Identification of 12 novel mutations in the SLC3A1 gene in Swedish cystinuria patients

Cystinuria is an autosomal recessive disorder that affects luminal transport of cystine and dibasic amino acids in the kidneys and the small intestine. Three subtypes of cystinuria can be defined biochemically, and the classical form (type I) has been associated with mutations in the amino acid transporter gene SLC3A1. The mutations detected in SLC3A1 tend to be population specific and have not been previously investigated in Sweden. We have screened the entire coding sequence and the intron/exon boundaries of the SLC3A1 gene in 53 cystinuria patients by means of single strand conformation polymorphism (SSCP) and DNA sequencing. We identified 12 novel mutations (a 2 bp deletion, one splice site mutation, and 10 missense mutations) and detected another three mutations that were previously reported. Five polymorphisms were also identified, four of which were formerly described. The most frequent mutation in this study was the previously reported M467T and it was also detected in the normal population with an allelic frequency of 0.5%. Thirty‐seven patients were homozygous for mutations in the SLC3A1 gene and another seven were heterozygous which implies that other genes may be involved in cystinuria. Future investigation of the non‐type I cystinuria gene SLC7A9 may complement our results but recent studies also suggest the presence of other potential disease genes. Hum Mutat 18:516–525, 2001. © 2001 Wiley‐Liss, Inc.     

Clinical, biochemical and molecular characterization of cystinuria in a cohort of 12 patients

Cystinuria is a rare autosomal inherited disorder characterized by impaired transport of cystine and dibasic aminoacids in the proximal renal tubule. Classically, cystinuria is classified as type I (silent heterozygotes) and non-type I (heterozygotes with urinary hyperexcretion of cystine). Molecularly, cystinuria is classified as type A (mutations on SLC3A1 gene) and type B (mutations on SLC7A9 gene). The goal of this study is to provide a comprehensive clinical, biochemical and molecular characterization of a cohort of 12 Portuguese patients affected with cystinuria in order to provide insight into genotype-phenotype correlations. We describe seven type I and five non-type I patients. Regarding the molecular classification, seven patients were type A and five were type B. In SLC3A1 gene, two large genomic rearrangements and 13 sequence variants, including four new variants c.611-2A>C; c.1136+44G>A; c.1597T (p.Y533N); c.*70A>G, were found. One large genomic rearrangement was found in SLC7A9 gene as well as 24 sequence variants including 3 novel variants: c.216C>T (p.C72C), c.1119G>A (p.S373S) and c.*82C>T. In our cohort the most frequent pathogenic mutations were: large rearrangements (33.3% of mutant alleles) and a missense mutation c.1400T>C (p.M467T) (11.1%). This report expands the spectrum of SLC3A1 and SLC7A9 mutations and provides guidance in the clinical implementation of molecular assays in routine genetic counseling of Portuguese patients affected with cystinuria.     

Functional analysis of mutations in SLC7A9, and genotype-phenotype correlation in non-Type I cystinuria

Cystinuria (OMIM 220100) is a common recessive disorder of renal reabsorption of cystine and dibasic amino acids that results in nephrolithiasis of cystine. Mutations in SLC3A1, which encodes rBAT, cause Type I cystinuria, and mutations in SLC7A9, which encodes a putative subunit of rBAT (b(o,+)AT), cause non-Type I cystinuria. Here we describe the genomic structure of SLC7A9 (13 exons) and 28 new mutations in this gene that, together with the seven previously reported, explain 79% of the alleles in 61 non-Type I cystinuria patients. These data demonstrate that SLC7A9 is the main non-Type I cystinuria gene. Mutations G105R, V170M, A182T and R333W are the most frequent SLC7A9 missense mutations found. Among heterozygotes carrying these mutations, A182T heterozygotes showed the lowest urinary excretion values of cystine and dibasic amino acids. Functional analysis of mutation A182T after co-expression with rBAT in HeLa cells revealed significant residual transport activity. In contrast, mutations G105R, V170M and R333W are associated to a complete or almost complete loss of transport activity, leading to a more severe urinary phenotype in heterozygotes. SLC7A9 mutations located in the putative transmembrane domains of b(o,+)AT and affecting conserved amino acid residues with a small side chain generate a severe phenotype, while mutations in non-conserved residues give rise to a mild phenotype. These data provide the first genotype-phenotype correlation in non-Type I cystinuria, and show that a mild urinary phenotype in heterozygotes may associate with mutations with significant residual transport activity.     

