Variant-specific quantification of factor H in plasma identifies null alleles associated with atypical hemolytic uremic syndrome.

Atypical hemolytic uremic syndrome (aHUS) is associated with complement alternative pathway defects in over half the cases. Point mutations that affect complement surface regulation are common in factor H (CFH); however, sometimes individuals have null mutations in heterozygosis. The latter are difficult to identify, although a consistently low plasma factor H (fH) concentration is suggestive; definitive proof requires demonstration that the mutant sequence is not expressed in vitro. Here, novel reagents and assays that distinguish and individually quantify the common factor H-Y402H polymorphic variants were used to identify alleles of the CFH gene, resulting in low or null expression of full-length fH and also normal or increased expression of the alternative splice product factor H-like-1 (FHL-1). Our assay identified three Y402H heterozygotes with low or absent fH-H402 but normal or increased FHL-1-H402 levels in a cohort of affected patients. Novel mutations explained the null phenotype in two cases, which was confirmed by family studies in one. In the third case, family studies showed that a known mutation was present on the Y allele. The cause of reduced expression of the H allele was not found, although the data suggested altered splicing. In each family, inheritance of low expression or null alleles for fH strongly associated with aHUS. Thus, our assays provide a rapid means to identify fH expression defects without resorting to gene sequencing or expression analysis.

Anti-disialoside antibodies kill perisynaptic Schwann cells and damage motor nerve terminals via membrane attack complex in a murine model of neuropathy.

Anti-disialoside antibodies (Abs) that bind NeuAc(alpha2-8) NeuAc epitopes on GQ1b and related gangliosides are found in human autoimmune neuropathy sera and are considered to be pathogenic. In a model system in mice, one mechanism by which anti-disialoside Abs have been demonstrated to induce paralysis is through a complement dependent blocking effect on transmitter release at the neuromuscular junction, similar to the effects of alpha-latrotoxin. Although direct targeting of presynaptic neuronal membranes occurs in this model, concomitant injury to perisynaptic Schwann cells (pSC) could indirectly contribute to this paralytic effect by influencing nerve terminal function and survival. To examine this possibility and the specific complement components that might mediate these effects, we exposed neuromuscular junctions in vivo and in vitro to an anti-disialoside Ab in conjunction with intact and selectively deficient complement sources. Using immuno-electron microscopy, we observed Ab deposits equally distributed on both neuronal and pSC membranes, and ultrastructural evidence of injury at both sites. Presynaptic neuronal injury was demonstrated functionally with microelectrode recordings and histologically as neurofilament loss. As hypothesized, concomitant pSC injury occurred, as indicated by abnormal uptake of ethidium dimer into pSC nuclei. The pSC and nerve terminal damage indicators correlated well with deposition of the pore-forming terminal complement component, membrane attack complex (MAC) in pSC and nerve terminal membranes. Furthermore, both neuronal and pSC injury were exacerbated in tissues from mice lacking the inhibitory complement regulator, CD59, where MAC formation is increased. These data demonstrate that both presynaptic neuronal membranes and pSCs are targets for anti-disialoside Abs, and that the injury to both sites is mediated by MAC and further regulated by CD59. This is the first demonstration that complement mediated pSC injury occurs in a model of autoimmune neuropathy and provides a rationale for investigating the possibility of pSC injury in equivalent conditions in man.