Identification and characterization of SMPD1 mutations causing Niemann-Pick types A and B in Spanish patients.

Niemann-Pick disease (NPD) types A/B are both caused by a deficiency of lysosomal acid sphingomyelinase and display autosomal recessive inheritance. These two types of the disease were described according to the presence (type A) or absence (type B) of neurological symptoms. We present a molecular analysis of 19 Spanish NPD A/B patients and two from Maghreb. Eight of the patients had type A and 13 had type B NPD. All mutant SMPD1 alleles were identified, including 17 different mutations, 10 of which were novel. The only frequent mutations in the 21 NPD patients were c.1823_1825delGCC (p.R608del) (38%) and c.1445C>A (p.A482E) (9%). Genotype-phenotype correlations were established for most of the mutations and, in particular, the p.R608del-type B association was confirmed. This mutation accounts for 61.5% of the mutant alleles in the type B subgroup of patients. Expression studies performed on six of the identified mutations confirmed them to be disease-causing due to their low enzyme activity. An allele with a mutation affecting a noncanonical donor splice site produced only aberrant mRNAs, corresponding to previously reported nonfunctional SMPD1 minor transcripts. This study is the first exhaustive mutational analysis of Spanish Niemann-Pick A/B disease patients.

Promising results of the chaperone effect caused by imino sugars and aminocyclitol derivatives on mutant glucocerebrosidases causing Gaucher disease.

Gaucher disease is an autosomal recessive disorder. It is characterized by the accumulation of glucosylceramide in lysosomes of mononuclear phagocyte system, attributable to acid beta-glucosidase deficiency. The main consequences of this disease are hepatosplenomegaly, skeletal lesions and, sometimes, neurological manifestations. At sub-inhibitory concentrations, several competitive inhibitors act as chemical chaperones by inducing protein stabilization and increasing enzymatic activity. Here we tested two iminosugars (NB-DNJ and NN-DNJ) and four aminocyclitols with distinct degrees of lipophilicity as pharmacological chaperones for glucocerebrosidase (GBA). We report an increase in the activity of GBA using NN-DNJ, NB-DNJ and aminocyclitol 1 in stably transfected cell lines, and an increment with NN-DNJ and aminocyclitol 4 in patient fibroblasts. These results on specific mutations validate the use of chemical chaperones as a therapeutic approach for Gaucher disease. However, the development and analysis of new compounds is required in order to find more effective therapeutic agents that are active on a broader range of mutations.

Haplotype analysis suggests a single Balkan origin for the Gaucher disease [D409H;H255Q] double mutant allele.

Gaucher disease is an autosomal recessive lysosomal storage disease that is mainly due to mutations in the GBA gene. Most of the mutant alleles described so far bear a single mutation. However, there are a few alleles bearing two or more DNA changes. It has been reported that patients homozygous for the [D409H;H255Q] double mutant allele (HGVS-approved nomenclature, p.[D448H;H294Q]) present a more severe phenotype than patients homozygous for the relatively common D409H mutation. In this study, we confirmed the detrimental cumulative effect of these two mutations at the enzymatic activity level by the heterologous expression of the single and double mutant alleles. Additionally, we found a high frequency of the [D409H;H255Q] allele in patients from the Balkans and the Adriatic area of Italy. This prompted us to perform a haplotype analysis, using five microsatellite polymorphisms close to the GBA gene, to determine the origin of this allele. The results of the 37 chromosomes analysed showed that most of them share a common haplotype and are consistent with a single origin in the Balkans and the Adriatic area of Italy for the [D409H;H255Q] allele.

An evolutionary and structure-based docking model for glucocerebrosidase-saposin C and glucocerebrosidase-substrate interactions - relevance for Gaucher disease.