Non-Type I Cystinuria Associated with Mental retardation and Ataxia in a Korean Boy with a New Missence Mutation(G173R) in the SLC7A9 Gene

Cystinuria is an inherited renal and intestinal disease characterized by defective amino acids reabsorption and cystine urolithiasis. It is unusually associated with neurologic symptoms. Mutations in two genes, SLC3A1 and SLC7A9, have been identified in cystinuric patients. This report presents a 13-yr-old boy with cystinuria who manifested difficulty in walking, ataxia, and mental retardation. Somatosensory evoked potential of posterior tibial nerve stimulation showed the central conduction dysfunction through the posterior column of spinal cord. He was diagnosed non-type I cystinuria by urinary amino acid analysis and oral cystine loading test. We screened him and his family for gene mutation by direct sequencing of SLC3A1 and SLC7A9 genes. In this patient, we identified new missence mutation G173R in SLC7A9 gene.     

Identification of novel SLC3A1 gene mutations in Spanish cystinuria families and association with clinical phenotypes

Cystinuria is an inherited metabolic disease characterized by an abnormal urinary excretion of cystine and dibasic amino acids, leading to kidney stone formation. Incidence of cystinuria in the Mediterranean Spanish population is one of the highest in the world. In view of the low prevalence of previously reported mutations in the SLC3A1 gene, analyses to identify novel variants were carried out on 20 cystinuria families. Additionally, we investigated the possible association between these molecular variants and clinical phenotypes. Genomic DNA from 48 cystinuria patients, 44 healthy relatives and 81 unrelated controls from the East Mediterranean coast of Spain was screened by conformation sensitive gel electrophoresis. Abnormal patterns were confirmed by nucleotide sequence determination and by further restriction fragment-length polymorphism. We only found 11 genetic variants within the SLC3A1 gene: five known polymorphisms (114C > A, 231T > A, 1136 + 3delT, 1332 + 7T > C and 1338G > A), four point mutations (M467T, R452W, I105R and Y461X), one single base pair deletion (1767delA) and one 2-bp insertion (1670insAT). Two of these genetic variants (I105R and 1670insAT) were described for the first time. All mutations but one were detected in families classified as Type I cystinuria due to the transmission pattern of the disease. Association analyses revealed that 231T > A (M467T), 1136 + 3delT and 1332 + 7T > C genetic variants were statistically related with urinary amino acid excretion in cystinuria patients. Although some molecular variants within the SLC3A1 gene were associated with clinical traits in cystinuria patients, the low detection rate of mutations in this gene strongly suggests that variation of the SLC3A1 is not the major genetic factor contributing to cystinuria in this Mediterranean population.     

Functional analysis of a new splice site mutation, c.605-3C>A, in the cystinuria gene SLC7A9 leading to exon skipping

Cystinuria is a hereditary disorder of cystine and dibasic amino acid transport across the luminal membrane of renal tubules and intestine, resulting in recurrent nephrolithiasis. While mutations in the SLC3A1 gene cause type I cystinuria, patients with non-type I cystinuria carry mutations in the SLC7A9 gene. Up to now, more than 80 mutations in SLC3A1 and 50 in SLC7A9 have been reported in the literature. While deletions, duplications, and truncating mutations can often unambiguously classified to be pathogenic, the functional relevance of base pair substitutions is often difficult to predict. To determine the functional relevance of a new splice site mutation in intron 5 of SLC7A9, c.605-3C>A, we transfected COS7 cells with expression constructs containing the wild-type and mutant allele, respectively. cDNAs derived from the resulting SLC7A9 mRNAs were sequenced. By this approach we could demonstrate that the mutant allele c.605-3A causes exon skipping and therefore represents a splice site mutation. To the best of our knowledge, this is the first splice site mutation in a cystinuria gene with a proven functional consequence.     

