Abstract
Genes of UMOD, HNF1B, MUC1, REN and SEC61A1 were reported to be associated with autosomal dominant tubulointerstitial kidney disease (ADTKD). 48 probands and their family members (N = 27) were enrolled in this genetic screening study. A combination of methods was employed for comprehensive molecular analysis of both copy number variations (CNVs) and single nucleotide variants (SNVs). 35 probands were followed for years. The phenotype-genotype and genotype-outcome correlation were inferred from these datasets. In this cohort, 18 probands were diagnosed with ADTKD, according to Kidney Disease: Improving Global Outcomes (KDIGO) guideline. Moreover, 11 probands were diagnosed with ADTKD-UMOD, one with ADTKD-REN and one with ADTKD-HNF1B, based on molecularly confirmed pathogenic variants. The 11 UMOD variants were mainly located in codons 28 to 289 and half of the variants were found to change the cysteine amino acid. According to the follow-up data, suspected ADTKD individuals had a better prognosis compared to ADTKD individuals (p = 0.029). Individuals with a cysteine substitution in the UMOD gene appeared to have a better prognosis than individuals with other amino acid substitutions (p = 0.015).
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Introduction
Autosomal dominant tubulointerstitial kidney disease (ADTKD) is considered to be one of the common causes of end stage renal disease (ESRD), especially in people whereby familial aggregation is observed1. ADTKD has been reported using different names, including familial juvenile hyperuricemic nephropathy (FJHN), medullary cystic kidney disease (MCKD) and maturity-onset diabetes mellitus of the young type 5 (MODY5)2,3,4. In terms of genetic etiologies, several genes, including UMOD (OMIM 16p12.3 and 191845)2, REN (OMIM 1q32.1 and 179820)5, HNF1B (OMIM 17q12 and 189907)4 and MUC1 (OMIM 1q22 and 158340)3 have been confirmed to be responsible for some forms of ADTKD. A recent study reported that SEC61A1 (OMIM: 609213) might be considered as a new disease-causing gene of ADTKD6. Variants in UMOD, REN, HNF1B, and SEC61A1 genes can be detected by DNA sequencing. In addition, gross deletions or duplications in HNF1B need to be detected by multiplex ligation-dependent probe amplification (MLPA), or quantitative PCR. Genotyping of MUC1 remains challenging because of the complex gene structure. A MUC1 mutation was described as a cytosine insertion in the extracellular variable number tandem repeat (VNTR) domain of the gene which led to a frameshift change3,7. Other insertion and deletion mutations (indel) in the VNTR region of MUC1 have also been described as pathogenic variants8.
The prevalence of ADTKD and subtypes remain unknown. Most of the ADTKD individuals have been clinically diagnosed as having chronic kidney disease (CKD) without a clear molecular diagnosis due to latent symptoms, mild urinary sediment, and atypical pathological lesions. In this study, we screened for variants in five genes associated with ADTKD by a combination of methods, analyzed the phenotype-genotype correlation and genotype-outcome correlation in a Chinese cohort.
Results
General clinical features of the cohort
In total, 18 patients were diagnosed with ADTKD according to the criteria of the KDIGO guideline1. Among them, clinically significant genetic variants were identified in 13 probands, and 5 probands were clinically diagnosed ADTKD without identifying pathogenic variants in known genes associated with ADTKD (Table 1). In addition to the clinically diagnosed ADTKD patients, there were 30 probands with suspected ADTKD, because of either positive family history or pathological data. When the biochemical traits, family history, and demographic information were examined, no statistical difference was found between the confirmed ADTKD and suspected ADTKD groups in terms of average age, male/female ratio, serum creatinine level, serum uric acid level, renal cysts identification and histological data (Table 1).
Mutational profiles of molecular genetic analysis
We utilized a combination of Sanger, next-generation sequencing (NGS), and MLPA (Supplementary figure S1) to detect SNVs and CNVs in 5 genes associated ADTKD and whole exome sequencing (WES) to identify new candidate genes. Briefly, we sequenced the four genes (UMOD/REN/HNF1B/SEC6lA1) by Sanger sequencing, CNVs of HNF1B by MLPA, and sequenced MUC1 by long-range high-fidelity PCR combined with NGS. We performed WES in patients without pathogenic variants in the 5 genes associated with ADTKD.