Gaucher disease, the most prevalent lysosomal storage disorder, is principally caused by malfunction of the lysosomal enzyme glucocerebrosidase (GBA), a 497-amino acid membrane glycoprotein that catalyzes the hydrolysis of glucosylceramide to ceramide and glucose in the presence of an essential 84-residue activator peptide named saposin C (SapC). Knowledge of the GBA structure, a typical (beta/alpha)(8) TIM barrel, explains the effect of few mutations, directly affecting or located near the catalytic site. To identify new regions crucial for proper GBA functionality, we analyzed the interactions of the enzyme with a second (substrate) and a third (cofactor) partner. We build 3D docking models of the GBA-SapC and the GBA-ceramide interactions, by means of methodologies that integrate both evolutive and structural information. The GBA-SapC docking model confirm the implication of three spatially closed regions of the GBA surface (TIM barrel-helix 6 and helix 7, and the Ig-like domain) in binding the SapC molecule. This model provides new basis to understand the pathogenicity of several mutations, such as the prevalent Leu444Pro, and the additive effect of Glu326Lys in the double mutant Glu326Lys-Leu444Pro. Overall, 39 positions in which amino acid changes are known to cause Gaucher disease were localized in the GBA regions identified in this work. Our model is discussed in relation to the phenotype (pathogenic effect) of these mutations, as well as to the enzymatic activity of the recombinant proteins when available. Both data fully correlates with the proposed model, which will provide a new tool to better understand Gaucher disease and to design new therapy strategies.

Maroteaux-Lamy syndrome: functional characterization of pathogenic mutations and polymorphisms in the arylsulfatase B gene.

Mucopolysaccharidosis VI (MPS VI; Maroteaux-Lamy syndrome) is an autosomal recessive lysosomal disorder caused by deficiency of N-acetylgalactosamine-4-sulfatase (ARSB), which is required for the degradation of dermatan sulfate. We recently reported mutational screening of 12 Spanish and 4 Argentinian MPS VI patients. In the present study, seven missense mutations (c.245T>G [p.L82R], c.413A>G [p.Y138C], c.719C>T [p.S240F], c.922G>A [p.G308R], c.937C>G [p.P313A], c.1340G>T [p.C447F] and c.1415T>C [p.L472P]) were transiently expressed in COS-7 cells and 4-sulfatase activity was measured in cell extracts. All mutations resulted in less than 6% of wild-type enzyme activity, in most cases undetectable. Mutations were expressed in their original haplotype context with respect to two non-synonymous polymorphisms present in the ARSB protein, p.V358M and p.S384N. The three less frequent haplotype combinations yielded an ARSB activity of 16%, 57% and 70%, when compared to the most frequent haplotype (p.358V and p.384S). Western blot analyses showed that the expressed mutations significantly reduced the amount of mature protein. Sub-cellular localization studies of mutant ARSB proteins in fibroblasts of MPS VI patients were performed. RNA analysis confirmed that nonsense-mediated RNA decay had taken place for all mutant alleles (c.1143-1G>C, c.1143-8T>G, p.W322X, c.427delG and c.1142+2T>A) which were candidates for causing RNA degradation by this mechanism. In summary, all the ARSB mutations studied had a significant effect on enzyme activity, protein processing and/or mRNA stability.

Twenty-one novel mutations in the GLB1 gene identified in a large group of GM1-gangliosidosis and Morquio B patients: possible common origin for the prevalent p.R59H mutation among gypsies.

GM1-gangliosidosis and Morquio B disease are rare lysosomal storage disorders caused by beta-galactosidase deficiency due to mutations in the GLB1 gene. Three major clinical forms of GM1-gangliosidosis have been established on the basis of age of onset and severity of symptoms: infantile, late infantile/juvenile, and adult. We performed mutation analysis on 30 GM1-gangliosidosis and five Morquio B patients, mainly of Spanish origin, and all the causative mutations were identified. Thirty different mutations were found, 21 of which were novel. With the exception of two adults and one juvenile patient, all the GM1-gangliosidosis patients were affected by the infantile form. Clinical findings are presented for all patients. We report the association of the novel mutations p.T420K and p.L264S with the adult form and the juvenile form, respectively. In addition, the novel mutation p.Y83C was associated with Morquio B disease. Among the 30 GM1-gangliosidosis patients, 6 were of Gypsy origin (Roma). Moreover, those six Gypsy patients shared not only the same mutation (p.R59H) but also a common haplotype. This observation indicates a possible founder effect in this group and suggests that screening of the p.R59H mutation may be appropriate in GM1-gangliosidosis patients of Gypsy origin. This is the first exhaustive mutational analysis performed in a large group of Iberian GM1-gangliosidosis and Morquio B patients.

