Abstract
Background
C3 glomerulopathy (C3G) is defined by dominant glomerular deposition of C3 and minimal or no immunoglobulin, with two subtypes—dense deposit disease (DDD) and C3 glomerulonephritis (C3GN)—distinguished by features on electron microscopy (EM). Given that this rare disease has generally unfavorable yet highly variable outcomes, we sought out to review the histopathology, complement/genetic studies, and renal outcomes of pediatric patients with C3G at our institution.
Methods
All native kidney biopsies performed in a single pediatric hospital over a 10-year period were reviewed for features of C3G. Of 589 biopsy reports, we identified 9 patients fulfilling the diagnostic criteria for C3G and retrospectively reviewed their clinical chart and renal biopsy findings.
Results
We identified 4 patients with DDD, 4 with C3GN, and 1 indeterminate case, with features of both C3GN and DDD. Five patients were positive for one or more nephritic factors (C3NeF, C4NeF, C5NeF) with 1 patient additionally positive for complement factor H (CFH) autoantibody. Genetic testing done in 5 of the 9 patients failed to identify any causative mutations. Three patients showed progressive renal dysfunction over a mean follow-up period of 33 months.
Conclusions
Complement and genetic studies are now routinely recommended for patients with a histopathological diagnosis of C3G. Careful interpretation of these studies and their prognostic and therapeutic implications in conjunction with biopsy findings is needed to further understand the pathophysiology of this rare disease in children.
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Introduction
Though defined by its characteristic histology, C3 glomerulopathy (C3G) has emerged as a disease process primarily driven by abnormal complement activation, deposition, and/or degradation. Renal biopsy findings demonstrate predominant glomerular C3 fragment deposition, with C3 immunofluorescence (IF) at least two orders of magnitude brighter than any other immune reactant and electron-dense deposits on EM [1, 2]. Dense deposit disease (DDD) and C3 glomerulonephritis (C3GN) are subsets of C3G, both of which are defined by dominant C3 IF staining. While heterogenous histologic changes are seen by light microscopy, distinction between the two entities is made by EM [3]. In DDD, there is hyperosmiophilic, electron-dense transformation of the lamina densa of the glomerular basement membrane. In C3GN, mesangial and/or glomerular basement membrane deposits are present in variable combinations of subepithelial, subendothelial and/or less dense, discontinuous intra-membranous deposits [4, 5]. The pathogenesis of C3G includes dysregulation of the complement alternative pathway (AP). Identification of genetic mutations, circulating autoantibodies, and/or abnormal complement profiles is somewhat heterogenous, and the etiology has generally been considered to be unknown in most patients [6].
C3G is considered an ultra-rare disease, with an estimated incidence of 1–2 per million per total population and is responsible for 3–5% of all pediatric nephrotic syndromes [7,8,9]. Histological recurrence post-transplant occurs in C3G and DDD and has been reported as possibly universal in DDD [3], which can lead to graft loss in a high percentage of patients making it a potentially devastating disease for children. Previous publications describing C3G have largely incorporated children and adults together, with limited pediatric centered studies detailing serologic and genetic complement data [8, 10,11,12,13,14,15]. For instance, Servais et al. reported that 17 out of 29 DDD patients and 14 out of 56 C3GN patients in their study were children and found progression to end-stage kidney disease (ESKD) and low serum C3 were reportedly more common in DDD compared to C3GN [16]. Recent research by Bomback et al. involving pediatric and adult patients found no differences between DDD and C3GN in progression to CKD and low C3 at diagnosis, with 3 out of 24 DDD patients and 32 out of 87 C3GN patients in their study < 18 years old [17]. These studies both included autoantibody and genetic testing and consistently identified complement regulatory genes and acquired autoantibodies in patients with C3G, including C3NeF, which stabilizes the AP C3 convertase, preventing its inactivation. However, there have been considerable advances in complement pathway assays, with increased numbers of autoantibodies and pathogenic mutations identified. Since standardized serologic and genetic testing for inherited and acquired abnormalities of AP of complement has only recently become common practice, with limited data in pediatric C3G patients, we sought to retrospectively review this information along with a comprehensive histopathological analysis for all cases of pediatric C3G at our single institution over a 10-year period. Our inclusion of available complement studies enhances identification of underlying abnormalities, which is necessary in larger studies to contribute to guiding treatment, predicting outcomes, and facilitating development of complement-directed therapeutics.
