Complement: a critical test of its biological importance.

The biological activities of the more than 30 proteins that comprise the complement system have been elucidated in parallel lines of investigation that resulted in the purification of the proteins and studies of their function in vitro. Twenty years ago, the first complement cDNA clones were generated. Subsequently the structure and chromosomal localization of the complement genes and the primary sequences of their gene products were revealed. For some, even their higher order structure was solved. This work, coupled with studies of complement gene expression, biosynthesis, post-synthetic processing and secretion, contributed to an analysis of the relatively rare naturally occurring genetic deficiencies of complement proteins discovered fortuitously in humans sand experimental animals. Not until the past 5 years, with the application of methods for manipulating genes in vivo (targeted deletion and overexpression), has it been possible to definitively assign specific functions to complement proteins and to assess their importance in the intact organism. These relatively recent studies have confirmed the in vitro work or revealed unexpected roles for complement effector and regulatory proteins in host defenses, specific immunity, immunopathology, metabolism and reproductive biology This work is reviewed and the implications for understanding human diseases and the design of novel pharmaceutical agents are discussed. The promise of this line of investigation is certain but the context imposed by gender, developmental stage, other genes and environment must be taken into account before the practical implications of this deeper understanding of complement biology are fully realized.

Disruption of disulfide bonds is responsible for impaired secretion in human complement factor H deficiency.

Factor H, a secretory glycoprotein composed of 20 short consensus repeat modules, is an inhibitor of the complement system. Previous studies of inherited factor H deficiency revealed single amino acid substitutions at conserved cysteine residues, on one allele arginine for cysteine 518 (C518R) and on the other tyrosine for cysteine 941 (C941Y) (Ault, B. H., Schmidt, B. Z., Fowler, N. L., Kashtan, C. E., Ahmed, A. E., Vogt, B. A., and Colten, H. R. (1997) J. Biol. Chem. 272, 25168-25175). To ascertain if the phenotype, impaired secretion of factor H, is due to the C518R substitution or the C941Y substitution and to ascertain the mechanism by which secretion is impaired, we studied COS-1 and HepG2 cells transfected with wild type and several mutant factor H molecules. The results showed markedly impaired secretion of both C518R and C941Y factor H as well as that of factor H molecules bearing alanine or arginine substitutions at the Cys518-Cys546 disulfide bond (C518A, C546A, C546R, C518A-C546A). In each case, mutant factor H was retained in the endoplasmic reticulum and degraded relatively slowly as compared with most other mutant secretory and membrane proteins that are retained in the endoplasmic reticulum. These data indicate that impaired secretion of the naturally occurring C518R and C941Y mutant factor H proteins is due to disruption of framework-specific disulfide bonds in factor H short consensus repeat modules.

Human factor H deficiency. Mutations in framework cysteine residues and block in H protein secretion and intracellular catabolism.

The synthesis and secretion of factor H, a regulatory protein of the complement system, were studied in skin fibroblasts from an H-deficient child who has chronic hypocomplementemic renal disease. In normal fibroblasts, factor H transcripts of 4.3 and 1.8 kilobase pairs (kb) encode a 155-kDa protein containing short consensus repeat (SCR) domains 1-20 and a 45-kDa protein which contains SCRs 1-7, respectively. The patient's fibroblasts expressed normal amounts of the 4.3- and 1.8-kb messages constitutively and after tumor necrosis factor-alpha/interferon-gamma stimulation. Lysates of [35S]methionine-labeled fibroblasts from the patient contained the 155- and 45-kDa H polypeptides, but secretion of the 155-kDa protein was blocked; the 45-kDa protein was secreted with normal kinetics. The patient's plasma lacked the 155-kDa protein but contained the small form of H. Moreover, in fibroblasts the retained 155-kDa factor H protein was not degraded, even after 12 h. Immunoflourescent staining and confocal microscopic imaging of the patient's fibroblasts indicated that factor H was retained in the endoplasmic reticulum. Sequence analysis of reverse transcription-polymerase chain reaction products (the entire coding region) and genomic DNA revealed a T1679C substitution on one allele and a G2949A substitution on the other (C518R mutation in SCR 9 and C991Y mutation in SCR 16, respectively). Both mutations affect conserved cysteine residues characteristic of SCR modules and therefore predict profound changes in the higher order structure of the 155-kDa factor H protein. These data provide the first description of a molecular mechanism for factor H deficiency and yield important insights into the normal secretory pathway for this and other plasma proteins with SCR motifs.