Collagen type IV‐related nephropathies in Portugal: pathogenic COL4A3 and COL4A4 mutations and clinical characterization of 25 families

Pathogenic mutations in genes COL4A3/COL4A4 are responsible for autosomal Alport syndrome (AS) and thin basement membrane nephropathy (TBMN). We used Sanger sequencing to analyze all exons and splice site regions of COL4A3/COL4A4, in 40 unrelated Portuguese probands with clinical suspicion of AS/TBMN. To assess genotype–phenotype correlations, we compared clinically relevant phenotypes/outcomes between homozygous/compound heterozygous and apparently heterozygous patients. Seventeen novel and four reportedly pathogenic COL4A3/COL4A4 mutations were identified in 62.5% (25/40) of the probands. Regardless of the mutated gene, all patients with ARAS manifested chronic renal failure (CRF) and hearing loss, whereas a minority of the apparently heterozygous patients had CRF or extrarenal symptoms. CRF was diagnosed at a significantly younger age in patients with ARAS. In our families, the occurrence of COL4A3/COL4A4 mutations was higher, while the prevalence of XLAS was lower than expected. Overall, a pathogenic COL4A3/COL4A4/COL4A5 mutation was identified in >50% of patients with fewer than three of the standard diagnostic criteria of AS. With such a population background, simultaneous next‐generation sequencing of all three genes may be recommended as the most expedite approach to diagnose collagen IV‐related glomerular basement membrane nephropathies.     

X-linked Alport syndrome in Hellenic families: phenotypic heterogeneity and mutations near interruptions of the collagen domain in COL4A5

The X-linked Alport syndrome (ATS) is caused by mutations in COL4A5 and exhibits a widely variable expression. Usually ATS is heralded with continuous microhematuria which rapidly progresses to proteinuria, hypertension and chronic or end-stage renal disease (ESRD) by adolescence, frequently accompanied by sensorineural deafness and ocular complications. Milder forms of ATS also exist. We studied 42 patients (19M, 23F) of nine Hellenic families suspected clinically of X-linked ATS who presented with marked phenotypic heterogeneity. We identified mutations in COL4A5 in six families. Two males with nonsense mutation E228X reached ESRD by ages 14 and 18. Frameshift mutation 2946delT followed the same course with early onset renal involvement and deafness. However, two males with the milder missense mutation G624D, reached ESRD after 39 years and one patient showed thin basement membrane nephropathy (TBMN). Another 5/8 affected males with missense mutation P628L also developed ESRD between 30 and 57 years, while three exhibit only mild chronic renal failure (CRF). The data support previous findings that certain mutations are associated with milder phenotypes and confirm that mutation G624D may be expressed as TBMN with familial hematuria. Similar conclusions apply for missense mutation P628L. Interestingly, mutations G624D and P628L are near the 12th natural interruption of COL4A5 triple helical domain, which may explain the milder phenotype.     

Efficient detection of alport syndrome COL4a5 mutations with multiplex genomic PCR‐SSCP

We have performed effective mutation screening of COL4A5 with a new method of direct, multiplex genomic amplification that employs a single buffer condition and PCR profile. Application of the method to a consecutive series of 46 United States patients with diverse indications of Alport syndrome resulted in detection of mutations in 31 cases and of five previously unreported polymorphisms. With a correction for the presence of cases that are not likely to be due to changes at the COL4A5 locus, the mutation detection sensitivity is greater than 79%. The test examines 52 segments, including the COL4A6/COL4A5 intergenic promoter region, all 51 of the previously recognized exons and two newly detected exons between exons 41 and 42 that encode an alternatively spliced mRNA segment. New genomic sequence information was generated and used to design primer pairs that span substantial intron sequences on each side of all 53 exons. For SSCP screening, 16 multiplex PCR combinations (15 4‐plex and 1 3‐plex) were used to provide complete, partially redundant coverage of the gene. The selected combinations allow clear resolution of products from each segment using various SSCP gel formulations. One of the 29 different mutations detected initially seemed to be a missense change in exon 32 but was found to cause exon skipping. Another missense variant may mark a novel functional site located in the collagenous domain. © 2001 Wiley‐Liss, Inc.     

