Pauciullo, Alfredo, Versace, Carmine, Gaspa, Giustino, Letaief, Neyrouz, Bedhiaf-Romdhani, Sonia, Fulgione, Andrea, and Cosenza, Gianfranco
Simple Summary: Milk proteins are crucial for a healthy diet and offer various health benefits. Genetic variants of milk proteins are often drivers of different technological and nutritional milk characteristics, as shown in cow milk research. Similarly, genetic variants have been identified in camel caseins, but information on the αs2-casein gene (CSN1S2) is limited. Therefore, this study investigated the CSN1S2 gene in Old-World camels (Camelus bactrianus and Camelus dromedarius). Both camel species share most of the gene characteristics, including the presence of the exon 12, formerly not described in large camels. Two novel allelic variants were discovered: one was a missense mutation (Bactrian camel), and the other was a noncoding mutation (dromedary camel). The gene promoter mutations affected the binding sites of transcription factors, and there were differences in microRNA seed sequences due to a single nucleotide polymorphism (SNP) at the 3′Untranslated region (UTR). The gene structure and interspersed element locations indicate a divergence between Tylopoda and Ruminantia. The CSN1S2 gene encodes αs2-casein, the third most abundant protein in camel milk. Despite its importance in foals, human nutrition, and dairy processing, the CSN1S2 gene in camels has received little attention. This study presents the first complete characterization of the CSN1S2 gene sequence in Old-World camels (Camelus bactrianus and Camelus dromedarius). Additionally, the gene promoter, consisting of 752 bp upstream of exon 1, was analyzed. The entire gene comprises 17 exons, ranging in length from 24 bp (exons 4, 8, 11, and 13) to 280 bp (exon 17). Interesting was the identification of the exon 12 in both species. The promoter analysis revealed 24 putative binding sites in the Bactrian camel and 22 in dromedary camel. Most of these sites were typical elements associated with milk protein, such as C/EBP-α, C/EBP-β, Oct-1, and AP1. The SNP discovery showed relatively high genetic diversity compared to other camel casein genes (CSN1S1, CSN2, and CSN3), with a total of 34 polymorphic sites across the two species. Particularly noteworthy is the transition g.311G>A in the CSN1S2 promoter, creating a new putative consensus binding site for a C/EBP-β in the Bactrian camel. At the exon level, two novel variants were found. One was detected in exon 6 of the Bactrian camel (g.3639C>G), resulting in an amino acid replacement, p.36Ile>Met. The second variant was found in noncoding exon 17 of dromedary CSN1S2 (g.1511G>T). Although this mutation occurs in the 3′-UnTranslated Region, it represents the first example of exonic polymorphism in the CSN1S2 for this species. This SNP also affects the binding sites of different microRNAs, including the seed sequence of the miRNA 4662a-3p, highlighting its role as a regulatory factor for CSN1S2 gene. A PCR-RFLP was set up for genotyping a dromedary Tunisian population (n = 157), and the minor allele frequency was found to be 0.27 for the G allele, indicating a potential yield improvement margin. The interspersed elements (INEs) analysis revealed 10 INEs covering 7.34% and 8.14% of the CSN1S2 sequence in the Bactrian and dromedary camels, respectively. Furthermore, six elements (A, B, F, H, I, and L) are shared among cattle and camels and are partially found in other ruminants, suggesting a common ancestral origin of these retrotransposons. Conversely, elements C, D, E, and G are specific to camels. [ABSTRACT FROM AUTHOR]