Molecular characterization of a new deletion of the GBA1 gene due to an inter Alu recombination event.

Gaucher disease is the most frequent lysosomal storage disorder due to the autosomal recessive deficiency of acid ß-glucosidase. More than 300 mutations in the GBA1 gene have been described. However only one large deletion of the GBA1 gene has been reported to date. Here, using a combination of different experimental approaches including PCR, sequencing and Southern blot analysis, we describe the identification and characterization of a new large deletion of the GBA1 gene due to an inter Alu recombination event.

Splicing mutations in glycogen-storage disease type II: evaluation of the full spectrum of mutations and their relation to patients' phenotypes.

Glycogen-storage disease type II is an autosomal recessive-inherited disorder due to the deficiency of acid α-glucosidase. A large number of mutations in the acid α-glucosidase gene have been described to date. Among them, ~15% are variations that may affect mRNA splicing process. In this study, we have for the first time comprehensively reviewed the available information on splicing mutations of the acid α-glucosidase gene and we have evaluated their possible impact on the splicing process using different in silico approaches. Out of the 39 different GAA-sequence variations described, an in silico analysis using seven different programs showed that 97% of them are predicted to have an impact on the splicing process. Moreover, this analysis showed a quite good correlation between the impact of the mutation on the splicing process and the clinical phenotype. In addition, we have performed the functional characterization of three novel sequence variants found in Italian patients and still uncharacterized. Using a minigene system, we have confirmed their pathogenic nature. In conclusion, this study has shown that in silico analysis represents a useful tool to select mutations that affect the splicing process of the acid α-glucosidase gene and provides an updated picture of all this kind of mutations reported till now.

Biochemical and molecular findings in a patient with myoclonic epilepsy due to a mistarget of the beta-glucosidase enzyme.

A deficiency of human LIMP-2, a receptor for lysosomal mannose 6-phosphate-independent targeting of the beta-glucosidase (betaGC), due to mutations in the SCARB2 gene was described only in six families presented with progressive myoclonic epilepsy and nephrotic syndrome. In one of them a mistarget of the betaGC was demonstrated. We report here the biochemical and molecular findings in a patient diagnosed with progressive myoclonic epilepsy due to a mistarget of the betaGC, probably caused by a LIMP-2 deficiency, providing valuable information for the diagnosis of this rare disorder.

Identification and molecular characterization of six novel mutations in the UDP-N-acetylglucosamine-1-phosphotransferase gamma subunit (GNPTG) gene in patients with mucolipidosis III gamma.

Mucolipidosis type III (MLIII) is an autosomal recessive disorder affecting lysosomal hydrolase trafficking. In a study of 10 patients from seven families with a clinical phenotype and enzymatic diagnosis of MLIII, six novel GNPTG gene mutations were identified. These included missense (p.T286M) and nonsense (p.W111X) mutations and a transition in the obligate AG-dinucleotide of the intron 8 acceptor splice site (c.610-2A>G). Three microdeletions were also identified, two of which (c.611delG and c.640_667del28) were located within the coding region whereas one (c.609+28_610-16del) was located entirely within intron 8. RT-PCR analysis of the c.610-2A>G transition demonstrated that the change altered splicing, leading to the production of two distinct aberrantly spliced forms, viz. the skipping of exon 9 (p.G204_K247del) or the retention of introns 8 and 9 (p.G204VfsX28). RT-PCR analysis, performed on a patient homozygous for the intronic deletion (c.609+28_610-16del), failed to detect any GNPTG RNA transcripts. To determine whether c.609+28_610-16del allele-derived transcripts were subject to nonsense-mediated mRNA decay (NMD), patient fibroblasts were incubated with the protein synthesis inhibitor anisomycin. An RT-PCR fragment retaining 43 bp of intron 8 was consistently detected suggesting that the 33-bp genomic deletion had elicited NMD. Quantitative real-time PCR and GNPTG western blot analysis confirmed that the homozygous microdeletion p.G204VfsX17 had elicited NMD resulting in failure to synthesize GNPTG protein. Analysis of the sequences surrounding the microdeletion breakpoints revealed either intrinsic repetitivity of the deleted region or short direct repeats adjacent to the breakpoint junctions. This is consistent with these repeats having mediated the microdeletions via replication slippage and supports the view that the mutational spectrum of the GNPTG gene is strongly influenced by the properties of the local DNA sequence environment.

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.

Altered intracellular redox status in Gaucher disease fibroblasts and impairment of adaptive response against oxidative stress.

