Membranoproliferative glomerulonephritis with C3NeF and genetic complement dysregulation

The development of membranoproliferative glomerulonephritis (MPGN) is associated with uncontrolled activation of the complement alternative pathway. This dysregulation is related either to C3 nephritic factor (C3NeF), an auto-antibody directed against the alternative C3 convertase, or to homozygous loss-of-function mutation of the complement regulatory protein factor H. Heterozygous mutations in the genes coding for factor H, or for the other alternative pathway inhibitory proteins factor I and membrane cofactor protein, have recently been identified in a small number of patients with MPGN with exclusive C3 deposits. We report three hypocomplementemic children with dense deposit disease (n = 1) or immune-complex-mediated MPGN type I (n = 2), associated with both C3NeF activity and heterozygous mutation of factor H or factor I. These observations highlight the possible combination of genetic and acquired defect in complement control in various subtypes of MPGN, a finding that may influence the treatment strategy in some patients.     

Binding of factor H to tubular epithelial cells limits interstitial complement activation in ischemic injury

Factor H is a regulator of the alternative pathway of complement, and genetic studies have shown that patients with mutations in factor H are at increased risk for several types of renal disease. Pathogenic activation of the alternative pathway in acquired diseases, such as ischemic acute kidney injury, suggests that native factor H has a limited capacity to control the alternative pathway in the kidney. Here we found that an absolute deficiency of factor H produced by gene deletion prevented complement activation on tubulointerstitial cells after ischemia/reperfusion (I/R) injury, likely because alternative pathway proteins were consumed in the fluid phase. In contrast, when fluid-phase regulation by factor H was maintained while the interaction of factor H with cell surfaces was blocked by a recombinant inhibitor protein, complement activation after renal I/R increased. Finally, a recombinant form of factor H, specifically targeted to sites of C3 deposition, reduced complement activation in the tubulointerstitium after ischemic injury. Thus, although factor H does not fully prevent activation of the alternative pathway of complement on ischemic tubules, its interaction with the tubule epithelial cell surface is critical for limiting complement activation and attenuating renal injury after ischemia.     

MPGN II – genetically determined by defective complement regulation?

MPGN II is a rare disease which is characterized by complement containing deposits within the GBM. The disease is characterized by functional impairment of the GBM causing progressive loss of renal function eventually resulting in end stage renal disease.It now becomes evident that in addition to C3NeF, which inhibits the inactivation of the alternative C3 convertase C3bBb, different genetically determined factors are also involved in the pathogenesis of MPGN II. These factors though different from C3NeF also result in defective complement regulation acting either through separate pathways or synergistically with C3NeF. Following the finding of MPGN II in Factor H deficient animals, patients with MPGN II were identified presenting with an activated complement system caused by Factor H deficiency. Factor H gene mutations result in a lack of plasma Factor H or in a functional defect of Factor H protein. Loss of Factor H function can also be caused by inactivating Factor H autoantibodies, C3 mutations preventing interaction between C3 and Factor H, or autoantibodies against C3. Identification of patients with MPGN II caused by defective complement control may allow treatment by replacement of the missing factor via plasma infusion, thus possibly preventing or at least delaying disease progress.     

Deletion of Lys224 in regulatory domain 4 of Factor H reveals a novel pathomechanism for dense deposit disease (MPGN II)

We report a novel pathomechanism for membranoproliferative glomerulonephritis type II (MPGN II) caused by a mutant Factor H protein expressed in the plasma. Genetic analyses of two patients revealed deletion of a single Lys residue (K224) located within the complement regulatory region in domain 4 of Factor H. This deletion resulted in defective complement control: mutant protein purified from the plasma of patients showed severely reduced cofactor and decay-accelerating activity, as well as reduced binding to the central complement component C3b. However, cell-binding activity of the mutant protein was normal and comparable to wild-type Factor H. The patients are daughters of consanguineous parents. As both patients but also their healthy mother were positive for C3 nephritic factor, the mutant Factor H protein is considered relevant for unrestricted activation of the disease-causing activation of the alternative complement pathway. Replacement of functional Factor H by fresh frozen plasma (10-15 ml/kg/14 days) was well tolerated, prevented so far disease progression in both patients, and is in the long run expected to preserve kidney function.     

