Strazza S, Hunter R, Walker E, Darnall D W
Arch Biochem Biophys. 1985 Apr;238(1):30-42. doi: 10.1016/0003-9861(85)90137-7.
Difference spectroscopy was used to determine the equilibrium constants and thermodynamic parameters for the monomer-dimer association of bovine and porcine insulin and bovine proinsulin at pH 2.0 and 7.0. At pH 2 delta G degree 25, delta S degree, and delta H degree for dimerization of bovine insulin were found to be -6.6 kcal/mol, -18 cal/mol-deg, and -12 kcal/mol, respectively. Porcine insulin behaved similarly to bovine insulin in its dimerization properties in that delta G degree 25, delta S degree, and delta H degree were found to be -6.8 kcal/mol, -14 cal/mol-deg, and -11 kcal/mol, respectively. At pH 7 delta G degree 25, delta S degree, and delta H degree for dimerization of bovine insulin were found to be -7.2 kcal/mol, -16 cal/mol/deg, and -12 kcal/mol, respectively. At pH 7.0 delta G degree 25, delta S degree, and delta H degree for dimerization of porcine insulin were -6.7 kcal/mol, -11.6 cal/mol-deg, and -10 kcal/mol, respectively. The similarity in the thermodynamic parameters of both insulin species at the different pH's suggests that there are minimal structural changes at the monomer-monomer contact site over this pH range. The dimerization of both insulin species is under enthalpic control. This may suggest that the formation of the insulin dimer is not driven by hydrophobic bonding but, rather, is driven by the formation between subunits of four hydrogen bonds in an apolar environment. At pH 2 delta G degree 25, delta S degree, and delta H degree for dimerization of bovine proinsulin were found to be -5.3 kcal/mol, -26 cal/mol-deg, and -13 kcal/mol, respectively. At pH 7 delta G degree 25, delta S degree, and delta H degree for dimerization of proinsulin were -5.9 kcal/mol, -4.2 cal/mol-deg, and -7.2 kcal/mol, respectively. Although the presence of the C-peptide on proinsulin does not drastically affect the overall free energy change of dimer formation (as compared to insulin), the other thermodynamic parameters are rather drastically altered. This may be because of electrostatic interactions of groups on the C-peptide with groups on the B-chain which are near the subunit contact site in the insulin dimer.
采用差示光谱法测定了牛胰岛素、猪胰岛素和牛胰岛素原在pH 2.0和7.0时单体 - 二聚体缔合的平衡常数和热力学参数。在pH 2时,发现牛胰岛素二聚化的ΔG°25、ΔS°和ΔH°分别为 -6.6千卡/摩尔、-18卡/摩尔·度和 -12千卡/摩尔。猪胰岛素在二聚化性质上与牛胰岛素相似,其ΔG°25、ΔS°和ΔH°分别为 -6.8千卡/摩尔、-14卡/摩尔·度和 -11千卡/摩尔。在pH 7时,牛胰岛素二聚化的ΔG°25、ΔS°和ΔH°分别为 -7.2千卡/摩尔、-16卡/摩尔/度和 -12千卡/摩尔。在pH 7.0时,猪胰岛素二聚化的ΔG°25、ΔS°和ΔH°分别为 -6.7千卡/摩尔、-11.6卡/摩尔·度和 -10千卡/摩尔。两种胰岛素在不同pH值下热力学参数的相似性表明,在该pH范围内,单体 - 单体接触位点的结构变化最小。两种胰岛素的二聚化受焓控制。这可能表明胰岛素二聚体的形成不是由疏水键驱动的,而是由非极性环境中亚基之间形成的四个氢键驱动的。在pH 2时,发现牛胰岛素原二聚化的ΔG°25、ΔS°和ΔH°分别为 -5.3千卡/摩尔、-26卡/摩尔·度和 -13千卡/摩尔。在pH 7时,胰岛素原二聚化的ΔG°25、ΔS°和ΔH°分别为 -5.9千卡/摩尔、-4.2卡/摩尔·度和 -7.2千卡/摩尔。虽然胰岛素原上C肽的存在不会显著影响二聚体形成的总体自由能变化(与胰岛素相比),但其他热力学参数却发生了相当大的改变。这可能是由于C肽上的基团与胰岛素二聚体中亚基接触位点附近B链上的基团发生了静电相互作用。
