The role of calcium, phosphate and citrate ions in the stabilization of casein micelles

Crude glycerol as glycogenic precursor in feed; effects on milk coagulation properties and metabolic profiles of dairy cows

As grain prices rise, the search for alternative glycogenic precursors in animal feed becomes increasingly important, and this study was conducted to determine if the replacement of starch with glycerol, as an alternative glycogenic precursor, affects the milk metabolic profile and milk coagulation ability, and therefore the quality of the milk. Eight primiparous mid-lactation Holstein cows were fed during a replicated 4 × 4 Latin square trial with four different isoenergetic rations: (1) control (T0) fed a total mixed ration (TMR) with barley meal; (2) group T1, decreased barley content, replaced isoenergetically with 1 kg crude glycerol; (3) group T2, the barley meal was replaced with 2 kg of crude glycerol; and (4) group T3 the barley meal was replaced with 3 kg of crude glycerol. Rumen, blood and milk samples were collected at the end of every 21-d treatment period. Rumen samples were analysed for proportion of total volatile fatty acid (VFA), blood samples for insulin and glucose, and milk for metabolites (e.g. citric-acid cycle compounds). The change in glycogenic precursors had a positive effect on rumen VFA proportions; the proportion of propionic acid increased (P < 0·001). Milk protein (P < 0·001) and curd firmness (P < 0·001) both increased. The increase in milk protein concentration may have been due to an increase in microbial protein. Regarding the milk metabolic profiles, different signals were positively associated with coagulation ability and change in the diet. Based on this study, changing the glycogenic precursor in animal diet in this way is possible, and may have no immediate deleterious consequences on milk quality or cow health. Indeed, there is evidence for benefits from this substitution.

31P-nuclear magnetic resonance study of milk fractions

Milk serum, whey and milk ultrafiltrate were examined by31P nuclear magnetic resonance (31P-NMR). About 20 phosphorylated milk constituents gave rise to resonances in the spectra. Most of these have been assigned to such well-known milk constituents as inorganic phosphate,N-acetylglucosamine-1-phosphate and glycerophosphorylcholine. Resonances from previously unknown constituents such as phosphocreatine were also observed. When the pH-dependence of inorganic phosphate,N-acetylglucosamine-1 -phosphate, glycerophosphorylcholine and gly-cerophosphorylethanolamine was examined it was observed that the resonance of inorganic phosphate overlapped that ofN-acetylglucosamine-1-phosphate around neutral pH. This is the most probable explanation as to why this constituent was not observed in earlier31P-NMR studies on milk.

Effects of colloidal calcium phosphate content and free calcium ion concentration in the milk serum on the dissociation of bovine casein micelles

The strength of binding of the individual caseins and the nature of the bonding within bovine casein micelles were examined through dissociation of the micelles by dialysis of skim milk either against phosphate-free buffers containing 3 or 6 mm-CaCl2, or against buffers that were nearly saturated with respect to micellar calcium phosphate, but which had a free Ca2+ concentration in the range 0·4–5·9 mm. Dissociation was followed by ultracentrifuging the dialysed milks and determining the partition of the total and the individual caseins between the pellet and serum. During dialysis against the phosphate-free buffers both colloidal Ca and Pi in the milks decreased and about 30 % of the Pi could be removed without significant casein dissociation. With further loss of Pi, however, increasing dissociation occurred and the proportions of the individual caseins retained in the casein pellet were in the order αs2- > αs1- > β- ≈ κ-casein. Dialysis against the calcium phosphate buffers resulted in no loss of colloidal Pi but colloidal Ca increased with the free Ca2+ concentration of the buffer. Little change in the casein partition occurred in the presence of more than 1 mm free Ca2+, but serum casein increased markedly at lower levels, and the strength of binding of the individual caseins in the pelleted casein was in the order αs2-> αs1- > β- > κ-casein. In both types of buffer, dissociation is considered to occur through the breaking of linkages between the caseins and inorganic constituents. Analysis of the amino acids in a calcium phosphate-rich material obtained after exhaustive proteolytic digestion of casein micelles suggests that these linkages involve the phosphate centres of the caseins.

