Abstract
Background
Autosomal recessive Alport syndrome (ARAS) is caused by pathogenic variants in both alleles of either COL4A3 or COL4A4 genes. Reports on ARAS are rare due to small patient numbers and there are no reports on renin-angiotensin-aldosterone system (RAAS) inhibition therapy in ARAS.
Methods
Retrospective study in 101 patients with ARAS from Chinese Registry Database of Hereditary Kidney Diseases and European Alport Registry. Genotype–phenotype correlations and nephroprotective effects of RAAS inhibition in ARAS were evaluated.
Results
Median age was 15 years (range 1.5–46 years). Twelve patients progressed to stage 5 chronic kidney disease (CKD5) at median age 20.5 years. Patients without missense variants had both higher prevalence and earlier onset age of hearing loss, nephrotic-range proteinuria, more rapid decline of eGFR, and earlier onset age of CKD5 compared to patients with 1 or 2 missense variants. Most patients (79/101, 78%) currently are treated with RAAS inhibitors; median age at therapy initiation was 10 years and mean duration 6.5 ± 6.0 years. Median age at CKD5 for untreated patients was 24 years. RAAS inhibition therapy delayed CKD5 onset in those with impaired kidney function (T-III) to median age 35 years, but is undefined in treated patients with proteinuria (T-II) due to low number of events. No treated patients with microalbuminuria (T-I) progressed to CKD5. ARAS patients with 1 or 2 missense variants showed better response to treatment than patients with non-missense-variants.
Conclusions
Our study provides the first evidence for early use of RAAS inhibition therapy in patients with ARAS. Furthermore, genotype in ARAS correlates with response to therapy in favor of missense variants.
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Introduction
Alport syndrome is a hereditary glomerular disease characterized by hematuria, proteinuria, and progressive kidney failure, usually accompanied with sensorineural hearing loss and ocular abnormalities [1,2,3,4]. To date, about 85% of patients are diagnosed with X-linked Alport syndrome (XLAS) caused by pathogenic variants in the COL4A5 gene [5, 6]. The remaining 15% of patients with Alport syndrome, in descending order of the number of cases reported, include autosomal recessive Alport syndrome (ARAS) caused by pathogenic variants in both alleles of either COL4A3 or COL4A4 genes [7,8,9], autosomal dominant Alport syndrome (ADAS) caused by heterozygous pathogenic variants in COL4A3 or COL4A4 genes [10, 11] and digenic Alport syndrome caused by coexisting pathogenic variants in COL4A3, COL4A4, or COL4A5 genes [12, 13].
Up to now, most reports on Alport syndrome describe patients with XLAS: age at stage 5 chronic kidney disease (CKD 5) strongly correlates with COL4A5 genotype in males with XLAS [14,15,16]. However, only a few reports describe patients with ARAS: a systematic review in 2019 included only 26 articles with 148 patients [17]. Furthermore, inhibition of the renin-angiotensin-aldosterone system (RAAS) by angiotensin-converting enzyme inhibitors (ACEi) or angiotensin receptor blockade (ARB) can delay kidney failure in both animal models and human patients with Alport syndrome [18,19,20,21]. Until now, no data has been reported on the effects of RAAS inhibition therapy in patients with ARAS. Therefore, this lack of sufficient data on therapeutic options in patients with ARAS led us to consider combining different international databases to enable researchers to analyze a large number of ARAS patients with long-term clinical course [22].
In this study, we describe the clinical and genetic characteristics in 101 patients with ARAS originating from the Chinese Registry Database of Hereditary Kidney Diseases and the European Alport Registry.
