The co-existence of two growth hormone receptors in teleost fish and their differential signal transduction, tissue distribution and hormonal regulation of expression in seabream

doi:10.1677/jme.1.01945

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The co-existence of two growth hormone receptors in teleost fish and their differential signal transduction, tissue distribution and hormonal regulation of expression in seabream

Baowei Jiao¹^,2, Xigui Huang¹^,3, Chi Bun Chan¹, Li Zhang³, Deshou Wang³ and Christopher H K Cheng¹

¹ Department of Biochemistry and
² the Environmental Science Programme, The Chinese University of Hong Kong, Shatin, New Territories, Hong Kong, China
³ Key Laboratory of Aquatic Science of Chongqing, Faculty of Life Sciences, Southwest University, Beibei, Chongqing 400715, China

(Requests for offprints should be addressed to C H K Cheng; Email: chkcheng{at}cuhk.edu.hk)

(All authors contributed equally to this work.)

Two genomic contigs of putative growth hormone receptors (GHRs)were identified in fugu and zebrafish genomes by in silico analysis,suggesting the presence of two GHR subtypes in a single teleostspecies. We have tested this hypothesis by cloning the full-lengthcDNA sequence of a second GHR subtype from the black seabreamin which the first GHR subtype had been previously reportedby us. In addition, we had also cloned the sequences of bothGHR subtypes from two other fish species, namely the Southerncatfish and the Nile tilapia. Phylogenetic analysis of knownGHR sequences from various vertebrates revealed that fish GHRscluster into two distinct clades, viz. GHR1 and GHR2. One clade(GHR1), containing 6 to 7 extracellular cysteine residues, isstructurally more akin to the non-teleost GHRs. The other clade(GHR2), containing only 4 to 5 extracellular cysteine residues,is unique to teleosts and is structurally more divergent fromthe non-teleost GHRs. In addition, we had examined the biologicalactivities of both GHR subtypes from seabream using a numberof reporter transcription assays in cultured eukaryotic cellsand demonstrated that both of them were able to activate theSpi 2.1 and ß-casein promoters upon receptor stimulationin a ligand specific manner. In contrast, only GHR1 but notGHR2 in seabream could trigger the c-fos promoter activity,indicating that the two GHR subtypes possess some differencesin their signal transduction mechanisms. Also, the expressionof GHR2 is significantly higher than GHR1 in many tissues ofthe seabream including the gonad, kidney, muscle, pituitaryand spleen. In vivo hormone treatment data indicated that cortisolupregulated hepatic GHR1 expression in seabream but not GHR2,whereas testosterone decreased hepatic GHR2 expression but notGHR1. On the other hand, hepatic expression of both GHR1 andGHR2 in seabream was decreased by estradiol treatment.

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