Molecular characterization, function, tissue differential expression, and single-nucleotide polymorphism of buffalo TP53 gene

Abstract. TP53 has been shown to be involved in lactation in cattle. However, the role of TP53 in buffalo lactation remains unknown. To this end, we isolated and identified the complete coding sequence (CDS) of the TP53 gene from the buffalo mammary gland and further analyzed its molecular characteristics, function, tissue differential expression, and single-nucleotide polymorphism (SNP). A transcript of this gene was cloned with a CDS length of 1161 bp, encoding a protein consisting of 386 amino acid residues. Bioinformatics analysis showed that buffalo TP53 CDS and the physicochemical characteristics, conserved domains, structure, and function of its encoded protein are highly similar to those of other species in Bovidae. The buffalo TP53 protein contains an N-terminal activation domain, a DNA-binding domain, and a tetrameric domain, and it plays a functional role in the nucleus. TP53 was found to express in all 11 detected buffalo tissues, and its expression in the heart, kidney, brain, muscle, and rumen during lactation was significantly higher than that during non-lactation (p<0.05), while in the liver, lung, and mammary gland, its expression was the opposite (p<0.05). Interference experiments in buffalo mammary epithelial cells (BuMECs) showed that TP53 inhibits the expression of genes related to milk protein and milk fat synthesis through the PI3K–AKT–mTOR pathway. A synonymous nucleotide substitution (c.204C > T) was found in the TP53 CDS of river buffalo, which is the CC homozygote in swamp buffalo. The results indicate that the TP53 gene is involved in buffalo lactation by negatively regulating the synthesis of milk protein and milk fat.