Methods
Patients
Patients with ARAS were selected from the Chinese Registry Database of Hereditary Kidney Diseases and the European Alport Registry. ARAS was diagnosed on either or both of the following two criteria, (i) kidney biopsy in young patients with typical changes of Alport syndrome, like splitting or lamellation in glomerular basement membrane (GBM), and both parents with hematuria or thin basement membrane nephropathy (TBMN) without proteinuria and CKD5; (ii) homozygous or compound heterozygous mutations (pathogenic variants) in COL4A3 or COL4A4 genes. Patients suspected of ARAS who had neither kidney biopsy nor genetic diagnosis, patients who had a heterozygous pathogenic variant in COL4A3 or COL4A4 genes, and patients who had coexisting variants in COL4A3 and COL4A4 genes were excluded.
Clinical data were retrospectively analyzed including gender, onset age of hematuria, proteinuria, estimated glomerular filtration rate (eGFR) decline and extra-renal manifestations, pathology of kidney biopsy and the age at kidney biopsy, results of genetic test, age at onset of CKD5, and RAAS inhibition therapy. Patients were categorized depending on number of missense variants and kidney function at initiation of RAAS inhibition therapy. Initiation of therapy was defined as follows:
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T-0 starts at patients with microhematuria only
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T-I starts at patients with microalbuminuria
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T-II starts at patients with proteinuria and eGFR ≥60 ml/min × 1.73m2
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T-III starts at patients with eGFR <60 ml/min × 1.73m2
The study was approved by the Ethical Committee of Peking University First Hospital (2016 [1179] V3.0), informed consent was obtained from the probands and their family members. The European Alport registry was approved by the Ethical Committee of the University Medical Center Goettingen (10/11/06).
Detection and definition of pathogenic variants
Genomic DNA samples from probands were tested for pathogenic variants by direct sequencing using the Sanger method for all exons and exon–intron boundaries of COL4A3 and COL4A4 genes (before 2014) and tested for all three Alport genes by targeted next-generation sequencing (NGS) or exome sequencing (since 2014). Sanger sequencing or qPCR (real-time quantitative PCR) was used to confirm the candidate pathogenic variants in probands and their family members. The pathogenicity of variants was assessed based on the ACMG classification and the expert consensus guidelines for the genetic diagnosis of Alport syndrome [23, 24]. Of note, rarely, some glycine substitutions (p.Gly43Arg in COL4A3, p.Gly999Glu in COL4A4, and p.Gly545Ala in COL4A4) are not pathogenic [25].
Statistical analysis
Statistical analysis was performed using GraphPad Prism V8 (GraphPad Software, Inc.). Medians and ranges were used for continuous variables. Frequencies and percentages were used for categorical variables. Mann–Whitney test was used to compare skewed distributed variables between two groups. Fisher’s test was used to compare the categorical variables in different groups. Log-rank (Mantel–Cox) test was used for censored time-to-event data. If the p value <0.05, the differences were considered to be statistically significant.
Results
Clinical features
A total of 101 patients (68 from China, 33 from Europe) with ARAS were enrolled in this study. The general characteristics and clinical features of the patients are shown in Table 1. Twenty-six patients (26/64, 41%) had a family history positive for kidney disease. Only two patients were from consanguineous families (2/68, 3%). The percentage of homozygous variants in ARAS patients was 16% (13/79), which implies heterozygous carriers of COL4A3 or COL4A4 variants are common in the population. Thirteen patients (13/46, 28%) had ocular abnormalities, seven of whom had temporal retinal thinning, five perimacular dot-and-fleck retinopathy, and one presented with a cataract. Twenty-five patients (25/51, 49%) had hearing loss (≥ 25 dB HL) and transmission hypoacusis was ruled out by an otolaryngologist with normal otolaryngological physical examination and pure tone audiometry. Twelve patients (12/101, 12%) developed CKD 5 at a median age of 20.5 years (range, 12 to 46 years).
