High prevalence of SLC6A8 deficiency in X-linked mental retardation

A novel X-linked mental retardation (XLMR) syndrome was recently identified, resulting from creatine deficiency in the brain caused by mutations in the creatine transporter gene, SLC6A8. We have studied the prevalence of SLC6A8 mutations in a panel of 290 patients with nonsyndromic XLMR archived by the European XLMR Consortium. The full-length open reading frame and splice sites of the SLC6A8 gene were investigated by DNA sequence analysis. Six pathogenic mutations, of which five were novel, were identified in a total of 288 patients with XLMR, showing a prevalence of at least 2.1% (6/288). The novel pathogenic mutations are a nonsense mutation (p.Y317X) and four missense mutations. Three missense mutations (p.G87R, p.P390L, and p.P554L) were concluded to be pathogenic on the basis of conservation, segregation, chemical properties of the residues involved, as well as the absence of these and any other missense mutation in 276 controls. For the p.C337W mutation, additional material was available to biochemically prove (i.e., by increased urinary creatine : creatinine ratio) pathogenicity. In addition, we found nine novel polymorphisms (IVS1+26G-->A, IVS7+37G-->A, IVS7+87A-->G, IVS7-35G-->A, IVS12-3C-->T, IVS2+88G-->C, IVS9-36G-->A, IVS12-82G-->C, and p.Y498) that were present in the XLMR panel and/or in the control panel. Two missense variants (p.V629I and p.M560V) that were not highly conserved and were not associated with increased creatine : creatinine ratio, one translational silent variant (p.L472), and 10 intervening sequence variants or untranslated region variants (IVS6+9C-->T, IVS7-151_152delGA, IVS7-99C-->A, IVS8-35G-->A, IVS8+28C-->T, IVS10-18C-->T, IVS11+21G-->A, IVS12+15C-->T, *207G-->C, IVS12+32C-->A) were found only in the XLMR panel but should be considered as unclassified variants or as a polymorphism (p.M560V). Our data indicate that the frequency of SLC6A8 mutations in the XLMR population is close to that of CGG expansions in FMR1, the gene responsible for fragile-X syndrome.     

Genetic basis of inosine triphosphate pyrophosphohydrolase deficiency

Inosine triphosphate pyrophosphohydrolase (ITPase) deficiency is a common inherited condition characterized by the abnormal accumulation of inosine triphosphate (ITP) in erythrocytes. The genetic basis and pathological consequences of ITPase deficiency are unknown. We have characterized the genomic structure of the ITPA gene, showing that it has eight exons. Five single nucleotide polymorphisms were identified, three silent (138G-->A, 561G-->A, 708G-->A) and two associated with ITPase deficiency (94C-->A, IVS2+21A-->C). Homozygotes for the 94C-->A missense mutation (Pro32 to Thr) had zero erythrocyte ITPase activity, whereas 94C-->A heterozygotes averaged 22.5% of the control mean, a level of activity consistent with impaired subunit association of a dimeric enzyme. ITPase activity of IVS2+21A-->C homozygotes averaged 60% of the control mean. In order to explore further the relationship between mutations and enzyme activity, we examined the association between genotype and ITPase activity in 100 healthy controls. Ten subjects were heterozygous for 94C-->A (allele frequency: 0.06), 24 were heterozygotes for IVS2+21A-->C (allele frequency: 0.13) and two were compound heterozygous for these mutations. The activities of IVS2+21A-->C heterozygotes and 94C-->A/IVS2+21A-->C compound heterozygotes were 60% and 10%, respectively, of the normal control mean, suggesting that the intron mutation affects enzyme activity. In all cases when ITPase activity was below the normal range, one or both mutations were found. The ITPA genotype did not correspond to any identifiable red cell phenotype. A possible relationship between ITPase deficiency and increased drug toxicity of purine analogue drugs is proposed.     

Identification of three novel mutations in the dihydropyrimidine dehydrogenase gene associated with altered pre-mRNA splicing or protein function

Dihydropyrimidine dehydrogenase (DPD) is the initial and rate-limiting enzyme in the catabolism of the pyrimidine bases uracil and thymine, as well as of the widely used chemotherapeutic drug 5-fluorouracil (5FU). Analysis of the DPD gene ( DPYD ) in two patients presenting with complete DPD deficiency and the parents of an affected child showed the presence of three novel mutations, including one splice site mutation IVS11 + 1G-->T and the missense mutations 731A-->C (E244V) and 1651G-->A (A551T). The G-->T mutation in the invariant GT splice donor site flanking exon 11 (IVS11 + 1G-->T) created a cryptic splice site within exon 11. As a consequence, a 141-bp fragment encoding the aminoacid residues 400-446 of the primary sequence of the DPD protein was missing in the mature DPD mRNA. Analysis of the crystal structure of pig DPD suggested that the E244V mutation might interfere with the electron flow between NADPH and the pyrimidine binding site of DPD. The A551T point mutation might prevent binding of the prosthetic group FMN and affect folding of the DPD protein. The identification of these novel mutations in DPYD will allow the identification of patients with an increased risk of developing severe 5FU-associated toxicity.     

