Milk forms a rich source of biologically interesting components. In particular, its protein fraction is known to encompass many kinds of biological functions. In this review we focus on antibacterial and antiviral properties of milk proteins and milk protein derivatives. The latter include chemically modified proteins and enzymatically induced peptides. If such peptides are released by enzymes present within the digestive tract (e.g. trypsin or pepsin), it is likely that they play a role in the health defense system. This is especially the case when the active fragments can survive the intestinal conditions long enough to arrive at the right place to exert their beneficial function. In the first part of this paper attention is paid to the antibacterial proteins lactoferrin, lactoperoxidase, and lysozyme. Furthermore, antibacterial peptides originating from caseins and whey proteins are described. The second part reports on studies of antiviral effects of milk proteins and derivatives thereof. Special focus is directed to the antiviral action towards the human immunodeficiency virus (HIV) and the human cytomegalovirus (HCMV). Unmodified milk proteins are generally not active against these viruses. An exception is lactoferrin, which shows significant antiviral activity against both HIV and HCMV. Several other milk proteins tested showed strong antiviral effects only after chemical modification, i.e. by making them polyanionic (for anti-HIV activity) or polycationic (for anti-HCMV activity). In a number of cases, conclusions are drawn concerning possible relationships between antibacterial/antiviral activity and molecular structure of the components described.
Bovine kappa-casein was fractionated at pH 8.0 on DEAE-Sepharose with an NaCl gradient, followed by DEAE-cellulose chromatography using a decreasing pH gradient from pH 6.0 to 4.5. At least ten components could be identified, each differing in N-acetylneuraminic acid (NeuAc) and/or phosphorus content. Two components appeared to be multiply-phosphorylated, but did not contain NeuAc. The possible significance of this finding in relation to the mode of phosphorylation and glycosylation in vivo is discussed. A carbohydrate-free fraction as well as two NeuAc-containing fractions were compared in their substrate behaviour towards the action of the milk-clotting enzyme chymosin at pH 6.6 and 30 degrees C. To this end the trichloroacetic acid-soluble reaction products were analysed by high-performance gel-permeation chromatography. In order of increasing carbohydrate content the kcat. values found ranged from 40 to 25 s-1 and the Km values from 9 to 3 microM; the overall substrate properties of these components as reflected by the kinetic parameter kcat./Km ranged from 5 to 8 microM-1 X S-1. Irreversible polymerization of the carbohydrate-free fraction brought about a more-than-2-fold increase in Km, the kcat. value remaining virtually constant. The kcat./Km found for the cleavage of whole kappa-casein at pH 6.6 was of the same magnitude as the kcat./Km found for the polymerized carbohydrate-free fraction (i.e. about 3 microM-1 X S-1). No indication of substrate inhibition was found for the carbohydrate-free fraction.
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