Materials and methods
Patient selection
Using the natural language processing tool in Cerner electronic medical record software a search was conducted to retrieve renal biopsies accessioned at Children’s Health Dallas from April 2007 through February 2017. The following terms were used for the search: membranoproliferative glomerulonephritis, membranoproliferative glomerulonephritis with dominant C3, dense deposit disease, acute diffuse proliferative glomerulonephritis, diffuse proliferative glomerulonephritis, endocapillary proliferative glomerulonephritis, post-streptococcal glomerulonephritis, and post-infectious glomerulonephritis. All cases with one or more of these terms in the original final diagnosis, and C3 dominant staining (defined as ≥ 2 orders of magnitude more than any other immune reactant on a semiquantitative scale of 0–4) by routine IF evaluation were included for use in the study. All retrieved cases were examined by two pathologists (N.E. and A.R.H.) to confirm that they met inclusion criteria, thus satisfying pathologic criteria for a diagnosis of C3G. The study was approved by the UT Southwestern Institutional Review Board having met all applicable requirements.
Biopsy sample processing techniques
All cases were processed by light, IF, and EM using standard techniques [18]. Kidney biopsy samples were fixed in buffered formalin, dehydrated in graded alcohols, and embedded in paraffin using standard methods. Serial 3-mm-thick sections were cut and treated with hematoxylin and eosin (H and E), Jones methenamine silver, Masson trichrome, and periodic acid–Schiff (PAS) reagent.
Samples submitted for IF studies were transported in Michel’s or other acceptable transport medium, washed in buffer and frozen in a cryostat. Sections, cut at 4 μm, were rinsed in buffer and reacted with fluorescein-tagged polyclonal rabbit anti-human antibodies to immunoglobulin (Ig) G, IgA, IgM, C3, C1q, albumin and fibrinogen [Agilent (formerly Dako), Carpenteria, CA] for 1 h, rinsed and a coverslip applied using aqueous mounting media. The staining intensity was graded 0 to 4+ on a semiquantitative scale.
EM was performed on specimens submitted for ultrastructural examination. The specimen was dehydrated using graded alcohols, and embedded in epon resin. Sections 1 mm thick were cut using an ultramicrotome, stained with toluidine blue and examined with a light microscope. Thin sections were examined in a Hitachi H-7500 transmission electron microscope. Photomicrographs were routinely taken at varying magnifications.
Clinical data collection
Clinical and laboratory data at the time of the first renal biopsy were manually obtained through retrospective chart review and included age, sex, ethnicity/race, presenting symptoms, family history of renal disease, serum creatinine, serum albumin, serum C3 and C4, and serum antibodies (anti-streptolysin-O titer ASOT, ANA, ANCA, dsDNA). Hematuria was defined by urine dipstick analysis and/or > 4 RBCs/hpf. Proteinuria was defined by the protein-creatinine ratio (g/g) in spot urine > 0.2. Estimated glomerular filtration rate (GFR) was determined using the revised Schwartz equation. When performed, complement autoantibodies, assays for complement biomarkers, and genetic screening results were obtained, with performing laboratories, detailed methods and established reference ranges for each test detailed in Table 3 and in supplementary material.
Results
Clinical features and laboratory findings
Out of 589 total native kidney biopsies examined from April 2007 through February 2017, eleven biopsy specimens from nine patients met inclusion criteria. Four patients (1 male, 3 female) had DDD, four patients (2 male, 2 female) had C3GN, and one patient (male) was deemed indeterminate based upon overlapping features seen by EM. The clinical and laboratory findings are described in Table 1. Of the 9 patients included in our study, mean age at diagnosis was 11 years (range 8–16), and 55% were females. All patients presented with hematuria and proteinuria. At onset, 2 patients with DDD presented with decreased kidney function (eGFR < 90 ml/min/1.73 m2). The mean follow-up was 33 months (range 2–120). Three patients showed progressive renal dysfunction (defined as declining eGFR < 90 ml/min/1.73 m2), including 2 patients with DDD (1 of whom required a kidney transplant) and 1 patient with C3GN and thrombotic microangiopathy (TMA) on the patient’s initial biopsy. Upon review of available records for this patient (including CBC done at the time of the biopsy and serial CBCs over the next 24 months), the patient had mild anemia (Hgb ranging from 10 to 12) without thrombocytopenia (platelets ranged from 233,000 to 320,000), thus lacking clinical manifestations of TMA.