Differences in methylation patterns in the methylation boundary region of IDS gene in Hunter syndrome patients: implications for CpG hot spot mutations.

Hunter syndrome, an X-linked disorder, results from deficiency of iduronate-2-sulfatase (IDS). Around 40% of independent point mutations at IDS were found at CpG sites as transitional events. The 15 CpG sites in the coding sequences of exons 1 and 2, which are normally hypomethylated, account for very few of transitional mutations. By contrast, the CpG sites in the coding sequences of exon 3, though also normally hypomethylated, account for much higher fraction of transitional mutations. To better understand relationship between methylation status and CpG transitional mutations in this region, the methylation patterns of 11 Hunter patients with transitional mutations at CpG sites were investigated using bisulfite genomic sequencing. The patient cohort mutation spectrum is composed of one mutation in exon 1 (one patient) and three different mutations in exon 3 (10 patients). We confirmed that in normal males, cytosines at the CpG sites from the promoter region to a portion of intron 3 were hypomethylated. However, specific CpG sites in this area were more highly methylated in patients. The patients with p.R8X (exon 1), p.P86L (exon 3), and p.R88H (exon 3) mutations had a hypermethylated condition in exon 2 to intron 3 but retained hypomethylation in exon 1. The same trend was found in four patients with p.A85T (exon 3), although the degree of hypermethylation was less. These findings suggest methylation patterns in the beginning of IDS genomic region are polymorphic in humans and that hypermethylation in this region in some individuals predisposes them to CpG mutations resulting in Hunter syndrome.

Homozygosity for the double D409H+H255Q allele in type II Gaucher disease.

Homozygosity for D409H has been associated with a unique type III subtype of the disease with a phenotype dominated by severe cardiovascular involvement, whereas neurological findings, if present, are restricted to oculomotor apraxia and features such as visceromegaly are either minimal or absent. Using PCR amplification followed by restriction enzyme analysis, 3 patients (1 Greek, 2 Albanians) were IDentified with the D409H/D409H genotype. All shared a very severe early-onset neurological phenotype that classified them as type II. Amplification and sequencing of the full coding region of the GBA gene revealed that all three patients were homozygous not only for D409H but also for H255Q. Both mutations were present on the same allele, as shown by analysis of the parental DNA. The double D409H+H255Q allele was found in heterozygosity in Greek, Bulgarian and Argentinian patients but was not IDentified in any Spanish patients carrying the D409H mutation.

Functional analysis of 13 GBA mutant alleles identified in Gaucher disease patients: Pathogenic changes and "modifier" polymorphisms.

