids of rainbow trout and brook trout. The examined fish were reared under identical conditions for about two and a half years after hatching. Expression of ten genes involved in cellular respiration (, ), mitochondrial functioning (, ), ribosome biogenesis (, ), proteasome-mediated protein turnover (, ), and protein chaperoning (, ) was studied in liver and muscle tissues. Most of the analyzed genes (, , , , , , and ) displayed comparable expression levels in the liver tissue across the examined triploid hybrids and diploid parental species, with stabilization of genes that were both positively and negatively compensated in the triploid rainbow trout. In turn, significant upregulation of , , and genes, together with downregulation of gene, was observed in the triploid rainbow trout liver and muscle, respectively. On the other hand, triploid hybrids showed marked transcriptional upregulation of genes primarily associated with energy metabolism and protein synthesis (, , , and ) relative to all the fish groups examined. Although protein-synthesis- and energy-related genes were upregulated in the muscles of triploid hybrids, the recorded growth performance data did not indicate clear evidence of growth heterosis (MPH = -14.3% for body weight; MPH = -0.4% for body length), suggesting that potential benefits of increased heterozygosity in this cross may not be fully reflected in enhanced growth. Three- to four-fold downregulation of the heat shock protein () gene was also observed in both tissues of triploid hybrids compared with purebred diploid and triploid trout, which may reflect potential maladaptive genomic effects commonly observed in distant salmonid crosses, suggesting altered stress-response regulation in the examined triploid hybrids.