JOURNAL CLUB

1. JOURNAL CLUB Barbara Labban, M.D.

3. Complement System • Crucial component of the innate immune system. • Host defense • Clearance of immune complexes and dying cells • Adjuvant role in immune response

4. Classical Pathway Alternative Pathway C3 Immune Complexes Non- Immune Complexes Endotoxin f D C3b Factor B Properdin (-) C1 Lectin Pathway C1-INH C4bp fI C2 C4 C3bBb (C3 Convertase) (-) C3 C4b C2a C3b C4b2a (C3 Convertase) C4b2a3b (C5 Convertase) C3bBb3b (C5 Convertase) C3 C3b C5 C5b +C6 +C7 +C8 +C9 C5b-9 (MAC)

5. Classical PathwayActivation Ab-dependent Ag-IgM, Ag-IgG complexes Ab-Independent polyanions, protamine, DNA, RNA of apoptotic cells, G- Bacteria, CRP + C1 ( - ) + C4 + C2 C1-INH ( - ) + C3 C 4b2a3b

6. Classical Pathway Immune Complexes Non- Immune Complexes (-) C1 C1-INH C4bp fI C2 C4 (-) C4b C2a C4b2a (C3 Convertase) C4b2a3b (C5 Convertase) C3 C3b C5 C5b +C6 +C7 +C8 +C9 C5b-9 (MAC)

7. Lectin Pathway • Ab-Independent Microbial Carbohydrates (+) MBL +(MASP-1, MASP-2) Activation C4

8. Alternative Pathway • Continuous state of low-level activation • Continuous generation of C3b in plasma • Active regulation is achieved by 2 plasma proteins: Factor H & Factor I.

9. Alternate Pathway C3(H2O) H2O + C3 + f B LPS C3NeF Stabilized, C3 Convertase. Auto-antibody attaches to convertase C3(H2O)Bb (C3 Convertase) C3(H2O)B f D C3a H C3b + f B C3bB IgG-C3bB- Properdin MCP CD46 CR1 H H f D IgG-C3b- Properdin f B + Amplification Loop Factor I i C3b + C3f Factor I C3dg + C3c n C3b IgG-C3bBb-Properdin (C3 Convertase) H H n C3

10. Factor H • Single chain glycoprotein. Produced by the liver. • Composed of 20 Short Consensus Repeat (SCR) domains. • Each SCR composed of 60 amino-acids. • N-terminal SCR domains: Regulation of fluid-phase C3 activation. • C-terminal domains: Regulation of surface bound C3b (surface recognition function, depends on the chemical composition of the surface).

12. Factor H - Regulates the alternative Pathway : • Inhibits the formation of the C3 Convertases of the alternative pathway by binding to C3b • Promotes dissociation of the C3 Convertases (Decay acceleration activity) • Cofactor to Factor I- mediated proteolytic conversion of C3b to inactive C3b (i C3b). - Deficiency of Factor H  Uncontrolled alternative pathway activation with secondary depletion of C3, Factor B and properdin.

13. Factor H and Renal Disease • Factor H gene mutation is associated with MPGN type II and atypical HUS. • Mutations located in the C terminal  aHUS. Rarely result in low complement or low Factor H plasma levels. • Mutations located in the N- terminal (complement regulatory domains) or complete factor H deficiency  MPGN 2. - Caprioli et al. The molecular basis of familial hemolytic uremic syndrome: mutation analysis of factor H gene reveals a hot spot in short consensus repeat 20. J Am Soc Nephrol 2001; 12:297-307 - Licht C., et al. Deletion of Lys224 in regulatory domain 4 of Factor H reveals a novel pathomechanism for dense deposit disease (MPGN II). Kidney Int. 2006;70:42–50)

14. MPGN type II (Dense Deposit Disease) • MPGN II: intramembranous electron-dense material along the GBM • Positive staining for C3, C5 & C9. • Cleavage fragments of C3b such as C3c and C3dg are found in the plasma of patients with MPGN2. • Complete Factor H deficiency in humans, pigs & mice results in uncontrolled Alternative pathway activation leading to MPGN2. Appel et al. Membranoproliferative Glomerulonephritis Type II (Dense Deposit Disease) An update. J Am Soc Nephrol 16: 1392-1404, 2005. doi: 10.1681

15. MPGN type II (Dense Deposit Disease) • Case Report: Patient with Autoantibody to factor H  MPGN2 Meri S. et al. Activation of the alternative pathway of complement by monoclonal lambda light chains in membranoproliferative glomerulonephritis. J. Exp. Med. 1992;175:939–950) • Case Report: Mutation of factor H complement regulatory domains  MPGN2 Licht C., et al. Deletion of Lys224 in regulatory domain 4 of Factor H reveals a novel pathomechanism for dense deposit disease (MPGN II). Kidney Int. 2006;70:42–50)

16. Hogasen et al. Hereditary porcine membranoproliferative glomeulonephritis type II is caused by Factor H deficiency. The American Society for Clinical Investigation.Vol 95, March 1995, 1054-1061 • Hogasen et al studied 13 piglets affected by MPGN type II to investigate the cause of complement activation . • Plasma transfusion resulted in - increase in C3 levels - increase in median and maximum survival ( 82 and 375 d vs 37 and 72 d) - MPGN was less proliferative compared to untreated pigs • Conclusion: The deficient regulatory protein was present in plasma.

