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Heat stability of milk: influence of colloidal and soluble salts and protein modification on the pH-dependent dissociation of micellar κ-casein

Published online by Cambridge University Press:  01 June 2009

Harjinder Singh  and
Patrick F. Fox
Harjinder Singh
Affiliation:
Department of Food Chemistry, University College, Cork, Irish Republic
Patrick F. Fox
Affiliation:
Department of Food Chemistry, University College, Cork, Irish Republic
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Summary

Reducing the colloidal calcium phosphate (CCP) content of milk by 40% or increasing it by 20% did not significantly affect the heat-induced pH-dependent dissociation of micellar κ-casein. However, changes in soluble Ca and phosphate affected the dissociation of κ-casein markedly; decreasing the phosphate concentration or increasing the Ca concentration reduced the formation of non-sedimentable N (NSN) and non-sedimentable 12% TCA-insoluble N-acetyl-neuraminic acid (NANA). Dialysis of milk against water for short periods (∼ 5 h) reduced the formation of both NSN and non-sedimentable 12% TCA-insoluble NANA, as did NaCl at concentrations above 0·05 M. Modification of protein amino groups by succinylation promoted the release of κ-casein while amidation of carboxyl groups had the opposite effect. It appears that the pH-dependent dissociation of κ-casein produced on heating milk above 90°C is controlled by electrostatic interactions. The effects of soluble ions such as Ca2+ or Na+ appear to be due to shielding of such negatively-charged groups as seryl phosphate and carboxyl on the protein, thus reducing the release of κ-casein.

Type
Original Articles
Information
Journal of Dairy Research , Volume 54 , Issue 4 , November 1987 , pp. 523 - 534
Copyright
Copyright © Proprietors of Journal of Dairy Research 1987

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References

REFERENCES

Aoki, T. & Kako, Y. 1983 Relation between micelle size and formation of soluble casein on heating concentrated milk. Journal of Dairy Research 50 207213CrossRefGoogle Scholar
Aoki, T., Suzuki, H. & Imamura, T. 1975 Some properties of soluble casein in heated concentrated whey protein-free milk. Milchwissenschaft 30 3035Google Scholar
Buchheim, W. & Welsch, U. 1973 Evidence for the submicellar composition of casein micelles on the basis of electron microscopical studies. Netherlands Milk and Dairy Journal 27 163180Google Scholar
Creamer, L. K., Berry, G. P. & Matheson, A. R. 1978 The effect of pH on protein aggregation in heated skim milk. New Zealand Journal of Dairy Science & Technology 13 915Google Scholar
Davies, D. T. & White, J. C. D. 1966 The stability of milk protein to heat. 1. Subjective measurement of heat stability of milk. Journal of Dairy Research 33 6781CrossRefGoogle Scholar
Fox, P. F. 1981 Heat-induced changes in milk preceding coagulation. Journal of Dairy Science 64 21272187CrossRefGoogle Scholar
Fox, P. F. 1982 Heat-induced coagulation of milk. In Developments in Dairy Chemistry – I. Proteins pp. 189228 (Ed. Fox, P. F.) London: Applied Science PublishersGoogle Scholar
Fox, P. F. & Hearn, C. M. 1978 Heat stability of milk: influence of dilution and dialysis against water. Journal of Dairy Research 45 149157CrossRefGoogle Scholar
Fox, P. F. & Hoynes, M. C. T. 1975 Heat stability of milk: influence of colloidal calcium phosphate and β-lactoglobulin. Journal of Dairy Research 42 427435CrossRefGoogle Scholar
Fox, P. F. & Morrissey, P. A. 1977 Reviews of the progress of Dairy Science: the heat stability of milk. Journal of Dairy Research 44 627646CrossRefGoogle Scholar
Fox, P. F. & Nash, B. M. 1979 Physico-chemical characteristics of casein micelles in dilute aqueous media. Journal of Dairy Research 46 357363CrossRefGoogle Scholar
W., Horwitz (Ed.) 1970 Official Methods of Analysis of the Association of Official Analytical Chemists 11th edn, p. 858, Washington DC: AOACGoogle Scholar
Jenness, R. & Koops, J. 1962 Preparation and properties of a salt solution which simulates milk ultrafiltrate. Netherlands Milk and Dairy Journal 16 153164Google Scholar
Kiddy, C. A. 1975 Gel electrophoresis in vertical starch beds. In Methods of gel electrophoresis of milk proteins pp. 1415 (Ed. Swaisgood, H. E.) Champaign, IL: American Dairy Science AssociationGoogle Scholar
Lin, S. H. C., Leong, S. L., Dewan, R. K., Bloomfield, V. A. & Morr, C. V. 1972 Effect of calcium ion on the structure of native bovine casein micelles. Biochemistry 11 18181821CrossRefGoogle ScholarPubMed
Morr, C. V. 1967 Effect of oxalate and urea upon ultracentrifugation properties of raw and heated skimmilk casein micelles. Journal of Dairy Science 50 17441751CrossRefGoogle Scholar
Morrissey, P. A. 1969 The heat stability of milk as affected by variations in pH and milk salts. Journal of Dairy Research 36 343351CrossRefGoogle Scholar
Pyne, G. T. & McGann, T. C. A. 1960 The colloidal phosphate of milk. II. Influence of citrate. Journal of Dairy Research 27 917CrossRefGoogle Scholar
Rose, D. 1963 Heat stability of bovine milk: a review. Dairy Science Abstracts 25 4552Google Scholar
Schmidt, D. G. & Buchheim, W. 1970 [An electron microscopic investigation of the substructure of casein micelles in cow's milk.] Milchwissenschaft 25 596600Google Scholar
Shalabi, S. I. & Fox, P. F. 1982 Heat stability of milk: influence of cationic detergents on pH sensitivity. Journal of Dairy Research 49 597605CrossRefGoogle ScholarPubMed
Singh, H. & Fox, P. F. 1985 a Heat stability of milk: the mechanism of stabilization by formaldehyde. Journal of Dairy Research 52 6576CrossRefGoogle Scholar
Singh, H. & Fox, P. F. 1985 b Heat stability of milk: pH-dependent dissociation of micellar κ-casein on heating milk at ultra high temperatures. Journal of Dairy Research 52 529538CrossRefGoogle Scholar
Singh, H. & Fox, P. F. 1986 Heat stability of milk: further studies on the pH-dependent dissociation of micellar κ-casein. Journal of Dairy Research 53 237248CrossRefGoogle Scholar
Singh, H. & Fox, P. F. 1987 a Heat stability of milk: influence of modifying sulphydryl-disulphide interactions on the HCT-pH profile. Journal of Dairy Research 54, 347359CrossRefGoogle Scholar
Singh, H. & Fox, P. F. 1987 b Heat stability of milk: role of β-lactoglobulin in the pH-dependent dissociation of micellar κ-casein. Journal of Dairy Research 54, 509521CrossRefGoogle Scholar
Tessier, H. & Rose, D. 1964 Influence of κ-casein and β-lactoglobulin on the heat stability of skimmilk. Journal of Dairy Science 47 10471051CrossRefGoogle Scholar
Thompson, M. P. & Farrell, H. M. 1973 The casein micelle – the forces contributing to its integrity. Netherlands Milk and Dairy Journal 27 220239Google Scholar
Warren, L. 1959 The thiobarbituric acid assay of sialic acid. Journal of Biological Chemistry 234 19711975CrossRefGoogle Scholar
White, J. C. D. & Davies, D. T. 1958 The relation between the chemical composition of milk and the stability of the caseinate complex. IV. Coagulation by heat. Journal of Dairy Research 25 281296CrossRefGoogle Scholar