Membranoproliferative glomerulonephritis type II (dense deposit disease): an update

Membranoproliferative glomerulonephritis type II (MPGN II) is a rare disease characterized by the deposition of abnormal electron-dense material within the glomerular basement membrane of the kidney and often within Bruch's membrane in the eye. The diagnosis is made in most patients between the ages of 5 and 15 yr, and within 10 yr, approximately half progress to end-stage renal disease, occasionally with the late comorbidity of visual impairment. The pathophysiologic basis of MPGN II is associated with the uncontrolled systemic activation of the alternative pathway (AP) of the complement cascade. In most patients, loss of complement regulation is caused by C3 nephritic factor, an autoantibody directed against the C3 convertase of the AP, but in some patients, mutations in the factor H gene have been identified. For the latter patients, plasma replacement therapy prevents renal failure, but for the majority of patients, there is no proven effective treatment. The disease recurs in virtually all renal allografts, and a high percentage of these ultimately fail. The development of molecular diagnostic tools and new therapies directed at controlling the AP of the complement cascade either locally in the kidney or at the systemic level may lead to effective treatments for MPGN II.     

Genetics and complement in atypical HUS

Central to the pathogenesis of atypical hemolytic uremic syndrome (aHUS) is over-activation of the alternative pathway of complement. Following the initial discovery of mutations in the complement regulatory protein, factor H, mutations have been described in factor I, membrane cofactor protein and thrombomodulin, which also result in decreased complement regulation. Autoantibodies to factor H have also been reported to impair complement regulation in aHUS. More recently, gain of function mutations in the complement components C3 and Factor B have been seen. This review focuses on the genetic causes of aHUS, their functional consequences, and clinical effect.     

Rare case of spot diagnosis of nephrotic syndrome in a Saudi male

A 26- year- old Saudi male school teacher presented with clinical features of nephrotic syndrome. Physical examination revealed loss of subcutaneous fat over the face and upper arms (partial lipodystrophy) and drusen in both eyes. The serum level of complement C3 was low, with normal C4. Renal biopsy revealed features consistent with membranoproliferative glomerulo- nephritis (MPGN) type II [Dense Deposit Disease (DDD)]. He was treated with prednisolone and mycophenolate mofetil with partial remission. He also received lipitor and lisinopril. The occurrence of partial lipo- dystrophy and drusen in a patient with nephrotic syndrome provides a rare clinical opportunity of making a bedside diagnosis of type II MPGN even before kidney biopsy.     

Membranoproliferative glomerulonephritis: pathogenetic heterogeneity and proposal for a new classification

Membranoproliferative glomerulonephritis (MPGN) is a pattern of injury that results from subendothelial and mesangial deposition of Igs caused by persistent antigenemia and/or circulating immune complexes. The common causes of Ig-mediated MPGN include chronic infections, autoimmune diseases, and monoclonal gammopathy/dysproteinemias. On the other hand, MPGN also can result from subendothelial and mesangial deposition of complement owing to dysregulation of the alternative pathway (AP) of complement. Complement-mediated MPGN includes dense deposit disease and proliferative glomerulonephritis with C3 deposits. Dysregulation of the AP of complement can result from genetic mutations or development of autoantibodies to complement regulating proteins with ensuing dense deposit disease or glomerulonephritis with C3 deposits. We propose a new histologic classification of MPGN and classify MPGN into 2 major groups: Ig-mediated and complement-mediated. MPGN that is Ig-mediated should lead to work-up for infections, autoimmune diseases, and monoclonal gammopathy. On the other hand, complement-mediated MPGN should lead to work-up of the AP of complement. Initial AP screening tests should include serum membrane attack complex levels, an AP functional assay, and a hemolytic assay, followed by tests for mutations and autoantibodies to complement-regulating proteins.     

C3 nephritic factor and mesangiocapillary glomerulonephritis

The association of a C3 splitting activity, known as C3 nephritic factor (C3NeF), with mesangiocapillary glomerulonephritis (MCGN), especially MCGN type II, has long been known. Several forms of C3NeF are now recognised, the main one being an IgG which acts as an autoantibody binding to factor H, a normally occurring component of the complement system. Complement is in a continuous state of activation with inbuilt checks and controls, and factor H plays a very important part in the controlling mechanisms by preventing the overwhelming activation of complement at the stage of C3 conversion. C3NeF binds to factor H, thus preventing its inhibitory action, and allowing complement activation to proceed with, in vivo, the well-known consequences in MCGN of very low serum levels of C3. The question naturally arose whether C3NeF causes MCGN. Complex relationships between MCGN, C3NeF and partial lipodystrophy, also characterised by C3NeF and hypocomplementaemia, but preceding the development of MCGN, suggest that hypocomplementaemia predisposes to MCGN. Another possibility is that C3NeF acts directly within glomeruli to cause local complement activation and ensuing damage. Neither possibility could be resolved, but some recent observations have restimulated interest in a possible causative role for C3NeF in MCGN. First, factor H deficiency, by mechanisms other than blocking by C3NeF, in animals and man is associated with MCGN. Second, adipocytes, now known themselves to produce complement system proteins, are lysed in vitro by C3NeF, thus suggesting a mechanism for partial lipodystrophy. By analogy, the C3NeF may produce glomerular damage, as glomerular cells produce complement components. Received July 18, 1996; accepted July 24, 1996     

