Modeling of the electrostatic potential field of plastocyanin.

The DelPhi computer program is used to calculate the electrostatic potential field of the photosynthetic electron transport protein plastocyanin. Knowledge of the potential field is important for understanding the mechanisms by which plastocyanin interacts with other charged reagents. The program uses a macroscopic, continuum approach in which the protein and solvent are assigned different dielectric constants, the crystal structure of the protein defines the dielectric boundary, and the ionic strength of the solvent is taken into account. The potential field is determined by numerically solving the Poisson-Boltzmann equation. The field surrounding plastocyanin is characterized by a region of positive potential over the copper center active site, and a region of negative potential over the adjacent association site containing tyrosine 83. The shape and magnitude of the potential field shows a strong dependence on the ionic strength and pH of the solvent. The program is able to accurately predict the effect of the copper center oxidation state on the pKa of a tetranitromethane derivative of tyrosine 83 using an intrinsic protein dielectric constant of 2 to 4. Evidence is also presented that the glutamate 68 side chain is exposed to the solvent to a greater extent in the solution structure of plastocyanin than in the crystal structure.