Abstract
Atypical hemolytic uremic syndrome (aHUS) is a thrombotic microangiopathy associated with mutations in complement proteins, most frequently in the main plasma alternative pathway regulator factor H (FH). The hotspot for the FH mutations is in domains 19-20 (FH19-20) that are indispensable for FH activity on C3b bound covalently to host cells. In aHUS, down-regulation of cell-bound C3b by FH is impaired, but it is not clear whether this is due to an altered FH binding to surface-bound C3b or to cell surface structures. To explore the molecular pathogenesis of aHUS we tested binding of 14 FH19-20 point mutants to C3b and its C3d fragment, mouse glomerular endothelial cells (mGEnC-1), and heparin. The cell binding correlated well, but not fully, with heparin binding and the cell binding site was overlapping but distinct from the C3b/C3d binding site that was shown to extend to domain 19. Our results show that aHUS-associated FH19-20 mutants have different combinations of three primary defects: impaired binding to C3b/C3d, impaired binding to the mGEnC-1 cells/heparin, and, as a novel observation, an enhanced mGEnC-1 cell or heparin binding. We propose a model of the molecular pathogenesis of aHUS where all three mechanisms lead eventually to impaired control of C3b on the endothelial cell surfaces. Based on the results with the aHUS patient mutants and the overlap in FH19-20 binding sites for mGEnC-1/heparin and C3b/C3d we conclude that binding of FH19-20 to C3b/C3d is essential for target discrimination by the alternative pathway.
Highlights
Factor H Function Impaired by Various Mechanisms in aHUSIng of mouse or human FH to glomerular endothelial cells has not been characterized despite the fact that in aHUS damage occurs mainly in the small vessels, especially in the glomeruli
In this study we describe a novel defect of FH in aHUS, where three aHUS-associated mutants (T1184RaHUS, L1189RaHUS, and E1198AaHUS) have enhanced binding to mouse glomerular endothelial cells and heparin with normal C3b or C3d binding (Table 1)
The results of this study indicate that the C3b/C3d binding site is located in FH domains and 20, and glomerular endothelial cell, and heparin binding sites in domain (Fig. 6)
Summary
Ing of mouse or human FH to glomerular endothelial cells has not been characterized despite the fact that in aHUS damage occurs mainly in the small vessels, especially in the glomeruli. The molecular pathogenesis leading to the clinical aHUS in patients with FH mutations remains elusive. The suggested molecular mechanisms for some aHUS-associated mutations include defective binding of the mutated FH to GAGs, endothelial cells, or C3b/C3d (28, 29, 33, 34). The aim of this study was to define the effects of nine aHUS-associated FH mutations and five other structurally closely located mutations on binding of FH19 –20 to C3b, C3d, mouse glomerular endothelial cells, and heparin. We identified three primary defects of the mutants: impaired C3b/C3d binding, enhanced mGEnC-1/heparin binding, and impaired mGEnC-1/heparin binding that could lead via three mechanisms to incapability of FH to eliminate C3b on plasma-exposed self-cells.
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