Impaired heme binding and aggregation of mutant cystathionine beta-synthase subunits in homocystinuria

During the past 20 years, cystathionine beta-synthase (CBS) deficiency has been detected in the former Czechoslovakia with a calculated frequency of 1:349,000. The clinical manifestation was typical of homocystinuria, and about half of the 21 patients were not responsive to pyridoxine. Twelve distinct mutations were detected in 30 independent homocystinuric alleles. One half of the alleles carried either the c.833 T-->C or the IVS11-2A-->C mutation; the remaining alleles contained private mutations. The abundance of five mutant mRNAs with premature stop codons was analyzed by PCR-RFLP. Two mRNAs, c.828_931ins104 (IVS7+1G-->A) and c.1226 G-->A, were severely reduced in the cytoplasm as a result of nonsense-mediated decay. In contrast, the other three mRNAs-c.19_20insC, c.28_29delG, and c.210_235del26 (IVS1-1G-->C)-were stable. Native western blot analysis of 14 mutant fibroblast lines showed a paucity of CBS antigen, which was detectable only in aggregates. Five mutations-A114V (c.341C-->T), A155T (c.463G-->A), E176K (c.526G-->A), I278T (c.833T-->C), and W409_G453del (IVS11-2A-->C)-were expressed in Escherichia coli. All five mutant proteins formed substantially more aggregates than did the wild-type CBS, and no aggregates contained heme. These data suggest that abnormal folding, impaired heme binding, and aggregation of mutant CBS polypeptides may be common pathogenic mechanisms in CBS deficiency.     

Analysis of alkaptonuria (AKU) mutations and polymorphisms reveals that the CCC sequence motif is a mutational hot spot in the homogentisate 1,2 dioxygenase gene (HGO)

We recently showed that alkaptonuria (AKU) is caused by loss-of-function mutations in the homogentisate 1,2 dioxygenase gene (HGO). Herein we describe haplotype and mutational analyses of HGO in seven new AKU pedigrees. These analyses identified two novel single-nucleotide polymorphisms (INV4+31A-->G and INV11+18A-->G) and six novel AKU mutations (INV1-1G-->A, W60G, Y62C, A122D, P230T, and D291E), which further illustrates the remarkable allelic heterogeneity found in AKU. Reexamination of all 29 mutations and polymorphisms thus far described in HGO shows that these nucleotide changes are not randomly distributed; the CCC sequence motif and its inverted complement, GGG, are preferentially mutated. These analyses also demonstrated that the nucleotide substitutions in HGO do not involve CpG dinucleotides, which illustrates important differences between HGO and other genes for the occurrence of mutation at specific short-sequence motifs. Because the CCC sequence motifs comprise a significant proportion (34.5%) of all mutated bases that have been observed in HGO, we conclude that the CCC triplet is a mutational hot spot in HGO.     

Mutagenic specificity of imidazole ring-opened 7-methylpurines in M13mp18 phage DNA

The most abundant lesion formed in DNA upon modification with methylating agents 7-methylguanine, under alkaline conditions is converted into 2,6-diamino-4-hydroxy-5N-methyl-formamidopyrimidine (Fapy-7MeGua). We have previously shown that treatment of dimethylsulfate methylated DNA with NaOH creates mutagenic base derivatives leading to a 60-fold increase in the frequency of A-->G transitions and a 2-3-fold increase of G-->T and G-->C transversions. We have analyzed which lesions lead to these mutations. We compared mutagenic spectra in the lacZ gene of M13mp18 phage DNA modified with dimethylsulfate and NaOH after selective elimination of damaged bases from molecules used for transfection into SOS-induced E. coli. Partial elimination of Fapy-7MeGua from phage DNA performed by its digestion with formamidopyrimidine-DNA glycosylase resulted in a 2-3-fold decrease of G-->T and G-->C transversions. Selective depurination of methylated bases (9 h, 37 degrees C, pH 7.0) resulting in almost complete loss of 7MeAde as demonstrated by HPLC analysis of [3H]MNU alkylated phage DNA used as a probe, caused a dramatic, 9-fold decrease of A-->G transitions. Alkali-catalysed rearrangement of 7MeAde was followed by HPLC analysis of [3H]MNU alkylated poly(A) and poly(dA). After incubation of these oligonucleotides in NaOH, 7MeAde disappeared from both chromatograms, but only in polyA, 2 new peaks migrating with retention time different from that of 1MeAde, 3MeAde or 7MeAde were detected, suggesting formation of two rotameric forms of Fapy-7MeAde as observed for Fapy-7MeGua. Thus the miscoding lesion, giving rise to A-->G transitions derived from 7MeAde was Fapy-7MeAde. Fapy-7MeGua was at least an order of magnitude less mutagenic, but in SOS-induced cells it gave rise to G-->T and G-->C transversions.     

