Giuseppina Garro

Effects of sheep α s1 -casein CC, CD and DD genotypes on milk composition and cheesemaking properties

The effects of sheep alpha s1-casein CC, CD and DD genotypes on milk composition and cheese yield were studied. Processed bulk milk was collected from three groups of 15 ewes, carrying alpha s1-casein CC, CD and DD genotypes. CC milk was higher in casein content than CD or DD milk (+3.5 and +8.6% respectively), and had a higher protein: fat ratio and a smaller casein micelle diameter. In addition, DD milk had a significantly lower alpha s1-casein content. The main differences were in curd formation: CC milk had better renneting properties. Cheesemaking trials, carried out in a pilot plant, showed that CC milk had better cheesemaking characteristics than DD milk, while CD milk was intermediate. Both 1 d old and fully ripened cheeses had different fat: dry matter ratios and alpha s1-I-casein electrophoretic mobilities: these were lower for DD cheese. As a consequence, these genotypes could be considered as markers of milk and/or cheese quality.

Occurrence of five alpha s1-casein variants in ovine milk.

Five ovine alpha s1-casein variants (A-E) were identified in an Italian population sample using gel electrophoresis at alkaline pH, gel isoelectric focusing, two dimensional gel electrophoresis, and immunoblotting with polyclonal antibodies against alpha s1-casein. Each casein sample produced two peaks by fast reversed-phase HPLC. Gel isoelectric focusing and electrospray mass spectrometry were used to demonstrate that the first HPLC peak contained the 191 residue alpha s1-casein molecular species and the second the 199 residue species, in proportions of approximately 20:80. Only in the case of the sample containing alpha s1-casein CE was the method for the separation of the single short and long forms of each variant unsuccessful. Both two dimensional electrophoresis followed by staining with polyclonal antibodies against alpha s1-casein and electrospray mass spectrometry showed a heterogeneity consistent with that expected from a protein chain with three levels of phosphorylation and two different lengths. However, especially for alpha s1-caseins D and E, a further uncharacterized heterogeneity was detected.

Proteomic characterization of donkey milk “caseome”

At present, compared with bovine milk, the characterization of donkey milk caseins is at a relatively early stage progress, and only limited data are related to its genetic polymorphism. In this work, the heterogeneity of donkey caseome was investigated using a proteomic approach, based on one- (PAGE, UTLIEF) and two-dimensional (PAGE-->UTLIEF) electrophoresis, stained with either Coomassie Brilliant Blue or specific polyclonal antibodies, and structural MS analysis. These combined methodologies allowed the contemporary identification of donkey alpha(s1), alpha(s2), beta and kappa-CN with their related heterogeneity due to phosphorylation (alpha(s1), alpha(s2) and beta-CN), glycosylation (kappa-CN) and incorrect splicing of RNA in mRNA (deleted forms of alpha(s1)-CN and beta-CN). The results achieved showed 11 components for kappa-CN, six phosphorylated components for beta and alpha(s1)-CN and three main phosphorylated components for alpha(s2)-CN, each accounting for 10, 11 and 12 P/mole. At this regard, for the first time, the primary structure of the expressed protein corresponding to the only available donkey alpha(s2)-CN cDNA sequence was determined. Furthermore beta-CN was found in homozygous and heterozygous state for the occurrence of a genetic beta-CN variant having a MW value 28 mass units higher than the common beta-CN phenotype.

Gel electrophoresis and immunoblotting for the detection of casein proteolysis in cheese.

The whole N fraction of six samples of hard and semi-hard pressed cheeses was analysed using PAGE, polyacrylamide gel isoelectric focusing and immunoblotting with polyclonal antibodies against beta- and alpha s1-casein. The origin of some electrophoretic bands corresponding to peptides produced from the enzymic degradation of the casein fractions was established. A number of these peptides were also present in the in vitro hydrolysates of casein with plasmin and chymosin. Thus, it was also possible to determine which casein was the source of each peptide and which enzymes were active in cheese. Compared with the traditional Coomassie staining procedures, immunoblotting is more sensitive and specific, making the interpretation of each electrophoretic profile easy. Thus, it was also possible to obtain a clear picture of the state of each casein fraction in a cheese variety. Two main peptides were isolated from the pH 4.6-insoluble N fraction of Parmigiano-Reggiano using DEAE-cellulose chromatography and identified, from the amino acid sequence of the N- and C-terminal ends, as gamma 3-casein (beta-casein(f108-209)) and alpha s1-PL1 (alpha s1-casein(f80-199). In both cases, a Lys-X bond was hydrolysed, indicating the action of a trypsin-like enzyme in beta- and alpha s1-casein hydrolysis during the ripening of this variety of hard pressed cheese.

