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Changes in casein composition of goats' milk during the course of lactation: physiological inferences and technological implications

Published online by Cambridge University Press:  01 June 2009

Joanna R. Brown
Affiliation:
Hannah Research Institute, Ayr, KA6 5HL, UK
Andrew J. R. Law
Affiliation:
Hannah Research Institute, Ayr, KA6 5HL, UK
Christopher H. Knight
Affiliation:
Hannah Research Institute, Ayr, KA6 5HL, UK

Summary

Five British Saanen goats were milk sampled during the first 39 weeks of lactation to determine changes in casein composition. Caseins were separated by anion- and cation-exchange FPLC to determine the relative amounts of the individual caseins. Acid, alkaline and SDS-PAGE were used to determine possible genetic polymorphisms and observe any lactational changes. Total casein nitrogen was determined using a micro-Kjeldahl method and this allowed the concentrations of individual caseins to be calculated. The milk of one animal, which had the deduced genotype αs1-CnAB, showed higher concentrations of both total and αs1-casein. The remainder of the group were either heterozygous αs1-CnBE or, more probably, homozygous αs1-CnE and produced milk of a generally lower protein concentration. Both FPLC and PAGE results showed that the relative amounts and concentrations of αs2-casein decreased with stage of lactation, consistent with its susceptibility to proteolysis. The relative amounts of the breakdown products of plasmin attack on β-casein, γ-caseins, were highly negatively correlated with milk yield (r = –0·942, P < 0·001) in the declining phase of lactation, reflecting the gradual involution of the gland at this time. The relative amount of κ-casein increased by ∼ 50% after peak lactation and its concentration almost doubled near the end of lactation. These compositional changes may alter the processing qualities of goats' milk in relation to cheese production.

Type
Original Articles
Copyright
Copyright © Proprietors of Journal of Dairy Research 1995

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References

REFERENCES

Aaltonen, M. L., Lehtonen, M., Lehdonkivi, T. & Antila, V. 1988 Plasmin activity in milk. Milchwissenschaft 43 573576Google Scholar
Andrews, A. T. & Alichanidis, E. 1983 Proteolysis of caseins and the proteose-peptone fraction of bovine milk. Journal of Dairy Research 50 275290CrossRefGoogle ScholarPubMed
Dalgleish, D. G. 1993 Bovine milk protein properties and the manufacturing quality of milk. Livestock Production Science 35 7593CrossRefGoogle Scholar
Dalgleish, D. G., Horne, D. S. & Law, A. J. R. 1989 Size-related differences in bovine casein micelles. Biochimica et Biophysica Acta 991 383387CrossRefGoogle Scholar
Davies, D. T. & Law, A. J. R. 1977 An improved method for the quantitative fractionation of casein mixtures using ion-exchange chromatography. Journal of Dairy Research 44 213221CrossRefGoogle Scholar
Davies, D. T. & Law, A. J. R. 1983 Variation in the protein composition of bovine casein micelles and serum casein in relation to micellar size and milk temperature. Journal of Dairy Research 50 6775CrossRefGoogle Scholar
Davies, D. T. & Law, A. J. R. 1987 Quantitative fractionation of casein mixtures by fast protein liquid chromatography. Journal of Dairy Research 54 369376CrossRefGoogle Scholar
Eigel, W. N. 1977 Formation of γ1,-A2, γ2-A2 and γ3A caseins by in vitro proteolysis of β-casein A2 with bovine plasmin. International Journal of Biochemistry 8 187192CrossRefGoogle Scholar
Grappin, R. 1986 Variations of the major nitrogen fractions of goat and ewe milk. International Dairy Federation Bulletin no. 202 7980Google Scholar
Grosclaude, F., Mahé, M. -F., Brignon, G., Di Stasio, L. & Jeunet, R. 1987 A Mendelian polymorphism underlying quantitative variations of goat αs1-casein. Génétique Sélection, Évolution 19 399411CrossRefGoogle Scholar
Jenness, R. 1980 Composition and characteristics of goat milk: review 1968–1979. Journal of Dairy Science 63 16051630CrossRefGoogle Scholar
Knight, C. H., Fowler, P. A. & Wilde, C. J. 1990 Galactopoietic and mammogenic effects of long-term treatment with bovine growth hormone and thrice daily milking in goats. Journal of Endocrinology 127 129138CrossRefGoogle ScholarPubMed
Korycka-Dahl, M., Ribadeau Dumas, B., Chene, N. & Martal, J. 1983 Plasmin activity in milk. Journal of Dairy Science 66 704711CrossRefGoogle Scholar
Law, A. J. R., Papoff, C. M., Dalgleish, D. G. & Campus, R. L. 1992 Quantitative fractionation of ovine casein by cation-exchange FPLC. Milchwissenschaft 47 279282Google Scholar
Law, A. J. R. & Tziboula, A. 1992 Quantitative fractionation of caprine casein by cation-exchange FPLC. Milchwissenschaft 47 558562Google Scholar
Law, A. J. R. & Tziboula, A. 1993 Fractionation of caprine Ac-casein and examination of polymorphism by FPLC. Milchwissenschaft 48 6871Google Scholar
Martin, P. & Grosclaude, F. 1993 Improvement of milk protein quality by gene technology. Livestock Production Science 35 95115CrossRefGoogle Scholar
Ossowski, L., Biegel, D. & Reich, E. 1979 Mammary plasminogen activator: correlation with involution, hormonal modulation and comparison between normal and neoplastic tissue. Cell 16 929940CrossRefGoogle ScholarPubMed
Pirisi, A., Colin, O., Laurent, F., Scher, J. & Parmentier, M. 1994 Comparison of milk composition, cheesemaking properties and textural characteristics of the cheese from two groups of goats with a high or low rate of αs1-casein synthesis. International Dairy Journal 4 329345CrossRefGoogle Scholar
Politis, I., Barbano, D. M. & Gorewit, R. C. 1992 a Distribution of plasminogen and plasmin in fractions of bovine milk. Journal of Dairy Science 75 14021410CrossRefGoogle ScholarPubMed
Politis, I., Barbano, D. M. & Gorewit, R. C. 1992 b Changes in plasminogen activator in different physiological states of the gland. Journal of Dairy Science 75 (Suppl. 1) 181Google Scholar
Politis, I., Block, E. & Turner, J. D. 1990 Effect of somatotropin on the plasminogen and plasmin system in the mammary gland; proposed mechanism of action for somatotropin on the mammary gland. Journal of Dairy Science 73 14941499CrossRefGoogle ScholarPubMed
Politis, I., Lachance, E., Block, E. & Turner, J. D. 1989 a Plasmin and plasminogen in bovine milk: a relationship with involution? Journal of Dairy Science 72 900906CrossRefGoogle ScholarPubMed
Politis, I., Ng-Kwai-Hang, K. -F. & Giroux, R. N. 1989 b Environmental factors affecting plasmin activity in milk. Journal of Dairy Science 72 17131718CrossRefGoogle ScholarPubMed
Remeuf, F. & Lenoir, J. 1986 Relationship between the physico-chemical characteristics of goat's milk and its rennetability. International Dairy Federation Bulletin no. 202 6872Google Scholar
Wilde, C. J. & Knight, C. H. 1989 Metabolic adaptations in mammary gland during the declining phase of lactation. Journal of Dairy Science 72 16791692CrossRefGoogle ScholarPubMed