GJB2 and mitochondrial A1555G gene mutations in nonsyndromic profound hearing loss and carrier frequencies in healthy individuals

This study aimed to assess mutations in GJB2 gene (connexin 26), as well as A1555G mitochondrial mutation in both the patients with profound genetic nonsyndromic hearing loss and healthy controls. Ninety-five patients with profound hearing loss (>90 dB) and 67 healthy controls were included. All patients had genetic nonsyndromic hearing loss. Molecular analyses were performed for connexin 26 (35delG, M34T, L90P, R184P, delE120, 167delT, 235delC and IVS1+1 A-->G) mutations, and for mitochondrial A1555G mutation. Twenty-two connexin 26 mutations were found in 14.7% of the patients, which were 35delG, R184P, del120E and IVS1+1 A-->G. Mitochondrial A1555G mutation was not encountered. The most common GJB2 gene mutation was 35delG, which was followed by del120E, IVS1+1 A-->G and R184P, and 14.3% of the patients segregated with DFNB1. In consanguineous marriages, the most common mutation was 35delG. The carrier frequency for 35delG mutation was 1.4% in the controls. 35delG and del120E populations, seems the most common connexin 26 mutations that cause genetic nonsyndromic hearing loss in this country. Nonsyndromic hearing loss mostly shows DFNB1 form of segregation.     

Identification of novel cystinuria mutations and polymorphisms in SLC3A1 and SLC7A9 genes: absence of SLC7A10 gene mutations in cystinuric patients

Cystinuria represents 3% of nephrolithiasis in humans with an overall prevalence of 1 in 7,000 neonates. Two genes have been reported to account for the genetic basis of cystinuria, the SLC3A1 and the SLC7A9. Recently, the possible involvement of the SLC7A10 gene in the genetic basis of the disorder was also reported. In the present study, we found a total of 15 mutations in 20 Greek cystinuric patients. Eight mutations are novel, 4 in the SLC3A1: F266S, T351I, R456C, and N516D, and 4 in the SLC7A9: 479-1G>C, Y232C, D233E, and 1399+1G>T. Furthermore, 2 polymorphisms were identified in the SLC3A1 gene and 16 polymorphic variants were also found in the SLC7A9 gene of which the 235+18C>A, 604+10G>A, and 604+24T>C are novel. Finally, no mutation was found in the SLC7A10 gene in all patients. Only, the novel 634+8C>G and the previously reported 913-11C+T polymorphisms were identified in the SLC7A10 gene. In conclusion, a spectrum of SLC3A1 and SLC7A9 mutations are responsible for the genetic basis of cystinuria in Greek patients.     

Mutation and polymorphism analysis of the human homogentisate 1, 2-dioxygenase gene in alkaptonuria patients.

Alkaptonuria (AKU), a rare hereditary disorder of phenylalanine and tyrosine catabolism, was the first disease to be interpreted as an inborn error of metabolism. AKU patients are deficient for homogentisate 1,2 dioxygenase (HGO); this deficiency causes homogentisic aciduria, ochronosis, and arthritis. We cloned the human HGO gene and characterized two loss-of-function mutations, P230S and V300G, in the HGO gene in AKU patients. Here we report haplotype and mutational analysis of the HGO gene in 29 novel AKU chromosomes. We identified 12 novel mutations: 8 (E42A, W97G, D153G, S189I, I216T, R225H, F227S, and M368V) missense mutations that result in amino acid substitutions at positions conserved in HGO in different species, 1 (F10fs) frameshift mutation, 2 intronic mutations (IVS9-56G-->A, IVS9-17G-->A), and 1 splice-site mutation (IVS5+1G-->T). We also report characterization of five polymorphic sites in HGO and describe the haplotypic associations of alleles at these sites in normal and AKU chromosomes. One of these sites, HGO-3, is a variable dinucleotide repeat; IVS2+35T/A, IVS5+25T/C, and IVS6+46C/A are intronic sites at which single nucleotide substitutions (dimorphisms) have been detected; and c407T/A is a relatively frequent nucleotide substitution in the coding sequence, exon 4, resulting in an amino acid change (H80Q). These data provide insight into the origin and evolution of the various AKU alleles.     

