In recent years, there has been increasing demand for red tilapia, which are commercial strains of hybrids of different tilapiine species or red variants of highly inbred Nile tilapia. However, red tilapia phenotypes are genetically unstable and affected by environmental factors, resulting in nonuniform coloration with black or dark-red color blotches that reduce their market value. Solute carrier family 45 member 2 (SLC45A2) is a membrane transporter that mediates melanin biosynthesis and is evolutionarily conserved from fish to humans. In the present study, we describe the generation of a stable and heritable red tilapia phenotype by inducing loss-of-function mutations in the slc45a2 gene. For this purpose, we identified the slc45a2 gene in Nile tilapia and designed highly specific guide RNAs (gRNA) for its genomic sequence. Multiplex microinjection of slc45a2-specific ribonucleoproteins to Nile tilapia zygotes induced up to 97-99% albinism, including loss of melanin in the eye. Next-generation sequencing of the injected zygotes demonstrated that all injected fish carried mutant alleles with variable mutagenesis efficiencies. Sanger sequencing of the genomic target region in the slc45a2 gene from fin clips, sperm, and F 1 offspring of a highly mutant male identified various genomic indels and germline transmission of the sperm-identified indels. Overall, this work demonstrates the generation of somatic and germline slc45a2 mutant alleles, which leads to complete albinism in Nile tilapia.
The growth and differentiation factor Myostatin (MSTN, also known as GDF8) negatively regulates skeletal muscle development and growth in vertebrates. Most fish genomes contain two or more mstn genes, which are expressed in muscle and other tissues. Yet, in the genome of Nile tilapia (Oreochromis niloticus), which is one of the world's most important aquaculture fish species, only one mstn gene has previously been identified. Here, we identify a second mstn gene in Nile tilapia. We show that it clusters phylogenetically with other piscine mstn2 genes and that it shares chromosomal synteny with the human and zebrafish orthologs. We further show that mstn2 is not expressed in red or white muscles of Nile tilapia, but rather that its main site of expression is the brain. To determine which physiological functions are correlated with mstn expression, adult Nile tilapia were exposed to various environmental conditions and their effect on mstn1 and mstn2 expression in the brain and muscles was measured using real-time PCR. We found that the centrally-and muscle-expressed mstn genes differ in their responsiveness to diverse challenges, suggesting differential gene-and tissue-specific regulation of their expression. Metabolic and stress marker analyses showed that the altered mstn expression is not regulated by classical stress response. Taken together, our findings expand the understanding of the MSTN system in Nile tilapia and provide evolutionary insight into its function.
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