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Surface active properties at the air–water interface of β-casein and its fragments derived by plasmin proteolysis

Published online by Cambridge University Press:  01 June 2009

Michael Wilson ,
Daniel M. Mulvihill ,
William J. Donnelly  and
Brian P. Gill
Michael Wilson
Affiliation:
Department of Food Chemistry, University College, Cork, Ireland
Daniel M. Mulvihill
Affiliation:
Department of Food Chemistry, University College, Cork, Ireland
William J. Donnelly
Affiliation:
The Agricultural Institute, Moorepark, Fermoy, Co. Cork, Ireland
Brian P. Gill
Affiliation:
Department of Food Chemistry, University College, Cork, Ireland
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Summary

β-Casein, was enzymically modified by incubation with plasmin to yield γ-caseins and proteose peptones. Whole γ-, γ1-, γ23-caseins and whole proteose peptone (pp) were isolated from the hydrolysate mixture. The time dependence of surface tension at the air-water interface of solutions of β-casein and its plasmin derived fragments, at concentrations of 10−1 to 10−4% (w/v) protein, pH 7.0, was determined, at 25 °C, using a drop volume apparatus. The ranking of the proteins with respect to rate of reduction of surface tension, during the first rate determining step, at 10-2% (w/v) protein, was γ23 ≫ pp > whole γ- > γ1- > β-casein. The ranking of the proteins with respect to surface pressures attained after 40 min (π40) was concentration dependent. γ23-Caseins were found to be very surface active, decreasing surface tension rapidly and giving a high π40. γ1 Casein decreased surface activity somewhat faster than β-casein, but generally reached a lower π40. Whole γ-casein reflected the properties of both γ1 and γ23-caseins. Proteose peptone was found to decrease surface tension rapidly during the initial rate determining step; it gave a relatively high π40 at a bulk phase concentration of 10−3% (w/v) protein, but, it was the least surface active protein at 10−1 and 10−2% (w/v) protein.

Type
Original Articles
Information
Journal of Dairy Research , Volume 56 , Issue 3: Special Issue: Proceedings of the Hannah Research Institute Casein Conference , May 1989 , pp. 487 - 494
Copyright
Copyright © Proprietors of Journal of Dairy Research 1989

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References

REFERENCES

Arnebrant, T. & Nylander, T. 1985 Surface tension measurements by an automated drop volume apparatus. Journal of Dispersion Science and Technology 6 209212CrossRefGoogle Scholar
Benjamins, J., De Feijter, J. A., Evans, M. T. A., Graham, D. E. & Phillips, M. C. 1975 Dynamic and static properties of proteins adsorbed at the air-water interface. Faraday Discussions of the Chemical Society 59 218229CrossRefGoogle ScholarPubMed
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
Dickinson, E., Pogson, D. J., Robson, E. W. & Stainsby, O. 1985 Time-dependent surface pressure of adsorbed films of Caseinate and gelatin at the oil–water interface. Colloids and Surfaces 14 135141CrossRefGoogle Scholar
Eigel, W. N., Butler, J. E., Ernstrom, C. A., Farrell, H. M. Jr, Harwalkar, V. R., Jenness, R. & Whitney, R. McL. 1984 Nomenclature of the proteins of cows milk. Fifth revision. Journal of Dairy Science 67 15991631CrossRefGoogle Scholar
Groves, M. L. & Gordon, W. G. 1969 Evidence from amino acid analysis for a relationship in the biosynthesis of γ and β-caseins. Biochimica et Biophysica Acta 194 421432CrossRefGoogle ScholarPubMed
Grufferty, M. B. & Fox, P. F. 1988 Milk alkaline proteinase: a Review. Journal of Dairy Research 55 609630CrossRefGoogle Scholar
Jackson, R. H. & Pallansch, M. J. 1961 Influence of milk proteins on interfacial tension between butter oil and various aqueous phases. Journal of Agriculture and Food Chemistry 9 424427CrossRefGoogle Scholar
Mitchell, J., Irons, L. & Palmer, G. J. 1970 A study of the spread and adsorbed films of milk proteins. Biochimica et Biophysica Acta 200 138150CrossRefGoogle ScholarPubMed
Swaisgood, H. E. 1982 In Developments in Dairy Chemistry-I-Proteins, pp. 159, (Ed. Fox, P. F..) London: Applied Science Publishers LtdGoogle Scholar
Tornberg, E. 1977 A surface tension apparatus according to the drop volume principle. Journal of Colloid and Interface Science 60 5053CrossRefGoogle Scholar
Tornberg, E. 1978 The application of the drop volume technique to measurements of the adsorption of proteins at interfaces. Journal of Colloid and Interface Science 64 391402CrossRefGoogle Scholar
Visser, S. 1981 Proteolytio enzymes and their action on milk proteins. A Review. Netherlands Milk and Dairy Journal 35 6588Google Scholar