Of 66 patients with kidney biopsy, 40 had an electron microscopy examination done with pathological changes like irregular thinning and thickening, splitting, and lamellation in GBM. In 44 patients with reports available for light microscopy, kidney pathology showed very different pathological changes. In children 10 years and younger, the histology changes included mesangial proliferative glomerulonephritis (63%), minor glomerular abnormalities (27%), and others (10%). In contrast, in patients older than 10 years, focal segmental glomerulosclerosis (FSGS) became the typical and most prominent finding (56%). Ten patients (10/44, 23%) showed FSGS by light microscopy and more than 90% of patients with FSGS were older than 10 years. The changes correlated with the age at kidney biopsy, as FSGS was the most common finding in the older patients (Fig. 1). The median age at kidney biopsy in the FSGS group was significantly older compared to the ages in groups of minor glomerular abnormalities and mesangial proliferative glomerulonephritis (17.5 vs. 5.4, p < 0.001; 17.5 vs. 7.5, p < 0.001; respectively).
Genetic features
In total, 79 patients (79/101, 79%) had the diagnosis confirmed genetically with pathogenic variants in the COL4A3 or COL4A4 genes. Among them, 58 cases (58/79, 73%) were caused by pathogenic variants in the COL4A3 gene and 21 (21/79, 27%) were caused by pathogenic variants in the COL4A4 gene. Sixteen percent of them (13/79) were homozygous and 84% (66/79) were compound heterozygous. The identified variants were confirmed to be inherited in trans in parents of 59 patients (59/79, 75%).
COL4A3 variants
A total of 58 variants were identified in the COL4A3 gene, 41 (41/58, 71%) of them were novel (Table 2). There were 24 missense variants (24/58, 41%), 14 frameshift variants (14/58, 24%), nine nonsense variants (9/58, 16%), seven splicing variants (7/58, 12%), three in-frame deletion variants (3/58, 5%), and one variant of initiation codon (1/58, 2%). Of the missense variants, 21 (21/24, 88%) were glycine substitutions in the collagen domain and the other three were missense variants located in the non-collagenous (NC) domain of α3 (IV) chain. Among the glycine substitutions, there were seven replaced by glutamic acid, six replaced by arginine, five replaced by aspartic acid, two replaced by valine, and one replaced by serine. The p.(Leu14_Leu21del) variant was the most frequent COL4A3 variant, which was detected in nine patients (1 homozygous, 8 compound heterozygous). In addition, the p.(Leu1598Arg) variant was detected in five patients in combination with glycine missense mutations and in one patient in combination with a frameshift variant.
COL4A4 variants
A total of 33 variants were identified in the COL4A4 gene, 29 (29/33, 88%) of them were novel (Table 3). There were 14 missense variants (14/33, 42%), eight splicing variants (8/33, 24%), six frameshift variants (6/33, 18%), two synonymous variants (2/33, 6%), one nonsense variant (1/33, 3%), one exon deletion variant (1/33, 3%) and one in-frame deletion variant (1/33, 3%). Of the missense variants, seven (7/14, 50%) were glycine substitutions in the collagen domain and the other seven were missense variants located in the non-collagenous (NC) domain of α4 (IV) chain. The two synonymous variants were predicted to create an exonic splicing silencer (ESS) site and potentially altering the splicing.
Genotype–phenotype correlations
Of the 79 patients with pathogenic variants in the COL4A3 or COL4A4 genes, the detailed gene variants were not available in two patients with COL4A4 gene mutations. We divided the remaining 77 patients into three groups according to the number of missense variants. Eighteen patients had 2 missense variants, 20 patients had 1 missense variant, and 39 patients had no missense variant.
In these three groups, patients without a missense variant showed a more severe course of disease with a higher prevalence of nephrotic-range proteinuria, hearing loss and ocular abnormalities, and an earlier age compared to patients with 1 or 2 missense variants (Table 4). Patients without a missense variant progressed to CKD 5 at an earlier age (18.5 years) compared to patients with 2 missense variants at an age of 30.0 years (p = 0.125). Of ten patients with FSGS, five patients (50%) had no missense variant, two patients (20%) had 1 missense variant, and three patients (30%) had 2 missense variants.