The alternative pathway C3 convertase and glomerular deposits

Five conditions in which the alternative pathway C3 convertase, C3b,Bb, circulates in excess as a result of factor H dysfunction are frequently accompanied by nephritis. These convertase-related nephritides are seen in association with heterozygous absence of a binding site for factor H on C3b (Marder disease), homozygous factor H deficiency, circulating factor H inhibitor, and with the nephritic factors, one of the amplification loop and the other of the terminal pathway, found in membranoproliferative glomerulonephritis (MPGN) types II and III, respectively. Observations which relate convertase to glomerular deposits are: (1) in MPGN type II, subepithelial deposits on the paramesangial segments of the glomerular basement membrane are with high frequency present in patients hypocomplementemic at biopsy, but not in those normocomplementemic; (2) in MPGN type III paramesangial deposits are similarly found with hypocomplementemia but are present for up to 1 year after normocomplementemia is achieved; (3) in MPGN type III, subendothelial deposits are present only with hypocomplementemia. The principal deposits foundin factor H deficiency and in Marder disease are also paramesangial. Differences in the incidence, severity, and morphology of the nephritides accompanying convertase in excess may relate to the characteristics of the circulating convertase and/or to the C3 conversion products formed by it. Received: 17 September 1998 / Accepted: 3 November 1998     

Inherited complement component deficiencies in membranoproliferative glomerulonephritis

Anecdotal reports of complement component deficiencies in patients with immune complex disease led to a systematic study of the levels of seven complement components in serum specimens from 178 patients with glomerulonephritis and 163 normal subjects. Deficiencies were found with significantly higher frequency (22.7%) among 44 patients with membranoproliferative glomerulonephritis (MPGN) types I and III, than among the normal subjects (6.7%, P less than 0.002) or among 134 patients with other glomerulonephritides (5.2%, P less than 0.001). The component deficiencies in MPGN were partial in nine patients and subtotal in one. They could not be ascribed to acquired hypocomplementemia or to a nephrotic syndrome. They were present over long periods, were found in family members, and involved C2, C3, factor B, C6, C7, and C8. Six were presumably the result of null structural genes, two were associated with a structurally abnormal component, and two were of unknown cause. The results give evidence that partial deficiency of one or more complement components is a factor predisposing to MPGN.     

Patterns of complement activation in idiopathic membranoproliferative glomerulonephritis, types I, II, and III

Complement profiles on 22 hypocomplementemic patients with membranoproliferative glomerulonephritis (MPGN) type I, on 11 with MPGN II, and on 16 with MPGN III, gave evidence that the nephritic factor of the amplification loop (NFa) is responsible for the hypocomplementemia in MPGN II and the nephritic factor of the terminal pathway (NFt) for the hypocomplementemia in MPGN III. In contrast, in MPGN I, there was evidence for three complement-activating modalities, NFa, NFt, and immune complexes. As a result, four different patterns of complement activation were seen. NFa, found in MPGN II, produces a complement profile characterized mainly by C3 depression. In addition, four of seven (57%) severely hypocomplementemic MPGN II patients (C3 less than 30 mg/dL) had slightly depressed levels of factor B, and one of seven (14%) of properdin, but in all the C5 concentration was normal. In contrast, all eight severely hypocomplementemic patients with MPGN II had depressed C5 and properdin levels, and six of eight (75%) depressed levels of C6, C7, and/or C9. Of eight MPGN III patients with moderate hypocomplementemia, 50% had depressed C5 and properdin levels and the remainder, depressed C3 only. This spectrum of profiles is most likely produced by varying concentrations of NFt. In MPGN I, nine of 23 (39%) had a profile indicating only classical pathway activation; seven of 23 (39%), a pattern compatible with NFt alone; four of 23 (9%), evidence for both classical pathway activation and NFt; and three of 23 (13%), a pattern compatible with NFa. The unique multifactorial origin of the hypocomplementemia in MPGN I, often giving evidence of classical pathway activation, together with previously reported differences in glomerular morphology and clinical features at onset, makes it distinct from MPGN III. Depressed C8 levels were found to some extent in all hypocomplementemic states. The levels were uncommonly depressed in patients with NFa, most markedly depressed with NFt, and moderately reduced with classical pathway activation. The cause is not known. Diagnostically, profiles showing classical pathway activation and low levels of C6, C7, and/or C9 are specific for MPGN I. Those showing only classical activation are likewise diagnostic of MPGN I if systemic lupus erythematosus (SLE) and chronic bacteremia are ruled out.     