Three novel COL4A4 mutations resulting in stop codons and their clinical effects in autosomal recessive Alport syndrome

Autosomal recessive Alport syndrome is caused by mutations in the COL4A3 and COL4A4 genes which code for the alpha3 and alpha4 chains of type IV collagen. These mutations result in haematuria, progressive renal impairment and often hearing loss, lenticonus and retinopathy. We describe here the mutations demonstrated by screening the 47 coding exons of the COL4A4 gene in six families with autosomal recessive Alport syndrome using PCR-single stranded conformational polymorphism (SSCP) analysis. Six sequence variants were identified. These included three novel mutations (2846delG, 2952delG and S969X) in exons 30 - 32 that all resulted in premature stop codons. These mutations were demonstrated in the heterozygous form in 3 families, and the S969X mutation was also present in the homozygous form in one of the two consanguinous families. These three mutations accounted for 40% (4/10) of the total mutant alleles in the six families studied. Six of the seven (86%) individuals with autosomal recessive Alport syndrome who had these mutations in the compound heterozygous or homozygous forms developed renal failure in adulthood, as well as hearing loss and ocular abnormalities. Haematuria was present in 15 of the 17 (88%) heterozygous mutation carriers. The other non-pathogenic sequence variants noted in COL4A4 included a nonglycine missense variant (L1004P), an intronic variant (4731-8 T>C) and a neutral polymorphism (V1516V).     

Frequent COL4 mutations in familial microhematuria accompanied by later‐onset Alport nephropathy due to focal segmental glomerulosclerosis

Familial microscopic hematuria (FMH) is associated with a genetically heterogeneous group of conditions including the collagen‐IV nephropathies, the heritable C3/CFHR5 nephropathy and the glomerulopathy with fibronectin deposits. The clinical course varies widely, ranging from isolated benign familial hematuria to end‐stage renal disease (ESRD) later in life. We investigated 24 families using next generation sequencing (NGS) for 5 genes: COL4A3, COL4A4, COL4A5, CFHR5 and FN1. In 17 families (71%), we found 15 pathogenic mutations in COL4A3/A4/A5, 9 of them novel. In 5 families patients inherited classical AS with hemizygous X‐linked COL4A5 mutations. Even more patients developed later‐onset Alport‐related nephropathy having inherited heterozygous COL4A3/A4 mutations that cause thin basement membranes. Amongst 62 heterozygous or hemizygous patients, 8 (13%) reached ESRD, while 25% of patients with heterozygous COL4A3/A4 mutations, aged >50‐years, reached ESRD. In conclusion, COL4A mutations comprise a frequent cause of FMH. Heterozygous COL4A3/A4 mutations predispose to renal function impairment, supporting that thin basement membrane nephropathy is not always benign. The molecular diagnosis is essential for differentiating the X‐linked from the autosomal recessive and dominant inheritance. Finally, NGS technology is established as the gold standard for the diagnosis of FMH and associated collagen‐IV glomerulopathies, frequently averting the need for invasive renal biopsies.     

一个新的COL4A5基因的剪接位点突变引起Alport综合征

目的 对一个Alport综合征家系进行研究,期望找到导致该家系发病的遗传基础.方法 对家系成员采样并提取DNA,对家系中的先证者和1名正常对照进行COL4A5基因全部编码区域的突变检测,限制性片段长度多态件分析技术对家系中所有成员和200名正常对照进行验证.结果 在该Alport综合征家系中发现一个新的COL4A5基因的剪接位点突变c.1517-1G＞T,而在家系的未患病成员,以及对照人群中未能检测到该突变.结论 发现了一个新的COL4A5基因的剪接位点改变c.1517-IG＞T,该突变可导致Alport综合征,该发现丰富了引起Alport综合征的COL4A5基因的突变谱.     

Detection of 12 novel mutations in the collagenous domain of the COL4A5 gene in Alport syndrome patients

A population of 35 Alport syndrome patients, defined by strict diagnostic criteria, was screened for mutations in 23 exons of the COL4A5 gene by SSCP analysis. Mobility shifts were observed in 12 out of 35 patients and were shown to represent genuine mutations. 9 of these were glycine substitutions in the collagenous domain (in exons 20, 25, 26, 29, 31, and 41), 2 were small deletions resulting in frameshifts (in exons 21 and 31), and one was a splice site mutation (in exon 12). © 1995 Wiley-Liss, Inc.     

A novel missense mutation in exon 3 of the COL4A5 gene associated with late-onset Alport syndrome

We have identified a novel missense transition (362G→A) in exon 3 of the COL4A5 gene in a male patient with late-onset Alport syndrome. We used non-isotopic single strand conformation polymorphism, heteroduplex analysis, and automated DNA sequencing. The mutation changes a conserved glycine at codon 54 for an aspartic acid (Gly54Asp), which abolishes a BstNI site. Using restriction analysis, we identified the heterozygous carrier status in the two daughters of the proband. Our findings are in keeping with the hypothesis that slower progressive forms of Alport syndrome are more often associated with missense mutations rather than large deletions or frameshifts. This is the first mutation described in the N-terminus triple helical 7S domain of the COL4A5 gene in an Alport syndrome patient.     

