Hostname: page-component-68945f75b7-55759 Total loading time: 0 Render date: 2024-09-02T15:41:21.710Z Has data issue: false hasContentIssue false
  • English
  • Français

Zinc binding in bovine milk

Published online by Cambridge University Press:  01 June 2009

Harjinder Singh ,
Albert Flynn  and
Patrick F. Fox
Harjinder Singh
Affiliation:
Departments of Food Chemistry, University College, Cork, Irish Republic
Albert Flynn
Affiliation:
Nutrition, University College, Cork, Irish Republic
Patrick F. Fox
Affiliation:
Departments of Food Chemistry, University College, Cork, Irish Republic
Get access Rights & Permissions [Opens in a new window]

Summary

About 90% of the Zn in bovine skim milk was sedimented by ultracentrifugation at 100000 g for 1 h. About half of the non-sedimentable Zn was non-dialysable, indicating that it was associated with protein, probably non-sedimented casein micelles. Casein micelles incorporated considerable amounts of Zn added to skim milk as ZnCl2, and at Zn concentrations ≥ 16 mM coagulation of casein micelles occurred. Ca was displaced from casein micelles by increasing ZnCl2 concentration and ˜ 40% of micellar Ca was displaced by 16 mM-ZnCl2. Micellar Zn, Ca and P1 were gradually rendered soluble as the pH of milk was lowered and at pH 4·6 > 95% of the Zn, Ca and P1 were non-sedimentable. These changes were largely reversible by readjustment of the pH to 6·7. About 40% of the total Zn in skim milk was non-sedimentable at 0·2 mM-EDTA and most of the remainder was gradually rendered soluble by EDTA over the concentration range 1–50 mM. This indicates that there are two distinct micellar Zn fractions. No micellar Ca or P1 was solubilized at EDTA concentrations up to 1·0 mM, indicating that both colloidal calcium phosphate (CCP) and casein micelles remained intact under conditions where the more loosely bound micellar Zn fraction dissolved. Depletion of casein micelles of colloidal Ca and P1 by acidification and equilibrium dialysis resulted in removal of Zn, and in colloidal Pi-free milk non-dialysable Zn was reduced to ·-2 mg/1 (˜ 32% of the original Zn). Thus, ˜ 32% of the Zn in skim milk is directly bound to caseins, while ˜ 63% is associated with CCP. Over 80% of the Zn in colloidal Pi-free milk was rendered soluble by 0·2 mM-EDTA, indicating that the casein-bound Zn is the loosely bound Zn fraction in casein micelles. A considerable fraction of the Zn in acid whey (pH 4·6) co-precipitated with Ca and Pi on raising the pH to 6·7 and heating for 2 h at 40 °C, indicating that insoluble Zn phosphate complexes form readily under these conditions. Studies on dialysis of milk against water, or dilution of milk or casein micelles with water, showed that CCP and its associated Zn is very stable and dissolves only very slowly at pH 6·6. The nature of Zn binding in casein micelles may help to explain the lower nutritional bioavailability of Zn in bovine milk and infant formulae compared with human milk.

Type
Original Articles
Information
Journal of Dairy Research , Volume 56 , Issue 2 , May 1989 , pp. 249 - 263
Copyright
Copyright © Proprietors of Journal of Dairy Research 1989

