[Cystinuria]. / Cistinuria.

Cystinuria is an autosomal recessive disorder characterized by impairment of the proximal renal tubules which are unable to reabsorb cystine and dibasic amino acids, leading to the formation of recurrent kidney stones. According to the most recent genetic knowledge, there are two types of cystinuria. The disease is more severe in men than in women in terms of early appearance and number of produced stones. Renal function is generally maintained even after long-lasting disease. Type A heterozygotes are generally asymptomatic while type B heterozygotes usually have a three-fold increased incidence of kidney stones compared to the general population. Medical treatment of cystinuria with cystine-binding drugs and alkali is feasible and effective but requires continuous monitoring of free-cystine urine levels and urine pH and careful surveillance of side effects, with particular attention to the onset of proteinuria.

Multi-system disorder syndromes associated with cystinuria type I.

Cystinuria type I is an autosomal recessive disorder with an exclusively renal phenotype caused by inactivating mutations in SLC3A1. Recently 3 similar but distinct syndromes associated with cystinuria type I have been described: 2p21 deletion syndrome, Hypotonia-Cystinuria Syndrome (HCS) and atypical HCS. Genetic analysis indicated that these are recessive contiguous gene deletion syndromes which differ in the number of genes affected. Patients with HCS are missing both alleles of SLC3A1 and PREPL. In atypical HCS an additional gene (C2orf34) is deleted, and finally, in the 2p21 deletion syndrome the open reading frame of PPM1B is also disrupted. With the exception of SLC3A1, the gene products have not been fully characterized. The severity of the different syndromes reflects the number of genes which are deleted. HCS, a relatively mild syndrome, is characterised by cystinuria type I, generalised hypotonia at birth, growth retardation and minor facial dysmorphic features. On the other end of the spectrum is the 2p21 deletion syndrome, a severe syndrome with a number of additional features including a moderate to severe psychomotor retardation and a decrease in activity of the respiratory chain complexes I, III, IV and V. Finally, atypical HCS displays an intermediate phenotype comparable with classical HCS but associated with mild to moderate mental retardation and a decrease in activity of only the respiratory chain complex IV. This review will focus on the phenotypic similarities and differences observed in these syndromes. Furthermore, we speculate on the function of the gene products, based on the available data.

Evidence for association of SLC7A9 gene haplotypes with cystinuria manifestation in SLC7A9 mutation carriers.

Cystinuria is a complex genetic disorder. In the present study, we report on the strict linkage disequilibrium of SLC7A9 mutations with the wild type SLC7A9 haplotype of 15 single nucleotide polymorphisms (SNPs) and their effect on cystinuria manifestation and classification. Specifically, screening for mutations and polymorphisms was performed in the family members of ten cystinuric patients with SLC7A9 gene mutations. The molecular genetic and clinical data of cystinuric patients and their relatives were combined to construct the SLC7A9 SNP haplotypes and evaluate the manifestation of the disorder in carriers for a SLC7A9 gene mutation. It was found that all carriers of a SLC7A9 mutation manifested cystinuria if their normal allele had non-wild type nucleotides in two or more of the identified polymorphic sites. Subsequently, the polymorphic background of the SLC7A9 gene probably affects the expression of the disorder in SLC7A9 mutation carriers and points to a revised genetic classification of cystinuric patients.

Cystinuria.

UNLABELLED: Cystinuria is an autosomal recessive disorder characterized by impaired transport of cystine, lysine, ornithine and arginine in the proximal renal tubule and in the epithelial cells of the gastrointestinal tract. Following recent progress in the genetic understanding of the disease, the traditional classification, based on the excretion of cystine and dibasic amino acids in obligate heterozygotes, may no longer be considered valid. A new classification is therefore needed: type A due to two mutations of SLC3A1 on chromosome 2, and type B due to two mutations of SLC7A9 on chromosome 19. The possibility of a third type, AB, with one mutation on each of the above-mentioned genes, is left open, but is unlikely. Clinical data show that cystinuria is more severe in males than in females in terms of stone production and early age of onset. The two types of cystinuria (A and B) have a similar outcome. A mild renal failure is present in 17% of patients. Medical treatment of this disorder is possible, but requires a composite approach: urine dilution and alkalization, and the use of drugs to form chemical bonds with the sulphydryl domains of the cystine molecule, which lower the amount of free cystine in the urine. CONCLUSION: Following new achievements in the genetics of cystinuria, a new classification has been proposed. Cystinuria is more severe in males than in females, but only rarely leads to renal insufficiency. The two types of cystinuria have a similar clinical outcome. A combined medical treatment may be effective in reducing renal stone incidence.

