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Gaucher disease (GD) is caused by a deficiency in glucocerebrosidase (GC). Enzyme replacement for GD disease is effective but expensive and requires life-long treatment. Development of alternative therapeutic strategies is therefore important. One approach is an enzyme delivery system which could supply GC into the circulation continuously. We have previously reported that human GC cDNA in a retroviral vector (MFG-GC) efficiently transduced a murine myoblast line (C2C12) and expressed GC intracellularly and extracellularly. Now we have demonstrated that primary murine and human myoblasts are transduced at very high efficiency by MFG-GC (five to ten copies of human GC gene per cell at a multiplicity of infection of 5-10), 100% of MFG-GC transduced cells expressed human GC. The transduced primary murine and human myoblasts had an intracellular GC activities about five to ten times above nontransduced controls. Furthermore, transduced primary myoblasts secreted human GC extracellularly for up to 35 weeks in vitro. The secreted human GC is specifically taken up by bone marrow derived macrophages, the cell type most important to the pathogenesis of GD. These data suggest that transduced primary myoblasts may be useful in supplying GC as an alternative approach to the treatment of GD.
J Mol Med (Berl) 1998 Oct
PMID:Long-term expression and secretion of human glucocerebrosidase by primary murine and human myoblasts and differentiated myotubes. 982 17

Gaucher disease, the most prevalent inherited sphingolipidosis, is characterized by lipid laden histiocytes in the spleen, liver and bone marrow sinusoids of affected individuals. It results from deleterious mutations in the functional gene of glucocerebrosidase (acid beta-glucosidase, EC. 3.2.1.45) and is transmitted as an autosomal recessive trait. Three clinical forms of Gaucher disease have been described: Type 1 non-neuronopathic, type 2 acute neuronopathic, and type 3 subacute neuronopathic. In this report, we describe the identification and characterization of three novel mutations from two patients who died with type 2 Gaucher disease. Two heterozygous missense point mutations, one at cDNA nucleotide 238A (E41L) and the other at cDNA nucleotide 508T (R131C) were identified, both in the context of a cDNA nucleotide 1448C (L444P) mutation in the second allele. One of these L444P mutations was identified as a novel complex allele resulting from a crossover involving the glucocerebrosidase functional gene and pseudogene beginning between genomic nucleotides 5689 and 5723 and extending through the rest of the coding sequence. Based on the recent identification and sequence analysis of the metaxin gene and pseudogene contiguous with the glucocerebrosidase pseudogene and functional gene respectively, we have developed a PCR-based method for the analysis of the origin and extent of this recombination.
Blood Cells Mol Dis 1998 Dec
PMID:A novel complex allele and two new point mutations in type 2 (acute neuronopathic) Gaucher disease. 985 95

The aim of this study was to characterize the spectrum of 13-glucocerebrosidase gene mutations in Czech and Slovak Gaucher patients and to study genotype/phenotype associations. We have analyzed fifty-eight chromosomes from twenty-six type I, two type 2, and one type 3 13-glucocerebrosidase deficient subjects by direct sequencing of PCR products. Fifty-eight mutant alleles were identified. Seventy-eight percent of mutant alleles carried common mutations (N370S 28/58, L444P 11/58, recNciI 5/58, and IVS2(+1)A 1/58), the remaining twenty-two percent carried rare and private mutations (1263del55, l326insT, S196P, rec(g4889-6506), 2O3delC, G202E, F216Y, R257X, R12OW, R359Q, S1O7L, L444P + V460V, and D409H + T369M). Six of these alleles have not been previously described (rec(g4889-6506), 1326insT, SI96P. G202E, D409H + T369M, and L444P + V460V). The most common genotypes were N370S/L444P (8/29). N370S/recNciI (5/29), and N370S/N370S (2/29). The spectrum of the mutations is characteristic for a Caucasian (non-Jewish) population, with N370S, L444P and recNciI being the most prevalent mutations. The absence of the mutation 84insG that is frequently associated with severe bone disease may have contributed to the low incidence of severe bone disease in Czech and Slovak Gaucher subjects.
Blood Cells Mol Dis
PMID:Analysis of the beta-glucocerebrosidase gene in Czech and Slovak Gaucher patients: mutation profile and description of six novel mutant alleles. 1074 24