No pathogenic variants were detected in MUC1 and SEC6lA1 in any of the patients. 12 missense changes and 1 frameshift mutation were detected in 13 probands. Among them, only 10 individuals had a family history of CKD or hyperuricemia. 11 probands were confirmed to have significant variants in UMOD. Moreover, 1 proband had compound heterozygous variants in REN and another was heterozygous for a change in HNF1B. For variants in UMOD, five of the missense variants were predicted to change a cysteine residue (p.Cys35Tyr, p.Cys112Gly, p.Cys248Trp, p.Cys287Phe, and p.Cys347Arg), and six variants resulted in the replacement of other residues (p.Asn38Ile, p.Leu66Pro, p.Val109Glu, p.Cys112Gly, p.Pro236Gln, and p.Arg385Trp) (Supplementary figure S2). The p.Asn38Ile change may affect a potential N-glycosylation site9. In addition, the REN change in family 12 was p.Lys32Thr which was located in exon 1 as previously reported10,11 and the HNF1B change in family 13 was a p.Arg295His in exon 4 (Table 2).
Pathogenicity of the identified variations was evaluated according to the American college of medical genetics and genomics (ACMG) standards and guidelines. For analysis, we examined the frequency of the variants in 1000 genome browser and human gene mutation database. In addition, we sequenced 92 healthy donors to obtain variants found in healthy individuals. Function study of variants in UMOD has been performed in our previous study except for p.Cys112Gly. Also, we evaluated the pathogenicity of missense variants with Polyphen and other software. One frameshift variant and nine missense variants can be classified as “pathogenic”. One missense variant in UMOD (p.Arg385Trp) and one missense variant in HNF1B (p.Arg295His) can be classified as “likely pathogenic”, while the missense variant of REN (p.Lys32Thr) can only be classified as “uncertain significance” (Table 2). One missense variant in HNF1B (p. Arg295His) identified in our cohort also report in another study12. We did not detect CNVs in HNF1B (Supplementary figure S3) and MUC1 variants in our cohort. Details of the ACMG evidence were presented at supplementary table S2.
WES was performed on 18 probands (4 clinically identified ADTKD and 14 suspected ADTKD). All of them had a positive family history of CKD, or hyperuricemia or both. We did not identify any potential candidate genetic variants associated with clinical features (Supplement table S3).
Genotype and phenotype correlation in the cohort with ADTKD
In the cohort, 35 patients including 13 genetically confirmed ADTKD, 2 ADTKD-NOS (ADTKD-not otherwise specified; clinically confirmed ADTKD), and 20 ADTKD suspected were followed during the year 2012 to 2018. Thirteen ADTKD and 11 individuals with suspected ADTKD received the proper medical management based on the appropriate treatment guidelines13. Two individuals with ADTKD and 9 individuals with suspected ADTKD presented with only minor symptoms and are being followed annually without treatment.
Among the 13 genetically confirmed ADTKD, the person with a REN mutation recovered in one year and the proband with a HNF1B variant remained stable. 5 out of the 10 ADTKD-UMOD progressed to ESRD (Table 2), whereas only one person progressed to ESRD among ADTKD suspected. Kaplan–Meier survival analysis indicated that individuals with suspected ADTKD had a better prognosis compared to the ADTKD individuals (p = 0.029, Fig. 1). Detailed clinical descriptions of the follow-up participants were shown in supplementary table S4.
The 11 UMOD variants located in exon 4 and exon 6. Six of the eleven (55%) UMOD variants were located in the three epidermal growth factor (EGF)-like domains (p.Cys35Tyr and p.Asn38Ile in the first, p.Leu66Pro and p.Ser91 in the second, and p.Val109Glu and p.Cys112Gly in the third EGF-like domain). Three of the eleven (27.2%) variants, p.Pro236Gln, p.Cys248Trp and p.Cys287Phe, located in the D8C region. Two variants (p.Cys347Arg, p.Arg385Trp) located in the zona pellucida (ZP)-N domain (Supplementary Figure S2). EGF-like domains might play important roles in protein–protein interactions while ZP domain might be essential for protein polymerization14. We grouped the variants into three classes based on domains and compared the outcomes of the individuals with these variants, but no differences were observed (Table 3A). Additionally, we divided the individuals with UMOD variants into two groups based on whether the variation was a cysteine substitution because more than half were cysteine changes. Individuals with cysteine substitution appeared to have a better prognosis compared to individuals with another amino acid substitution (Table 3B).