Contributions of Terminal Peptides to the Associative Behavior of αs1-Casein

The N- and C-terminal segments of bovine alphas1-casein-B (f1-23 and f136-196) were characterized under conditions that promoted or inhibited self-association to determine the relative contributions of each fragment to the interaction of alphas1-casein with itself or with other caseins. In earlier studies of f1-23, nuclear magnetic resonance (NMR) data and circular dichroism (CD) spectra showed that its conformation was thermostable between 10 degrees and 25 degrees C. In contrast, NMR studies of f136-196 indicated temperature sensitivity between 10 and 60 degrees C, as did near-UV and far-UV CD data, suggesting a molten globule-like structure at higher temperatures. To compare the effects of temperature on conformational attributes of alphas1-casein and its terminal peptides, additional CD studies were conducted over a broader temperature range (10 to 70 degrees C). The far-UV CD spectra indicated little temperature sensitivity for alphas1-casein, and the N-terminal peptide remained thermostable. During molecular dynamics simulations, the N-terminal peptide conformation did not change significantly, but the conformation of the C-terminal peptide (f136-196) was dramatically altered. These changes are correlated with the thermal instability observed by both CD and NMR in f136-196. Analytical ultracentrifugation studies of the self-association reactions of genetic variants A, B, and C of alphas1-casein showed that at 37 degrees C the associative state is primarily dimeric; the amounts of higher order polymers significantly decreased when temperature was increased from 20 to 37 degrees C. In all 3 genetic variants, the C-terminal portion of the whole molecule showed thermal instability with respect to aggregation to higher polymers, confirming the predictions of CD data and molecular dynamics simulations. The temperature dependency of these conformational changes suggests a possible function for alphas1-casein in facilitating casein-casein interactions in casein micelle formation.

The liquid-state 31P-nuclear magnetic resonance study on microfiltrated milk

To gain further insight into diversiform phosphorus in bovine milk, we separated skim milk into casein micelle and serum fractions by microfiltration and subjected them to liquid-state 31P-nuclear magnetic resonance (NMR) spectroscopy. As previously reported, the skim milk spectrum showed a broad and indistinct peak from phosphoserine residue (SerP) of casein. In the casein micelle spectrum, however, the SerP peak was more clearly observed with a phosphate peak that may be from micellar calcium phosphate (MCP). The serum spectrum was the same as skim milk spectrum, except for SerP peak. Furthermore, two types of casein micelle fractions, with 0.90 and 1.04 of [beta-casein + kappa-casein]/[alpha(s1)-casein + alpha(s2)-casein] ratios were generated by different temperature microfiltrations, occurring because beta-casein is released from the micelle at a low temperature. The shape of SerP peaks changed dramatically in both the casein micelle spectra, when the temperature dropped from 35 to 5 degrees C. Deconvolution analysis indicated that each SerP peak comprised the same set of four peaks. Half-width and composition discriminated between the two types of casein micelle fractions. As a consequence, there was significant interaction between casein micelle and milk serum, causing cloudiness of SerP in the liquid-state 31P-NMR spectrum of milk. Casein composition influenced the SerP-MCP interaction in micellar structure. Shape changing of the SerP peak was discussed in connection with beta-casein-release phenomenon.

Effect of the anion citrate on the mineral composition of artificial casein micelles

The composition of artificial casein micelles (ACM) prepared at constant concentration of caseins, calcium (Ca), and phosphate (P(i)) in media with different citrate (Cit) concentrations was studied. The incorporation of the different mineral and protein components to the ACM was conditioned by the Cit concentration. In our working condition, the ACM size remained almost constant for Cit concentration ranging from 7 to 10 mM. This behavior could be indicating that the action of Cit essentially consists of a regulation of the Ca activity. The molar ratio at which Ca and P(i) were incorporated to the ACM varied for different Cit concentrations. At decreasing pH, the Ca/P(i) molar ratios for the remanent ions in the ACM were dependent on the Cit concentration. These observations could be related to a certain kind of competition between Cit, micellar calcium phosphate (MCP), and other groups able to bind Ca in the ACM.