Gaucher disease, the most prevalent sphingolipidosis, is caused by the deficient activity of acid beta-glucosidase, mainly due to mutations in the GBA gene. Over 200 mutations have been identified worldwide, more than 25 of which were in Spanish patients. In order to demonstrate causality for Gaucher disease, some of them: c.662C>T (p.P182L), c.680A>G (p.N188S), c.886C>T (p.R257X), c.1054T>C (p.Y313H), c.1093G>A (p.E326K), c.1289C>T (p.P391L), c.1292A>T (p.N392I), c.1322T>C (p.I402T), and the double mutants [c.680A>G; c.1093G>A] ([p.N188S; p.E326K]) and [c.1448T>C; c.1093G>A] ([p.L444P; p.E326K]), were expressed in Sf9 cells using a baculovirus expression system. Other well-established Gaucher disease mutations, namely c.1226A>G (p.N370S), c.1342G>C (p.D409H), and c.1448T>C (p.L444P), were also expressed for comparison. The levels of residual acid beta-glucosidase activity of the mutant enzymes produced by the cDNAs carrying alleles c.662C>T (p.P182L), c.886C>T (p.R257X), c.1054T>C (p.Y313H), c.1289C>T (p.P391L), and c.1292A>T (p.N392I) were negligible. The c.1226A>G (p.N370S), c.1322T>C (p.I402T), c.1342G>C (p.D409H), c.1448T>C (p.L444P), and [c.1448T>C; c.1093G>A] ([p.L444P; p.E326K]) alleles produced enzymes with levels ranging from 6 to 14% of the wild-type. The three remaining alleles, c.680A>G (p.N188S), c.1093G>A (p.E326K), and [c.680A>G; c.1093G>A] ([p.N188S; p.E326K]), showed higher activity (66.6, 42.7, and 23.2%, respectively). Expression studies revealed that the c.1093G>A (p.E326K) change, which was never found alone in a Gaucher disease-causing allele, when found in a double mutant such as [c.680A>G; c.1093G>A] ([p.N188S; p.E326K]) and [c.1448T>C; c.1093G>A] ([p.L444P; p.E326K]), decreases activity compared to the activity found for the other mutation alone. These results suggest that c.1093G>A (p.E326K) should be considered a "modifier variant" rather than a neutral polymorphism, as previously considered. Mutation c.680A>G (p.N188S), which produces a mutant enzyme with the highest level of activity, is probably a very mild mutation or another "modifier variant."

Molecular analysis in Fabry disease in Spain: fifteen novel GLA mutations and identification of a homozygous female.

Fabry disease, an X-linked inborn error of glycosphingolipid catabolism, results from mutations in the alpha-galactosidase A gene (GLA). Here we report molecular studies in 22 unrelated Spanish patients with Fabry disease ( 20 males and two females). Fifteen novel mutations were identified. In addition 7 previously described mutations and two previously reported polymorphisms were detected. The 15 novel mutations comprise: eight missense E48K (c.142G>A), W81S (c.242G>C), D170H (c.508G>C), W226C (c.678G>T), Q279R (c.836A>G), C382Y (c.1145G>A), I407K (c.1220T>A), L414S (c.1241T>C); one nonsense W95X (c.284G>A); one insertion Y216fsX15 (c.646_647insT); two small deletions G346fsX1 (c.1037delG), K426fsX23 (c.1277_1278delAA); one gross deletion comprising exons 5, 6, 7; one complex mutation (insertion and deletion) A368fsX24 (c.1102delGinsTTATAC), and one splice-site mutation IVS4+1G>A (c.639+1G>A). One of the females was found homozygous for Q279R mutation and she presented with the classic phenotype since the age of 8 years, this case extending into women the severe phenotype observed in classically affected males. Mutation analysis provided precise identification for 30 heterozygotes among female relatives and detection of a de novo mutation. The molecular studies on Spanish Fabry patients here reported further contribute to the identification of new mutations in this disease, and allow reliable detection of heterozygotes which has consequences for genetic counselling and for treatment.

Mapping the genetic and clinical characteristics of Gaucher disease in the Iberian Peninsula.

BACKGROUND: Gaucher disease (GD) is due to deficiency of the glucocerebrosidase enzyme. It is panethnic, but its presentation reveals ethnicity-specific characteristics. METHODS: We evaluated the distribution, and clinical and genetic characteristics of GD patients in the Iberian Peninsula (IP). We analysed geographical distribution, demographic, genetic and clinical data, age at diagnosis, type, and years of therapy in 436 GD patients from the IP. RESULTS: The prevalence of GD was 1/149,000 inhabitants; 88.3% were type 1, 6.7% type 2, and 5.0% type 3. The mean age at diagnosis in type 1 was 28.7 years. A total of 72.7% were classified as having mild forms, 25.5% moderate, and 1.7% severe. Anemia and thrombocytopenia were present in 56% and 55%, respectively. Bone disease and hepatomegaly were reported in 62% and 68%, respectively, and were more likely in asplenic than in non-splenectomized patients. Sixty-nine mutant alleles were identified, and five mutations accounted for 75% of the GBA alleles. Several patients described in our series had interesting phenotypes. A total of 58.7% of patients had received enzyme replacement therapy and 12.6% were treated with miglustat. CONCLUSIONS: A broad spectrum of GBA mutations is present in the IP, with 98.2% of type 1 GD being mild and 23.0% never treated. These data highlight genetic and phenotypic heterogeneities among geographic populations.