Kidney biopsy findings
The complete kidney biopsy findings are summarized in Table 2. Six cases had weakly positive Ig staining by IF, but all met inclusion criteria with dominant C3 IF staining. EM studies showed mesangial and glomerular capillary wall electron-dense deposits in all biopsies of C3GN, and highly electron-dense intra-membranous deposits in all biopsies of DDD. Chronicity was minimal with all cases showing 0–10% interstitial fibrosis and tubular atrophy. All initial biopsies at our institution showed a membranoproliferative pattern of injury, except patient 1 whose biopsy showed a diffuse endocapillary proliferative and exudative glomerulonephritis with focal (10%) necrotizing crescents and medullary angiitis by light microscopy; representative kidney biopsy findings are shown in Figs. 1 and 2. Medullary angiitis has been reported in other causes of acute glomerulonephritis, but not in C3G to our knowledge [19].
Patient 7 also had focal crescents. C3G with a crescentic phenotype has been previously described [10]; however, the extent of crescent formation they reported was greater than that seen in our two patients.
Patient 8 had features of TMA by EM, including fibrin tactoids and expansion of subendothelial spaces by electron-lucent material (Fig. 2d). Features of TMA were not seen by light microscopy.
Patient 6 was classified as “indeterminate” due to EM, which showed subepithelial, subendothelial, and mesangial electron-dense deposition in addition to segmental ribbon-like highly electron-dense intra-membranous deposits.
Infection-related glomerulonephritis was clinically suspected in three patients prior to biopsy based upon clinical symptoms or laboratory parameters; however in these patients, the C3 remained persistently low at least 6 weeks or greater and was the indication for biopsy. The presence of subepithelial “hump-shaped” deposits was identified by electron microscopy in three patients (cases 1, 4, and 6). Streptococcal infection may precede the development of C3G and “hump-shaped” subepithelial deposits are commonly seen in both infection-related GN and C3G [1, 20].
Patients 7 and 8 received follow-up biopsies at 72 and 29 months post initial biopsy, respectively. Repeat biopsies showed proliferative features and only patient 7’s biopsy showed significant disease progression, with chronic injury characterized by severe interstitial fibrosis and tubular atrophy. Patient 7’s allograft biopsy 30 days post-transplant showed no evidence of recurrent disease.
Evaluation of complement profiles and genetic testing
Four patients had extensive complement-profiling performed, which revealed variable abnormalities in the AP as shown in Table 3. Five patients in this study had limited or no complement evaluation including patient 7 who was the only one to have CFH autoantibodies.
Genetic testing done in 5 of the 9 patients failed to identify any causative mutations. Of note, 3 patients had variants of unknown significance (VUS) identified. Specifically, patient 2 had a heterozygous VUS in the gene ADAMTS13 (c.3287G>A,p.Arg1096His) not predicted to be pathogenic, and patient 4 also had a heterozygous VUS in gene ADAMTS13 (c.2936G>A,p.Arg979Gln) predicted to be pathogenic. Patient 8 had a heterozygous variant in the gene CFI (c.1354G>A,p.Ala452Thr) reported as a VUS though predicted to be pathogenic. Mutations in CFI, along with CFH and membrane cofactor protein (MCP) genes, have been described in association with C3G and atypical hemolytic-uremic syndrome (aHUS) [7, 21, 22].
Treatment and follow-up
All patients were treated with renin-angiotensin blockade (either with ACE inhibitors or angiotensin receptor II blockers), with 2 patients (patients 2 and 6) treated solely with these agents without disease progression. Six patients (patients 1, 3, 4, 5, 8, and 9) received steroids, four of whom (patients 1, 3, 5, and 8) were additionally treated with mycophenolate mofetil (MMF) at their initial diagnosis. Patient 8 also received tacrolimus, with doses outlined in Table 1.