Glucose-6-phosphate dehydrogenase variants in Hawaii.

Sequence analysis has been performed on the DNA of 13 glucose-6-phosphate dehydrogenase (G6PD) deficient males from Hawaii, 6 of Filipino, 6 of Laotian, and 1 of Chinese extraction. Four different mutations were found: A-->T at cDNA nt 835, G-->A at nt 871, C-->T at nt 1360, and G-->A at nt 1388. The mutations at nt 835 and nt 1360 have not been described previously, and the latter, in particular, appears to be relatively common. The nt 1360 mutation changes the same codon as is altered in a previously described mutation, G6PD Andalus.     

A novel substitution at the translation initiator codon (ATG-->ATC) of the lipoprotein lipase gene is mainly responsible for lipoprotein lipase deficiency in a patient with severe hypertriglyceridemia and recurrent pancreatitis

A patient with severe hypertriglyceridemia and recurrent pancreatitis was found to have significantly decreased lipoprotein lipase (LPL) activity and normal apolipoprotein C-II concentration in post-heparin plasma. DNA analysis of the LPL gene revealed two mutations, one of which was a novel homozygous G-->C substitution, resulting in the conversion of a translation initiation codon methionine to isoleucine (LPL-1). The second was the previously reported heterozygous substitution of glutamic acid at residue 242 with lysine (LPL-242). In vitro expression of both mutations separately or in combination demonstrated that LPL-1 had approximately 3% protein mass and 2% activity, whereas LPL-242 had undetectable activity but normal mass. The combined mutation LPL-1-242 exhibited similar changes as for LPL-1, with markedly reduced mass, and for LPL-242, with undetectable activity. These results suggest that the homozygous initiator codon mutation rather than the heterozygous LPL-242 alteration was mainly responsible for the patient phenotypes.     

Molecular analysis of alpha/beta-thalassemia in a southern Chinese population

Thalassemia is endemic to many regions in southern China. The screening of severe determinants of thalassemia is of critical importance in management and control of thalassemia. We designed a protocol based on microarray technology to screen for a spectrum of alpha/beta-globin gene mutations in the Chinese population. A total of 38 probes were capable of screening 98% of alpha/beta-globin gene mutations in the China population, including 16 mutations of beta-globin [beta(41-42)(-TCTT), IVSII-654(C-->T), beta17(A-->T), -28(A-->G), beta(71-72)(+A), beta(71-72)(+T), HbE26(G-->A), -29(A-->G), beta(27-28)(+C), IVSI-1(G-->T), IVSI-5(G-->C), beta(14-15)(+G), IVSII-5(G-->C), beta41(+T), 37(G-->A), and beta43(G-->T)] and five mutations of alpha/beta[three deletions of -alpha;(3.7), -alpha(4.2), and --(SEA); two nondeletions of alpha(Quong Sze) codon alpha125(T-->C) and alpha(Constant Spring) codon alpha142(T-->C)]. Multiplex PCR products were amplified from human genomic DNA and allowed to hybridize with the oligonucleotide array. alpha/beta-Globin genotypes were assigned by quantitative analysis of the hybridization results. The protocol, standardized by analysis of 100 thalassemia samples with known mutations and 13 recombinant plasmids, was 100% reliable in genotyping all mutant alleles. In subsequent screening of 2,030 Chinese with unknown mutations, the protocol was 100% accurate. This method provides unambiguous detection of complex combinations of heterozygous, compound heterozygous, and homozygous alpha/beta-thalassemia genotypes. The protocol was also flexible, detecting globin gene mutations from different population groups.     