Decline of kidney function in the three groups is shown in Fig. 2. The median time with preserved kidney function (defined as eGFR >90 ml/min × 1.73m2, Fig. 2a; eGFR >60 ml/min × 1.73m2, Fig. 2b) was improved in patients with 2 missense variants compared to patients without a missense variant (30.0 vs. 20.0 years, 35.0 vs. 26.0 years, respectively) though the difference did not reach statistical significance. The probability of having a preserved kidney function (eGFR >60 ml/min × 1.73m2, Fig. 2b) at 25 years in ARAS patients without missense, 1 missense, and 2 missense variants was 40%, 60%, and 80%, respectively. These results demonstrate that kidney function declines earlier and faster in ARAS patients without a missense variant compared to patients with 1 or 2 missense variants.
Nephroprotective effect of RAAS inhibition
Of 101 patients, 79 patients currently received RAAS inhibition therapy (ACEi or ARB). The median age at initiation of therapy was 10 years (1.0 to 33.0 years) and the mean duration of therapy was 6.5 ± 6.0 years. There were 22 untreated patients with a median age of 11 years (2.0 to 46.0 years). Of the untreated patients, ten had only hematuria, six had CKD 5 at the beginning of diagnosis, and six were newly diagnosed as ARAS and presented with hematuria and proteinuria. In Fig. 3a, the nephroprotective effect of RAAS blockade on kidney survival (defined as starting kidney replacement therapy) is shown (p = 0.004). In Fig. 3b, the median kidney survival for patients without therapy was 24 years. RAAS inhibition therapy decreased the risk of CKD 5 and delayed the onset age of CKD 5 in ARAS patients depending on the time respective to the stage of disease at initiation of therapy (p = 0.002). In very late treated patients (T-III) with a mean duration of therapy of 9.0 years, therapy delayed onset of CKD 5 to 35 years of age (p = 0.949 vs. no therapy). Late treated patients (T-II) had a mean duration of therapy of 6.2 years and early treated patients (T-I) had a mean duration of therapy of 6.8 years. In both groups, T-II and T-I, the median age at onset of CKD 5 was still undefined because of their young age and the much slower progression of disease due to nephroprotective therapy (T-II vs. no therapy, p < 0.001; T-I vs. no therapy, p = 0.190; respectively).
Finally, the effect of the genotype on the response to nephroprotective therapy was analyzed in 77 patients with a genetic diagnosis (Fig. 4). The median survival time of kidney function was prolonged to 35 years in patients with RAAS inhibition therapy compared to 24 years in patients with no therapy (Fig. 4a). This result was in agreement with what we found in the paragraph above in all 101 ARAS patients with both clinical and genetic diagnosis, though the difference here did not reach statistical significance. It was found that, in spite of therapy, the onset of CKD 5 was still earlier in patients with no missense variants (m0) compared to patients with 1 or 2 missense variants (m1 + m2) (Fig. 4b). However, the difference was not statistically significant. The median age of patients with 1 or 2 missense variants (m1 + m2) was 16.5 years (range 1.5 to 35 years) in the therapy group and 7.0 years (range 2.0 to 34 years) in the no therapy group, respectively. The median age of patients with no missense variants (m0) was 11.0 years (range 2.0 to 30 years) in the therapy group and 13 years (range 1.0 to 46 years) in the no therapy group, respectively.
Discussion
Taking advantage of the combination of the Chinese Registry Database of Hereditary Kidney Diseases and the European Alport registry, the present study describes the clinical and genetic features of 101 patients with ARAS. Furthermore, the study analyzed the genotype–phenotype correlations with a special focus on the response to nephroprotective therapy. For the first time, we confirm the nephroprotective effects of RAAS inhibition therapy in patients with ARAS.