We also analyzed the association between clinical data and genetic variations. All probands with UMOD/REN/HNF1B variants had a clinical history of hyperuricemia and increased plasma creatinine, and the proband with HNF1B variation also presented with diabetes mellitus, hypokalemia and an abnormal liver test (Table 2). The patient with a REN mutation had a positive family history of renal cysts. Most of ADTKD-UMOD individuals presented with family histories of hyperuricemia or CKD. In family 6, the mother and the elder brother of the proband carried the same heterozygous variant of UMOD, without hyperuricemia or CKD (Fig. 2). Incomplete penetrance may explain this phenomenon as previously reported15,16. We also identified UMOD variants in family 1 and family 2 who had negative family history. Proband of family 1 had an increased plasma uric acid (749 μmol/L) and creatinine (163 μmol/L) at the time of diagnosis and his plasma creatinine increased to 242 μmol/L after 4 years. His parents had kept normal plasma creatinine and uric acid levels during the 4 years. Proband of family 2 had an increased uric acid 691 μmol/L and creatine 154 μmol/L at diagnosis and progressed for 5 years, while her parents presented no signs of CKD or hyperuricemia. We did not get permission to do genetic tests for the parents of family 1 and family 2. We cannot confirm whether the UMOD variants in family one and 2 are de novo or incomplete penetrance. Thus it is difficult to give an exact rate of incomplete penetrance and compared to other studies15,16.
We compared the clinical features of the probands with genetically confirmed ADTKD (N = 13) and clinically confirmed ADTKD-NOS (N = 5). Genetically confirmed ADTKD appeared to have a higher percentage of hypertension, but the other clinical features were similar between the two groups (Table 4). We also collected plasma from 6 ADTKD-UMOD, 5 ADTKD individuals without UMOD variants (ADTKD-others), 11 individuals with suspected ADTKD (ADTKD-suspected) and 9 healthy controls. The plasma uromodulin concentration in the ADTKD-UMOD group (7.05 ± 13.08 ng/ml) was statistically significant (p = 0.017) lower than the ADTKD-others (70.3 ± 68.6 ng/ml). Both of the ADTKD-UMOD and ADTKD-suspected (34.3 ± 28.0 ng/ml) groups had lower plasma concentrations compared to healthy controls (153.5 ± 63.7 ng/ml) (Fig. 3).
Discussion
In the present study, we screened for variants in five disease genes known to cause ADTKD including UMOD, REN, HNF1B, SEC61A1, and MUC1 in a Chinese cohort with suspected ADTKD. We identified 13 significant variants in this cohort. Eleven, one and one variants located in the UMOD (11/21 = 52%), REN and HNF1B genes, respectively. Previous studies of ADTKD in Chinese cohort were mainly case reports. Twelve variants in the UMOD gene have been reported in patients with ADTKD-UMOD17 and more than half of them were reported by our group18,19,20. Although the disease prevalence varied across different studies in different ethnic groups, a study with 136 probands from France showed that 17.6% and 3.7% variants were detected in the UMOD and HNF1B genes, respectively15. Another study from 56 Spanish families reported 16% and 28% variants in UMOD and MUC1 genes, respectively16. The difference between groups may be due to the clinical evaluation of the suspected-ADTKD patients and that not all suspected patients accepted genetic testing. MUC1 is another important disease-causing gene for ADTKD. Genetic testing for MUC1 is challenging due to its complex VNTR region. Researchers have reported several methods to detect MUC1 mutations, including snapshot, mass spectrometry and long-range PCR with NGS3,7,8,21,22. Early studies reported only one mutation of a single cytosine insertion in the MUC1 VNTR region. Moreover, a recent study showed other novel frameshift mutations in MUC18. In this study, we used long-range high-fidelity PCR and NGS to sequence the entire MUC1 gene. Studies from Europe and America showed a varied prevalence of ADTKD-MUC1. ADTKD-MUC1 was reported to be rare in Chinese23,24. The clinical manifestations of hereditary cystic kidney disease were hard to distinguish, therefore, suspected ADTKD patient without ADTKD gene mutations may be due to other hereditary kidney diseases. Even though we performed WES in ADTKD-suspected patients with a family history in this Chinese cohort, we did not detect pathogenic variants in genes responsible for hereditary kidney disease. However, further investigation is warranted due to the limited number of patients enrolled.
