Nature of the metal ion requirement for assembly and function of the first component of human complement.

Abstract

The first component of human complement (C1) was reconstituted from equimolar concentrations of its purified subunits C1q, C1r, and C1s, in the presence of each of nine different metal ions for the purpose of studying the qualitative and quantitative nature of the metal ion requirement for C1 assembly and function. For C1 reconstituted with each metal ion, three assays characteristic of C1 were performed as follows: (1) spontaneous C1 activation in the absence of the regulatory protein C1-inhibitor was assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis by simultaneously quantifying the specific proteolysis of the C1r and C1s subunits; (2) C1 activation induced by aggregated IgG in the presence of C1 inhibitor was similarly analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis; and (3) formation of 16 S macromolecular C1 was determined in the analytical ultracentrifuge. For all experiments, trace metal contaminants were removed from buffers and proteins. All divalent cations tested from the first transition period of the periodic table (i.e. Ca2+, Mn2+, Co2+, Ni2+, and Zn2+) effectively mediated the formation of functional macromolecular C1. Dose curves showed maximal C1 assembly and activation at ion concentrations of 30 to 50 microM for each of the above metal ions. However, when ion concentrations were increased above 50 microM, C1 assembly and activation became inhibited. The further to the right in the periodic table, the better inhibitor was the metal ion. Competition experiments indicated that the ion binding sites mediating inhibition are distinct from those promoting activation. Other metal ions that also effectively mediated C1 assembly and function were Cd2+ and Tb3+; however, Mg2+ and Ba2+ were ineffective. All metal ions that mediated C1 assembly and activation also promoted C2 consumption by C1 in normal human serum treated with aggregated IgG. In conclusion, the assembly and function of C1 can be mediated by numerous metal ions. In direct opposition to accepted theory, there is no specific requirement for calcium.