TY - JOUR

T1 - Temperature effects on calcium binding to caseins

AU - Liu, Xiao Chen

AU - Jiang, Yuan

AU - Ahrné, Lilia M.

AU - Skibsted, Leif H.

N1 - Funding Information: This work was supported by the China Scholarship Council [CSC, No. 201806360266] and the Danish Dairy Research Council/Innovation Fund Denmark as the project Procalcium. We are grateful for the help with ICP measurement from Jing Wang at the Department of Food Science, University of Copenhagen. Funding Information: This work was supported by the China Scholarship Council [CSC, No. 201806360266 ] and the Danish Dairy Research Council/Innovation Fund Denmark as the project Procalcium. We are grateful for the help with ICP measurement from Jing Wang at the Department of Food Science, University of Copenhagen. Publisher Copyright: © 2022 The Authors

PY - 2022

Y1 - 2022

N2 - The kinetics of binding of calcium ions in molar excess to individual caseins and casein ingredients was studied in pH 6.4 aqueous solutions using stopped-flow absorption spectroscopy. An initial second-order reaction, faster for β-casein than for αs-casein due to lower energy of activation (ΔEa1,β = 8.2 kJ∙mol−1; ΔEa1,α = 18.1 kJ∙mol−1, respectively), is followed by a slower first-order reaction with similar energies of activation (ΔEa2,β = 25.3 kJ∙mol−1 and ΔEa2,α = 20.7 kJ∙mol−1) as determined from temperature dependence of rate between 25 °C and 50 °C. Sodium caseinate reacts faster with calcium than both αs-casein and β-casein in the first reaction of the two consecutive reactions, while the rate of the second falls between αs-casein and β-casein. Global spectral analysis showed the UV–visible spectra of the reaction intermediates of the caseins to be more similar to the final products than to the initial casein reactants. Dynamic and static light scattering indicated decreasing particle sizes and increasing particle surface upon calcium-binding most significantly at low temperatures. The calcium binding to casein was found endothermic by isothermal titration calorimetry. Calcium binding seems to be controlled by enthalpy/entropy compensation corresponding to an isoequilibrium temperature of 38 °C in agreement with binding of calcium to o-phosphoserine rather than to aspartate or glutamate side chains of the caseins. Binding capacity and affinity for calcium to αs-casein and sodium caseinate both increased with increasing temperature in agreement with the endothermic nature of the binding. Decreasing enthalpy of binding for each calcium indicating a decrease in heat capacity of the caseins upon calcium-binding. The small difference between binding enthalpy and energy of activation for association of calcium to αs-casein lead to the conclusion that calcium dissociation goes through an early transition state. The rate of calcium dissociation hardly depends on temperature also explaining why calcium binding to caseins is important for calcium bioaccessibility.

AB - The kinetics of binding of calcium ions in molar excess to individual caseins and casein ingredients was studied in pH 6.4 aqueous solutions using stopped-flow absorption spectroscopy. An initial second-order reaction, faster for β-casein than for αs-casein due to lower energy of activation (ΔEa1,β = 8.2 kJ∙mol−1; ΔEa1,α = 18.1 kJ∙mol−1, respectively), is followed by a slower first-order reaction with similar energies of activation (ΔEa2,β = 25.3 kJ∙mol−1 and ΔEa2,α = 20.7 kJ∙mol−1) as determined from temperature dependence of rate between 25 °C and 50 °C. Sodium caseinate reacts faster with calcium than both αs-casein and β-casein in the first reaction of the two consecutive reactions, while the rate of the second falls between αs-casein and β-casein. Global spectral analysis showed the UV–visible spectra of the reaction intermediates of the caseins to be more similar to the final products than to the initial casein reactants. Dynamic and static light scattering indicated decreasing particle sizes and increasing particle surface upon calcium-binding most significantly at low temperatures. The calcium binding to casein was found endothermic by isothermal titration calorimetry. Calcium binding seems to be controlled by enthalpy/entropy compensation corresponding to an isoequilibrium temperature of 38 °C in agreement with binding of calcium to o-phosphoserine rather than to aspartate or glutamate side chains of the caseins. Binding capacity and affinity for calcium to αs-casein and sodium caseinate both increased with increasing temperature in agreement with the endothermic nature of the binding. Decreasing enthalpy of binding for each calcium indicating a decrease in heat capacity of the caseins upon calcium-binding. The small difference between binding enthalpy and energy of activation for association of calcium to αs-casein lead to the conclusion that calcium dissociation goes through an early transition state. The rate of calcium dissociation hardly depends on temperature also explaining why calcium binding to caseins is important for calcium bioaccessibility.

KW - Intermediate spectrum

KW - Isothermal titration calorimetry

KW - Sodium caseinate

KW - Stepwise calcium association

KW - Stopped-flow spectroscopy

KW - α-casein

U2 - 10.1016/j.foodres.2022.110981

DO - 10.1016/j.foodres.2022.110981

M3 - Journal article

C2 - 35337555

AN - SCOPUS:85125474983

VL - 154

JO - Food Research International

JF - Food Research International

SN - 0963-9969

M1 - 110981

ER -