Hostname: page-component-cd9895bd7-gvvz8 Total loading time: 0 Render date: 2024-12-28T04:10:02.387Z Has data issue: false hasContentIssue false
  • English
  • Français

Effects of milk protein genetic variants and composition on heat stability of milk

Published online by Cambridge University Press:  01 June 2009

Douglas M. McLean ,
E. R. Bruce Graham ,
Raul W. Ponzoni  and
Hugh A. Mckenzie
Douglas M. McLean
Affiliation:
Northfield Research Centre, Adelaide, South Australia 5000, Australia Division of Animal Services, Department of Agriculture, Adelaide, South Australia 5000, Australia
E. R. Bruce Graham
Affiliation:
Northfield Research Centre, Adelaide, South Australia 5000, Australia Division of Animal Services, Department of Agriculture, Adelaide, South Australia 5000, Australia
Raul W. Ponzoni
Affiliation:
Division of Animal Services, Department of Agriculture, Adelaide, South Australia 5000, Australia
Hugh A. Mckenzie
Affiliation:
Protein Chemistry Group, John Curtin School of Medical Research, Australian National University, Canberra, ACT 2601, Australia
Get access Rights & Permissions [Opens in a new window]

Summary

Skim milk samples from 126 Friesian and 147 Jersey cows in eight commercial herds were preheated at 85 °C for 30 min and concentrated to 200 g l−1 total solids. A heat coagulation time–pH curve was determined at 120 °C for each treated sample. Heat coagulation times ranged from 1 to 50 min at the non-adjusted pH and 1 to 60 min at the pH of maximum stability. The following statistically significant effects were found. Maximum heat stability was affected by genetic variants of κ-casein (B > AB > A; P < 0·001) and β-lactoglobulin (B, AB>A; P < 0·05) whereas natural heat stability was affected only by κ-casein genetic variants (B > AB > A; P < 0·001). Maximum and natural heat stability were corre-lated positively with β-casein and κ-casein concentrations and were negatively correlated with αs1-casein and β-lactoglobulin concentrations. Milk from Jersey cows had greater maximum and natural heat stability than milk from Friesian cows. Differences were found between herds within breed for natural heat stability, but not for maximum heat stability. Maximum heat stability declined with age of the cow. The heat stability of skim milk samples taken from 40 Jersey cows in one of the herds was determined at 140 °C. A considerable variation was found in the coagulation time–pH curves. There was a difference in natural heat stability between κ-casein variants (B > AB; P < 0°05). Natural and maximum heat stability were correlated positively with urea concentration. No relationship was found between the heat stability of preheated concentrated skim milk and the heat stability of the original skim milk. The pH of skim milk samples was associated with αs1-casein genetic variant, age of cow, stage of lactation and concentration of γ-casein.

Type
Original Articles
Information
Journal of Dairy Research , Volume 54 , Issue 2 , May 1987 , pp. 219 - 235
Copyright
Copyright © Proprietors of Journal of Dairy Research 1987

