Early Components of the Complement Classical Activation Pathway in Human Systemic Autoimmune Diseases

The complement system consists of effector proteins, regulators, and receptors that participate in host defense against pathogens. Activation of the complement system, via the classical pathway (CP), has long been recognized in immune complex-mediated tissue injury, most notably systemic lupus erythematosus (SLE). Paradoxically, a complete deficiency of an early component of the CP, as evidenced by homozygous genetic deficiencies reported in human, are strongly associated with the risk of developing SLE or a lupus-like disease. Similarly, isotype deficiency attributable to a gene copy number variation, and/or the presence of autoantibodies directed against a CP component or a regulatory protein that result in an acquired deficiency are relatively common in SLE patients. Applying accurate assay methodologies with rigorous data validations, low gene copy numbers of total C4, heterozygous and homozygous deficiencies of C4A have been shown as medium to large effect size risk factors, while high copy numbers of total C4 or C4A as prevalent protective factors, of European and East-Asian SLE. Here, we summarize the current knowledge related to genetic deficiency and insufficiency, and acquired protein alterations for C1q, C1r, C1s, C4A/C4B, and C2 in disease pathogenesis and prognosis of SLE, and, briefly, for other systemic autoimmune diseases. As the complement system is increasingly found to be associated with autoimmune diseases, it has become an attractive therapeutic target. We highlight the recent developments and offer a balanced perspective concerning future investigations and therapeutic applications with a focus on early components of the CP in human systemic autoimmune diseases

H deficiency in two brothers with atypical dense intramembranous deposit disease

H deficiency in two brothers with atypical dense intramembranous deposit disease. We report an H deficiency in two Algerian brothers who had early–onset glomerulonephritis. In addition, one suffered from serious lung infections. The H deficiency was defined by undetectable CH50 and AP50, and low levels of H, C3 and B (less than 10% of normal levels). I and classical pathway components, including C4-bp were normal. CR1 was present on both patients' erythrocytes. No nephritic factor or other circulating alternative pathway activator was detected. The parents, who are first cousins, and a healthy brother and sister had half–normal levels of H. These findings favor an autosomal recessive transmission of the H defect. Although by electron microscopy renal biopsies from both patients were typical for dense intramembranous deposit disease, immunofluorescence microscopy showed an atypical pattern with abundant granular C3 deposits within the mesangium and along the capillary walls. Alternative pathway activators, possibly related to dense deposits, may allow the formation of membrane–associated C3/C5 convertases, unusually stable in the absence of H, since C5, C6, C7, C8 and C9 levels were decreased in both patients. This observation may represent an interesting clue to the relationship between nephritic factor, alternative pathway activation, and dense intramembranous deposit disease

École doctorale n O 432: SMI- Sciences des Métiers de l’Ingénieur

pour obtenir le grade de docteur délivré par l’École nationale supérieure des mines de Paris Spécialité Mathématiques et Systèmes présentée et soutenue publiquement pa