Previous studies did not reveal specific differences between ADTKD-UMOD and ADTKD-MUC1 or ADTKD groups16. In this study, we also found that the clinical characteristics were similar between genetically confirmed ADTKD and clinically confirmed ADTKD-NOS patients. Family history of CKD or hyperuricemia suggested a higher detection rate for variants. In the sporadic individuals, the average age was much younger than those with a family history, which may be due to the inclusion criteria. However, in “sporadic” probands, we also indeed identified UMOD mutations, suggesting that genetic testing should be considered in young individuals with tubulointerstitial nephropathy.
Plasma uromodulin level is highly correlated with eGFR and lower uromodulin concentration associated with lower eGFR25,26. All individuals with ADTKD had lower levels of plasma uromodulin compared with healthy controls, which is consistent with the decreased eGFR in the ADTKD groups. It is noteworthy that the plasma uromodulin levels in individuals with UMOD variants showed a decreasing trend when compared to patients without UMOD variants in our study (Fig. 3). Individuals with UMOD variants often had a common feature of decreased secretion of uromodulin into the urine, due to the retention and accumulation of mutant protein in the endoplasmic reticulum27,28. The lower plasma uromodulin concentration in ADTKD-UMOD individuals may be caused by the accumulation of mutant uromodulin in the endoplasmic reticulum, decreased protein production or rapid proteolysis for degradation. Thus, the plasma or urinary uromodulin level may be considered as a marker to distinguish ADTKD-UMOD from other subtypes of ADTKD. Survival analysis indicated a better prognosis in ADTKD which may provide another clue to differentiate the ADTKD groups. However, further investigation with the inclusion of more clinical samples to reproduce these results is warranted to further demonstrate the clinical utility of this uromodulin biomarker found in plasma.
Up-to-date more than 100 variants in the UMOD gene have been identified, and 50% of them were cysteine replacement29. Researchers have raised the question regarding the relationship between prognosis and mutation type. A study showed that the individuals with a cysteine substitution had worse renal survival, however, it was a slight trend without significance (p = 0.41)15. In our cohort, 45.5% of variants lead to a cysteine replacement, similar to the previous report. Besides, individuals with cysteine substitution showed a better prognosis in our follow-up study. We also analyzed the relationship of genotype and outcome, based on the protein location of the variants. In previous reports, around 60% of UMOD variants were located in the D8C region, 30% in the EGF-like domains, and less than 10% in the ZP domain17,29,30,31,32,33,34. In this study, there was no obvious clustering among the three domains, even though more than half of the variants were located in the EGF-like domains. The results suggested that for this patient cohort the outcome of the ADTKD-UMOD group was associated with the type of amino acid substitution rather than the location of the variants. A larger cohort study is essential to replicate this genotype–phenotype correlation in ADTKD-UMOD.
Uromodulin is a glycoprotein with approximate 30% N-glycans and is suspected to be a factor that influences the prognosis of ADTKD. The N-glycans play an important role in uromodulin polymerization and defense against urinary tract diseases35. Abnormal uromodulin glycosylation was identified in renal transplant recipients and is associated with renal tubular injury as well as renal allograft rejection36. Some of the variants in the UMOD gene can influence the glycosylation process, or even change the binding sites of glycans directly. In this study, we only observed one residue that can change the potential glycosylation site (p. Asn38Ile, F3), and the person with this variation reached ESRD within 2 years.
In summary, we found gene variants in 61.9% of individuals in a Chinese ADTKD cohort and most of the mutations located in the UMOD gene. Family history was an important indication for further genetic diagnosis. Renal survival of individuals with ADTKD-UMOD was unrelated to the position of the variants. Direct sequencing of UMOD was the preferred method for ADTKD diagnosis. The plasma or urinary uromodulin level may be considered as a marker to distinguish ADTKD-UMOD from other subtypes of ADTKD. Even though WES in ADTKD-NOS patients with family history, we did not find other pathogenic variants in genes associated with hereditary kidney disease. However, further investigation is warranted due to the limited number of patients enrolled in this study.