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

Bartsch, B. D., Graham, E. R. B. & McLean, D. M. 1979 Protein and fat composition and some manufacturing properties of milk from dairy cows fed on hay and concentrate in various ratios. Australian Journal of Agricultural Research 30 191199CrossRefGoogle Scholar
Benton, A. G. & Albery, H. G. 1926 Studies on the stability of evaporated milk during sterilization, with reference to the hydrogen ion concentration, alcohol test and the addition of specific buffers. Journal of Biological Chemistry 68 251263CrossRefGoogle Scholar
Brady, L. P. 1974 Heat treatment of milk for specialized powder production. Part A, Powder for recombination. In Winter School on Spray Drying pp. 5253Highett, Victoria: Australian Society of Dairy TechnologyGoogle Scholar
De Koning, P. J., Koops, J. & Van Rooijen, P. J. 1974 Some features of the heat stability of concentrated milk. III. Seasonal effects on the amounts of casein, individual whey proteins and NPN and their relation to variations in heat stability. Netherlands Milk and Dairy Journal 28 186202Google Scholar
Feagan, J. T., Bailey, L. F., Hehir, A. F., McLean, D. M. & Ellis, N. J. S. 1972 Coagulation of milk proteins. I. Effect of genetic variants of milk proteins on rennet coagulation and heat stability of normal milk. Australian Journal of Dairy Technology 27 129134Google Scholar
Feagan, J. T., Griffin, A. T. & Lloyd, G. T. 1966 Effects of subclinical mastitis on heat stability of skimmilk and skimmilk powder. Journal of Dairy Science 49 940944CrossRefGoogle ScholarPubMed
Fox, P. F. 1982 Heat-induced coagulation of milk. In Developments in Dairy Chemistry -1. Proteins pp. 189228 (Ed. Fox, P. F.). London: Applied Science PublishersGoogle Scholar
Goodnight, J. H. 1979 SAS Users′ Guide. Cary, NC: SAS Institute Inc.Google Scholar
Graham, E. R. B. & McLean, D. M. 1982 The heat stability of concentrated milks having different micelle size distributions. 21st International Dairy Congress, Moscow 1(2) 46Google Scholar
Holm, G. E., Webr, B. H. & Deysher, E. F. 1932 The heat coagulation of milk. I. Variations in the compositions, heat stability, and other tests of milks from four cows during the course of a lactation period. Journal of Dairy Science 15 331343CrossRefGoogle Scholar
Holt, C., Muir, D. D. & Sweetsur, A. W. M. 1978 Seasonal changes in the heat stability of milk from creamery silos in south-west Scotland. Journal of Dairy Research 45 183190CrossRefGoogle Scholar
Jenness, R. & Parkash, S. 1967 Heat stability of milks containing different casein polymorphs. Journal of Dairy Science 50 952Google Scholar
Kelly, P. M. 1982 The effect of preheat temperature and urea addition on the seasonal variation in the heat stability of skim-milk powder. Journal of Dairy Research 49 187196CrossRefGoogle Scholar
Kelly, P. M., O'Keeffe, A. M., Keogh, M. K. & Phelan, J. A. 1982 Studies of milk composition and ts relationship to some processing criteria. III. Seasonal variation in heat stability of milk. Irish Journal of Food Science and Technology 6 2938Google Scholar
Kieseker, F. G. & Pearce, R. J. 1978 Heat stability of recombined milks as influenced by preheating and pH adjustment. 20th International Dairy Congress, Paris 1E 975Google Scholar
Kirchmeier, O., Mehana, A., Graml, R., Buchberger, J. & Pirchner, F. 1983 [Studies on physicochemical properties of casein. Superposition of genetic and seasonal effects]. Milchwissenschaft 38 589591Google Scholar
Lin, R. H. 1977 Influence of mastitis on the heat stability of bovine milk. Thesis, Texas A. & M. University, USA. Dissertation Abstracts International B 38 1637Google Scholar
McLean, D. M., Graham, E. R. B., Ponzoni, R. W. & Mckenzie, H. A. 1982 Heat stability of preheated concentrated skim milk from individual cows: association with milk protein genotype and composition. Australian Dairy Technology Review Conference, Glenormiston, pp. 190191Canberra, ACT: CSIROGoogle Scholar
McLean, D. M., Graham, E. R. B., Ponzoni, R. W. & Mckenzie, H. A. 1984 Effects of milk protein genetic variants on milk yield and composition. Journal of Dairy Research 51 531546CrossRefGoogle ScholarPubMed
Mariani, P., Losi, G., Russo, V., Castagnetti, G. B., Grazia, L., Morini, D. & Fossa, E. 1976 [Caseification tests made with milk characterized by variants A and B of κ-casein in the production of Parmigiano-Reggiano cheese]. Scienza e Tecnica Lattiero-Casearia 27 208227Google Scholar
