Restricted genetic defects underlie human complement C6 deficiency

Complement C6 homozygous deficiency (C6D) has been rarely observed in Caucasians but was reported at higher prevalence among African-Americans. We report on the molecular basis of C6D in seven unrelated black individuals of North or Central Africa descent who live in France. These patients have presented Neisseria meningitidis infection (four cases), focal and segmental glomerulosclerosis with hyalinosis (one case), systemic lupus erythematosus (one case) or Still's disease (one case). All patients exhibited undetectable antigenic C6 by using a sensitive ELISA assay. An additional four cases of complete C6 deficiency with no associated disease have been characterized after family studies. Exons 6, 7 and 12 have been described recently as the location of molecular defects on the C6 gene in randomly chosen black Americans. Genomic DNA from the seven patients were subjected to direct polymerase chain reaction amplification of these three exons. Nucleotide sequencing analysis of the amplified DNA fragments revealed a homozygous single-base deletion (1936delG) in exon 12 in three cases and four compound heterozygous deletions for a single base in exon 7 (1195delC) or in exon 6 (878delA) associated with the same deletion in exon 12 (1936delG). Our observations further establish the restricted pattern of genetic defects associated with homozygous C6 complement deficiency in individuals of African descent.     

Implications of the initial mutations in membrane cofactor protein (MCP; CD46) leading to atypical hemolytic uremic syndrome

The hemolytic uremic syndrome is characterized by the triad of microangiopathic hemolytic anemia, thrombocytopenia and acute renal failure. There are two general types. One occurs in epidemic form and is diarrheal associated (D+HUS). It has a good prognosis. The second is a rare form known as atypical (aHUS), which may be familial or sporadic, and has a poor prognosis. aHUS is increasingly recognized to be a disease of defective complement regulation, particularly cofactor activity. Mutations in membrane cofactor protein (MCP; CD46) that predispose to the development of aHUS were first identified in 2003. MCP is a membrane-bound complement regulator that acts as a cofactor for the factor I-mediated cleavage of C3b and C4b deposited on host cells. More than 20 different mutations in MCP have now been identified in patients with aHUS. Many of these mutants have been functionally characterized and have helped to define the pathogenic mechanisms leading to aHUS development. Over 75% of the reported mutations cause a reduction in MCP expression, due to homozygous, compound heterozygous or heterozygous mutations. This deficiency of MCP leads to inadequate control of complement activation on endothelial cells after an initiating injury. The remaining MCP mutants are expressed, but demonstrate reduced ligand (C3b/C4b) binding capacity and cofactor activity of MCP. MCP mutations in aHUS demonstrate incomplete penetrance, indicating that additional genetic and environmental factors are required to manifest disease. MCP mutants as a cause of aHUS have a favorable clinical outcome in comparison to patients with factor H (CFH) or factor I (IF) mutations. In 90% of the renal transplants performed in patients with MCP-HUS, there has been no recurrence of the primary disease, whilst >50% of factor I or factor H deficient patients have had a prompt recurrence. This highlights the importance of defining and characterizing the underlying genetic defects in patients with aHUS.     

Pathophysiology of thrombotic microangiopathies: current understanding

Thrombotic microangiopathies (TMA) encompass various severe diseases characterized by microangiopathic hemolytic anemia and peripheral thrombocytopenia, associated with fever, neurological signs and renal involvement. Microvascular thrombosis is the typical lesion, and results in tissue ischemia. Thrombotic thrombocytopenic purpura (TTP) and hemolytic uremic syndrome (HUS) are the two most classical forms. These two entities are clinically and histopathologically closely related. There is a body of evidence suggesting that endothelial cell injury is the initial event in TTP and HUS, and that it may be related to a large number of triggering factors, such as infection, connective tissue disease, drugs, cancer and chemotherapy, transplantation, and pregnancy. Endothelial cell injury enhances the release of ultra large forms of von Willebrand factor (ULvWF) multimers and other prothrombotic agents, such as plasminogen activator inhibitor and platelet activating factor, whereas it decreases the release of prostaglandin-I2, a strong inhibitor of platelet aggregation. Recently however, it has been shown that TTP and HUS were pathophysiologically distinct. Actually, TTP is associated with a deficiency in von Willebrand factor-cleaving protease, an enzyme involved in cleavage of ULvWF into circulating 200 kDa and 350 kDa fragments. This deficiency may be either congenital or acquired, and then related to an IgG inhibitory autoantibody. This protease deficiency may account for the high amounts of plasmatic ULvWF in TTP patients. In HUS, vWF-cleaving protease activity is found normal. HUS encompasses two distinct entities. Epidemic, or diarrhea-associated HUS, is associated with verotoxin or Shiga toxin-associated enterobacteriaceae. These toxins are directly responsible for endothelial cell injury. Sporadic HUS (also termed atypical HUS in children) is closely related to TTP, and shares the same triggering factors. Familial HUS has been associated in some cases with hypocomplementemia and factor H dysfunction, the pathophysiological role of which remains unclear. The study of the different triggering factors and predisposing factors may be useful to define different subsets of TMA, that may be characterized by their course and prognosis.     

Common genetic variants in complement genes other than CFH, CD46 and the CFHRs are not associated with aHUS

It is well established that common genetic variants in CFH, CD46 and the CFHRs are additional risk factors for the development of aHUS. To examine the hypothesis that common variants in other complement genes have a similar effect we genotyped 501 SNPs in 47 complement genes in 94 aHUS patients from Newcastle, 126 aHUS patients from Paris, 374 UK controls and 165 French controls. We replicated the associations in CFH, CD46 and the CFHRs but found no association with any other complement gene. The strongest associations replicated in both cohorts were found for four SNPs within CD46 (p-value<10(-3)) and five SNPs within CFH (p-value<5×10(-3)). Significant replicable associations with single SNPs in CFHR2, CFHR4 and an intergenic SNP (CR1-CD46) were also found. Analysis of the Paris cohort showed that the association with CD46 SNPs was only present in those patients with complement mutations. Haplotype analysis showed at-risk and protective haplotypes in both CD46 and CFH. The CD46 haplotype was only disease-associated in those patients with mutations.