Spectrum of mutations in cystinuria patients presenting with prenatal hyperechoic colon

Cystinuria is a heterogeneous, rare but important cause of inherited kidney stone disease due to mutations in 2 genes: SLC3A1 and SLC7A9. Antenatal hyperechoic colon (HEC) has been reported in some patients as a non‐pathological consequence of the intestinal transport defect. We report 83 patients affected by cystinuria: 44 presented prenatally with a HEC (HEC group) and 39 with a classical postnatal form (CC group). SLC3A1 and SLC7A9 were sequenced. All patients were fully genotyped, and the relationship between the genotype and clinical features was analyzed. We identified mutations in SLC3A1 in 80% of the HEC group and in only 49% of the CC group. The SLC3A1 p.Thr216Met mutation was found in 21% of the alleles in the HEC group but was never found in the CC group. Most of the mutations found in the HEC group were considered severe mutations in contrast with the CC group. Twenty‐five novel mutations were reported. This study shows a relationship between genotype and the clinical form of cystinuria, suggesting that only the patients with the most severe mutations presented with an HEC. These results emphasized the need for prenatal cystinuria screening using classical third‐trimester ultrasound scan and the early management of suspected newborns.     

New insights into cystinuria: 40 new mutations, genotype-phenotype correlation, and digenic inheritance causing partial phenotype

Objective: To clarify the genotype–phenotype correlation and elucidate the role of digenic inheritance in cystinuria. Methods: 164 probands from the International Cystinuria Consortium were screened for mutations in SLC3A1 (type A) and SLC7A9 (type B) and classified on the basis of urine excretion of cystine and dibasic amino acids by obligate heterozygotes into 37 type I (silent heterozygotes), 46 type non-I (hyperexcretor heterozygotes), 14 mixed, and 67 untyped probands. Results: Mutations were identified in 97% of the probands, representing 282 alleles (86.8%). Forty new mutations were identified: 24 in SLC3A1 and 16 in SLC7A9. Type A heterozygotes showed phenotype I, but mutation DupE5-E9 showed phenotype non-I in some heterozygotes. Type B heterozygotes showed phenotype non-I, with the exception of 10 type B mutations which showed phenotype I in some heterozygotes. Thus most type I probands carried type A mutations and all type non-I probands carried type B mutations. Types B and A mutations contributed to mixed type, BB being the most representative genotype. Two mixed cystinuria families transmitted mutations in both genes: double compound heterozygotes (type AB) had greater aminoaciduria than single heterozygotes in their family. Conclusions: Digenic inheritance is an exception (two of 164 families), with a limited contribution to the aminoaciduria values (partial phenotype) in cystinuria. Further mutational analysis could focus on one of the two genes (SLC3A1 preferentially for type I and SLC7A9 for type non-I probands), while for mixed probands analysis of both genes might be required, with priority given to SLC7A9.     

Characterization of SLC26A9 in Patients with CF‐Like Lung Disease

Diffuse bronchiectasis is a common problem in respiratory clinics. We hypothesized that mutations in the solute carrier 26A9 (SLC26A9) gene, encoding for a chloride (Cl^?) transporter mainly expressed in lungs, may lead to defects in mucociliary clearance. We describe two missense variants in the SLC26A9 gene in heterozygote patients presenting with diffuse idiopathic bronchiectasis : p.Arg575Trp, identified in a patient also heterozygote for p.Phe508del in the CFTR gene; and p.Val486Ile. Expression of both mutants in Xenopus laevis oocytes abolished SLC26A9‐mediated Cl^? conductance without decreasing protein membrane expression. Coexpression of CFTR with SLC26A9–p.Val486Ile resulted in a significant increase in the Cl^? current induced by PKA stimulation, similar to that obtained in oocytes expressing CFTR and SLC26A9–WT. In contrast, coexpression of CFTR with SLC26A9–p.Arg575Trp inhibited SLC26A9‐enhanced CFTR activation upon PKA. Further structure–function analyses led us to propose a site encompassing Arg575 in the SLC26A9–STAS domain for CFTR–SLC26A9 interaction. We hypothesize that SLC26A9–p.Arg575Trp prevented SLC26A9‐mediated functional activation of CFTR by altering SLC26A9–CFTR interaction. Although we cannot confirm that these mutations by themselves are deleterious, we propose that they trigger the pathogenic role of a single CFTR mutation and provide insight into a novel mechanism of Cl^? transport alteration across the respiratory mucosa, based on functional inhibition of CFTR.     