Morini, D., Losi, G., Castagnetti, G. B., Benevelli, M., Resmini, P. & Volonterio, G. 1975 [The influence of genetic variants of κ-casein on the size of casein micelles]. Scienza e Tecnica Lattiero-Casearia 26 437444Google Scholar
Morrissey, P. A., Murphy, M. F., Hearn, C. M. & Fox, P. F. 1981 Composition and stability of mid-lactation milks. Irish Journal of Food Science and Technology 5 117127Google Scholar
Muir, D. D. & Sweetsur, A. W. M. 1976 The influence of naturally occurring levels of urea on the heat stability of bulk milk. Journal of Dairy Research 43 495499CrossRefGoogle Scholar
Muir, D. D. & Sweetsur, A. W. M. 1978 The effect of concentration on the heat stability of skim-milk. Journal of Dairy Research 45 3745CrossRefGoogle Scholar
Newstead, D. F. 1977 Heat stability of evaporated milk. New Zealand Journal of Dairy Science and Technology 12 8993Google Scholar
Newstead, D. F., Sanderson, W. B. & Baucke, A. G. 1975 The effect of heat treatment and pH on the heat stability of recombined evaporated milk. New Zealand Journal of Dairy Science and Technology 10 113118Google Scholar
Newstead, D. F., Sanderson, W. B. & Conaghan, E. F. 1977 Effects of whey protein concentrations and heat treatment on the heat stability of concentrated and unconcentrated milk. New Zealand Journal of Dairy Science and Technology 12 2936Google Scholar
Newstead, D. F., Sanderson, W. B. & Woodhams, D. J. 1974 Effects of composition on the heat stability of forewarmed concentrated skim milk. 19th International Dairy Congress, New Delhi 1E 182Google Scholar
Pearce, R. J. 1978 The effect of β-lactoglobulin on the heat stabilities of concentrated and non-concentrated milks. 20th International Dairy Congress, Paris E 251252Google Scholar
Pearce, R. J. 1979 Heat stability in concentrated and non-concentrated milks–the effect of urea and β-lactoglobulin levels and the influence of preheating. Journal of Dairy Research 46 385386CrossRefGoogle ScholarPubMed
Robertson, N. H. & Dixon, A. 1969 The nitrogen fractions and the heat stability of bovine milk. Agroanimalia 1 141144Google Scholar
Rogers, L. A., Deysher, E. F. & Evans, F. R. 1921 The relation of acidity to the coagulation temperature of evaporated milk. Journal of Dairy Science 4 294309CrossRefGoogle Scholar
Rose, D. 1961 a Variations in the heat stability and composition of milk from individual cows during lactation. Journal of Dairy Science 44 430441CrossRefGoogle Scholar
Rose, D. 1961 b Factors affecting the pH-sensitivity of the heat stability of milk from individual cows. Journal of Dairy Science. 44 14051413CrossRefGoogle Scholar
Rose, D. 1961 c β-Lactoglobulin and pH-sensitivity of the heat stability of evaporated milk. Journal of Dairy Science 44 1763CrossRefGoogle Scholar
Rose, D. 1962 Factors affecting the heat stability of milk. Journal of Dairy Science 45 13051311CrossRefGoogle Scholar
Schmidt, D. G. & Koops, J. 1965 Some features of the heat stability of concentrated milk. 1. Effect of genetic variants of κ-casein. Netherlands Milk and Dairy Journal 19 6368Google Scholar
Schmidt, D. G. & Koops, J. 1977 Properties of artificial casein micelles. 2. Stability towards ethanol, dialysis, pressure and heat in relation to casein composition. Netherlands Milk and Dairy Journal 31 342357Google Scholar
Sommer, H. H. & Hart, E. B. 1926 Heat coagulation of evaporated milk. Wisconsin University Agricultural Experiment Station Research Bulletin no. 67Google Scholar
Sweetsur, A. W. M. & Muir, D. D. 1982 Natural variation in heat stability of concentrated milk before and after homogenization. Journal of the Society of Dairy Technology 35 120126CrossRefGoogle Scholar
Sweetsur, A. W. M. & Muir, D. D. 1983 Influence of sulphydryl group interactions on the heat stability of homogenized concentrated milk. Journal of Dairy Research 50 301308CrossRefGoogle 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, D. I. & Postle, D. S. 1964 The Wisconsin mastitis test–an indirect estimation of leucocytes in milk. Journal of Milk and Food Technology 27 271275CrossRefGoogle Scholar
Webb, B. H. 1928 Heat coagulation of evaporated milk as affected by mixing different grades of raw milk. Journal of Dairy Science 11 471478CrossRefGoogle Scholar
Webb, B. H. & Holm, G. E. 1932 The heat coagulation of milk. II. The influence of various added salts upon the heat stabilities of milks of different concentrations. Journal of Dairy Science 15 345366CrossRefGoogle 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