SLC7A9 mutations in all three cystinuria subtypes.

BACKGROUND: Cystinuria is an inherited disorder of cystine and dibasic amino acid transport in kidney. Subtypes are defined by the urinary cystine excretion patterns of the obligate heterozygous parents: Type I/N (fully recessive or silent); Type II/N (high excretor); Type III/N (moderate excretor). The first gene implicated in cystinuria (SLC3A1) is associated with the Type I urinary phenotype. A second cystinuria gene (SLC7A9) was recently isolated, and mutations of this gene were associated with dominant (non-Type I) cystinuria alleles. Here we report genotype-phenotype studies of SLC7A9 mutations in a cohort of well-characterized cystinuria probands and their family members. METHODS: Individual exons of the SLC7A9 gene were screened by single strand conformation polymorphism (SSCP) analysis and sequencing of abnormally migrating fragments. RESULTS: Seven mutations were identified. A single bp insertion (799insA) was present in four patients: on Type III alleles in two patients and on Type II alleles in two patients. These results suggest that Type II and Type III may be caused by the same mutation and, therefore, other factors must influence urinary cystine excretion. A 4bp deletion in intron 12 (IVS12+4delAGTA) and a missense mutation (1245G-->A, A354T) were identified on Type III alleles. A nonsense codon (1491G-->T, E436X) and a possible splicing mutation (IVS9-17G-->A) were seen in a Type I/III patient, but the mutations could not be assigned to particular alleles. Of additional interest were two missense mutations (316T-->C, I44T and 967C-->T, P261L) linked to Type I alleles. CONCLUSION: Our results provide evidence that some SLC7A9 mutations may be associated with fully recessive (Type I) forms of cystinuria. We also demonstrate SLC7A9 mutations in dominant Types II and III cystinuria. The finding of SLC7A9 mutations in all three subtypes underscores the complex interactions between specific cystinuria genes and other factors influencing cystine excretion. A simpler phenotypic classification scheme (recessive and dominant) for cystinuria is warranted.

Comparison between SLC3A1 and SLC7A9 cystinuria patients and carriers: a need for a new classification.

Recent developments in the genetics and physiology of cystinuria do not support the traditional classification, which is based on the excretion of cystine and dibasic amino acids in obligate heterozygotes. Mutations of only two genes (SLC3A1 and SLC7A9), identified by the International Cystinuria Consortium (ICC), have been found to be responsible for all three types of the disease. The ICC set up a multinational database and collected genetic and clinical data from 224 patients affected by cystinuria, 125 with full genotype definition. Amino acid urinary excretion patterns of 189 heterozygotes with genetic definition and of 83 healthy controls were also included. All SLC3A1 carriers and 14% of SLC7A9 carriers showed a normal amino acid urinary pattern (i.e., type I phenotype). The rest of the SLC7A9 carriers showed phenotype non-I (type III, 80.5%; type II, 5.5%). This makes the traditional classification imprecise. A new classification is needed: type A, due to two mutations of SLC3A1 (rBAT) on chromosome 2 (45.2% in our database); type B, due to two mutations of SLC7A9 on chromosome 19 (53.2% in this series); and a possible third type, AB (1.6%), with one mutation on each of the above-mentioned genes. Clinical data show that cystinuria is more severe in males than in females. The two types of cystinuria (A and B) had a similar outcome in this retrospective study, but the effect of the treatment could not be analyzed. Stone events do not correlate with amino acid urinary excretion. Renal function was clearly impaired in 17% of the patients.

Analysis of the genes SLC7A9 and SLC3A1 in unclassified cystinurics: mutation detection rates and association between variants in SLC7A9 and the disease.

