A novel allelic donkey β-lactogobulin I protein isoform generated by a non-AUG translation initiation codon is associated with a nonsynonymous SNP.

β-Lactoglobulin I (β-LG I) is one of the most important whey proteins in donkey milk. However, to our knowledge, there has been no study focusing on the full nucleotide sequences of this gene (BLG I). Current investigation of donkey BLG I gene is very limited with only 2 variants (A and B) characterized so far at the protein level. Recently, a new β-LG I variant, with a significantly higher mass (+1,915 Da) than known variants has been detected. In this study, we report the whole nucleotide sequence of the BLG I gene from 2 donkeys, whose milk samples are characterized by the β-LG I SDS-PAGE band with a normal electrophoretic mobility (18,514.25 Da, β-LG I B1 form) the first, and by the presence of a unique β-LG I band with a higher electrophoretic mobility (20,428.5 Da, β-LG I D form) the latter. A high genetic variability was found all over the 2 sequenced BLG I alleles. In particular, 16 polymorphic sites were found in introns, one in the 5' flanking region, 3 SNPs in the 5' untranslated region and one SNP in the coding region (g.458G > A) located at the 40th nucleotide of exon 2 and responsible for the AA substitutions p.Asp28 > Asn in the mature protein. Two SNPs (g.920-922CAC > TGT and g.1871G/A) were genotyped in 93 donkeys of 2 Italian breeds (60 Ragusana and 33 Amiatina, respectively) and the overall frequencies of g.920-922CAC and g.1871A were 0.3065 and 0.043, respectively. Only the rare allele g.1871A was observed to be associated with the slower migrating β-LG I. Considering this genetic diversity and those found in the database, it was possible to deduce at least 5 different alleles (BLG I A, B, B1, C, D) responsible for 4 potential β-LG I translations. Among these alleles, B1 and D are those characterized in the present research, with the D allele of real novel identification. Haplotype data analysis suggests an evolutionary pathway of donkey BLG I gene and a possible phylogenetic map is proposed. Analyses of mRNA secondary structure showed relevant changes in the structures, as consequence of the g.1871G > A polymorphism, that might be responsible for the recognition of an alternative initiation site providing an additional signal peptide. The extension of 19 AA sequence to the mature protein, corresponding to the canonical signal peptide with an additional alanine residue, is sufficient to provide the observed molecular weight of the slower migrating β-LG I encoded by the BLG I D allele.

[1]  C. Henry,et al.  Top-Down proteomics based on LC-MS combined with cDNA sequencing to characterize multiple proteoforms of Amiata donkey milk proteins. , 2022, Food Research International.

[2]  R. MacLaren,et al.  An analysis of the Kozak consensus in retinal genes and its relevance to gene therapy , 2021, Molecular vision.

[3]  F. Mallet,et al.  RNA-Seq Transcriptome Analysis Reveals Long Terminal Repeat Retrotransposon Modulation in Human Peripheral Blood Mononuclear Cells after In Vivo Lipopolysaccharide Injection , 2020, Journal of Virology.

[4]  G. Chemello,et al.  Sequencing of lipoprotein lipase gene in the Mediterranean river buffalo identified novel variants affecting gene expression. , 2020, Journal of dairy science.

[5]  M. Maćkowski,et al.  Genes encoding equine β-lactoglobulin (LGB1 and LGB2): Polymorphism, expression, and impact on milk composition , 2020, PloS one.

[6]  Jianzhi Zhang,et al.  Mammalian alternative translation initiation is mostly nonadaptive. , 2020, Molecular biology and evolution.

[7]  G. Garro,et al.  Casein composition and differential translational efficiency of casein transcripts in donkey's milk. , 2019, The Journal of dairy research.

[8]  R. Işık The Identification of Novel Single‐Nucleotide Polymorphisms of Equine Beta‐Lactoglobulin and Lactotransferrin Genes , 2019, Journal of equine veterinary science.

[9]  Fabien Moretto,et al.  Repression of Divergent Noncoding Transcription by a Sequence-Specific Transcription Factor , 2018, bioRxiv.

[10]  G. Cosenza,et al.  Sequence variation and detection of a functional promoter polymorphism in the lysozyme c-type gene from Ragusano and Grigio Siciliano donkeys. , 2018, Animal genetics.

[11]  A. Hinnebusch,et al.  eIF1A residues implicated in cancer stabilize translation preinitiation complexes and favor suboptimal initiation sites in yeast , 2017, eLife.

