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The roles of native milk proteinase and its zymogen during proteolysis in normal bovine milk

Published online by Cambridge University Press:  01 June 2009

Olivier de Rham  and
Anthony T. Andrews
Olivier de Rham
Affiliation:
National Institute for Research in Dairying, Shinfield, Reading RG2 9 AT, UK
Anthony T. Andrews
Affiliation:
National Institute for Research in Dairying, Shinfield, Reading RG2 9 AT, UK
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Summary

Proteolysis was measured quantitatively in normal bulk milk, either raw, pasteurized or heated (95 °C, 15 min). During incubation at 37 °C for 24 h, about 0·7 mM of peptide bonds were split in raw milk, and 1·8 mM after activation of the zymogen with urokinase. The same values were observed in pasteurized milk, and no significant activity was present in heated milk. When compared with a commercial plasmin preparation, these levels correspond to about 1·4 and 3·6μg/ml of plasmin respectively. Most of this activity was separated in the micellar fraction, and it was suppressed by addition of soyabean trypsin inhibitor (SBTI). The remaining activity in the serum phase was not inhibited by SBTI and gave a rather non-specific breakdown with few well-defined casein fragments being produced. Upon further incubation, after the first 24 h, the activity increased, indicating that activation of the zymogen (plasminogen) occurred spontaneously. The rate of this activation was independent of the addition of more plasminogen and was higher in pasteurized than in raw milk. In pasteurized milk, all the native milk proteinase was in the form of the zymogen at the time of secretion. β-Casein was the preferred substrate for the milk proteinase (plasmin) and produced γ-caseins and proteose-peptone components 5 and 8-fast; other fragments were clearly visible on polyacrylamide gel electrophoresis, and included degradation products of αs1-casein. The formation of all these fragments was enhanced by addition of urokinase alone, or of plasminogen and urokinase, or by increasing the incubation time. They were also produced by incubating the micellar fraction alone, but not the serum fraction. Additional fragments were produced when porcine plasmin was added presumably due to differences in specificity between the porcine and bovine enzymes or to contaminating enzymes. Proteolysis induced by additions of plasminogen alone, or of plasminogen plus urokinase, was closer to that observed for the native milk proteinase, and must be recommended for future work in which it is desired to enhance the level of proteinase without altering breakdown patterns, unless a very pure bovine plasmin is available.

Type
Original Articles
Information
Journal of Dairy Research , Volume 49 , Issue 4 , November 1982 , pp. 577 - 585
Copyright
Copyright © Proprietors of Journal of Dairy Research 1982

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References

REFERENCES

Andrews, A. T. 1978 The composition, structure and origin of proteose-peptone component 5 of bovine milk. European Journal of Biochemistry 90 5065Google ScholarPubMed
Andrews, A. T. 1983 Proteinases in normal bovine milk and their action on caseins. Journal of Dairy Research 50 in pressGoogle Scholar
Astrup, T. & Sterndorff, I. 1953 A fibrinolytic system in human milk. Proceedings of the Society for Experimental Biology and Medicine 84 605608Google Scholar
Barry, J. G. & Donnelly, W. J. 1981 Casein compositional studies. II. The effect of secretory disturbance on casein composition in freshly drawn and aged bovine milks. Journal of Dairy Research 48 437446Google Scholar
Chen, J. H. & Ledford, R. A. 1971 Purification and characterization of milk protease. Journal of Dairy Science 54 763Google Scholar
Driessen, F. M. & Van Der Waals, C. B. 1978 Inactivation of native milk proteinase by heat treatment. Netherlands Milk and Dairy Journal 32 245254Google Scholar
Eioel, W. N. 1977 Effect of bovine plasmin on αs1-B and κ-A caseins. Journal of Dairy Science 60 13991403Google Scholar
Eioel, W. N., Hofmann, C. J., Chibber, B. A. K., Tomich, J. M., Keenan, T. W. & Mertz, E. T. 1979 Plasmin-mediated proteolysis of casein in bovine milk. Proceedings, National Academy of Sciences of the United States of America 76 22442248Google Scholar
Ged, J. & Alais, C. 1976 [Protease activity persisting in sterilized milk.] Lait 56 645656CrossRefGoogle Scholar
Habeeb, A. F. S. A. 1966 Determination of free amino groups in proteins by trinitrobenzenesulfonic acid. Analytical Biochemistry 14 328336CrossRefGoogle ScholarPubMed
Hofmann, C. J., Keenan, T. W. & Eigel, W. N. 1978 Protease associated with milk fat globule membrane. Journal of Dairy Science 61 (Suppl. 1) 151Google Scholar
Humbert, G. & Alais, C. W. 1979 Review of the progress of dairy science: The milk proteinase system. Journal of Dairy Research 46 559571Google Scholar
Kaminooawa, S., Mizobuchi, H. & Yamauchi, K. 1972 Comparison of bovine milk protease with plasmin. Agricultural and Biological Chemistry 36 21632167CrossRefGoogle Scholar
Kaminooawa, S. & Yamauchi, K. 1972 Acid protease of bovine milk. Agricultural and Biological Chemistry 36 23512356Google Scholar
Kiddy, C. A., Rollins, R. E. & Zikakis, J. P. 1972 Discontinuous polyacrylamide gel èlectrophoresis for β-lactoglobulin typing of cow's milk. Journal of Dairy Science 55 15061507CrossRefGoogle ScholarPubMed
Kiermeier, F. & Semper, G. 1960 [Incidence of a proteolytic enzyme and a trypsin-inhibitor in cow's milk. I. Proteolytic activity.] Zeitschrift für Lebensmittel-Untersuchung und -Forschung 111 282307Google Scholar
Noomen, A. 1975 Proteolytic activity of milk protease in raw and pasteurized cow's milk. Netherlands Milk and Dairy Journal 29 153161Google Scholar
Reimerdes, E. H., Halpaap, I. & Klostermeyer, H. 1981 a [Milk proteinases. 8. Comparative characterization of plasmin from cow's blood with a serine proteinase from cow's milk.] Milchwissenschaft 36, 1922Google Scholar
Reimerdes, E. H., Halpaap, I. & Klostermeyer, H. 1981 b [Milk proteinases. 10. Enzyme-kinetic comparison of bovine plasmin with two milk proteinases.] Milchwissenschaft 36 7379Google Scholar
Reimerdes, E. H. & Klostermeyer, H. 1974 [Milk proteinases. I. Micelle-associated protease—purification and hydrolysis of caseins.] Milchwissenschaft 29 517523Google Scholar
Reimerdes, E. H., Petersen, F. & Kielwein, G. 1979 [Milk proteinases. 9. Proteolytic activity profiles of casein micelles, milk serum, blood serum and Pseudomonas fluorescens.] Milchwissenschaft 34 548551Google Scholar
Skudder, P. J. 1981 Effects of adding potassium iodate to milk before UHT treatment II. Iodate-induced proteolysis during subsequent aseptic storage. Journal of Dairy Research 48 115122CrossRefGoogle ScholarPubMed
Snoeren, T. H. M. & Van Riel, J. A. M. 1979 Milk proteinase, its isolation and action on αs2- and β-casein. Milchwissenschaft 34 528531Google Scholar
Snoeren, T. H. M., Van Der Speck, C. A., Dekker, R. & Both, P. 1979 Proteolysis during the storage of UHT-sterilized whole milk. 1. Experiments with milk heated by the direct system for 4 seconds at 142 °C. Netherlands Milk and Dairy Journal 33 3139Google Scholar