Cystinuria is a common inherited disorder of defective renal reabsorption of cystine and dibasic amino acids. Recently, 2 responsible genes have been identified: mutations in the SLC3AI gene encoding the glycoprotein rBAT cause cystinuria type I, while variants in the SLC7A9 gene have been demonstrated in non-type I cystinuria; its gene product b(0)+AT is the light chain of the renal cystine transport system rBAT/b(0),+-AT. To estimate the role of both genes in the etiology of cystinuria, we searched for sequence alterations in SLC7A9 and SLC3AI: 30 unclassified cystinurics were investigated. In 50% of patients (15/30), point mutations in SLC3A1 were detected. Screening of the SLC7A9 gene revealed 10 mutations in 8 patients corresponding to a frequency of 27%. In addition to previously published mutations in the SLC7A9 gene, we detected 2 new mutations (F 140S, c747delG). An overall detection rate of 73% (22/30) in unclassified patients is delineated for mutations in both genes. In 33% (10/30), 2 mutations were detected, in 40% (12/30) 1 mutation. Furthermore, 5 new polymorphic sites were identified in SLC7A9. While the base pair variation in intron 9 is homogeneously distributed in patients and control individuals, the allelic and genotypic distributions of the polymorphisms in 3 exons of SLC7A9--exons 2, 5 and 6--and intron 3 differ significantly between both groups. Our results suggest that some haplotypes defined through the exons 2, 5 and 6 and intron 3 might be markers of a functional variant in the SLC7A9 gene. Evidently, since the mutation detection rates in the 2 so far known cystinuria genes never reach 100%, further genes and modulating factors should influence the phenotype in a subset of patients. However, the presented data show that testing for mutations in the 2 currently known cystinuria genes is already a meaningful approach to the molecular diagnostics of the disease.

Cystinuria type I: identification of eight new mutations in SLC3A1.

BACKGROUND: Cystinuria is a heritable disorder of amino acid transport characterized by the defective transport of cystine and the dibasic amino acids through the brush border epithelial cells of the renal tubule and intestine tract. Three types of cystinuria (I, II, and III) have been described based on the urinary excretion of cystine and dibasic amino acids in obligate heterozygotes. The SLC3A1 gene coding for an amino acid transporter named rBAT is responsible for type I cystinuria, whereas the SLC7A9 gene coding for a subunit (b0,+AT) of rBAT is involved in determining non-type I (types II and III) cystinuria. METHODS: The SLC3A1 gene sequence was investigated in a sample of seven type I/type I, three type I/non-type I, six type I/untyped, and four untyped unrelated cystinuric patients by RNA single-strand conformation polymorphism (RNA-SSCP). RESULTS: Eight new point mutations (S168X, 765+1G>T, 766-2A>G, R452Q, Y461X, S547W, L564F, and C673W) and seven previously reported mutations were detected. These new mutations increase the number of mutated alleles so far characterized in SLC3A1 to 62. CONCLUSIONS: We have found SLC3A1 mutations in 0.739 of the type I chromosomes studied. The relatively high proportion of uncharacterized type I chromosomes suggests either that there may be mutations not yet found in SLC3A1 or that many of the assigned type I chromosomes in mixed type I/non-type I patients may have mutations in SLC7A9. If the hypothesis is excluded in the future, we believe that a third gene may be involved in 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.

[Molecular biology of cystinuria]. / Molekularbiologie der Zystinurie.

Cystine stones belong to the kidney stones diseases which are difficult to manage due to the high rate of recidivation and the necessary surgical procedures. Cystinuria is an autosomal recessive defect of the transport of cystine and the dibasic amino acids in the proximal kidney tube. Recently, two subunits of a renal cystine transporter have been identified. Mutations in these genes have been shown to lead to the cystinuria phenotype. Genetic and functional analyses have helped to modify the classification of cystinuria which had previously been exclusively based on biochemical data. Furthermore, first steps towards a molecular genetic testing have been carried out replacing the so far diagnostic procedure which are stressing for the patients. The results of these testings make an individual therapy possible.

[Phenotypical manifestations of cystinuria: a study of 20 families in the Community of Valencia]. / Manifestaciones fenotípicas de la cistinuria: estudio de 20 familias en la Comunidad Valenciana.

BACKGROUND: The aim of this study was to classify phenotypically cystinuria patients in the Comunidad Valenciana using their genealogy and to study the large heterogeneity of the disease expression. SUBJECTS AND METHOD: From 29 patients diagnosed of cystinuria, 20 families were enrolled in the study. An urine sample of every subject was collected to quantify urine amino acids using high pressure liquid chromatography. We also looked for the presence of cystine crystals. Genetic analyses were carried out using PCR (Polymerase Chain Reaction), and RFLPs (Restriction Fragment Length Polymorphisms). Demographic and clinical characteristics were recorded in a standard questionnaire. RESULTS: From 20 families, 4 were classified Type I, 10 as Type non I, and 6 as Type unknown. Type I cystinuria patients showed the highest urinary levels of cystine and ornithine. We also found an association of cystine crystals and M467T mutation in SLC3A1 gene with Type I. However, we did not find a higher risk of nephrolithiasis associated to any family type. CONCLUSIONS: Phenotypical characterization of patients with cystinuria has showed the wide variability of phenotypical traits indeed in the same transmission pattern. This variability could be due to the genetic and environmental heterogeneity which has developed this pathology and modulated its evolution.