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Anon. 1986 Zinc bioavailability of human and cow's milk. Nutrition Reviews 44 181183Google Scholar
Association Of Official Agricultural Chemists 1960 Officiai Methods of Analysis of the AOAC, 9th edn (Ed. Horwitz, W.). Washington, DC: AOACGoogle Scholar
Association Of Official Analytical Chemists 1970 Official Methods of Analysis of the AOAC, 11th edn, p. 248 (Ed. Horwitz, W.). Washington, DC: AOACGoogle Scholar
Blakeborough, P., Gurr, M. I. & Salter, D. N. 1986 Digestion of the zinc in human milk, cow's milk and a commercial babyfood: some implications for human infant nutrition. British Journal of Nutrition 55 209217CrossRefGoogle Scholar
Blakeborough, P., Salter, D. N. & Gurr, M. I. 1983 Zinc binding in cow's milk and human milk. Biochemical Journal 209 505512CrossRefGoogle ScholarPubMed
Casey, C. E., Walravens, P. A. & Hambidge, K. M. 1981 Availability of zinc: loading tests with human milk, cow's milk and infant formulas. Pediatrics 68 394396CrossRefGoogle ScholarPubMed
Dalgleish, D. G. & Parker, T. G. 1980 Binding of calcium ions to bovine αs1-casein and precipitability of the protein-calcium ion complexes. Journal of Dairy Research 47 113122CrossRefGoogle Scholar
Dickson, I. R. & Perkins, D. J. 1971 Studies on the interactions between purified bovine caseins and alkaline-earth-metal ions. Biochemical Journal 124 235240CrossRefGoogle ScholarPubMed
Evans, G. W. & Johnson, P. E. 1977 Determination of zinc availability in foods by the extrinsic label technique. American Journal of Clinical Nutrition 30 873878CrossRefGoogle ScholarPubMed
Flynn, A. & Power, P. 1985 Nutritional aspects of minerais in bovine and human milks, In Developments in Dairy Chemistry-3. Lactose and minor constituents pp. 183215 (Ed. Fox, P. F.) London: Elsevier 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. & Nash, B. M. 1979 Physico-chemical characteristics of casein micelles in dilute aqueous media. Journal of Dairy Research 46 357363CrossRefGoogle Scholar
Fransson, G.-B. & Lönnerdal, B. 1983 Distribution of trace elements and minerais in human and cow's milk. Pediatrie Research 17 912915CrossRefGoogle Scholar
Hambidge, K. M., Walravens, P. A., Casey, C. E., Brown, R. M. & Bender, C. 1979 Plasma zinc concentrations of breast-fed infants. Journal of Pediatrics 94 607608CrossRefGoogle ScholarPubMed
Hambraeus, L. 1977 Proprietary milk versus human breast milk in infant feeding. Pediatrie Clinics of North America 24 1736CrossRefGoogle ScholarPubMed
Harzer, G. & Kauer, H. 1982 Binding of zinc to casein. American Journal of Clinical Nutrition 35 981987CrossRefGoogle ScholarPubMed
Herrington, B. L. & Klevn, D. H. 1960 A potentiometric method for the determination of chloride in milk. Journal of Dairy Science 43 10501057CrossRefGoogle Scholar
Holt, C. 1982 Inorganic constituents of milk. III. The colloidal calcium phosphate of cow's milk. Journal of Dairy Research 49 2938CrossRefGoogle ScholarPubMed
Hurley, L. S. & Lönnerdal, B. 1982 Zinc binding in human milk: citrate versus picolinate. Nutrition Reviews 40 6571CrossRefGoogle ScholarPubMed
Jenness, R. 1973 Caseins and caseinate micelles of various species. Netherlands Milk and Dairy Journal 27 251257Google Scholar
Johnson, P. E. & Evans, G. W. 1978 Relative zinc availability in human breast milk, infant formulas, and cow's milk. American Journal of Clinical Nutrition 31 416421CrossRefGoogle ScholarPubMed
Kiely, J., Singh, H., Flynn, A. & Fox, P. F. 1988 Improved zinc bioavailability from colloidal calcium phosphate-free cow's milk. In Trace Elements in Man and Animais – TEMA 6. New York: Plenum Publishing Co. In press.Google Scholar
Lönnerdal, B., Cederblad, A., Davidsson, L. & Sandström, B. 1984 The effect of individual components of soy formula and cows' milk formula on zinc bioavailability. American Journal of Clinical Nutrition 40 10641070CrossRefGoogle ScholarPubMed
Lönnerdal, B., Hoffman, B. & Hurley, L. S. 1982 Zinc and copper binding proteins in human milk. American Journal of Clinical Nutrition 36 11701176CrossRefGoogle ScholarPubMed
Lönnerdal, B., Keen, C. L., Bell, J. G. & Hurley, L. S. 1985 Zinc uptake and retention from chelates and milk fractions. In Trace Elements inMan and Animais – TEMA 5 pp. 427430 (Eds Mills, C. F., Bremner, I. and Chesters, J. K.). Slough, England: Commonwealth Agricultural BureauxGoogle Scholar
Lönnerdal, B., Keen, C. L. & Hurley, L. S. 1981 Iron, copper, zinc, and manganese in milk. Annual Review of Nutrition 1 149174CrossRefGoogle ScholarPubMed
Lönnerdal, B., Stanislowski, A. G. & Hurley, L. S. 1980 Isolation of a low molecular weight zinc binding ligand from human milk. Journal of Inorganic Biochemistry 12 7178CrossRefGoogle ScholarPubMed
Martin, M. T., Jacobs, F. A. & Brushmiller, J. G. 1984 Identification of copper- and zinc-binding ligands in human and bovine milk. Journal of Nutrition 114 869879CrossRefGoogle ScholarPubMed
McGann, T. C. A., Buchheim, W., Kearney, R. D. & Richardson, T. 1983 Composition and ultrastructure of calcium phosphate-citrate complexes in bovine milk Systems. Biochimica et Biophysica Acta 760 415420CrossRefGoogle ScholarPubMed
Morr, C. V., Josephson, R. V., Jenness, R. & Manning, P. B. 1971 Composition and properties of submicellar casein complexes in colloidal phosphate-free skimmilk. Journal of Dairy Science 54 15551563CrossRefGoogle Scholar
Parkash, S. & Jenness, R. 1967 Status of zinc in cow's milk. Journal of Dairy Science 50 127134CrossRefGoogle ScholarPubMed
Pyne, G. T. 1962 Reviews of the progress of dairy science. Section C. Some aspects of the physical chemistry of the salts of milk. Journal of Dairy Research 29 101130CrossRefGoogle 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
Roth, H. P. & Kirchgessner, M. 1985 Utilization of zinc from picolinic or citric acid complexes in relation to dietary protein source in rats. Journal of Nutrition 115 16411649CrossRefGoogle ScholarPubMed
Sandström, B., Cederblad, Å. & Lönnerdal, B. 1983 a Zinc absorption from human milk, cow's milk and infant formulas. American Journal of Diseases of Children 137 726729Google ScholarPubMed
Sandström, B., Keen, C. L. & Lönnerdal, B. 1983 b An experimental model for studies of zinc bioavailability from milk and infant formulas using extrinsic labelling. American Journal of Clinical Nutrition 38 420428CrossRefGoogle Scholar
Schmidt, D. G. 1982 Association of caseins and casein micelle structure. In Developments in Dairy Chemistry 1. Proteins pp. 6186 (Ed. Fox, P. F.), London: Applied Science PublishersGoogle Scholar
Singh, H., Flynn, A. & Fox, P. F. 1989 Binding of zinc to bovine and human milk proteins. Journal of Dairy Research 56 235248CrossRefGoogle ScholarPubMed
Slattery, C. W. 1976 Casein micelle structure: an examination of models. Journal of Dairy Science 59 15471556CrossRefGoogle ScholarPubMed
Van Hooydonk, A. C. M., Hagedoorn, H. G. & Boerrigter, I. J. 1986 pH-induced physico-chemical changes of casein micelles in milk and their effect on renneting. 1. Effect of acidification on physico-Chemical properties. Netherlands Milk and Dairy Journal 40 281296Google Scholar