Glycogen storage disease type II in Spanish patients: high frequency of c.1076-1G>C mutation.

Glycogen storage disease type II is an autosomal recessive disorder of glycogen metabolism due to deficiency of lysosomal acid alpha-glucosidase. We present the molecular and enzymatic analyses of 22 Spanish GSD II patients. Molecular analyses revealed nine novel mutations. The most common defects were mutations c.-32-13T>G (25%) and c.1076-1G>C (14%) and we report the first homozygous patient for c.1076-1G>C mutation presenting with an infantile form. Alleles bearing mutation c.-32-13T>G are associated with the same haplotype.

Expression and characterization of 14 GLB1 mutant alleles found in GM1-gangliosidosis and Morquio B patients.

GM1-gangliosidosis and Morquio B disease are lysosomal storage disorders caused by beta-galactosidase deficiency attributable to mutations in the GLB1 gene. On reaching the endosomal-lysosomal compartment, the beta-galactosidase protein associates with the protective protein/cathepsin A (PPCA) and neuraminidase proteins to form the lysosomal multienzyme complex (LMC). The correct interaction of these proteins in the complex is essential for their activity. More than 100 mutations have been described in GM1-gangliosidosis and Morquio B patients, but few have been further characterized. We expressed 12 mutations suspected to be pathogenic, one known polymorphic change (p.S532G), and a variant described as either a pathogenic or a polymorphic change (p.R521C). Ten of them had not been expressed before. The expression analysis confirmed the pathogenicity of the 12 mutations, whereas the relatively high activity of p.S532G is consistent with its definition as a polymorphism. The results for p.R521C suggest that this change is a low-penetrant disease-causing allele. Furthermore, the effect of these beta-galactosidase changes on the LMC was also studied by coimmunoprecipitations and Western blotting. The alteration of neuraminidase and PPCA patterns in several of the Western blotting analyses performed on patient protein extracts indicated that the LMC is affected in at least some GM1-gangliosidosis and Morquio B patients.

Identification of the molecular defects in Spanish and Argentinian mucopolysaccharidosis VI (Maroteaux-Lamy syndrome) patients, including 9 novel mutations.

Maroteaux-Lamy syndrome, or mucopolysaccharidosis VI (MPS VI), is an autosomal recessive lysosomal storage disorder caused by a deficiency of N-acetylgalactosamine-4-sulfatase or arylsulfatase B (ARSB). We aimed to analyze the spectrum of mutations responsible for the disorder in Spanish and Argentinian patients, not previously studied. We identified all the ARSB mutant alleles, nine of them novel, in 12 Spanish and 4 Argentinian patients. The new changes were as follows: six missense mutations: c.245T>G [p.L82R], c.413A>G [p.Y138C], c.719C>T [p.S240F], c.922G>A [p.G308R], c.1340G>T [p.C447F] and c.1415T>C [p.L472P]; one nonsense mutation: c.966G>A [p.W322X]; and two intronic changes involving splice sites: c.1142+2T>A, in the donor splice site of intron 5, which promotes skipping of exon 5, and c.1143-1G>C, which disrupts the acceptor site of intron 5, resulting in skipping of exon 6. We also report 10 previously described mutations as well as several non-pathogenic polymorphisms. Haplotype analysis indicated a common origin for most of the mutations found more than once. Most of the patients were compound heterozygotes, whereas only four of them were homozygous. These observations confirm the broad allelic heterogeneity of the disease, with 19 different mutations in 16 patients. However, the two most frequent mutations, c.1143-1G>C and c.1143-8T>G, present in both populations, accounted for one-third of the mutant alleles in this group of patients.

Characterization of two unusual truncating PMM2 mutations in two CDG-Ia patients.