Gaucher disease (GD) is a lysosomal storage disorder, due to glucosylceramide (GlcCer) accumulation in several body tissues, which causes cellular failure by yet unidentified mechanisms. Several evidence indicates that GD pathogenesis is associated to an impairment in intracellular redox state. In fibroblast primary cultures, reactive oxygen species (ROS) levels and protein carbonyl content resulted significantly increased in GD patients compared to healthy donors, suggesting that GD cells, facing a condition of chronic oxidative stress, have evolved an adaptive response to survive. The ROS rise is probably due to NAD(P)H oxidase activity, being inhibited by the treatment with diphenylene iodonium chloride. Interestingly, GD cells are more sensitive to H(2)O(2) induced cell death, suggesting a dysregulation in the adaptive response to oxidative stress in which APE1/Ref-1 plays a central role. We found that the cytoplasmic amounts of APE1/Ref-1 protein were significantly higher in GD fibroblasts with respect to controls, and that GD cells failed to upregulate its expression upon H(2)O(2) treatment. Both ROS and APE1/Ref-1 increases are due to GlcCer accumulation, being prevented by treatment of GD fibroblasts with Cerezyme and induced in healthy fibroblasts treated with conduritol-beta-epoxide. These data, suggesting that GD cells display an impairment in the cellular redox state and in the adaptive cellular response to oxidative stress, may open new perspectives in the comprehension of GD pathogenesis.

Characterization of two novel GBA mutations causing Gaucher disease that lead to aberrant RNA species by using functional splicing assays.

The correct identification of disease-causing mutations from the background of harmless nucleotide polymorphisms/substitutions has become a critical issue in the investigation of human genetic diseases. Here, we describe two novel disease-causing splicing mutations in the glucocerebrosidase gene, g.4252C>G and g.4426A>G, that have been found in two patients affected by Gaucher disease. The g.4252C>G substitution occurred in intron 5 and was located 12 nucleotides upstream of exon 6 acceptor site whilst the g.4426A>G mutation was located within this exon, 12 nucleotides upstream of the donor site. An in silico analysis suggested that both mutations could have altered the splicing process of exon 6 by creating a novel acceptor and donor site, respectively. However, because the wild-type acceptor and donor sites of exon 6 were not apparently affected, the severity of both mutations could not be established by simple sequence analysis alone. Nonetheless, the use of minigene functional assays to complement transcript analysis of patient fibroblasts shows that both mutations cause the almost complete switch of splice site usage from the wild-type to the newly-created ones, thus providing a functional explanation for the appearance of disease.

Identification and functional characterization of five novel mutant alleles in 58 Italian patients with Gaucher disease type 1.

Gaucher disease (GD) is the most frequent lysosomal glycolipid storage disorder due to an autosomal recessive deficiency of acid beta-glucosidase characterized by the accumulation of glucocerebroside. In this work we carried out the molecular analysis of the glucocerebrosidase gene (GBA) in 58 unrelated patients with GD type 1. We identified five novel genetic alterations: three missense changes c.187G>A (p.D63N), c.473T>G (p.I158S), c.689T>A (p.V230E), a gene-pseudogene recombinant allele and a non-pseudogene-derived complex allele [c.1379G>A;c.1469A>G] encoding [p.G460D;p.H490R]. All mutant alleles were present as compound heterozygotes in association with c.1226A>G (p.N409S), the most common mutation in GD1. The missense mutant proteins were expressed in vitro in COS-1 cells and analyzed by enzyme activity, protein processing and intracellular localization. Functional studies also included the c.662C>T (p.P221L) mutation recently reported in the Spanish GD population (Montfort et al., 2004). The missense mutant alleles retained an extremely low residual enzyme activity with respect to wild type; the complex allele expressed no activity. Processing of the mutant proteins was unaltered except for c.473T>G which was differently glycosylated due to the exposition of an additional glycosylation site. Immunofluorescence studies showed that protein trafficking into the lysosomes was unaffected in all cases. Finally, the characterization of the novel recombinant allele identified a crossover involving the GBA gene and pseudogene between intron 5 and exon 7.

Comparative in vitro expression study of four Fabry disease causing mutations at glutamine 279 of the alpha-galactosidase A protein.

Fabry disease is an X-linked lysosomal storage disorder caused by the deficiency of alpha-galactosidase A that results in the accumulation of neutral sphingolipids. We report a novel point mutation in exon 6, Q279K, carried by an asymptomatic child with a family history of classic Fabry disease. Moreover, we comparatively study the in vitro expression and enzyme activity of Q279K and three other already described mutants in glutamine 279. The Q279K, Q279H and Q279R mutants transfected in COS-1 cells expressed no activity while the residual enzyme activity of the Q279E mutant represented 10% of wild type value. Western blot analysis demonstrated a differential behavior of the mutant proteins: Q279K and Q279H persisted as the inactive 50-kD precursor, indicating that these mutations may affect the normal processing of the enzyme, while the Q279R mutant was not detected probably due to an unstable protein which is rapidly degraded. The in vitro expression studies of the novel Q279K mutation were confirmed by Western blot analysis performed in the patient's lymphocytes which revealed the alpha-galactosidase A precursor of 50 kD but not the processed form.