A study of the SCN5A gene in a cohort of 76 patients with Brugada syndrome

We aim to study the SCN5A gene in a cohort of Brugada syndrome (BS) patients and evaluate the genotype–phenotype correlation. BS is caused by mutations in up to 10 different genes, SCN5A being the most frequently involved. Large genomic rearrangements in SCN5A have been associated with conduction disease, but its prevalence in BS is unknown. Seventy‐six non‐related patients with BS were studied. Clinical characteristics and family risk profile were recorded. Direct sequencing and multiplex ligation‐dependent probe amplification (MLPA) of the SCN5A gene for identification of mutations and larger rearrangements were performed, respectively. Eight patients (10.5%) had point mutations (R27H, E901K, G1743R (detected in three families), V728I, N1443S and E1152X). Patients with mutations had a trend toward a higher proportion of spontaneous type I Brugada electrocardiogram (ECG) (87.5% vs 52.9%, p = 0.06) and had evidence of familial disease (62.5%, vs 23.5%, p = 0.03). The symptoms and risk profile of the carriers were not different from wild‐type probands. There were non‐significant differences in the prevalence of type I ECG, syncope and history of arrhythmia in carriers of selected polymorphisms. None of the patients had any deletion/duplication in the SCN5A gene. In conclusion, 10.5% of our patients had mutations in the SCN5A gene. Patients with mutations seemed to have more spontaneous type I ECG, but no differences in syncope or arrhythmic events compared with patients without mutations. Larger studies are needed to evaluate the role of polymorphisms in the SCN5A in the expression of the phenotype and prognosis. Large rearrangements were not identified in the SCN5A gene using the MLPA technique.     

Precise variant interpretation,phenotype ascertainment,and genotype–phenotype correlation of children in the EARLY PRO‐TECT Alport trial

Early initiation of therapy in patients with Alport syndrome (AS) slows down renal failure by many years. Genotype–phenotype correlations propose that the location and character of the individual's variant correlate with the renal outcome and any extra renal manifestations. In‐depth clinical and genetic data of 60/62 children who participated in the EARLY PRO‐TECT Alport trial were analyzed. Genetic variants were interpreted according to current guidelines and criteria. Genetically solved patients with X‐linked inheritance were then classified according to the severity of their COL4A5 variant into less‐severe, intermediate, and severe groups and disease progress was compared. Almost 90% of patients were found to carry (likely) pathogenic variants and classified as genetically solved cases. Patients in the less‐severe group demonstrated a borderline significant difference in disease progress compared to those in the severe group (p = 0.05). While having only limited power according to its sample size, an obvious strength is the precise clinical and genetic data of this well ascertained cohort. As in published data differences in clinical progress were shown between patients with COL4A5 less‐severe and severe variants. Therefore, clinical and segregational data are important for variant (re)classification. Genetic testing should be mandatory allowing early diagnosis and therapy of AS.     

Spectrum of ATP7B mutations and genotype–phenotype correlation in large‐scale Chinese patients with Wilson Disease

Wilson disease (WD), an inherited disorder associated with ATP7B gene, has a wide spectrum of genotypes and phenotypes. In this study, we developed a rapid multiplex PCR‐MassArray method for detecting 110 mutant alleles of interest, and used it to examine genomic DNA from 1222 patients and 110 healthy controls. In patients not found to have any mutation in the 110 selected alleles, PCR‐Sanger sequencing was used to examine the ATP7B gene. We identified 88 mutations, including 9 novel mutations. Our analyses revealed p.Arg778Leu, p.Arg919Gly and p.Thr935Met showed some correlations to phenotype. The p.Arg778Leu was related to younger onset age and lower levels of ceruloplasmin (Cp) and serum copper, while p.Arg919Gly and p.Thr935Met both indicated higher Cp levels. Besides, the p.Arg919Gly was related to neurological subtype, and p.Thr935Met showed significant difference in the percentage of combined neurological and visceral subtype. Moreover, for ATP7B mutations, the more severe impact on ATP7B protein was, the younger onset age and lower Cp level presented. The feasibility of presymptomatic DNA diagnosis and predicting clinical manifestation or severity of WD would be facilitated with identified mutations and genotype–phenotype correlation precisely revealed in the study.     