Congenital disorders of glycosylation type Ia (CDG-Ia) is a recessive metabolic disorder caused by mutations in the PMM2 gene and characterized by a defect in the synthesis of N-glycans. The clinical presentation ranges from very severe multi-organ failure to mild neurological problems. A plethora of PMM2 mutations has been described and the vast majority are missense mutations. This selection reflects the requirement of a minimal phosphomannomutase activity to be compatible with life. We describe the characterization of two unusual truncating mutations in two CDG-Ia patients. The first patient is compound heterozygous for the PMM2 mutation p.V231M (c.691G>A) and a deep intronic point mutation (c.639-15.479C>T). The latter variant activates a cryptic splice site which results in an in-frame insertion of a pseudoexon of 123 bp between exon 7 and 8. The second patient is compound heterozygous for the mutation p.V44A (c.131T>C) and an Alu retrotransposition mediated complex deletion of approximately 28 kb encompassing exon 8. These types of mutations have not been described before in CDG-Ia patients. Their detection stresses the importance to combine PMM2 mutation screening on genomic DNA with analysis of the transcripts and/or with the enzymatic analysis of the phosphomannomutase activity. Next to the exonic deletions, which already receive more attention than before, it is likely that deep intronic mutations represent an increasingly important category of mutations.

Analysis of nonsense-mediated mRNA decay in mutant alleles identified in Spanish Gaucher disease patients.

Most of the mutations described in the GBA gene as responsible for Gaucher disease are missense mutations. Nevertheless, other alterations, including nonsense and frameshift mutations, have been reported. These mutations generate premature termination codons (PTC) that could trigger the degradation of mRNA through a mechanism known as nonsense-mediated decay (NMD). It has been established that NMD requires the presence of at least one intron downstream of the PTC, and that this PTC should be at least 50-55 nucleotides upstream of the 3'-most exon-exon junction. In this study, we analyse four GBA truncating mutations - c.108G > A (W(-4)X; HGVS recommended nomenclature: p.W36X), c.886C > T (R257X; HGVS: p.R296X), c.1098_1099insA and c.1451_1452delAC - found in Spanish Gaucher disease patients in order to determine whether they undergo mRNA decay and, if so, whether this occurs via the NMD pathway. RT-PCR showed a clear reduction of RNA for three of the alleles: W(-4)X, R257X and c.1098_1099insA. After treatment with cycloheximide (CHX), a known inhibitor of both protein synthesis and NMD, two of the mutant alleles, R257X and c.1098_1099insA, showed a partial recovery of the amount of mRNA. The third mutation, W(-4)X, did not show any significant CHX-induced recovery, while allele c.1451_1452delAC did not show mRNA decay at all. Real-time PCR confirmed these results and allowed the decay and recovery to be quantified. Finally, the protein truncation test was performed to detect the corresponding proteins. Expected products for alleles R257X, c.1451_1452delAC and c.1098_1099insA, but not for W(-4)X, were observed.

RNAi-mediated inhibition of the glucosylceramide synthase (GCS) gene: A preliminary study towards a therapeutic strategy for Gaucher disease and other glycosphingolipid storage diseases.

Small interference RNAs (siRNAs) have recently been used in various experimental settings to silence gene expression. In some of them, chemically synthesized or in vitro transcribed siRNAs have been transfected into cells. In others, siRNAs have been expressed endogenously from siRNA expression vectors. Enzyme replacement and substrate deprivation therapies are currently used to treat Gaucher disease. Although good results have been reported, there are several limitations and side effects that make necessary to search for new alternatives. We present a new approach based on the inhibition of the GCS gene using siRNAs as a potential therapeutic strategy for Gaucher disease. We have designed four siRNAs for the human GCS gene and transfected them into HeLa cells. A clear reduction of GCS RNA levels and enzyme activity was obtained using two of the four siRNAs. Furthermore, a reduction in glucosylceramide synthesis was also observed. Similar results were obtained when plasmids expressing shRNAs (targeting the same sequences) were transfected into the cells. The inhibition of the mouse homolog Ugcg gene was also achieved, using a siRNA that targeted both human and mouse sequences.