Summary
The efficiency of cytolysis by the terminal complement proteins C5b-9 can be markedly enhanced by C3b molecules bound on the target cell membrane (Hammer et al. 1976). This enhancement was shown to be proportional to the number of C3b molecules on the cell membrane. The present experiments have shown that the hemolytic efficiency of the complement membrane attack system is two to five times greater on paroxysmal nocturnal hemoglobulinuria erythrocytes (PNHE) than on normal human E. This difference is attribut to a derivative of C3, probably C3b, on PNHE since it was abolished by anti-C3 but not by anti-C2. The efficiency of C5b-9 to lyse PNHE was only partially decreased by C3b inactivator and β 1H, indicating that the C3b on PNHE is not readily inactivated by its regulatory proteins. Furthermore, cells from a single severely affected patient consumed 3-fold more C5b6 than normal human E yet concommitantly measured membrane fluidity was normal. From these observations we conclude that cell-bound C3b on PNHE serves two functions: (a) it increases the hemolytic efficiency of membrane attack components of the complement system; and (b) it provides sites for assembly of the alternative pathway convertases.
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Jones, C.M., Shin, M.L. & Mayer, M.M. On the lysis of paroxysmal nocturnal hemoglobinuria erythrocytes by complement: Dual role of C3b. Blut 45, 249–259 (1982). https://doi.org/10.1007/BF00320192
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DOI: https://doi.org/10.1007/BF00320192