Position of Glycine Substitutions in the Triple Helix of COL6A1, COL6A2, and COL6A3 is Correlated with Severity and Mode of Inheritance in Collagen VI Myopathies

Glycine substitutions in the conserved Gly‐X‐Y motif in the triple helical (TH) domain of collagen VI are the most commonly identified mutations in the collagen VI myopathies including Ullrich congenital muscular dystrophy, Bethlem myopathy, and intermediate (INT) phenotypes. We describe clinical and genetic characteristics of 97 individuals with glycine substitutions in the TH domain of COL6A1, COL6A2, or COL6A3 and add a review of 97 published cases, for a total of 194 cases. Clinical findings include severe, INT, and mild phenotypes even from patients with identical mutations. INT phenotypes were most common, accounting for almost half of patients, emphasizing the importance of INT phenotypes to the overall phenotypic spectrum. Glycine substitutions in the TH domain are heavily clustered in a short segment N‐terminal to the 17th Gly‐X‐Y triplet, where they are acting as dominants. The most severe cases are clustered in an even smaller region including Gly‐X‐Y triplets 10–15, accounting for only 5% of the TH domain. Our findings suggest that clustering of glycine substitutions in the N‐terminal region of collagen VI is not based on features of the primary sequence. We hypothesize that this region may represent a functional domain within the triple helix.     

Identification and characterization of 20 novel pathogenic variants in 60 unrelated Indian patients with mucopolysaccharidoses type I and type II

Mucopolysaccharidoses (MPS), a subgroup of lysosomal storage disorders, are caused due to deficiency of specific lysosomal enzyme involved in catabolism of glycosaminoglycans. To date more than 200 pathogenic variants in the alpha‐l ‐iduronidase (IDUA) for MPS I and ～500 pathogenic variants in the iduronate‐2‐sulphatase (IDS) for MPS II have been reported worldwide. The mutation spectrum of MPS type I and MPS type II disorders in Indian population is not characterized yet. In this study, we carried out clinical, biochemical, molecular and in silico analyses to establish the mutation spectrum of MPS I and MPS II in the Indian population. We conducted molecular analysis for 60 MPS‐affected patients [MPS I (n = 30) (Hurler syndrome = 17, Hurler–Scheie syndrome = 13), and MPS II (n = 30) (severe = 18, attenuated = 12)] and identified a total of 44 [MPS I (n = 22) and MPS II (n = 22)] different pathogenic variants comprising missense, nonsense, frameshift, gross deletions and splice site variants. A total of 20 [MPS I (n = 14), and MPS II (n = 6)] novel pathogenic sequence variants were identified in our patient cohort. We found that 32% of pathogenic variants detected in IDUA were recurrent and 25% in MPS II. This is the first study revealing the mutation spectrum of MPS I and MPS II patients in the Indian population.     

The international dystrophic epidermolysis bullosa patient registry: an online database of dystrophic epidermolysis bullosa patients and their COL7A1 mutations

Dystrophic epidermolysis bullosa (DEB) is a heritable blistering disorder that can be inherited autosomal dominantly (DDEB) or recessively (RDEB) and covers a group of several distinctive phenotypes. A large number of unique COL7A1 mutations have been shown to underlie DEB. Although general genotype-phenotype correlation rules have emerged, many exceptions to these rules exist, compromising disease diagnosing and genetic counseling. We therefore constructed the International DEB Patient Registry (http://www.deb-central.org), aimed at worldwide collection and sharing of phenotypic and genotypic information on DEB. As of May 2011, this MOLGENIS-based registry contains detailed information on 508 published and 71 unpublished patients and their 388 unique COL7A1 mutations, and includes all combinations of mutations. The current registry RDEB versus DDEB ratio of 4:1, if compared to prevalence figures, suggests underreporting of DDEB in the literature. Thirty-eight percent of mutations stored introduce a premature termination codon (PTC) and 43% an amino acid change. Submission wizards allow users to quickly and easily share novel information. This registry will be of great help in disease diagnosing and genetic counseling and will lead to novel insights, especially in the rare phenotypes of which there is often lack of understanding. Altogether, this registry will greatly benefit the DEB patients.     

Functional characterization of novel NR5A1 variants reveals multiple complex roles in disorders of sex development

Variants in the NR5A1 gene encoding SF1 have been described in a diverse spectrum of disorders of sex development (DSD). Recently, we reported the use of a targeted gene panel for DSD where we identified 15 individuals with a variant in NR5A1, nine of which are novel. Here, we examine the functional effect of these changes in relation to the patient phenotype. All novel variants tested had reduced trans‐activational activity, while several had altered protein level, localization, or conformation. In addition, we found evidence of new roles for SF1 protein domains including a region within the ligand binding domain that appears to contribute to SF1 regulation of Müllerian development. There was little correlation between the severity of the phenotype and the nature of the NR5A1 variant. We report two familial cases of NR5A1 deficiency with evidence of variable expressivity; we also report on individuals with oligogenic inheritance. Finally, we found that the nature of the NR5A1 variant does not inform patient outcomes (including pubertal androgenization and malignancy risk). This study adds nine novel pathogenic NR5A1 variants to the pool of diagnostic variants. It highlights a greater need for understanding the complexity of SF1 function and the additional factors that contribute.