Gaucher disease, the most common glycolipid storage disease, can be caused by a large variety of mutations. We report here the identification and characterization of a novel mutation in the human glucocerebrosidase gene, IVS 8 (-11delC) (-14T>A), in two siblings with Gaucher disease type I which occurs within the 3' end of intron 8. Both siblings were compound heterozygotes for the IVS 8 (-11delC) (-14T>A) mutation and for the c.626 G>C (R170P) substitution within exon 6. No mRNA species carrying the IVS 8 (-11delC) (-14T>A) mutation were detected by RT-PCR analysis of the RNA extracted from the patients' fibroblasts. To study the possible effects of the IVS 8 (-11delC) (-14T>A) sequence alteration on the splicing of the proximal exon 9, we have established an in vitro system generating a minigene carrying the genomic region of human glucocerebrosidase spanning from exon 8 to exon 10. Transfections into the human Hep3B cell line of the wild-type construct resulted in the expression of mRNA with the glucocerebrosidase exons correctly spliced. On the contrary, transfections of the construct carrying the IVS 8 (-11delC) (-14T>A) mutation resulted in the expression of mRNA with an 11-bp insertion located between the end of exon 8 and the beginning of exon 9. These results indicated that the 5243T>A substitution created a new 3' splice site 11 bp upstream of the wild-type one, leading to the incorporation into the mRNA of these extra 11 bases. Moreover, the new 3' splice site created by this 5243T>A transversion was preferred over the wild-type one in 100% of cases. The in vitro studies suggest that, in the patients, the 11-bp inclusion causes a shift in the reading frame with the generation of a stop codon after codon 388 which undergoes early degradation.
Blood Cells Mol Dis 2000 Jun
PMID:Functional characterization of the novel mutation IVS 8 (-11delC) (-14T>A) in the intron 8 of the glucocerebrosidase gene of two Italian siblings with Gaucher disease type I. 1095 Sep 36

Gaucher disease is caused by a deficiency of beta-glucocerebrosidase activity. The optimum dose and frequency of enzyme replacement therapy for Gaucher patients have not been determined. We set to compare the therapeutic effects of initiating treatment with macrophage-targeted glucocerebrosidase at a high dose followed by progressive dose reductions with that produced by initial treatment at a low dose in patients with type I Gaucher disease. The study included two parts: (i) Twelve patients received every 2 weeks enzyme replacement therapy at 60 IU/kg body wt for 24 months followed by sequential dose reduction every 6 months to 30 and then to 15 IU/kg body wt. (ii) Thirty-two patients received enzyme replacement therapy at 10 IU/kg every 2 weeks for 12 months. Hematologic parameters and liver and spleen volume were monitored in all patients. All patients had intact spleens. In patients who were started on high-dose enzyme replacement therapy, hemoglobin, acid phosphatase, and organ volume improved or remained unchanged at the end of each dose reduction. Platelet count decreased significantly when the dose of enzyme was reduced from 30 to 15 IU/kg body wt. Initiation of therapy at a low dose led to a significant improvement in all measured parameters at the end of 1 year. We conclude that the minimal effective dose for the nonskeletal manifestations of Gaucher disease can be achieved either by initiating enzyme replacement therapy with a high dose followed by a stepwise dose reduction or by starting treatment at the minimal dose. High dose provides a faster clinical response and should be considered for patients with more aggressive disease. The therapeutic threshold for macrophage-targeted glucocerebrosidase appears to be 10-15 IU/kg body wt every 2 weeks.
Blood Cells Mol Dis 2000 Aug
PMID:Comparative efficacy of dose regimens in enzyme replacement therapy of type I Gaucher disease. 1104 31

Gaucher disease (GD) results from deleterious mutations in the glucocerebrosidase gene. The relatively high frequency of some of these, especially at cDNA nucleotide 1226G (N370S) and at cDNA nucleotide 1448C (L444P), has led to the development of rapid screening techniques that can sometimes be misleading. In this report, we describe a novel rearrangement between the glucocerebrosidase gene and its pseudogene, identified as a consequence of a discrepancy between the genotype, homozygous for the common 1226G mutation, of an Italian patient with type 1 Gaucher disease, and the absence of the 1226G allele in her daughter. Additional investigations went on to reveal a novel recombinant allele beginning in intron 6 and extending through the rest of the coding sequence. Italian GD patients found homozygous for a specific mutation or with one or both alleles still unknown were further investigated and the novel recombinant allele was identified in an adult type 1 patient previously genotyped 1226G/1226G and in a young patient with an unknown genotype. The detection of this allele in three unrelated GD patients originating from the same geographic area in central Italy suggested a founder effect. This study emphasizes the implications of an accurate genotyping for the prognostic value of glucocerebrosidase genotype and reliable genetic counseling.
Blood Cells Mol Dis 2000 Aug
PMID:Identification of a novel recombinant allele in three unrelated Italian Gaucher patients: implications for prognosis and genetic counseling. 1104 32

The two most common Gaucher disease mutations in the Ashkenazi population, 1226A-->G and 84G-->GG in the glucocerebrosidase gene, are tightly linked to a marker in the nearby pyruvate kinase gene. This paper develops a simulation of the Ashkenazi population that considers the effects of selection and drift on the mutant allele frequency and the recombinant haplotype frequency over time. Although the fraction of mutants that are linked to the original marker decays exponentially on average, this expected value is not very likely to occur. Instead, due to random loss of the recombinant haplotype, a mutation has a significant probability of retaining complete linkage disequilibrium long after its origin, so there may be large errors in estimating the age of a mutation based on linkage data. The simulations show that the 1226G mutation probably originated between 40 and 1000 generations ago (1000 to 25,000 years ago), and the 84GG mutation probably originated between 50 and 4800 generations ago (1300 to 120,000 years ago). The recent origin of the 1226G mutation and its high current allele frequency provide strong evidence for heterozygote selection. New techniques and results developed in this paper have general applicability toward analyzing linkage disequilibrium near other mutations. For example, they potentially explain the unexpected pattern of linkage disequilibrium seen around the DeltaF508 mutation of the cystic fibrosis transmembrane conductance regulator gene.
Blood Cells Mol Dis 2000 Aug
PMID:Linkage to Gaucher mutations in the Ashkenazi population: effect of drift on decay of linkage disequilibrium and evidence for heterozygote selection. 1104 36