Mass spectrometry-based procedure for the identification of ovine casein heterogeneity

The efficiency of reversed-phase HPLC, capillary electrophoresis (CE), PAGE and isoelectric focusing with immunoblotting in separating ovine caseins has been evaluated. The assessment was carried out by employing electrospray ionization-mass spectrometry (ESI-MS) and matrix-assisted laser desorption ionization-time of flight as reference tools for identifying protein components. Ovine casein was fractionated by HTPC into four major peaks. With ESI-MS, each peak contained components belonging to only one of the four casein families. On-line liquid chromatography-ESI-MS allowed us to determine each fractions composition by detecting thirteen alphas1-, eleven alphas2-, seven beta-, and three kappa-casein (CN) components. The alphas1-CN and alphas2-CN consisted of eight and two protein chains respectively of lengths differing through the deletion of one or more peptide sequences; they were also discretely phosphorylated as kappa-CN and beta-CN. By CE at pH 2.5, each casein fraction was as heterogeneous as that resulting from ESI-MS for the single HPLC-derived fractions. The separation of alphas1-CN and alphas2-CN proved to be excellent, with the exception of a co-migration of kappa0-CN with a minor alphas1-CN component and of a glycosylated kappa-CN for with low-phosphorylated = alphas1-CN and beta-CN components. Dephosphorylation of whole casein was used to reduce the heterogeneity of the native fractions and by applying currently used analytical techniques it was possible to visualize the protein moiety difference along the CE profile. CE, HPLC, and immunoblotting were all equally capable of effecting an accurate separation of the four dephosphorylated casein families. The spectra obtained by ESI-MS directly on dephosphorylated whole ovine casein samples contained the signals of the four casein families and the relative alphas1-CN variants, the non-allelic alphas1-CN and alphas2-CN forms, dimeric kappa-CN and other newly formed peptides. We suggest using this procedure for rapid characterization of whole casein.

Discrete phosphorylation generates the electrophoretic heterogeneity of ovine β-casein

The heterogeneity of ovine β-casein, apparent after discontinuous gel electrophoresis at alkaline pH and gel isoelectric focusing either by staining with Coomassie blue or immunoblotting, was investigated in detail. Electrospray mass spectrometry was used to characterize ovine casein by direct examination of whole casein samples. β-Casein in individual milks consisted of several components which were characterized through the accurate determination of their molecular masses. It was demonstrated that protein species occurring simultaneously in individual ovine milks differed mainly in the number of phosphate groups.

Discovery of an ovine α s2 -casein variant

A novel ovine alpha S2-casein variant has been detected using discontinuous polyacrylamide gel electrophoresis at alkaline pH, two dimensional electrophoresis and immunoblotting. It is characterized by a greater negative net charge and a lower isoelectric point compared with the most common ovine alpha S2-casein variant. The phenotypic frequency in the Manchega breed is 5.5%.

The occurrence of genetic polymorphism and related non‐allelic proteins increases the compositional complexity of goat α(s1)‐CN

A genetic survey on three autochthonous goat breeds reared in Italy was carried out by a proteomic approach. This methodology, further to providing the phenotypic frequency of identified αs1 genetic variants, allowed to determine (i) the additional constitutive presence of a non‐allelic ‘αs1‐casein (CN) F like’ protein in goat ‘strong’ αs1 variants; (ii) an αs1‐CN B2 like protein, expressed at very low quantitative level, in goat ‘weak’ αs1‐CN variants, and, as main focus; (iii) the occurrence of a new αs1‐CN D1 variant characterised by the lack of αs1 (f59‐69) sequence otherwise encoded by exon 9 in goat αs1 B2 reference. The same exon skipping event had been identified since 1990, as responsible of the ‘weak quantitative class’ of αs1‐CN D variant (0.6 g/L), while the new αs1‐CN D1, has been ‘quantitatively’ classified as an ‘intermediate’ variant, since 1.8 g/L per allele was assessed in the milk.