Mutation spectrum of human SLC39A4 in a panel of patients with acrodermatitis enteropathica

Acrodermatitis enteropathica is rare autosomal recessive disorder characterized by a severe nutritional zinc deficiency. We and others have recently identified the human gene encoding an intestinal zinc transporter of the ZIP family, SLC39A4, as the mutated gene in acrodermatitis enteropathica (AE). A first mutation screening in 8 AE families (15 patients out of 36 individuals) revealed the presence of six different mutations described elsewhere. Based on these results, we have evaluated the involvement of SLC39A4 in 14 patients of 12 additional AE pedigees coming either from France, Tunisia, Austria or Lithuania. A total of 7 SLC39A4 mutations were identified (1 deletion, 2 nonsense, 2 missense, and 2 modifications of splice site), of which 4 are novel: a homozygous nonsense mutation in 3 consanguineous Tunisian families [c.143T>G (p.Leu48X)], a heterozygous nonsense mutation (c.1203G>A (p.Trp401X)) in a compound heterozygote from Austria also exhibiting an already known missense mutation, and distinct homozygous mutations in families from France or Tunisia [c.475-2A>G and c.184T>C (p.Cys62Arg)]. Furthermore, two other potential mutations [c.850G>A (p.Glu284Lys) and c.193-113T>C] were also observed at homozygous state in a French family formerly described. This study brings to 21 the number of reported SLC39A4 mutations in AE families.     

Association of SLC26A4 muations with clinical features and thyroid function in deaf infants with enlarged vestibular aqueduct

Pendred syndrome and non-syndromic recessive deafness associated with enlarged vestibular aqueduct (NSRD with EVA) are caused by mutations in the SLC26A4 (PDS) gene. Unlike NSRD with EVA, Pendred syndrome is characterized by goiter, which may be present after early adulthood. However, the clinical diagnosis of these two disorders is difficult in deaf children. Expression of the SLC26A4 gene may be responsible for iodide transport in the thyroid as well as for formation and function of the inner ear. Here, we analyzed the SLC26A4 gene and performed thyroid function tests (FT3, FT4, TSH, and Thyroglobulin) on six congenitally deaf infants (mean age 2.7 years) with EVA. Mutation of the SLC26A4 gene was identified in five patients: four were compound heterozygous (H723R/919−2A>G, H723R/IVS15+5G>A, H723R/R581S, IVS7-2A>G/IVS8+1G>A), the fifth had a frameshift mutation (322delC). All the patients demonstrated an elevation of serum thyroglobulin level. FT3 level was elevated in four of the five patients. The patient who did not have a detectable gene mutation showed normal thyroid function. We conclude that the mutations in the SLC26A4 gene identified here are highly associated with high serum thyroglobulin levels in congenital and deafness infants. These mutations may be of value for the diagnosis of Pendred syndrome and NSRD with EVA.     

变性高效液相色谱法分析非综合征型耳聋人群SLC26A4基因突变

目的 研究非综合征型耳聋(nonsyndromic hearing loss,NSHL)患者SLC26A4基因的突变情况,为临床上NSHL患者基因诊断提供指导.方法 PCR分别扩增SLC26A4基因的21个外显子及其侧翼序列,所得目的 片段用变性高效液相色谱(denaturing high-performance liquid chromatorgraphy,DHPLC)进行突变筛查,有异常峰形的样本进行DNA测序.结果 在所选30例无血缘关系且GJB2基因检测未发现突变的NSHL患者中,共检测出10种SLC26A4基因变异,其中包括7种已知突变,2种未见报道的新突变(F572L和D87Y),及一种已知多态(Ivs11+47T＞C),其中Ivs7-2A＞G是最常见的突变,约占总突变的40%.结论 SLC26A4基因为仅次于GJB2的导致NSHL的相关基因,在(GJB2基因检测未发现突变的NSHL人群中SLC26A4基因的检出率达到23.3%,其中Ivs7-2A＞G是其最常见的突变.     