Gaucher disease is the most prevalent sphingolipid storage disorder in humans caused by a recessively inherited deficiency of the enzyme glucocerebrosidase. More than 100 mutations have been described in the glucocerebrosidase gene causing Gaucher disease. Some of them are complex alleles with several mutations due to recombination events between the gene and its highly homologous pseudogene. The generation of these recombinant alleles involves, in most cases, a crossover in the 3' end of the gene, beyond exon 8. However, in a few cases recombination took place in a more upstream location. Here we describe the analysis of a patient with type I Gaucher disease who bears a new complex allele. This allele was originated by a crossover between the gene and the pseudogene at intron 2, the most upstream recombination site described so far, which gave rise to a fusion gene. The patient was first diagnosed as homozygous for the c.1226 A --> G (N370S) mutation but the early onset of the disease prompted us to perform parental DNA analysis which showed that the mother was not a N370S carrier, suggesting deletion of at least part of the gene. Molecular analysis of the complex allele was carried out by Southern blot, PCR, and sequencing. We were able to close down the region of the recombination event to an interval of 18 nucleotides, corresponding to the last 15 nucleotides of intron 2 and the first 3 nucleotides of exon 3 of the gene. These 18 nucleotides are identical between the gene and pseudogene making any further refinement impossible. An exhaustive list of published glucocerebrosidase complex alleles, describing their recombination points, is included for comparison.
Blood Cells Mol Dis 2000 Oct
PMID:A new gene-pseudogene fusion allele due to a recombination in intron 2 of the glucocerebrosidase gene causes Gaucher disease. 1111 77

A 55-bp deletion in exon 9 of the glucocerebrosidase gene was identified in a 28-year-old male affected with Gaucher disease. The diagnosis was established during an evaluation for mild pancytopenia and was confirmed by bone marrow histology and biochemical studies. The patient is of German ancestry. Initial DNA testing indicated homozygosity for the N370S mutation. However, subsequent testing of the patient's parents suggested that the patient and his mother carried a null allele by our assay for N370S. Further molecular studies identified a 55-bp deletion in exon 9 of the glucocerebrosidase gene (g.6767_6822del55). This deletion has been previously reported in a patient with severe Gaucher disease (1), and is present in the glucocerebrosidase pseudogene. In the previously reported case, initial DNA testing also suggested the genotype N370S/N370S, but further mutation studies were undertaken because clinical severity was greater than expected for that genotype. In contrast, our patient has an unusually mild clinical course. Thus, clinical severity cannot be reliably used to determine when to test for the presence of the 55-bp deletion. While the 55-bp deletion is not reported to be common, its actual frequency may be underestimated since it eludes detection by many standard clinical assays for Gaucher disease. This report points out the need to consider this deletion mutation which may cause erroneous interpretation of results in existing assays for the common mutations N370S and L444P. Furthermore, the importance of recommending parental analysis for individuals who test homozygous for autosomal mutations is highlighted.
Mol Genet Metab 2001 Mar
PMID:Identification of a 55-bp deletion in the glucocerebrosidase gene in Gaucher disease: phenotypic presentation and implications for mutation detection assays. 1124 31

Among the many phenotypes associated with Gaucher disease, the inherited deficiency of glucocerebrosidase, are reports of patients with parkinsonian symptoms. The basis for this association is unknown, but could be due to alterations in the gene or gene region. The human glucocerebrosidase gene, located on chromosome 1q21, has a nearby pseudogene that shares 96% identity. Immediately adjacent to the glucocerebrosidase pseudogene is a convergently transcribed gene, metaxin, which has a pseudogene that is located just downstream to the glucocerebrosidase gene. We describe a patient with mild Gaucher disease but impaired horizontal saccadic eye movements who developed a tremor at age 42, followed by rapid deterioration of her gait. A pallidotomy at age 47 was unsuccessful. Her motor and cognitive deterioration progressed despite enzyme replacement therapy. Sequencing of the glucocerebrosidase gene identified mutations L444P and D409H. Southern blot analysis using the enzyme SspI showed that the maternal allele had an additional 17-kb band. PCR amplifications and sequencing of this fragment demonstrated a duplication which included the glucocerebrosidase pseudogene, metaxin gene, and a pseudometaxin/metaxin fusion. Gene alterations associated with this novel rearrangement, resulting from a crossover between the gene for metaxin and its pseudogene, could contribute to the atypical phenotype encountered in this patient.
Mol Genet Metab 2001 Aug
PMID:Gaucher disease and parkinsonism: a phenotypic and genotypic characterization. 1150 13

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