THE REACTION MECHANISM OF {beta}1C-GLOBULIN (C'3) IN IMMUNE HEMOLYSIS

doi:10.1084/jem.123.1.33

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ARTICLE

THE REACTION MECHANISM OF ß_1C-GLOBULIN (C'3) IN IMMUNE HEMOLYSIS

Hans J. Müller-Eberhard M.D.¹, Agustin P. Dalmasso M.D.¹, and Mary Ann Calcott ¹

¹ From the Division of Experimental Pathology, Scripps Clinic and Research Foundation, La Jolla, California

During immune hemolysis by human complement, C'3 (ß_1C-globulin)becomes physically attached to the erythrocyte membrane. Bindingof C'3 was found to be mediated by cell-bound, activated C'2and to have the characteristics of an enzymatic reaction. Asingle C'4,2a site on the cell surface effected the bindingof several hundred molecules of C'3 if the latter was providedin excess. The accumulation of hemolytically inactive, physicochemicallyaltered C'3 in the fluid phase was found to be an inherent featureof the process of C'3 binding. It is postulated that C'4,2aactivates C'3 for its subsequent reaction with cell membranereceptors. Antierythrocyte antibody did not play an essentialrole in C'3 uptake; C'3 could be bound to erythrocyte-C'4,2acomplexes which were entirely devoid of antibody.

Cell-boundC'3 proved hemolytically active, the degree of hemolysis beingproportional to the number of C'3 molecules per cell. Bindingof a large number of C'3 molecules per cell was found to bea prerequisite for the production of the immune adherence phenomenonand for immune hemolysis.

Submitted on September 7, 1965

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