Follow-up ranged from 2 months to 10 years after initial renal biopsy with a mean follow-up of 11 months. Patient 1 presented with significant renal impairment (eGFR of 30 ml/min/1.73 m2) with DDD and crescents on her initial biopsy; however, after treatment with steroids and MMF, her kidney function normalized. Three patients, two with DDD (patients 7 and 9) and one with C3GN (patient 8) showed significant decline in renal function. Despite treatment with steroids, MMF, and rituximab, patient 7 developed end-stage kidney disease, requiring peritoneal dialysis for 32 months until receiving a deceased donor renal allograft. Patient 9, also with DDD, was treated with steroids alone and showed progressive kidney disease, with eGFR declining from 93 ml/min/1.73 m2 to 72 ml/min/1.73 m2 over a period of 2 months. Patient 8, with C3GN, was treated with steroids, MMF, prograf, and rituximab, with continued proteinuria and decline in renal function at last follow-up from 125 ml/min/1.73 m2 to 49 ml/min/1.73 m2 (46 months).
Discussion
In this study, we describe the clinical features, kidney biopsy findings, complement abnormalities, and course of 9 pediatric patients with C3G. Since the entity of C3G was defined in 2013, a complete evaluation with genetic testing, autoantibody screening, and complement function assays are routinely recommended. However, how these findings correlate with prognosis, response to treatment, and variations observed on renal biopsy remain unknown, particularly in the pediatric population.
C3G is defined by histopathological findings of dominant glomerular C3 deposition (two orders of magnitude greater than any other immune reactant); other glomerular diseases may occasionally satisfy “C3-dominant deposition with scanty immunoglobulins” including post-infectious glomerulonephritis (PIGN) [23]. Our study re-examined 589 biopsies and found one patient that was re-classified as C3G following our review. Also, several biopsies in this small case series identified unusual pathological findings after detailed review of the initial biopsies, highlighting the diagnostic challenges of this disease.
Previous studies have identified causative genetic variants and/or acquired factors that dysregulate the complement AP in only a subset of patients, leaving the etiology of disease unknown for many [24]. We report evidence of complement dysregulation in all 6 patients that underwent complement profile testing. Of the 5 patients who underwent genetic testing, no causative variants were identified. Now that this testing is more readily available, clinicians must be versed in ordering and interpreting such studies. While complement profile abnormalities were detected, no single marker was consistent across all patients tested. Larger studies with extensive complement testing are necessary to investigate the clinical significance of individual markers, and further studies are needed to understand if the presence of multiple autoantibodies/nephritic factors are clinically and/or prognostically significant. As previously reportedly, one of the most significant pathogenic factors in C3G is autoantibody against the C3 convertase of the AP (C3NeF): subsequent studies have shown additional nephritic factors driving disease. Although our sample size is small and not all patients were screened for C4NeF, two patients with C3GN were found to have the presence of both C3Nef and C4NeF. Zhang et al. studied 168 adults (age range 17–44 years) with C3G and found C4NeF present in approximately 3%, including 3 with C3GN and 1 with DDD. In the C4NeF positive patients with C3GN, 1 had autoantibodies to FH, and 1 was positive for C3NeF [3]. A recent study by Marinozzi et al. investigated C3NeF and C5NeF in C3G. The authors found that out of 59 tested, 29% were positive for C3NeF only, 10% were positive for C5NeF only, and 39% were positive for both. The authors found that children who were double positive had a better outcome than those who were double negative [25]. Two of our DDD patients (1 and 5) were also double positive. Both had persistent hematuria and proteinuria but saw improvement in eGFR.
There are several limitations to this study. The sample size is small compared to studies that include pediatric and adult patients. Currently, there is no standardized treatment for C3G and with highly variable outcomes; one cannot make predictions regarding prognostic factors for kidney disease progression. Given that it was done retrospectively, genetics and complement profiles were not completed on all patients reported. While established clinical laboratories were utilized for complement studies and genetic testing, this was not standardized, and some tests were not performed in all of the patients.
In conclusion, we present an entirely pediatric cohort of C3G patients, including their clinical presentation, renal biopsy features, results of complement investigation studies, and renal outcome. Genetic testing, autoantibody assays, and complement pathway functional assays are now routinely recommended in the evaluation of patients with a histopathological diagnosis of C3G. The outcome of patients with C3G at this time remains heterogeneous with poor predictive markers for progression of kidney disease. Thus, large, prospective, multi-institutional studies are needed to elucidate the prognostic and therapeutic implications of these varied complement abnormalities of this rare disease in children.
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Drake, K.A., Ellington, N., Gattineni, J. et al. Clinicopathological features of C3 glomerulopathy in children: a single-center experience. Pediatr Nephrol 35, 153–162 (2020). https://doi.org/10.1007/s00467-019-04388-3
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DOI: https://doi.org/10.1007/s00467-019-04388-3