[12]  J. Wilusz,et al.  Non-AUG translation: a new start for protein synthesis in eukaryotes , 2017, Genes & development.

[13]  R. Capparelli,et al.  Molecular characterisation, genetic variability and detection of a functional polymorphism influencing the promoter activity of OXT gene in goat and sheep , 2017, Journal of Dairy Research.

[14]  R. Capparelli,et al.  The SNP g.1311T>C associated with the absence of β-casein in goat milk influences CSN2 promoter activity. , 2016, Animal genetics.

[15]  G. Erhardt,et al.  Alpha S1-casein polymorphisms in camel (Camelus dromedarius) and descriptions of biological active peptides and allergenic epitopes , 2016, Tropical Animal Health and Production.

[16]  L. Pacios,et al.  Structural similarities of human and mammalian lipocalins, and their function in innate immunity and allergy , 2015, Allergy.

[17]  A. Hinnebusch,et al.  The β-hairpin of 40S exit channel protein Rps5/uS7 promotes efficient and accurate translation initiation in vivo , 2015, eLife.

[18]  A. Brodkorb,et al.  Bovine β-lactoglobulin/fatty acid complexes: binding, structural, and biological properties , 2014, Dairy science & technology.

[19]  Tamir Tuller,et al.  New Universal Rules of Eukaryotic Translation Initiation Fidelity , 2013, PLoS Comput. Biol..

[20]  V. Bâlteanu,et al.  Identification of an intronic regulatory mutation at the buffalo αS1-casein gene that triggers the skipping of exon 6 , 2013, Molecular Biology Reports.

[21]  T. Haertlé,et al.  Interactions of β-lactoglobulin variants A and B with Vitamin A. Competitive binding of retinoids and carotenoids. , 2013, Journal of agricultural and food chemistry.

[22]  G. Vegarud,et al.  Antimicrobial effect of donkeys’ milk digested in vitro with human gastrointestinal enzymes , 2011 .

[23]  J. Jordana,et al.  Association between the polymorphism of the goat stearoyl-CoA desaturase 1 (SCD1) gene and milk fatty acid composition in Murciano-Granadina goats. , 2010, Journal of dairy science.

[24]  P. Ferranti,et al.  Proteomic characterization of donkey milk "caseome". , 2010, Journal of chromatography. A.

[25]  P. Ferranti,et al.  Genomics and proteomics of deleted ovine CSN1S1∗I , 2010 .

[26]  D. Di Berardino,et al.  A point mutation in the splice donor site of intron 7 in the alphas2-casein encoding gene of the Mediterranean River buffalo results in an allele-specific exon skipping. , 2009, Animal genetics.

[27]  C. Goding,et al.  Target Gene Specificity of USF-1 Is Directed via p38-mediated Phosphorylation-dependent Acetylation* , 2009, The Journal of Biological Chemistry.

[28]  Ronny Lorenz,et al.  The Vienna RNA Websuite , 2008, Nucleic Acids Res..

[29]  Jan Komorowski,et al.  Whole-genome maps of USF1 and USF2 binding and histone H3 acetylation reveal new aspects of promoter structure and candidate genes for common human disorders. , 2008, Genome research.

[30]  D. Di Berardino,et al.  An SNP in the goat CSN2 promoter region is associated with the absence of beta-casein in milk. , 2007, Animal genetics.

[31]  G. Felsenfeld,et al.  USF1 Recruits Histone Modification Complexes and Is Critical for Maintenance of a Chromatin Barrier , 2007, Molecular and Cellular Biology.

[32]  L. Parfrey,et al.  Genome-wide analysis of transcriptional dependence and probable target sites for Abf1 and Rap1 in Saccharomyces cerevisiae , 2006, Nucleic acids research.

[33]  S. Corre,et al.  Upstream stimulating factors: highly versatile stress-responsive transcription factors. , 2005, Pigment cell research.

[34]  D. Di Berardino,et al.  Comparative analysis of gene sequence of goat CSN1S1 F and N alleles and characterization of CSN1S1 transcript variants in mammary gland. , 2005, Gene.

[35]  C. Leroux,et al.  Proteomic tools to characterize the protein fraction of Equidae milk , 2004, Proteomics.

[36]  Lindsay Sawyer,et al.  Invited Review: β-Lactoglobulin: Binding Properties, Structure, and Function , 2004 .

