O. de Rham scite author profile

O. de Rham

5Publications

165Citation Statements Received

47Citation Statements Given

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Affiliations

Nestlé (Switzerland), Nestlé (United Kingdom), University of Lausanne

Publications

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Qualitative and quantitative determination of proteolysis in mastitic milks

Rham¹,

Andrews²

1982

Journal of Dairy Research

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SUMMARYProteolytic activity in mastitic skim-milk was often 5–10 fold higher than in normal milk, its level being related to somatic cell count but not precisely correlated with it. In milks with the highest levels of activity plasmin accounted for about one third of the total proteinase. A further third was sedimented with the micellar fraction together with the plasmin, but unlike plasmin, was not inhibited by addition of soyabean trypsin inhibitor (SBTI). The final third remained in the serum phase.Polyacrylamide gel electrophoresis (PAGE) showed that αsl- and β-caseins were degraded at about the same overall rate. The plasmin produced the usual readily identified fragments from β-casein, but incubation of mastitic milk also produced changes in patterns in the γ-casein region differing from plasmin-induced changes which were also apparent when the micellar fraction was incubated. As they were inhibited by SBTI, a second trypsin-like enzyme in addition to plasmin may also have been present. Other proteinase(s) not inhibited by SBTI was also associated with casein micelles and produced at least 3 characteristic protein fragments seen on PAGE. The serum phase proteinase(s) was likewise not inhibited by SBTI, and did not produce any well-defined electrophoretic bands, suggesting a rather non-specific breakdown of caseins. After separation of mastitic whole milk, a considerable proportion of the proteolytic activity was found in the cream phase. The proportion was enhanced by freezing and thawing, and the enzyme appeared to be identical to the SBTI-resistant micellar proteinase.Because of the considerable proteolysis likely to occur under the time and temperature conditions involved, our results may provide some explanation for the problems encountered in cheesemaking with mastitic milks (e.g. yield losses, poor curd strength and off-flavour development).

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Phytate‐protein Interactions in Soybean Extracts and Low‐phytate Soy Protein Products

Rham

Jost

1979

Journal of Food Science

124

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Table 1 -Analysis of the defatted soy flourThe solubility of phytate and protein in soy extracts as influenced by pH, NaCl, calcium and EDTA was measured. The behavior of phytate is explained in terms of its binding to calcium-magnesium and/or to proteins. Three processes for preparing low-phytate soy protein products were derived from this theory, at both the laboratory and pilot plant scale. The nutritional properties of isolates prepared with these processes were examined. moisture protein (N X 6.25) fat phytate Ca Mg Ne K P ash NSI pH (5% suspension) 7.6 % 50.0 % 0.9 % 1.5 % 0.24% 0.32 % 0.01 % 0.05 % 0.7 % 4.2 % higher than 90 6.7

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

Rham¹,

Andrews²

1982

Journal of Dairy Research

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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 HIM 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 -6/*g/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. /?-Casein was the preferred substrate for the milk proteinase (plasmin) and produced y-caseins and proteose-peptone components 5 and 8-fast; other fragments were clearly visible on polyacrylamide gel electrophoresis, and included degradation products of a sl -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.

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Role of Ionic Environment in Insolubilization of Whey Protein During Heat Treatment of Whey Products

Rham

Chanton

1984

Journal of Dairy Science

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Proteolysis of Bovine Immunoglobulins

Rham

Isliker

1977

Int Arch Allergy Immunol

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Bovine serum IgG1, colostral IgG1 and serum IgG2 with anti-ferritin activity were digested with pepsin or trypsin. Their fragments were characterized by immunoelectrophoresis, gel electrophoresis and gel filtration; their ferritin-binding ability was determined. The kinetics of proteolysis were established by measuring the appearance of free amino groups. No differences were observed between serum and colostrum IgG1. IgG1 was more susceptible to pepsin, and IgG2 to trypsin. This became evident from both the amount of intact IgG determined by gel electrophoresis, immunoelectrophoresis or gel filtration, and from the kinetics of the appearance of amino groups. A model is presented to explain the size, mobilities and properties of the obtained fragments.

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O. de Rham

Qualitative and quantitative determination of proteolysis in mastitic milks

Phytate‐protein Interactions in Soybean Extracts and Low‐phytate Soy Protein Products

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

Role of Ionic Environment in Insolubilization of Whey Protein During Heat Treatment of Whey Products

Proteolysis of Bovine Immunoglobulins

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