Materials and methods
Study subjects and laboratory analyses
Forty-eight probands and other family members (N = 27) were enrolled in this study from 2012 to 2018. All participants accepted an informed consent form for genetic testing. Among them, 18 probands were diagnosed as ADTKD patients, based on combining genetic screening, family history, clinical features, and renal histological changes according to the KDIGO guideline (Table 1)1. The inclusion criteria are; (1) patients who have positive family history of chronic kidney disease, or early-onset hyperuricemia/gout compatible with ADTKD clinical characters; (2) patients without positive family history of CKD, must fulfill the clinical characteristics, or demonstration of compatible histology on kidney biopsy (interstitial fibrosis, tubular atrophy or dilatation, thickening and lamellation of tubular basement membranes, negative immunofluorescence for complement and immunoglobulins) or extrarenal manifestations compatible with HNF1B mutations. The clinical characters of ADTKD patients are autosomal dominant inheritance, progressive loss of kidney function, bland urinary sediment, absent-to-mil albuminuria or proteinuria, no severe hypertension during early stage, no drug exposure potentially causing tubulointerstitial nephritis, normal or small-sized kidneys on ultrasound, nocturia or enuresis in children. Patients were excluded if they have other causes of tubulointerstitial nephropathy, such as drug-induced or other knew genetic kidney disease. Estimated glomerular filtration rate (eGFR) was calculated using the formula of CKD-EPI. The definition of CKD was evaluated based on the KDIGO guideline (2012). The definition of ESRD was patient received renal replacement therapy or renal transplant. Moreover, the clinical data and family history of the patients were obtained from their medical records.
The first diagnosed ADTKD-UMOD patient was in 2012. Part of the protocol included follow-up. Individuals were interviewed by telephone or at an outpatient clinic. The follow-up study was focused on two aspects, treatment and progression of the disease. The primary endpoint was death or ESRD.
The study was approved by the local ethics committee of Peking University First Hospital (protocol No. 2016 [1133]). The study was performed in accordance with the Helsinki declaration and its later amendments or comparable ethical standards. All participants in this study signed written informed consent forms.
Measurement of plasma uromodulin concentration
The plasma uromodulin concentration was measured with an enzyme-linked immunosorbent assay (ELISA) kit according to the manufacturer’s instructions (Euroimmun Medizinische Labordiagnostika AG, Germany).
Screening for genetic variants
Sanger sequencing of the UMOD, REN, HNF1B and SEC61A1 genes
Genomic DNA was extracted from peripheral leukocytes derived from whole blood samples37. All of the coding and splicing regions of UMOD (NM_001008389), REN (NM_000537) and HNF1B (NM_000458) were amplified by PCR (Supplementary table S1) and Sanger sequenced with the ABI 3730XL Genetic Analyzer (Applied Biosystems). The reference sequences were obtained from Ensembl (Transcript number for UMOD, REN, HNF1B are ENST00000302509, ENST00000272190 and ENST00000225893). SEC61A1 was a recently reported candidate gene for ADTKD6. We detected SEC61A1 variants using the touch-down PCR program described by Bolar et al.6. Confirmatory testing was performed by bidirectional sequencing.
To validate variant pathogenicity, we sequenced DNA samples from 92 healthy controls and performed mutation and population database searches, namely, 1000 genomes (http://browser.1000genomes.org/), ExAC Browser (http://exac.broadinstitute.org/), human gene mutation database (http://www.hgmd.org/) and ClinVar (http://www.ncbi.nlm.nih.gov/clinvar). We utilized two software for pathogenicity predictions of novel variants, including Polyphen2 (http://genetics.bwh.harvard.edu/pph2/) and SIFT (http://sift.jcvi.org). Pathogenicity of the identified variations was evaluated using the ACMG criteria38.
Copy number variation of HNF1B detected by MLPA assay
Since gross deletions of the HNF1B gene can cause ADTKD4,39, we detected these types of copy number variants (CNVs) using multiple ligation-dependent probe amplification (MLPA) assays (SALSA MLPA P241-B1 MODY, MRC-Holland, Amsterdam, Netherland)40. With this method, all exons of HNF1B were amplified by PCR and assessed for CNVs inpatients and 10 healthy controls. Following MLPA, we performed capillary electrophoresis with ABI 3730XLGenetic Analyzer (Applied Biosystems) for fragment size determination and CNV detection using the Coffalyser.NET (MRC-Holland, Amsterdam, Netherland) software.
Long-range high fidelity PCR and next-generation sequencing for MUC1
Variants in MUC1 were a challenge for NGS detection because of the VNTR region. In this study, we used long-range high fidelity PCR combined with NGS to overcome this challenge. A similar strategy was reported by Martina Zivná et al. previously8. Through PCR amplification with PrimeSTAR GXL DNA Polymerase (TAKARA BIO INC), The 4.7 kb product which covered the entire MUC1 gene was acquired using previously designed primers. The PCR products were purified with Agentcourt AMPure X, followed by fragmentation to a library size of 350 bp. The library was constructed using the fragmented PCR products and the KAPA HyperPlus Library Preparation Kit. Moreover, quantification of the library was completed with the Library Quantification kit (KAPA, KK4824) and sequenced using the HiSeq (Illumina). Sequence reads were aligned to the reference sequence NM_001204286 and analyzed using NextGENE software. The MUC1 mutation positive control was donated by professor Hong Cheng24.
