[Exon and Intron Variability in Salmonidae Growth Hormone Genes].

Gene duplication is one of the main mechanisms of formation of new genetic material in evolution. The occurrence of a gene duplication is believed to relax selection pressure on one of the copies. Consequently, this gene accumulates mutations at a higher rate, and over time it acquires a new function. As a result of several rounds of polyploidization, many genes in salmon are duplicated, including the growth hormone gene. The analysis of nucleotide diversity in the paralogous genes of growth hormone, gh1 and gh2, demonstrated that the level of variability in their introns was higher than in the exons. In addition, the variability of each exon weakly correlated with its length, and seems to be determined by the functional significance of the protein region encoded. The level of variability in the exons of the gh2 gene was higher than that in the gh1 one, which was probably due to the current process of gene subfunctionalization.

[Divergence of paralogous growth-hormone-encoding genes and their promoters in Salmonidae].

In many fish species, including salmonids, the growth-hormone is encoded by two duplicated paralogous genes, gh1 and gh2. Both genes were already in place at the time of divergence of species in this group. A comparison of the entire sequence of these genes of salmonids has shown that their conserved regions are associated with exons, while their most variable regions correspond to introns. Introns C and D include putative regulatory elements (sites Pit-1, CRE, and ERE), that are also conserved. In chars, the degree of polymorphism of gh2 gene is 2-3 times as large as that in gh1 gene. However, a comparison across all Salmonidae species would not extent this observation to other species. In both these chars' genes, the promoters are conserved mainly because they correspond to putative regulatory sequences (TATA box, binding sites for the pituitary transcription factor Pit-1 (F1-F4), CRE, GRE and RAR/RXR elements). The promoter of gh2 gene has a greater degree of polymorphism compared with gh1 gene promoter in all investigated species of salmonids. The observed differences in the rates of accumulation of changes in growth hormone encoding paralogs could be explained by differences in the intensity of selection.

[Fish growth hormone genes: Divergence of coding sequences in salmonid fishes].

Comparison of coding nucleotide sequences of the paralogous GH1 and GH2 genes, as well as of the growth hormone amino acid sequences, in the species of closely related salmonid genera Salvelinus, Oncorhynchus, and Salmo was performed. It was demonstrated that, in different groups of salmonids, the amino acid substitution rates were considerably different. In some cases, an obvious discrepancy between the divergence of growth hormone genes and phylogenetic schemes based on other methods and approaches was revealed. These findings suggest that the reason may be multidirectional selection at duplicated genes at different stages of evolution.

[Fish growth-hormone genes: functionality evidence of paralogous genes in Levanidov's charr].

In the genome of most vertebrates growth-hormone gene is presented in a single copy, while in salmonids after one of the duplication events many genes were multiplied, including growth hormone gene. In salmonids, the growth-hormone gene exists as two independently inherited functional paralogues, gh1 and gh2. In this study, we performed a comparative analysis of gh1 and gh2 growth-hormone genes and their adjacent sequences in Levanidov's charr Salvelinus levanidovi to determine their functionality and define the potential differences. We found that both genes have the same gene structure and are composed of six exons (I-VI) and five introns (A, B, C, D, E). However, the respective gene sequences differ in length. A comparison of exons showed that the size of each exon is identical in both paralogues. The overall length of genes differs due to the varying lengths of introns. Coding sequence of both genes contains an open reading frame for 210 amino acids. We identified regulatory elements in the promoter region of both genes: TATA box, A/T-rich regions that contain binding sites for pituitary-specific transcriptional activator Pit-1, and regions responsible for interaction with other transcriptional activators and initiators, in particular hormone receptors. The obtained data indicate that both genes are functional.

[Fish growth hormone genes: divergence of intron sequence in charrs of Salvelinus genus].

Sequences of the two large introns (C and D) from two paralogous growth hormone genes, GH1 and GH2, were compared in eight charr species of the Salvelinus genus (Osteichthes, Salmonidae). It was demonstrated that the rates of intron divergence in these two genes were remarkably different. Introns in the GH1 gene appeared to be more conservative, while the rate of intron variations was considerably higher in the GH2 gene. These data suggest that noncoding regions of nuclear genes are shaped by selective pressure. The lower congruence of phylogenetic scheme constructed based on an analysis of the GH1 introns compared to that based on the GH2 data, as well as with the traditional views on the evolution of charr species, also favors the supposition on contrasted patterns of selective pressure in noncoding intronic sequences.