Expression of normal and mutant GFP-tagged y(+)L amino acid transporter-1 in mammalian cells

Lysinuric protein intolerance (LPI; MIM 222700) is an autosomal recessive disorder characterized by defective transport of cationic amino acids lysine, arginine and ornithine. The defect is localized in the basolateral membrane of polar epithelial cells of the renal tubules and intestine. The SLC7A7 (solute carrier family 7, member 7) gene that encodes y(+)LAT-1 (y(+)L amino acid transporter-1) is mutated in LPI, and leads to the malfunction of the heterodimer composed of y(+)LAT-1 and 4F2hc (4F2 heavy chain) responsible for the system y(+)L amino acid transport activity at the membrane. In this study, the intracellular trafficking and membrane expression of wild type and four mutant y(+)LAT-1 proteins (LPI(Fin), G54V, 1548delC, W242X) was studied in two human cell lines by expressing green fluorescent protein (GFP) tagged proteins. Different SLC7A7 mutations influenced the trafficking of y(+)LAT-1 in the cells differently, as the wild type and missense mutant fusion proteins localized to the plasma membrane, while the frameshift and nonsense mutants sequestered to the cytoplasmic membranes, never reaching the target areas of the cell.     

Arginine transport through system y(+)L in cultured human fibroblasts: normal phenotype of cells from LPI subjects

Inlysinuric protein intolerance (LPI), impaired transport of cationicamino acids in kidney and intestine is due to mutations of theSLC7A7 gene. To assess the functional consequences of the LPI defect in nonepithelial cells, we have characterized cationic aminoacid (CAA) transport in human fibroblasts obtained from LPI patientsand a normal subject. In both cell types the bidirectional fluxes ofarginine are due to the additive contributions of two Na⁺-independent, transstimulated transport systems. One ofthese mechanisms, inhibited by N-ethylmaleimide (NEM) andsensitive to the membrane potential, is identifiable with systemy⁺. The NEM- and potential-insensitive component,suppressed by L-leucine only in the presence ofNa⁺, is mostly due to the activity of systemy⁺L. The inward and outward activities of the two systemsare comparable in control and LPI fibroblasts. Both cell types expressSLC7A1 (CAT1) and SLC7A2 (CAT2B and CAT2A) aswell as SLC7A6 (y+LAT2) and SLC7A7 (y+LAT1). Weconclude that LPI fibroblasts exhibit normal CAA transport throughsystem y⁺L, probably referable to the activity ofSLC7A6/y+LAT2.

     

Mutation analysis of SLC7A9 in cystinuria patients in Sweden

Cystinuria is an autosomal recessive disorder characterized by increased urinary excretion of cystine and dibasic amino acids, which cause recurrent stone formation in affected individuals. Three subtypes of cystinuria have been described (type I, II, and III): type I is caused by mutations in the SLC3A1 gene, whereas nontype I (II and III) has been associated with SLC7A9 mutations. Of the 53 patients reported in our previous work, patients that showed SLC7A9 mutations in single-strand conformation polymorphism (SSCP) screening and/or either lacked or showed heterozygosity for SLC3A1 mutations were included in the present study. The entire coding region and the exon/intron boundaries of the SLC7A9 gene were analyzed by means of both SSCP and DNA sequencing in 16 patients, all but one of which were clinically diagnosed as homozygous cystinurics. Three novel SLC7A9 mutations were identified in the patient group: two missense mutations (P261L and V330M), and one single base-pair deletion (1009 delA). We also detected the previously reported A182T and nine novel polymorphisms in the patients. Mutations V330M and 1009delA occurred on different alleles in one individual, and we suggest that these mutations cause cystinuria in this patient. One patient that was homozygously mutated in the SLC3A1 gene carried the third novel mutation (P261L). We conclude that SLC3A1 is still the major disease gene among Swedish cystinuria patients, with only a minor contribution of SLC7A9 mutations as the genetic basis of cystinuria. The absence of SLC3A1 and SLC7A9 mutations in a substantial proportion of the patients implies that mutations in parts of the genes that were not analyzed may be present, as well as large deletions that escape detection by the methods used. However, our results raise the question of whether other, as yet unknown genes, may also be involved in cystinuria.     

The facile detection of 1505G-->A in Gaucher patients with different phenotypes

In Gaucher disease patients, over 100 disease-causing mutations have been identified. For identification of the 1504C-->T (R463C) mutation it is common to use PCR-restriction fragmentation analysis using the restriction enzyme MspI. In the present study we investigated the reliability of this approach because accurate determination of genotypes is important in genotype-phenotype correlations. A simple modification, i.e. using the restriction enzyme HphI instead of MspI, revealed that type I and II Gaucher disease patients who had previously been identified as carrying the 1504C-->T mutation in fact carried the 1505G-->A (IVS10(-1)G-->A) mutation. Sequencing of the appropriate fragment confirmed this. The PCR method easily differentiates between these two mutations in Gaucher disease patients, thus circumventing the need for sequencing procedures. The phenotypes of the patients found to be carrying the 1505G-->A mutation are also described.