Whole-exome sequencing
Whole exome sequencing was used in individuals with family history of ADTKD, but without identified variants in the 5 candidate genes. The positive family history was defined as family members with CKD, or hyperuricemia or both. One μg of DNA from probands was used to construct the exome library. Products were purified using AMPure XP system (Beckman Coulter, USA). DNA library enriched were sequenced on Illumina using paired-end 150 bp reads. The filtered reads were aligned to the NCBI human reference genome (GRCh37/hg19) by Burrows-Wheeler Aligner (BWA) software.
Statistical analyses
Statistical analyses were performed with IBM SPSS Statistics package version 20. Quantitative parameters were presented as mean ± standard deviation. Qualitative parameters were presented as a number and percentage. Independent sample t-test was used to compare parametrical data (age, creatinine, uric acid, blood urea nitrogen, 24-h urinary protein) and chi-squared test or Fisher exact test was used appropriately to analyze the categorical variables. Kaplan–Meier analysis was used to analyze the prognosis. The results were considered statistically significant at p < 0.05.
Data availability
The datasets generated and analyzed during the current study are available from the corresponding author on reasonable request.
References
Eckardt, K. U. et al. Autosomal dominant tubulointerstitial kidney disease: diagnosis, classification, and management–A KDIGO consensus report. Kidney Int. 88, 676–683. https://doi.org/10.1038/ki.2015.28 (2015).
Hart, T. C. et al. Mutations of the UMOD gene are responsible for medullary cystic kidney disease 2 and familial juvenile hyperuricaemic nephropathy. J. Med. Genet. 39, 882–892 (2002).
Kirby, A. et al. Mutations causing medullary cystic kidney disease type 1 lie in a large VNTR in MUC1 missed by massively parallel sequencing. Nat. Genet. 45, 299–303. https://doi.org/10.1038/ng.2543 (2013).
Lindner, T. H. et al. A novel syndrome of diabetes mellitus, renal dysfunction and genital malformation associated with a partial deletion of the pseudo-POU domain of hepatocyte nuclear factor-1beta. Hum. Mol. Genet. 8, 2001–2008 (1999).
Zivna, M. et al. Dominant renin gene mutations associated with early-onset hyperuricemia, anemia, and chronic kidney failure. Am. J. Hum. Genet. 85, 204–213. https://doi.org/10.1016/j.ajhg.2009.07.010 (2009).
Bolar, N. A. et al. Heterozygous loss-of-function SEC61A1 mutations cause autosomal-dominant tubulo-interstitial and glomerulocystic kidney disease with anemia. Am. J. Hum. Genet. 99, 174–187. https://doi.org/10.1016/j.ajhg.2016.05.028 (2016).
Ekici, A. B. et al. Renal fibrosis is the common feature of autosomal dominant tubulointerstitial kidney diseases caused by mutations in mucin 1 or uromodulin. Kidney Int. 86, 589–599. https://doi.org/10.1038/ki.2014.72 (2014).
Zivna, M. et al. Noninvasive immunohistochemical diagnosis and novel MUC1 mutations causing autosomal dominant tubulointerstitial kidney disease. J. Am. Soc. Nephrol. 29, 2418–2431. https://doi.org/10.1681/ASN.2018020180 (2018).
van Rooijen, J. J., Voskamp, A. F., Kamerling, J. P. & Vliegenthart, J. F. Glycosylation sites and site-specific glycosylation in human Tamm-Horsfall glycoprotein. Glycobiology 9, 21–30 (1999).
Bleyer, A. J. et al. Clinical and molecular characterization of a family with a dominant renin gene mutation and response to treatment with fludrocortisone. Clin. Nephrol. 74, 411–422 (2010).
Beck, B. B. et al. Autosomal dominant mutation in the signal peptide of renin in a kindred with anemia, hyperuricemia, and CKD. Am. J. Kidney Dis. 58, 821–825. https://doi.org/10.1053/j.ajkd.2011.06.029 (2011).
