Satish M. Sood

Interactions in human casein systems: Self-association of nonphosphorylated human β-casein

Since caseins were originally defined as phosphoproteins, nonphosphorylated beta-casein, comprising nearly 5% of the total beta-casein in the isoelectric precipitate from human milk, appears to be unique. Despite the relatively small amount present, its properties suggest that it may play an important role in micelle formation and structure. It has a partial specific volume, v, of 0.749 +/- 0.008 and an absorbance, E1% 1 cm,280 nm of 6.2 +/- 0.2. Sedimentation and viscosity data yield a solvation of 3 g H2O/g protein and an axial ratio of about 5 for the monomer. This would be consistent with a prolate ellipsoid of 10 nm length and 2 nm width. Equilibrium in the system is attained quite slowly and the temperature-dependent polymerization was found to be reversible. With calcium, the solubility behavior reflects an increased hydrophobicity and lower electrostatic repulsion in the molecule. There is essentially no strong calcium binding to this protein but there is evidence which strongly suggests that calcium binds to nonphosphate groups at higher concentrations. Increasing the temperature from 4 to 37 degrees C causes an apparent conformational change and an increase in protein aggregation which is further increased by addition of NaCl at 37 degrees C until a limiting size is reached at about 0.1 M NaCl. This limiting size polymer contains about 75 monomers and is nearly spherical with a radius of about 12 nm and a solvation of 1.5 g H2O/g protein. Laser light scattering measurements on the solution in 0.25 M NaCl revealed a relatively homogeneous particle size with a corrected diffusion coefficient, D20,w, of 2.8 X 10(-7) cm2/s.

Hydrophobic interactions in human casein micelle formation: beta-casein aggregation.

The association of non-phosphorylated (0-P) and fully phosphorylated (5-P) human beta-caseins was studied by fluorescence spectroscopy and laser light scattering. The tryptophan fluorescence intensity (FI) level increased between 20 and 35 degrees C, indicating a change in the environment of that residue. A similar transition occurred when ANS was used as a probe. Transition temperatures were slightly lower in 10 mM-CaCl2 but were not affected by an equivalent increase in ionic strength caused by NaCl. The magnitude of the FI change was less for the 5-P than the 0-P protein but was increased for both by CaCl2 addition. These FI data were characteristic of a conformational change and this was supported by fluorescence polarization which indicated that with CaCl2, tryptophan and ANS mobility increased at the transition temperature even though the extent of protein association also increased. Light scattering suggested that protein association proceeded with the primary formation of submicellar aggregates containing 20-30 monomers which then associated further to form particles of minimum micelle size (12-15 submicelles), and eventually larger. The temperature of precipitation of the 5-P form in the presence of CaCl2 was lower than the conformational transition and suggested that both hydrophobic interactions and Ca bridges between phosphate esters on adjacent molecules are important in micelle formation.

Interactions of triply phosphorylated human β-casein: Fluorescence spectroscopy and light-scattering studies of conformation and self-association☆

Structural changes of triply phosphorylated human beta-casein, caused by shifts in temperature between 5 and 40 degrees C, were studied using intrinsic and extrinsic fluorescence, fluorescence polarization, turbidity, and light scattering measurements. Intrinsic fluorescence declined between 5 and 20 degrees C then rose between 25 and 40 degrees C, indicative of a shift of the tryptophan fluor toward a more nonpolar environment. The fluorescence of the extrinsic probe, 8-anilino-1-naphthalene-sulfonic acid (ANS), increased only slightly between 5 and 25 degrees C, and then more sharply between 25 and 40 degrees C, suggesting a change in conformation leading to a change in either the dissociation constant, Kd, or the number of ANS binding sites, N. The presence of Ca+2 ions did not significantly alter the pattern of changes of intrinsic and extrinsic fluorescence with changing temperature. For ANS binding, values of Kd and N were calculated by two different procedures, each based upon different assumptions. The results point to increased exposure of hydrophobic surfaces with increased temperature, strongly supportive of conformational changes. Although more opportunity for hydrophobic interaction leads to increased protein-protein association, turbidity and light-scattering also suggest ion bridge formation between protein molecules. A comparison of the primary sequences of beta-caseins from six species reveal residues that are common in all species examined and thus are pivotal in protein folding and conformation, intermolecular hydrophobic interactions and ion bridge formation with Ca+2 and inorganic phosphate.

Interactions of triply phosphorylated human β-casein : monomer characterization and hydrodynamic studies of self-association

The triply phosphorylated form of human beta-casein comprises about 15% of that fraction and is thus a significant component about midway between the two extremes of zero and five phosphoryls. Its partial specific volume, v, of 0.74 +/- 0.01 and absorbancy, E1% 1 cm, 280 nm, of 6.2 +/- 0.2 are almost identical to the other human beta-caseins. Equilibrium dialysis gave an average of 3.1 +/- 0.4 major Ca2+ binding sites at 37 degrees C with Kdiss = 8.6 x 10(-4) M. Sedimentation and viscosity at low temperatures or in 3.3 M urea suggested a prolate ellipsoidal monomer with 1.4 g H2O/g protein, 10 nm in length and 1.4 nm in width. The concentrated charge of the phosphoryls may be near one end of the ellipsoid, allowing the molecules to align with the flow in the viscometer at low concentration but, due to intermolecular electrostatic interactions, not when concentration is high. This would provide a reason for the heretofore unexplained curvature in the plots of reduced viscosity, eta red, vs beta-casein protein concentration. Self-association increased with temperature. At 37 degrees C in low salt buffer, s20,W was 16 S, which increased to about 33 S as ionic strength, I, was increased to 0.2 and above. At the same time, eta red in low salt buffer decreased from about 22 ml/g at 4 degrees C to a constant value of about 5 ml/g above 23 degrees C. A similar value for eta red at 37 degrees C, which was almost independent of protein concentration, was obtained at I greater than 0.25, giving an extrapolated intrinsic viscosity value of [eta] = 4.0 ml/g. Using this value and assuming a spherical aggregate, calculations suggest a radius of 9 nm with about 48 monomers and 0.86 g H2O/g protein.