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Molecular bases for the association of FHR-1 with atypical hemolytic uremic syndrome and other diseases.

Héctor Martín-MerineroMarta SubíasAmaia PeredaElena Gomez-RubioLucia Juana LopezConstantino Fernandez RiveraElena Goicoechea de JorgeSonsoles Martin-SantamariaFrancisco Javier CañadaSantiago Rodríguez de Córdoba
Published in: Blood (2021)
Factor H (FH)-related proteins are a group of partly characterized complement proteins thought to promote complement activation by competing with FH in binding to surface-bound C3b. Among them, FH-related protein 1 (FHR-1) is remarkable because of its association with atypical hemolytic uremic syndrome (aHUS) and other important diseases. Using a combination of biochemical, immunological, nuclear magnetic resonance, and computational approaches, we characterized a series of FHR-1 mutants (including 2 associated with aHUS) and unraveled the molecular bases of the so-called deregulation activity of FHR-1. In contrast with FH, FHR-1 lacks the capacity to bind sialic acids, which prevents C3b-binding competition between FH and FHR-1 in host-cell surfaces. aHUS-associated FHR-1 mutants are pathogenic because they have acquired the capacity to bind sialic acids, which increases FHR-1 avidity for surface-bound C3-activated fragments and results in C3b-binding competition with FH. FHR-1 binds to native C3, in addition to C3b, iC3b, and C3dg. This unexpected finding suggests that the mechanism by which surface-bound FHR-1 promotes complement activation is the attraction of native C3 to the cell surface. Although C3b-binding competition with FH is limited to aHUS-associated mutants, all surface-bound FHR-1 promotes complement activation, which is delimited by the FHR-1/FH activity ratio. Our data indicate that FHR-1 deregulation activity is important to sustain complement activation and C3 deposition at complement-activating surfaces. They also support that abnormally elevated FHR-1/FH activity ratios would perpetuate pathological complement dysregulation at complement-activating surfaces, which may explain the association of FHR-1 quantitative variations with diseases.
Keyphrases
  • magnetic resonance
  • signaling pathway
  • escherichia coli
  • staphylococcus aureus
  • binding protein
  • mass spectrometry
  • machine learning
  • dna binding
  • contrast enhanced
  • artificial intelligence