By analyzing the available clinical data in this study, we found that hematuria was present in 100% of patients with ARAS, which was first diagnosed at a median age of 4 years. Proteinuria was diagnosed in 86% of patients at a median age of 7 years. Hearing loss was observed in 49% of patients at a median age of 10 years and ocular lesions were observed in 28% of patients at a median age of 11 years. Patients with ARAS developed CKD 5 at a median age of 20.5 years, which is in agreement with the systematic review of ARAS by Lee and coworkers, who reported CKD 5 at a median age of 21 years [17]. Of note, 39% of our patients developed nephrotic-range proteinuria at a median age of 11 years. These results suggest that ARAS should be considered in the differential diagnosis for children with hematuria and proteinuria, even for children with nephrotic-range proteinuria.
In previous reports, 10% of patients with ARAS had only diffuse thinning of the GBM [17]. In this study, all the available kidney biopsy results showed typical changes of GBM on electron microscopy, including irregular thinning and thickening, splitting, and lamellation in GBM. Thus, electronic microscopy examination of GBM in kidney biopsy remains a very reliable method for diagnosis of Alport syndrome.
One interesting aspect of our study is the opportunity to correlate the results of kidney biopsy by light microscopy with the age at biopsy. We can see that kidney pathological changes progress over time (as a spectrum from minor glomerular abnormalities resulting in an FSGS-like pattern). In other words, the older the patient with ARAS is when they receive a kidney biopsy, the more likely FSGS can become the mis-diagnosis, if one does not include electron microscopy or one does not exclude Alport syndrome as the underlying cause of FSGS. Recently, heterozygous variants in COL4A3 were identified in FSGS patients, 12.5% of FSGS families, and one sporadic FSGS patient had heterozygous variants in the COL4A3 gene [37]. In that report, some patients had segmental GBM thinning, but these were not classified as changes typical for Alport syndrome. Of note, FSGS is a very common finding, which can be primary or secondary [38]. It has been reported that patients with a diagnosis of TBMN and ADAS also presented FSGS [39, 40]. Fogo et al. speculated that some variants could result in an incomplete penetrance of the Alport syndrome kidney phenotype, resulting in a varying spectrum of glomerular lesions with secondary FSGS [41]. In 2018, Braunisch et al. reported one case who was erroneously considered to have hereditary FSGS at 28 years and after she developed hearing impairment at the age of 34 years, and was shown to have Alport syndrome by genetic analysis [42]. Our data very strongly support the fact that pathogenesis of the type IV collagen disease Alport syndrome leads to secondary changes, which mimic FSGS, but should not be called FSGS, because this wrong diagnosis is misleading and might trigger false and harmful immunosuppressive therapies. Thus, the new classification of Alport syndrome by “the Alport Syndrome Classification Working Group” published in 2018 can help to minimize diagnostic confusion of disorders arising from the COL4A3 or COL4A4 genes [43].
The present study investigated the genotype–phenotype correlation with regard to the probability and age at onset of nephrotic-range proteinuria, hearing loss, ocular abnormalities, and CKD 5 between the subgroups of patients with no. 1 and 2 missense variants. Of note, patients without a missense variant reached CKD 5 earlier, had a higher prevalence of ocular abnormalities, and had both earlier median age and higher prevalence of hearing loss and nephrotic-range proteinuria compared to patients with 1 or 2 missense variants. Moreover, eGFR declined earlier and faster in patients without a missense variant. The results indicate that the severity of disease and the speed of decline of kidney function are negatively correlated with the number of missense variants detected in ARAS. These data are in agreement with investigations in patients with XLAS, who also showed a correlation between type of variant and decline of kidney function [44].