Bellanne-Chantelot, C. et al. Clinical spectrum associated with hepatocyte nuclear factor-1beta mutations. Ann. Intern. Med. 140, 510–517. https://doi.org/10.7326/0003-4819-140-7-200404060-00009 (2004).
Stevens, P. E., Levin, A. & Kidney Disease: Improving Global Outcomes Chronic Kidney Disease Guideline Development Work Group M. Evaluation and management of chronic kidney disease: synopsis of the kidney disease: Improving global outcomes 2012 clinical practice guideline. Ann. Intern. Med. 158, 825–830. https://doi.org/10.7326/0003-4819-158-11-201306040-00007 (2013).
Rampoldi, L., Scolari, F., Amoroso, A., Ghiggeri, G. & Devuyst, O. The rediscovery of uromodulin (Tamm-Horsfall protein): From tubulointerstitial nephropathy to chronic kidney disease. Kidney Int. 80, 338–347. https://doi.org/10.1038/ki.2011.134 (2011).
Bollee, G. et al. Phenotype and outcome in hereditary tubulointerstitial nephritis secondary to UMOD mutations. Clin. J. Am. Soc. Nephrol. 6, 2429–2438. https://doi.org/10.2215/CJN.01220211 (2011).
Ayasreh, N. et al. Autosomal dominant tubulointerstitial kidney disease: Clinical presentation of patients with ADTKD-UMOD and ADTKD-MUC1. Am. J. Kidney Dis. 72, 411–418. https://doi.org/10.1053/j.ajkd.2018.03.019 (2018).
Yang, J., Zhang, Y. & Zhou, J. UMOD gene mutations in Chinese patients with autosomal dominant tubulointerstitial kidney disease: A pediatric case report and literature review. BMC Pediatr. 19, 145. https://doi.org/10.1186/s12887-019-1522-7 (2019).
Liu, M. et al. Novel UMOD mutations in familial juvenile hyperuricemic nephropathy lead to abnormal uromodulin intracellular trafficking. Gene 531, 363–369. https://doi.org/10.1016/j.gene.2013.08.041 (2013).
Xia, M. et al. Investigation of uromodulin gene mutations for the diagnosis of familial interstitial nephropathy. Chin. J. Blood Purif. 14, 41–46 (2015).
Gong, K. et al. Study of autosomal dominant tubulointerstitial kidney disease in a Chinese cohort. Chin. J. Blood Purif. 16, 413–419 (2017).
Blumenstiel, B. et al. Development and validation of a mass spectrometry-based assay for the molecular diagnosis of mucin-1 kidney disease. J. Mol. Diagn. 18, 566–571. https://doi.org/10.1016/j.jmoldx.2016.03.003 (2016).
Knaup, K. X. et al. Biallelic expression of mucin-1 in autosomal dominant tubulointerstitial kidney disease: Implications for nongenetic disease recognition. J. Am. Soc. Nephrol. 29, 2298–2309. https://doi.org/10.1681/ASN.2018030245 (2018).
Si, N. et al. Genetic testing of the mucin 1 gene-variable number tandem repeat single cytosine insertion mutation in a Chinese family with medullary cystic kidney disease. Chin. Med. J. (Engl.) 130, 2459–2464. https://doi.org/10.4103/0366-6999.216408 (2017).
Wang, G. Q. et al. SMRT sequencing revealed to be an effective method for ADTKD-MUC1 diagnosis through follow-up analysis of a Chinese family. Sci. Rep. 10, 8616. https://doi.org/10.1038/s41598-020-65491-2 (2020).
Steubl, D. et al. Plasma uromodulin correlates with kidney function and identifies early stages in chronic kidney disease patients. Medicine 95, e3011. https://doi.org/10.1097/MD.0000000000003011 (2016).
Delgado, G. E. et al. Serum uromodulin and mortality risk in patients undergoing coronary angiography. J. Am. Soc. Nephrol. 28, 2201–2210. https://doi.org/10.1681/ASN.2016111162 (2017).
Williams, S. E. et al. Uromodulin mutations causing familial juvenile hyperuricaemic nephropathy lead to protein maturation defects and retention in the endoplasmic reticulum. Hum. Mol. Genet. 18, 2963–2974. https://doi.org/10.1093/hmg/ddp235 (2009).
Lee, M. N., Jun, J. E., Kwon, G. Y., Huh, W. S. & Ki, C. S. A novel UMOD mutation (c.187T>C) in a Korean family with juvenile hyperuricemic nephropathy. Ann. Lab. Med. 33, 293–296. https://doi.org/10.3343/alm.2013.33.4.293 (2013).
