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Proteolysis and aggregation of casein micelles treated with immobilized or soluble chymosin

Published online by Cambridge University Press:  01 June 2009

Douglas G. Dalgleish
Affiliation:
Hannah Research Institute, AyrScotland, KA6 5HL

Summary

The relationship between extent of κ-casein proteolysis and aggregatability of milk casein micelles has been studied using chymosin either bound to porous glass supports or free in solution. Both enzyme preparations demonstrated that, overall, 86–90 % of the κ-casein had to be destroyed before any aggregation could occur. Based on these results, a mathematical model of chymosin action on casein is described involving (i) the attack on κ-casein by chymosin, via a Michaelis–Menten mechanism (ii) the probability that sufficient κ-casein on any micelle is destroyed to allow aggregation, and (iii) the aggregation of para-casein micelles by a von Smoluchowski mechanism.

Type
Original Articles
Copyright
Copyright © Proprietors of Journal of Dairy Research 1979

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References

REFERENCES

Ashoor, S. H., Sair, R. A., Olson, N. F. & Richardson, T. (1971). Biochimica et Biophysica Acta 229, 423.CrossRefGoogle Scholar
Berridge, N. J. (1942). Nature, London 149, 194CrossRefGoogle Scholar
Brown, R. J. & Swaisgood, H. W. (1975). Journal of Dairy Science 58, 796.Google Scholar
Castle, A. V. & Wheelock, J. V. (1972). Journal of Dairy Research 39, 15.CrossRefGoogle Scholar
Cho, I. C. & Swaisgood, H. W. (1974). Biochimica d Biophysiea Acta 334, 243.Google Scholar
Dixon, M. & Webb, E. C. (1964). Enzymes, 2nd Edn. p. 114. London: Longmans.Google Scholar
Ekstrand, B. & Larsson-Raźnikiewicz, M. (1978). Biochimica et Biophysiea Acta 536, 1.CrossRefGoogle Scholar
Green, M. L. & Crutchfield, G. (1969). Biochemical Journal 115, 183.CrossRefGoogle Scholar
Green, M. L., Hobbs, D. G., Morant, S. V. & Hill, V. A. (1978). Journal of Dairy Research 45, 413.CrossRefGoogle Scholar
Green, M. L. & Marshall, R. J. (1977). Journal of Dairy Research 44, 521.Google Scholar
Holt, C., Dalgleish, D. G. & Parker, T. G. (1973). Biochimica d Biophysiea Acta 328, 428.CrossRefGoogle Scholar
Hyslop, D. B., Richardson, T. & Ryan, D. S. (1979). Biochimica et Biophysiea Acta 566, 390.CrossRefGoogle Scholar
Lin, S. H. C., Dewan, R. K., Bloomfield, V. A. & Morr, C. V. (1971). Biochemistry 10, 4788.CrossRefGoogle Scholar
Payens, T. A. J. (1977). Biophysical Chemistry 6, 263.Google Scholar
Payens, T. A. J., Wiersma, A. K. & Brinkhuis, J. (1977). Biophysical Chemistry 6, 253.CrossRefGoogle Scholar
Robinson, P. J., Dunnill, P. & Lilly, M. D. (1971). Biochimica et Biophysica Ada 242, 659.CrossRefGoogle Scholar
Von Smoluchowski, M. (1971). Zeitschrift für Physikalische Chemie 92, 129.Google Scholar
West, D. W. & Towers, G. E. (1976). Analytical Biochemistry 74, 53.Google Scholar