Modulation of complement activation on hemodialysis membranes by immobilized heparin.

To determine the effects of surface-associated heparin on the capacity of hemodialysis membranes to activate complement, cellulose acetate (CA) membranes that were untreated and CA membranes that had been coated with heparin (HCA) were incubated with C3-depleted serum repleted with radio-labeled C3. Next, the proteins in the supernatant and those eluted from the membranes were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis. C3 activation was quantified by determining the radioactivity of the C3a-containing band in the gel. Total C3a generation (fluid phase C3a plus membrane-associated C3a) was three times greater in the presence of HCA compared with CA. Most (88%) of the C3a generated in the presence of HCA, however, was adsorbed onto the membrane surface. Consequently, there was more C3a in the CA supernatant than in the HCA supernatant. To determine the mechanism by which heparin enhanced alternative pathway activity, binding studies with radiolabeled factor B and factor H were performed. HCA bound 3.4 times more factor B and 20 times more factor H than did CA. The binding of these proteins, however, was not dependent on complement activation. Studies designed to test the functional activity of isolated factor H and factor B that had been adsorbed to the membrane showed that factor H was active on both CA and HCA, whereas factor B was active only on HCA. These data demonstrate that heparin immobilized onto CA hemodialysis membrane enhances C3 activation but produces low levels of C3a in the fluid phase because of high surface adsorption of the anaphylatoxin. Heparin appears to augment alternative pathway activity by favoring the interactions of factor B with other constituents of the amplification C3 convertase of the alternative pathway of complement.     

Recurrent haemolytic uraemic syndrome and acquired hypomorphic variant of the third component of complement

In a girl with recurrent haemolytic uraemic syndrome (HUS), persistently low serum levels of C3 were found. Analysis of complement phenotype revealed a hypomorphic variant of C3 Fast in the patient (C3fS) and a normal heterozygous pattern in both parents and the brother (C3FS). Other complement aberrations in the patient were: the presence of a null gene for C4A and C4B and low serum levels of factor H. The father also had partial factor H deficiency. It is hypothesized that the hypomorphic C3 variant may predispose to recurrent HUS. In the acquired forms the role of uraemia in alteration of C3F should be considered.     

Glomerular deposition of complement-control proteins in acute and chronic glomerulonephritis.

Acute poststreptococcal glomerulonephritis (AGN) differed from membranoproliferative glomerulonephritis (MPGN) and lupus nephritis (SLE) in that two of the proteins that control the C3b-dependent convertase, beta 1H and the C3bC4b-inactivator cofactor (C3bC4bICo), were frequently absent from the glomerular deposits. In addition, factor B was distributed with C3 in the capillary walls in hypocomplementemic AGN patients. From this, it can be assumed that C3bBb is in the deposits, uninhibited by control proteins as would be predicted for alternative pathway activation. Factor B could not be found in normocomplementemic AGN, was rarely present in MPGN, but was usually present in SLE, most often in the mesangium. In MPGN and SLE, the control proteins were nearly always present in the glomeruli in a distribution like that of C3; IN MPGN they were particularly abundant. Complement profiles indicated an occasional transient reduction in serum C4 level early in AGN. Thus, although there is occasional evidence of early classical activation in AGN, more characteristic is a long period of alternative activation. Serum levels of control proteins did not deviate greatly from normal except for reduced serum beta 1H levels in MPGN type I.     