Devuyst, O., Olinger, E. & Rampoldi, L. Uromodulin: from physiology to rare and complex kidney disorders. Nat. Rev. Nephrol. 13, 525–544. https://doi.org/10.1038/nrneph.2017.101 (2017).
Moskowitz, J. L. et al. Association between genotype and phenotype in uromodulin-associated kidney disease. Clin. J. Am. Soc. Nephrol. 8, 1349–1357. https://doi.org/10.2215/CJN.11151012 (2013).
Dinour, D., Ganon, L., Nomy, L. I., Ron, R. & Holtzman, E. J. Wild-type uromodulin prevents NFkB activation in kidney cells, while mutant uromodulin, causing FJHU nephropathy, does not. J. Nephrol. 27, 257–264. https://doi.org/10.1007/s40620-014-0079-7 (2014).
Stewart, A. P., Sandford, R. N., Karet Frankl, F. E. & Edwardson, J. M. Pathogenic uromodulin mutations result in premature intracellular polymerization. FEBS Lett. 589, 89–93. https://doi.org/10.1016/j.febslet.2014.11.029 (2015).
Raffler, G., Zitt, E., Sprenger-Mahr, H., Nagel, M. & Lhotta, K. Autosomal dominant tubulointerstitial kidney disease caused by uromodulin mutations: Seek and you will find. Wien. Klin. Wochenschr. 128, 291–294. https://doi.org/10.1007/s00508-015-0948-7 (2016).
Malakoutian, T., Amouzegar, A., Vali, F., Asgari, M. & Behnam, B. First report of familial juvenile hyperuricemic nephropathy (FJHN) in iran caused by a novel de novo mutation (E197X) in UMOD. J. Mol. Genet. Med. https://doi.org/10.4172/1747-0862.1000218 (2016).
Serafini-Cessi, F., Monti, A. & Cavallone, D. N-Glycans carried by Tamm-Horsfall glycoprotein have a crucial role in the defense against urinary tract diseases. Glycoconj. J. 22, 383–394 (2005).
Wu, T. H. et al. Altered glycosylation of Tamm-Horsfall glycoprotein derived from renal allograft recipients leads to changes in its biological function. Transpl. Immunol. 18, 237–245. https://doi.org/10.1016/j.trim.2007.07.001 (2008).
Miller, S. A., Dykes, D. D. & Polesky, H. F. A simple salting out procedure for extracting DNA from human nucleated cells. Nucleic Acids Res. 16, 1215 (1988).
Richards, S. et al. Standards and guidelines for the interpretation of sequence variants: a joint consensus recommendation of the American College of Medical Genetics and Genomics and the Association for Molecular Pathology. Genet. Med. 17, 405–424. https://doi.org/10.1038/gim.2015.30 (2015).
Heidet, L. et al. Spectrum of HNF1B mutations in a large cohort of patients who harbor renal diseases. Clin. J. Am. Soc. Nephrol. 5, 1079–1090. https://doi.org/10.2215/CJN.06810909 (2010).
Schouten, J. P. et al. Relative quantification of 40 nucleic acid sequences by multiplex ligation-dependent probe amplification. Nucleic Acids Res. 30, e57 (2002).
Acknowledgements
We are grateful to the volunteer families and individuals who participated in this study. MUC1 genotyping was performed by AmCare Genomics Laboratory, Guangzhou, China. We acknowledge Doctor Guoqin Wang and Doctor Hongliang Rui for assistance with MUC1 mutation test. The work was supported by National Natural Science Foundation of China (81570664).
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Y.C. conceived of and designed the study. M.X., Y.W., Y.L. and N.W. collected the samples and analyzed the data. V.W.Z. provided MUC1 sequence and analyzed the data. K.G. analyzed and interpreted the data; searched the literature; and wrote the draft. Y.C. and V.W.Z. reviewed and edit the writing. H.C. collected and provided the MUC1 mutation positive control. All authors approved the final version of the manuscript.
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Gong, K., Xia, M., Wang, Y. et al. Autosomal dominant tubulointerstitial kidney disease genotype and phenotype correlation in a Chinese cohort. Sci Rep 11, 3615 (2021). https://doi.org/10.1038/s41598-020-79331-w
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DOI: https://doi.org/10.1038/s41598-020-79331-w
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