For the first time, our study showed that in patients with ARAS, CKD 5 can be delayed by RAAS blockade in a time-dependent manner. Initiation of therapy at an earlier stage of ARAS resulted in a superior preservation of kidney function. These nephroprotective effects are in agreement with previous reports of ACEi-therapy in Alport syndrome, in which the majority of patients had XLAS [19]. Furthermore, RAAS blockade in 49 patients with different ARAS genotypes was less effective in patients without a missense variant, who had a higher prevalence and earlier age of onset of CKD 5 compared to patients with at least one missense variant. Collectively, these results demonstrate that early RAAS blockade delays onset of CKD 5 in ARAS. These data are in agreement with the investigation in patients with XLAS, who also showed a correlation between type of variant and response to nephroprotective therapy [44].
Therefore, genetic testing should be the priority choice for diagnosing Alport syndrome. It can benefit Alport patients from many aspects, such as early diagnosis, determining the hereditary modes, indicating the likely clinical course and response to nephroprotective therapy, and genetic counseling. All these advantages make genetic testing the first option instead of kidney biopsy for Alport patients. However, this does not mean genetic testing can replace kidney biopsy for all Alport patients. In some patients with suspected Alport syndrome who have no COL4 pathogenic variants identified or gene variants of uncertain significance, GBM appearance is critical to determine the necessity of further specialized tests and diagnosis for them.
Our study has its own limitations. First, one of the inclusion criteria for patient selection was clinical diagnosis of ARAS based on typical ultrastructural changes of GBM in patients and hematuria without proteinuria or CKD 5 in both parents. This is often correct and helpful to distinguish ARAS from XLAS, but it can also be missleading in families with a coincidental kidney disease [45] or exclude some ARAS cases, as parents with a single autosomal variant are at risk of both hematuria and proteinuria [46]. Second, the low median age of the cohort and the small number of patients on kidney replacement therapy prevents us from having more robust data on CKD 5.
In conclusion, this is the largest study conducted to date in patients with ARAS, including the longest follow-up period on response to therapy. Our findings demonstrate that clinical features in patients with ARAS commonly include nephrotic-range proteinuria and FSGS in advanced stages in children and young adults. Furthermore, decline of eGFR, and age at onset of CKD 5, hearing loss, and ocular abnormalities are strongly correlated with the number of missense variants detected in ARAS. Our study provides further evidence for early use of nephroprotective RAAS blockade in young patients with ARAS.
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Acknowledgments
We thank the patients, the families, and the physicians who contributed to this project (Dr. Liang Zhao, Dr. Yong Yao, Dr. Huijie Xiao, Dr. Xuhui Zhong, Dr. Hongwen Zhang, Dr. Na Guan, Dr. Xiaoyu Liu, Dr. Baige Su, and Dr. Ke Xu). We thank the European patient group FEDERG, all national Alport patient groups in the USA, France, UK, Belgium, The Netherlands, Spain, Switzerland, Italy, Israel, Australia, China, and Germany for their support and for sharing their individual medical history.
Funding
The study was supported by grants from the National Key Research and Development Program of China (No. 2016YFC0901505): the registry study of rare diseases in children, the Beijing key laboratory of molecular diagnosis and study on pediatric genetic diseases (BZ0317). This work was supported by the German Research Foundation DFG (GR 1852/6-1 to OG) and the German Federal Ministry of Education and Research (01KG1104 to OG). The European Alport Registry is supported by the Association pour l’Information et la Recherche sur les Maladies Rénales Génétiques (AIRG-France) (to OG). The author gratefully acknowledges the support of K. C. Wong Education Foundation and DAAD.
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The manuscript was drafted by YZ, OG, and JD; the study was conceived by OG and JD. YZ, JB, FW, SW, and DR contributed to data interpretation and data analysis. All authors read and approved the final manuscript.
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Zhang, Y., Böckhaus, J., Wang, F. et al. Genotype–phenotype correlations and nephroprotective effects of RAAS inhibition in patients with autosomal recessive Alport syndrome. Pediatr Nephrol 36, 2719–2730 (2021). https://doi.org/10.1007/s00467-021-05040-9
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DOI: https://doi.org/10.1007/s00467-021-05040-9