Mutations in the SLC3A1 gene in cystinuric patients: frequencies and identification of a novel mutation.

Cystinuria is a frequent autosomal recessive transport disorder characterized by defective renal resorption of cystine and other dibasic amino acids. Biochemically, three types of cystinuria can be defined. Here we present our results of screening for mutations in the SLC3A1 gene, which codes for a dibasic amino acid transporter protein and appears to be involved in the pathogenesis of cystinuria type I. Our study population consists of 5 Italian cystinuria type I patients and 10 cystinuric patients as yet unclassified as to clinical type. The latter were of different ethnic origin. In total, we found 13 point mutations and 8 genomic rearrangements in 15 cystinuric patients, i.e., our detection rate was 70% (23/30 chromosomes). Remarkably, in patients known to be suffering from cystinuria type I, the mutation detection rate was only 50%, whereas in patients unselected as to cystinuria type, we found 80% of mutations. Additionally, our results, as with those published in the literature, indicate a possible population specific distribution of mutations: Each of the 4 Greek patients analyzed here showed homozygosity for mutation T216M in exon 3. Analysis of a Yugoslavian patient showed homozygosity for a novel mutation, R365L, in exon 6 (nt1094G > T). Findings from molecular genetic studies, as well as physiological investigations, suggest that there are further genes that play a role in the etiology of cystinuria. Nevertheless, our results show that screening for mutations in the SLC3A1 gene can be a meaningful step toward molecular genetic diagnosis of cystinuria in patients without biochemical classification. As with cystic fibrosis, the finding of specific mutations in particular ethnic populations, suggest that the diagnostic approach should take into consideration a patient's ethnic origins.

Reference values of urinary excretion of cystine and dibasic aminoacids: classification of patients with cystinuria in the Valencian Community, Spain.

OBJECTIVE: Cystinuria is an autosomal-recessive disorder of the kidneys and small intestine affecting a luminal transport mechanism shared by cystine, ornithine, arginine, and lysine. Three different types of cystinuria can be distinguished according to the excretion of these amino acids in urine samples. We propose cutoff values from our population as references and we present a classification of cystinuric patients using quantitative amino acid chromatography in first morning urine samples. DESIGN AND METHODS: A random sample of forty healthy subjects belonging to general population of the Valencian Community were selected as control subjects. Cystine, lysine, arginine, and ornithine were quantified by reverse-phase HPLC. Seventy-two subjects, diagnosed previously as cystinuric by the cyanide-nitroprusside test were classified. Probands excreting more than 113.12 micromol cystine per mmol of creatinine (i.e., 1,000 micromol cystine per gram of creatinine) were classified as homozygotes. Parents of homozygotes in whom excretion of amino acids were normal were classified as heterozygotes type I. Those probands showing the excretion of at least one amino acid and the sum of urinary cystine plus the basic amino acids higher than the corresponding references ranges in our population were classified as heterozygotes type II or type III (heterozygotes non-type 1). RESULTS: We identified 24 homozygotes, 39 non-type I heterozygotes and 3 type I heterozygotes. The remaining 6 probands could not be classified. Means for cystine, lysine, arginine ornithine and their sum in homozygotes and heterozygotes non-type I were significantly (p < 0.001) in excess of the respective reference ranges. Moreover, means values in homozygotes were statistically different (p < 0.001) from heterozygotes non-type I. CONCLUSION: Urinary excretion of cystine per mmol creatinine allow us to distinguish heterozygotes from homozygotes. However, the best discriminator to distinguish non-type I heterozygotes from normal population might be the excretion of lysine per mmol creatinine. Additional studies including characterization of appropriate haplotypes should be carried out for a more precise identification of types of cystinuria.

Cystinuria subtype and the risk of nephrolithiasis.