17. Hogasen et al. Hereditary porcine membranoproliferative glomerulonephritis type II is caused by Factor H deficiency. The American Society for Clinical Investigation.Vol 95, March 1995, 1054-1061 • Fractionation of normal plasma, and administration of single proteins with monitoring of the C inhibitory activity in vivo • Conclusion: Inhibitory activity is confined to one single protein. - 150 kDa - Cofactor to factor I in vitro - NH2-terminal amino acid sequence was homologous with human, murine and rabbit FH

18. Pickering et al. Uncontrolled C3 activation causes membranoproliferative glomerulonephritis in micedeficient in complement factor H. Nature genetics • volume 31 • august 2002 • Pickering et al produced Factor H deficient mice and compared cohorts of Cfh-/-, Cfh+/- and wild-type mice for 8 months • At 8 months: • 23 % mortality in Cfh -/- mice • Cfh -/- mice developed light microscopic features of MPGN II

20. Light microscopy: the glomerulus of Cfh–/– mice shows hypercellularity, mesangial expansion and thickening of the capillary walls with double contours.

21. Immunoflurescence microscopy capillary wall and mesangial deposition of C3 and C9 occurs in Cfh–/– mice. No deposition of C3 or C9 is seen in wild-type mice.

22. Glomerular C3 deposition preceded the appearance of GBM dense deposit which preceded the histological light microscopic appearance of MPGN. • MPGN II was totally dependent on C 3 activation. • Generation of mice deficient in factors H and factor B prevented C3 activation and prevented the development of MPGN

23. Capillary wall deposition of C3 can be seen in Cfh–/–Bf+/– mice but is absent in Cfh–/–Bf–/– littermates. Age-matched healthy Cfh–/– mice show capillary wall deposition of C3 and C9. Before the developmentof MPGN, no IgG deposition is evident in the kidneys of Cfh–/– mice.

24. Pickering et al. Prevention of C5 activation ameliorates spontaneous and experimental glomerulonephritis in factor H-deficient mice. Proc Natl Acad Sci U S A. 2006 June 20; 103(25): 9649–9654. • In another study, Pickering et al. prevented C5 activation by crossing factor H- deficient mice with C 5 deficient animals. • No prevention in the development of the GBM deposits. • Reduction in glomerular cellularity, serum creatinine levels and mortality.

25. Reduction in glomerular cellularity, serum creatinine levels and mortality in Cfh-/- C5-/- mice.

26. Uncontrolled activation of C3 in plasma is essential for the development of MPGN II • Factor H deficiency • IgG autosomal Ab (C3NeF): binds to and stabilizes the Alternative Pathway C3 Convertase  enhanced Alternative Pathway activation. • Inherited dysfunctional C3 molecules: C3 convertase are resistant to inhibiton by factor H  Enhanced AP activation. - Linshaw M.A., et al. Hypocomplementemic glomerulonephritis in an infant and mother. Evidence for an abnormal form of C3. Am. J. Nephrol. 1987;7:470–477 - Schena FP et al. Biological significance of the C3 Nephritic factor in membranoproliferative Glomerulonephritis. Clin Nephrol 1982; 18:240-6

27. Alternative Pathway C3(H2O) H2O + C3 + f B LPS C3NeF Stabilized, C3 Convertase. Auto-antibody attaches to convertase C3(H2O)Bb (C3 Convertase) C3(H2O)B f D C3a H C3b + f B C3bB IgG-C3bB- Properdin MCP CD46 CR1 H H f D IgG-C3b- Properdin f B + Amplification Loop Factor I i C3b + C3f Factor I C3dg + C3c n C3b IgG-C3bBb-Properdin (C3 Convertase) H H n C3

28. Factor I • 88 k-Da serine protease • Function: inactivation of C3b • Inactivation of C3b in 2 steps: • Step 1: Factor I cleaves the α-chain of C3b at 2 sites, releasing C3f and forming i C3b. Cofactors: Factor H, MCP, CD 46, CR1. - Step 2: Factor I further cleaves iC3b to produce C3dg & C3c.

29. Appel et al. Membranoproliferative Glomerulonephritis Type II (Dense Deposit Disease) An update. J Am Soc Nephrol 16: 1392-1404, 2005. doi: 10.1681

30. Factor I inhibits C3b  inhibits the C3 convertase of the alternative pathway  limits the alternative pathway amplification. • Factor I deficiency: Uncontrolled AP activation • Depletion of C3, Factor B & Properdin • High C3b • Reduction of Factor H levels (due to formation of factor H- C3b complexes) NEVER ASSOCIATED WITH MPGN 2 !

31. Study Purpose • MPGN2 has never been reported in individuals with Factor I deficiency • To determine why uncontrolled C3 activation in the context of factor I deficiency does not result in MPGN II.

32. Cf i -/- mice were produced (disrupted the gene encoding factor I, by deleting exon 4 of the Cfi gene with a gene-targeting replacement vector).