Acquired and genetic complement abnormalities play a critical role in dense deposit disease and other C3 glomerulopathies

Dense deposit disease and glomerulonephritis with isolated C3 deposits are glomerulopathies characterized by deposits of C3 within or along the glomerular basement membrane. Previous studies found a link between dysregulation of the complement alternative pathway and the pathogenesis of these diseases. We analyzed the role of acquired and genetic complement abnormalities in a cohort of 134 patients, of whom 29 have dense deposit disease, 56 have glomerulonephritis with isolated C3 deposits, and 49 have primary membranoproliferative glomerulonephritis type I, with adult and pediatric onset. A total of 53 patients presented with a low C3 level, and 65 were positive for C3 nephritic factor that was significantly more frequently detected in patients with dense deposit disease than in other histological types. Mutations in CFH and CFI genes were identified in 24 patients associated with a C3 nephritic factor in half the cases. We found evidence for complement alternative pathway dysregulation in 26 patients with membranoproliferative glomerulonephritis type I. The complement factor H Y402H variant was significantly increased in dense deposit disease. We identified one at-risk membrane cofactor protein (MCP) haplotype for glomerulonephritis with isolated C3 deposits and membranoproliferative glomerulonephritis type I. Thus, our results suggest a critical role of fluid-phase alternative pathway dysregulation in the pathogenesis of C3 glomerulopathies as well as in immune complex-mediated glomerular diseases. The localization of the C3 deposits may be under the influence of MCP expression.     

C3 glomerulopathy: what's in a name?

Whereas early classifications of membranoproliferative glomerulonephritis (MPGN) were based on morphologic features, the modern approach is directed at immunofluorescence findings. Glomerular deposits of C3 alone, without immunoglobulin, are the hallmark of alternative complement pathway dysregulation through inherited or acquired defects. These immunoglobulin-negative forms are referred to as C3 glomerulopathy, which encompasses both dense deposit disease and C3 glomerulonephritis. Distinguishing C3 glomerulopathy from immunoglobulin-mediated MPGN is opening the way to better diagnostic, prognostic, and treatment algorithms.     

Hypocomplementemic glomerulonephritis in an infant and mother. Evidence for an abnormal form of C3

A mother developed hematuria during the fourth month of pregnancy, and her nursing infant son from this otherwise uncomplicated pregnancy developed hematuria at 3.5 months of age. Both had a mild glomerulonephritis characterized by mesangial prominence, focal thickening and mottling of the glomerular basement membrane and electron-dense deposits, predominantly in the intramembranous and subendothelial positions. Immunofluorescence studies revealed striking accumulations of C3 and other complement components associated with alternative complement pathway activation within glomeruli, and the presence of small or equivocal amounts of immunoglobulin. C1q, C4 and factor B were not detectable. The glomerular lesion was accompanied by hypocomplementemia. Sera of both mother and infant displayed half normal levels of C3 and factor B, increased levels of C4, and normal levels of 12 other complement proteins. High normal or slight elevation in nephritic factor-like activity was observed in serial serum samples. Studies suggested that this mother and son represent the second kindred having an abnormal form of C3 which produces an alternative complement pathway C3 convertase, C3b, Bb, resistant to control by factor H. No additional affected family members were identified. The course of the nephritis over 7 years without drug therapy has been mild with resolving hematuria and no abnormal proteinuria or decrease in creatinine clearance.     

Complete factor H deficiency-associated atypical hemolytic uremic syndrome in a neonate

Recent advances have shown that atypical hemolytic uremic syndrome (aHUS) is a disease of complement dysregulation. Almost 50% of cases are associated with mutations in the three complement regulatory genes, factor H (HF1), membrane co-factor protein (MCP) and factor I (IF). The corresponding gene products act in concert and affect the same enzyme, alternative pathway convertase C3bBb, which initiates the alternative pathway and amplification of the complement system. Factor H (FH) deficiency-associated aHUS usually occurs in infants to middle-aged adults and only rarely in neonates. Moreover, the vast majority of patients are heterozygous for the HF1 gene mutations. We report on a case of neonatal-onset aHUS associated with complete FH deficiency due to novel compound heterozygous mutations in the HF1 gene. A 22-day-old baby girl developed acute renal failure and a remarkably low serum complement C3 level, which was rapidly followed by the development of micro-angiopathic hemolytic anemia. Western blot analysis revealed nearly zero plasma FH levels, and an HF1 gene study showed compound heterozygous mutations, C1077W/Q1139X. Renal pathology findings were compatible with glomerular involvement in HUS. The baby recovered completely after the repetitive infusion of fresh frozen plasma. During follow-up (until she was 20 months old) after the initial plasma therapy, the disease recurred three times; twice after the tapering off of plasma therapy, and once during a weekly plasma infusion. All recurrence episodes were preceded by an upper respiratory tract infection, and were successfully managed by restarting or increasing the frequency of plasma therapy.