BACKGROUND: Cystinuria patients may be classified into several subgroups based on the urinary phenotype of heterozygotes. However, the relative risk for nephrolithiasis and the prevalence of SLC3A1 mutations in these subgroups are unknown. METHODS: Urinary cystine excretion, age at onset of nephrolithiasis and nature of SLC3A1 mutations were assessed prospectively in 23 cystinuria patients identified primarily through the Quebec Newborn Screening Program. Probands were classified as to cystinuria subtype on the basis of parental urinary cystine excretion. RESULTS: For classical Type I/I cystinuria, both parents excrete cystine in the normal range and probands carry two mutations of the SLC3A1 gene in nearly every case. Between ages 1 to 7 years, mean cystine excretion was high (4566 +/- 480 microns cystine/g creatinine) and exceeded the theoretic threshold for solubility on 70% of visits. Four of eight Type I/I patients began forming stones in the first decade. Type I/III patients (N = 12) excreted less cystine (1544 +/- 163 mumol cystine/g creatinine), exceeded the threshold of urinary cystine solubility less frequently (22% of visits) and had no nephrolithiasis in the first decade; one formed a stone at age 16 years. Only one SLC3A1 mutation was identified in this group. Two Type II/N cystinuria children were identified. In these families, the same level of relatively high excretion (> 600 mumol cystine/g creatinine) was noted in two or three generations, but no SLC3A1 mutations were identified. CONCLUSIONS: Classical recessive Type I/I cystinuria is genetically and phenotypically distinct from the other subtypes (Type I/III and Type II/N) identified in our population.

Localization, by linkage analysis, of the cystinuria type III gene to chromosome 19q13.1.

Cystinuria is an autosomal recessive aminoaciduria in which three urinary phenotypes (I, II, and III) have been described. An amino acid transporter gene, SLC3A1 (formerly rBAT), was found to be responsible for this disorder. Mutational and linkage analysis demonstrated the presence of genetic heterogeneity in which the SLC3A1 gene is responsible for type I cystinuria but not for type II or type III. In this study, we report the identification of the cystinuria type III locus on the long arm of chromosome 19 (19q13.1), obtained after a genomewide search. Pairwise linkage analysis in a series of type III or type II families previously excluded from linkage to the cystinuria type I locus (SLC3A1 gene) revealed a significant maximum LOD score (zeta max) of 13.11 at a maximum recombination fraction (theta max) of .00, with marker D19S225. Multipoint linkage analysis performed with the use of additional markers from the region placed the cystinuria type III locus between D19S414 and D19S220. Preliminary data on type II families also seem to place the disease locus for this rare type of cystinuria at 19q13.1 (significant zeta max = 3.11 at theta max of .00, with marker D19S225).

Molecular genetics of cystinuria in French Canadians: identification of four novel mutations in type I patients.

Cystinuria, a hereditary disorder of cystine and dibasic amino acid reabsorption, has been classified into three subtypes on the basis of urinary excretion in obligate heterozygous parents. Thirteen cystinuric patients, identified primarily through the Quebec newborn urinary screening program, were investigated by phenotypic classification and by mutational analysis of the D2H (rBAT) gene. Mutations were identified on 7 of 25 alleles; all of these 7 mutant alleles were associated with Type I cystinuria. Four of the mutations (a large deletion, a 5'splice site mutation, a 2 bp deletion, and a nonsense mutation) have not been previously reported. These findings suggest that abnormalities in the D2H gene may account for only one subtype (Type I) of cystinuria, and that this subtype can be caused by a wide variety of population-specific mutations.

Genetic heterogeneity in cystinuria: the SLC3A1 gene is linked to type I but not to type III cystinuria.

Cystinuria is an autosomal recessive amino-aciduria where three urinary phenotypes have been described (I, II, and III). An amino acid transporter gene, SLC3A1 (formerly rBAT), was found to be responsible for this disorder. To assess whether mutations in SLC3A1 are involved in different cystinuria phenotypes, linkage with this gene and its nearest marker (D2S119) was analyzed in 22 families with type I and/or type III cystinuria. Linkage with heterogeneity was proved (alpha = 0.45; P < 0.008). Type I/I families showed homogeneous linkage to SLC3A1 (Zmax > 3.0 at theta = 0.00; alpha = 1), whereas types I/III and III/III were not linked. Our data suggest that type I cystinuria is due to mutations in the SLC3A1 gene, whereas another locus is responsible for type III. This result establishes genetic heterogeneity for cystinuria, classically considered as a multiallelic monogenic disease.