[37]  A. Prats,et al.  Generation of protein isoform diversity by alternative initiation of translation at non‐AUG codons , 2003, Biology of the cell.

[38]  M. Kozak,et al.  Pushing the limits of the scanning mechanism for initiation of translation , 2002, Gene.

[39]  L. Zwierzchowski,et al.  The impact of genetic polymorphisms on the protein composition of ruminant milks. , 2002, Reproduction, nutrition, development.

[40]  S. Gabriel,et al.  The Structure of Haplotype Blocks in the Human Genome , 2002, Science.

[41]  G. Kontopidis,et al.  The core lipocalin, bovine β-lactoglobulin. , 2000 .

[42]  D. Mollé,et al.  New Genetic Variants Identified in Donkey's Milk Whey Proteins , 2000, Journal of protein chemistry.

[43]  R. Pena,et al.  Isolation, sequencing and relative quantitation by fluorescent-ratio PCR of feline β-lactoglobulin I, II, and III cDNAs , 1999, Mammalian Genome.

[44]  P. Mariani,et al.  Characterization of the CSN1AG allele of the bovine alpha s1-casein locus by the insertion of a relict of a long interspersed element. , 1998, Journal of dairy science.

[45]  R. Passey,et al.  Exon skipping in the ovine alpha s1-casein gene. , 1996, Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology.

[46]  Miguel Calvo Rebollar,et al.  Interaction of beta-lactoglobulin with retinol and fatty acids and its role as a possible biological function for this protein: a review. , 1995, Journal of dairy science.

[47]  C. Leroux,et al.  Occurrence of a LINE sequence in the 3' UTR of the goat alpha s1-casein E-encoding allele associated with reduced protein synthesis level. , 1994, Gene.

[48]  R. Goodman,et al.  Bovine mammary lactoferrin: implications from messenger ribonucleic acid (mRNA) sequence and regulation contrary to other milk proteins. , 1993, Journal of dairy science.

[49]  Miguel Calvo Rebollar,et al.  Comparison of the ability to bind lipids of β-lactoglobulin and serum albumin of milk from ruminant and non-ruminant species , 1993, Journal of Dairy Research.

[50]  N. Mazure,et al.  Mutations away from splice site recognition sequences might cis-modulate alternative splicing of goat alpha s1-casein transcripts. Structural organization of the relevant gene. , 1992, The Journal of biological chemistry.

[51]  C. Leroux,et al.  Exon-skipping is responsible for the 9 amino acid residue deletion occurring near the N-terminal of human beta-casein. , 1992, Biochemical and biophysical research communications.

[52]  L. Napolitano,et al.  Microanalysis of the amino-acid sequence of monomeric beta-lactoglobulin I from donkey (Equus asinus) milk. The primary structure and its homology with a superfamily of hydrophobic molecule transporters. , 1988, Biological chemistry Hoppe-Seyler.

[53]  M. Mahé,et al.  A Mendelian polymorphism underlying quantitative variations of goat αs1-casein , 1987, Génétique, sélection, évolution.

[54]  G. Heijne A new method for predicting signal sequence cleavage sites. , 1986 .

[55]  K. Brew,et al.  Purification and characterization of the major whey proteins from the milks of the bottlenose dolphin (Tursiops truncatus), the Florida manatee (Trichechus manatus latirostris), and the beagle (Canis familiaris). , 1986, Archives of biochemistry and biophysics.

[56]  A. Conti,et al.  The primary structure of monomeric beta-lactoglobulin I from horse colostrum (Equus caballus, Perissodactyla). , 1984, Hoppe-Seyler's Zeitschrift fur physiologische Chemie.

[57]  A. Criscione,et al.  Whey proteins and their antimicrobial properties in donkey milk: a brief review , 2016 .

[58]  Szymanowska,et al.  Effects of polymorphism at 5 ’-noncoding regions ( promoters ) of α S 1-and α S 2-casein genes on selected milk production traits in Polish Black-and-White cows * , 2007 .

[59]  M. Paetzel,et al.  Signal peptidases. , 2002, Chemical reviews.

[60]  L. Napolitano,et al.  Covalent structure of the minor monomeric beta-lactoglobulin II component from donkey milk. , 1990, Biological chemistry Hoppe-Seyler.

[61]  M. Goossens,et al.  DNA analysis in the diagnosis of hemoglobin disorders. , 1981, Methods in enzymology.