33. C3 level Cfi -/- : Low Cfi +/ - : normal Cfi +/+ : normal Factor H level Cfi -/- : Low Cfi +/ - : normal Cfi +/+ : normal Factor B level Cfi -/- : Low Cfi +/ - : normal Cfi +/+ : normal ResultsComplement analysis

34. Complement analysis in Cfi-/- mice Plasma C3, factor H and factor B levels in Cfi deficient, Cfi+/–, and wild-type mice. Horizontal bars denote median values.

35. Western blot to determine the nature of plasma C3: C3 α chain 115 kDa C3b α’ chain 110 kDa ß chain 55-60 kDa • Cfi -/- : HMW bands ( aggregates of C3b) present C3c not detectable • Cfi +/+: HMW bands ( aggregates of C3b) absent C3c Detectable

36. Western blot from wild-type and Cfi–/– mice: (D) α′-chain(C3b) derived from Cfi–/– plasma ran at approximately 110 kDa. α-chain(C3) derived from wild-type plasma 115 kDa (E) C3c was detectable only in plasma derived from wild-type mice, as evident by the presence of 130-kDa bands .

37. MPGN2 development • Monitored cohorts of wild type, Cfi+/- and Cfi-/- mice over an 8 month period at which time all were sacrificied and renal function and histology assessed. • No difference in plasma urea levels or albuminuria • No difference in glomerular hypercellularity. No capillary wall double contour. • More mesangial expansion and deposition of nodular hyaline material.

39. Light microscopic appearances of mesangial hyalinosis in 8-month-old Cfi–/– mice. PAS-stained glomerular sections from 8-month-old wild-type (A) and Cfi–/– mice (B and C). The glomerulus from the wild-type mouse had normal appearances. In contrast, areas of mesangial expansion with a nodular hyaline appearance were evident in the Cfi–/– mice (arrows). Original magnification, ×40 (B); ×100(A and C).

40. Glomerular C3 staining in Cfi-/- mice : • Increased glomerular C3 staining in Cfi-/- mice but MESANGIAL in distribution. • Linear capillary wall staining pattern in age matched Cfh-/- animals. • Glomerular Ig G staining did not differ between Cfi-/- and wild type mice.

41. Glomerular C3 staining in 8-month-old Cfi–/– mice. (A) Increased glomerular C3 staining in Cfi–/– mice, with mesangial in distribution. (B) linear capillary wall staining pattern in Cfh–/– mice.(C) Glomerular C3 staining in Cfi+/– mice is identical to the wild-type animals (D). (E) Quantification of the glomerular C3 staining confirmed significantly increased glomerular C3 in the Cfi deficient mice

42. Cfi-/- mice developed increased mesangial C3 staining but not deposition of C3 along GBM • Factor I is an absolute requirement for GBM C3 deposition and the development of MPGN II in Cfh-/- mice • Glomerular staining patterns in Cfi-/- mice with either heterozygous or homozygous factor H deficiency

43. Glomerular C3 staining in Cfi–/– mice with normal (Cfh+/+), heterozygous (Cfh+/–), and homozygous (Cfh–/–) factor H genotypes. A mesangial staining pattern was evident in the glomeruli of the Cfi–/– mice regardless of factor H genotype.

44. Factor I deficiency prevented accumulation of C3 along the GBM in Cfh-/- mice. • Light Microscopy: No evidence of MPGN2 in 8 month old Cfh-/- Cfi-/- mice.

45. Factor H deficient mice (cfh -/-) - Florid C3 deposition along GBM/ MPGN2 occurred • Factor I deficient mice (cfi -/-) Uncontrolled AP - Did not develop C3 deposition /MPGN2 • Factor H & Factor I deficient (cfh -/-, cfi -/-) Uncontrolled AP - Did not develop C3 deposition/MPGN2

46. Plasma C3 (B) and factor B (C) levels in Cfi–/– mice with heterozygous and homozygous factor H deficiency. C3 level is lowest in Cfh-/- mice. Factor B level is equally low in all types.

47. Plasma analysis: (cfi -/-): C3b (cfh -/-) : C3b cleavage products (cfi -/- , cfh -/-): C3b • Addition of Factor I: (cfi-/-),(cfi-/-,cfh-/-) + Factor I  C3b fragments in plasma. • Plasma analysis

48. Western blot for C3 from Cfi–/– and Cfi–/–Cfh–/– mice under reducing conditions show α′-chain and HMW bands. Fragments were only present in the Cfh–/– EDTA plasma . Sera from Cfi–/– and Cfi–/–Cfh–/– mice before and after incubation with murine sera deficient in C3 (as a source of autologous factors I and H) show complete cleavage of the α′-chain with the concomitant appearance of the α′-chain fragment

49. Under nonreducing conditions C3c was detectable in EDTA plasma from Cfh–/– and wild-type mice, but not from Cfi–/– mice.

50. Following injections of sera from Cfh–/–C3–/– mice (used as a source of autologous factor I) to mice with combined deficiency of factor H and factor I. plasma C3 levels fell rapidly to levels comparable with those seen in mice with factor H deficiency alone