Is the SLC7A10 gene on chromosome 19 a candidate locus for cystinuria?

One of the genes (SLC7A9) that causes cystinuria, an inborn error of amino acid transport, is localized to 19q13. Close examination of human genomic DNA sequences has identified a similar gene (SLC7A10) that also maps to the 19q13.1 region and is highly expressed in kidney. The homologies between SLC7A9 and SLC7A10 are likely the result of gene duplication. SLC7A10 is known to encode a protein with a function similar to that of the SLC7A9 gene product. To determine if mutations in the SLC7A10 gene could also cause cystinuria, we characterized the primary genomic structure and sequenced the 11 exons and surrounding sequences from 10 unrelated patients with cystinuria. We identified one missense mutation which may account for cystinuria in one family. We also observed one intronic change, as well as one silent mutation, that were seen only in cystinuria patients. We therefore suggest that the SLC7A10 gene warrants further investigation as another candidate gene for cystinuria.     

Identification of seven novel mutations including the first two genomic rearrangements in SLC26A3 mutated in congenital chloride diarrhea

Congenital chloride diarrhea (CLD) is an autosomal recessive disorder characterized by defective intestinal electrolyte absorption, resulting in voluminous osmotic diarrhea with high chloride content. A variety of mutations in the solute carrier family 26, member 3 gene (SLC26A3, previously known as CLD or DRA) are responsible for the disease. Since the identification of the SLC26A3 gene and the determination of its genomic structure, altogether three founder and 17 private mutations have been characterized within miscellaneous ethnic groups. We screened for mutations in seven unrelated families with CLD. The diagnoses were confirmed by fecal chloride measurements. The combined PCR-SSCP and sequencing analyses revealed altogether seven novel mutations including two missense mutations (S206P, D468V), two splicing defects (IVS12-1G>C, IVS13-2delA), one nonsense mutation (Q436X), one insertion/deletion mutation (2104-2105delGGins29-bp), and an intragenic deletion of SLC26A3 exons 7 and 8. Two previously identified mutations were also found. This is the first report of rearrangement mutations in SLC26A3. Molecular features predisposing SLC26A3 for the two rearrangements may include repetitive elements and palindromic-like sequences. The increasingly wide diversity of SLC26A3 mutations suggests that mutations in the SLC26A3 gene may not be rare events.     

Clinical and Molecular Characteristics of SLC16A2 (MCT8) Mutations in Three Families with the Allan–Herndon–Dudley Syndrome

Mutations in the thyroid hormone transporter SLC16A2 (MCT8) cause the Allan–Herndon–Dudley Syndrome (AHDS), characterized by severe psychomotor retardation and peripheral thyrotoxicosis. Here, we report three newly identified AHDS patients. Previously documented mutations were identified in probands 1 (p.R271H) and 2 (p.G564R), resulting in a severe clinical phenotype. A novel mutation (p.G564E) was identified in proband 3, affecting the same Gly564 residue, but resulting in a relatively mild clinical phenotype. Functional analysis in transiently transfected COS‐1 and JEG‐3 cells showed a near‐complete inactivation of TH transport for p.G564R, whereas considerable cell‐type‐dependent residual transport activity was observed for p.G564E. Both mutants showed a strong decrease in protein expression levels, but differentially affected V_max and K_m values of T3 transport. Our findings illustrate that different mutations affecting the same residue may have a differential impact on SLC16A2 transporter function, which translates into differences in severity of the clinical phenotype.     

