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C3(H2O) prevents rescue of complement-mediated C3 glomerulopathy in Cfh–/– Cfd–/– mice
Yuzhou Zhang, Adam Keenan, Dao-Fu Dai, Kristofer S. May, Emily E. Anderson, Margaret A. Lindorfer, John B. Henrich, Gabriella R. Pitcher, Ronald P. Taylor, Richard J.H. Smith
Yuzhou Zhang, Adam Keenan, Dao-Fu Dai, Kristofer S. May, Emily E. Anderson, Margaret A. Lindorfer, John B. Henrich, Gabriella R. Pitcher, Ronald P. Taylor, Richard J.H. Smith
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Research Article Nephrology

C3(H2O) prevents rescue of complement-mediated C3 glomerulopathy in Cfh–/– Cfd–/– mice

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Abstract

Therapeutic complement inhibition is a major focus for novel drug development. Of upstream targets, factor D (FD) is appealing because it circulates in plasma at low concentrations and has a single function: to cleave factor B to generate C3 convertase of the alternative pathway (AP). Mice with a targeted deletion of factor H (FH; Cfh–/– mice) develop C3 glomerulopathy (C3G) due to uncontrolled AP activity. To assess the impact of FD inhibition, we studied Cfh–/– Cfd–/– mice. We show that C3G in Cfh–/– mice is not rescued by removing FD. We used serum from Cfh–/– Cfd–/– mice to demonstrate that residual AP function occurs even when both FD and FH are missing and that hemolytic activity is present due to the action of C3(H2O). We propose that uncontrolled tick-over leads to slow activation of the AP in Cfh–/– Cfd–/– mice and that a minimal threshold of FH is necessary if tissue deposition of C3 is to be prevented. The FD/FH ratio dictates serum C3 level and renal C3b deposition. In C3G patients with chronic renal disease, the FD/FH ratio correlates inversely with C3 and C5 serum levels, suggesting that continuous AP control may be difficult to achieve by targeting FD.

Authors

Yuzhou Zhang, Adam Keenan, Dao-Fu Dai, Kristofer S. May, Emily E. Anderson, Margaret A. Lindorfer, John B. Henrich, Gabriella R. Pitcher, Ronald P. Taylor, Richard J.H. Smith

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Figure 7

FH and FD modulate renal C3 deposition in Cfh–/– Cfd–/– mice.

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FH and FD modulate renal C3 deposition in Cfh–/– Cfd–/– mice.
(A) Inject...
(A) Injection of human FH decreases and eventually eliminates C3 deposition in Cfh–/– Cfd–/– mice in a dose-dependent manner. (B) The C3 deposition pattern changes from predominantly mesangial to capillary, with increasing amounts of human FD (from left to right). For A and B, each image represents 3 injected mice with 10 glomeruli surveyed under each condition. Scale bars: 50 μM. (C and D) Pharmacodynamics of human FD in Cfh–/– Cfd–/– mice. The minimum concentration of FD required to deplete complement (arrow, C) and the time-to-deplete and time-to-restore C3 after a single dose of human FD (1 μg/kg, D). (E) Pharmacodynamics of human FH and FD in Cfh–/– Cfd–/– mice. C3 levels in Cfh–/– Cfd–/– mice are high if neither FH nor FD is added. When a single dose of FD is given (1 μg/kg), the minimum concentration of FH required to control complement activity is ~30 μg/mL (arrow). (F) Plasma C3 levels vary as a function of the FD/FH ratio. Higher FD/FH ratios are associated with poorer levels of complement control, as reflected by lower levels of C3. (G) With increasing levels of FD, higher levels of FH are required to control complement activity. Note that the same amount of FH (plasma concentration of FH for all animals in G is ~50 μg/mL) fails to normalize plasma C3 in animals treated with a high dose of FD (100 μg/kg).

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