Molecular spectrum of SLC22A5 (OCTN2) gene mutations detected in 143 subjects evaluated for systemic carnitine deficiency

Systemic primary carnitine deficiency (CDSP) is caused by recessive mutations in the SLC22A5 (OCTN2) gene encoding the plasmalemmal carnitine transporter and characterized by hypoketotic hypoglycemia, and skeletal and cardiac myopathy. The entire coding regions of the OCTN2 gene were sequenced in 143 unrelated subjects suspected of having CDSP. In 70 unrelated infants evaluated because of abnormal newborn screening (NBS) results, 48 were found to have at least 1 mutation/unclassified missense variant. Twenty‐eight of 33 mothers whose infants had abnormal NBS results were found to carry at least 1 mutation/unclassified missense variant, including 11 asymptomatic mothers who had 2 mutations. Therefore, sequencing of the OCTN2 gene is recommended for infants with abnormal NBS results and for their mothers. Conversely, 52 unrelated subjects were tested due to clinical indications other than abnormal NBS and only 14 of them were found to have at least one mutation/unclassified variant. Custom designed oligonucleotide array CGH analysis revealed a heterozygous ～1.6 Mb deletion encompassing the entire OCTN2 gene in one subject who was apparently homozygous for the c.680G>A (p.R227H) mutation. Thus, copy number abnormalities at the OCTN2 locus should be considered if by sequencing, an apparently homozygous mutation or only one mutant allele is identified. ©2010 Wiley‐Liss, Inc.     

Update on SLC26A3 mutations in congenital chloride diarrhea

Congenital chloride diarrhea (CLD) is an autosomal recessive disorder with around 250 cases reported so far. Life‐long secretory diarrhea is caused by mutations in the solute carrier family 26 member 3 (SLC26A3) gene disrupting the epithelial Cl^?/HCO transport in the ileum and colon. Although salt substitution allows favorable outcome, possible manifestations include renal impairment, intestinal inflammation, and male infertility. At least 55 mutations, of which 21 (38%) novel are reported here, cause CLD. Majority of the mutations are single nucleotide substitutions (n = 30; 55%) with 18 missense, 7 nonsense, and 5 splice‐site mutations. Additional mutations are minor deletions/insertions or their combinations (n = 21; 38%), major deletions (n = 3; 5%), and a major insertion (n = 1; 2%). Distinct founder mutations appear in Finland, Poland, and Arab countries, whereas patients from other countries carry rare homozygous or compound heterozygous mutations. None of the studied SLC26A3 mutants shows significant Cl^?/HCO exchange activity in vitro, and accordingly, evidence of genotype–phenotype differencies remain nonexistent. The domain interaction between SLC26A3 and the cystic fibrosis transmembrane conductance regulator (CFTR) raises a possibility of CFTR modulation in the pathogenesis of CLD. This review summarizes the current knowledge of SLC26A3 mutations and polymorphisms, and their biological and clinical relevance. Hum Mutat 32:1–8, 2011. © 2011 Wiley‐Liss, Inc.     

De Novo Mutations in SLC35A2 Encoding a UDP‐Galactose Transporter Cause Early‐Onset Epileptic Encephalopathy

Early‐onset epileptic encephalopathies (EOEE) are severe neurological disorders characterized by frequent seizures accompanied by developmental regression or retardation. Whole‐exome sequencing of 12 patients together with five pairs of parents and subsequent Sanger sequencing in additional 328 EOEE patients identified two de novo frameshift and one missense mutations in SLC35A2 at Xp11.23, respectively. The three patients are all females. X‐inactivation analysis of blood leukocyte DNA and mRNA analysis using lymphoblastoid cells derived from two patients with a frameshift mutation indicated that only the wild‐type SLC35A2 allele was expressed in these cell types, at least in part likely as a consequence of skewed X‐inactivation. SLC35A2 encodes a UDP‐galactose transporter (UGT), which selectively supplies UDP‐galactose from the cytosol to the Golgi lumen. Transient expression experiments revealed that the missense mutant protein was correctly localized in the Golgi apparatus. In contrast, the two frameshift mutant proteins were not properly expressed, suggesting that their function is severely impaired. Defects in the UGT can cause congenital disorders of glycosylation. Of note, no abnormalities of glycosylation were observed in three serum glycoproteins, which is consistent with favorably skewed X‐inactivation. We hypothesize that a substantial number of neurons might express the mutant SLC35A2 allele and suffer from defective galactosylation, resulting in EOEE.