Complex alleles of the acid beta-glucosidase gene in Gaucher disease.

Gaucher disease is inherited in an autosomal recessive manner and is the most prevalent lysosomal storage disease. Gaucher disease has marked phenotypic variation and molecular heterogeneity, and seven point mutations in the acid beta-glucosidase (beta-Glc) gene have been identified. By means of sequence-specific oligonucleotides (SSO), mutation 6433C has been detected homozygously in neuronopathic type 2 (acute) and type 3 (subacute) patients, as well as in children with severe visceral involvement who are apparently free of neuronopathic disease. To investigate the molecular basis for this puzzling finding, amplified beta-Glc cDNAs from 6433C homozygous type 2 and type 3 Gaucher disease patients were cloned and sequenced. The Swedish type 3 Gaucher disease patient was truly homozygous for alleles only containing the 6433C mutation. In comparison, the type 2 patient contained a singly mutated 6433C allele and a "complex" allele with multiple discrete point mutations (6433C, 6468C, and 6482C). Each of the mutations in the complex allele also was present in the beta-Glc pseudogene. SSO hybridization of 6433C homozygotes revealed that both type 2 patients contained additional mutations in one allele, whereas the 6433C alone was detected in both type 3 and in young severe type 1 Gaucher disease patients. These results suggest that the presence of the complex allele influences the severity of neuronopathic disease in 6433C homozygotes and reveal the central role played by the pseudogene in the formation of mutant alleles of the beta-Glc gene. Analysis of additional cDNA clones also identified two new alleles in a type 3 patient, emphasizing the molecular heterogeneity of neuronopathic Gaucher disease.     

Clinical and genetic studies of Japanese homozygotes for the Gaucher disease L444P mutation

In patients originally genotyped as homoallelic for the Gaucher disease (GD) L444P (1448C) mutation, we sought to confirm previously reported phenotypic differences between Caucasians and Japanese, to determine the prevalence and phenotypic impact of recombinant alleles, and to explore the phenotypic influence of genetic background. We therefore analyzed data from longer-term clinical follow-up, more comprehensive genotyping and polymorphism and mitochondrial DNA (mtDNA) testing in all known Japanese L444P homozygotes (n=15). Our studies demonstrated that, of 12 patients in our series originally diagnosed with non-neuronopathic GD, 9 developed neurological signs/symptoms during follow-up (at a mean of 14 years 11 months±11 years 4 months). Of three patients originally diagnosed with acute neuronopathic (type 2) GD, all three were compound heterozygotes for L444P and the complex allele RecNci I. In the entire series, Pvu II and liver erythrocyte pyruvate kinase (PKLR) polymorphism and prevalence of the 9 bp mtDNA deletion were heterogeneous, and these background genetic factors could not predict phenotypic expression. Our data suggest that, in Japanese as in Caucasian patients, the L444P/L444P genotype is highly associated with subacute neuronopathic (type 3) GD, and the presence of a complex allele together with an L444P allele leads to type 2 disease. Our findings also underline the importance of comprehensive genotyping (particularly testing for recombinant alleles), long-term follow-up and careful neurological examination in patients with early-onset GD. Such measures ultimately may improve genotype/phenotype correlations and, with them, genetic counseling and therapeutic decision making. Electronic Publication     

Non-existence of a tight association between a 444leucine to proline mutation and phenotypes of Gaucher disease: high frequency of a NciI polymorphism in the non-neuronopathic form

Summary A ⁴⁴⁴leucine to proline mutation detected by a NciI polymorphism in the human glucocerebrosidase gene was studied to investigate the correlation of the three clinical phenotypes of Gaucher disease with this mutation in 11 Japanese patients with Gaucher disease (type I, 8 patients; type II, 1 patient; type III, 2 patients) and to determine the feasibility of the use of genomic probe DNA for carrier detection and prenatal diagnosis in 8 Japanese families with Gaucher disease and agreeable to family study (type I, 6 families; type III, 2 families). The homoallelic ⁴⁴⁴leucine to proline mutation was found only in patients with type I disease. Of the 8 type I patients, 5 had the homoallelic mutation and 2 had one mutant allele. One patient with type II disease did not have this mutant allele. Of the 2 type III patients, one had a single mutant allele whereas the other exhibited no mutation of this kind. These results suggest that the ⁴⁴⁴leucine to proline mutation is very common in the type I (non-neuronopathic form) disease and is not tightly associated only with neuronopathic types of Gaucher disease in Japanese patients. These findings seem to conflict with others showing that this mutation is partially responsible for the occurrence of neuronopathic Gaucher disease. Thus, the NciI polymorphism will not be useful for the diagnosis of subtypes of Gaucher disease. Carrier detection was feasible in three families with type I disease of the 8 families analyzed by the NciI polymorphism.     

Phenotype/genotype correlations in Gaucher disease type I: clinical and therapeutic implications.

Gaucher disease is the most frequent lysosomal storage disease and the most prevalent genetic disease among Ashkenazi Jews. Gaucher disease type 1 is characterized by marked variability of the phenotype and by the absence of neuronopathic involvement. To test the hypothesis that this phenotypic variability was due to genetic compounds of several different mutant alleles, 161 symptomatic patients with Gaucher disease type 1 (> 90% Ashkenazi Jewish) were analyzed for clinical involvement, and their genotypes were determined. Qualitative and quantitative measures of disease involvement included age at onset of the disease manifestations, hepatic and splenic volumes, age at splenectomy, and severity of bony disease. Highly statistically significant differences (P < .005) were found in each clinical parameter in patients with the N370S/N370S genotype compared with those patients with the N370S/84GG, N370S/L444P, and N370S/? genotypes. The symptomatic N370S homozygotes had onset of their disease two to three decades later than patients with the other genotypes. In addition, patients with the latter genotypes have much more severely involved livers, spleens, and bones and had a higher incidence of splenectomy at an earlier age. These predictive genotype analyses provide the basis for genetic care delivery and therapeutic recommendations in patients affected with Gaucher disease type 1.     

A new glucocerebrosidase-gene missense mutation responsible for neuronopathic Gaucher disease in Japanese patients.

We have identified a new T-to-A single-base substitution at nucleotide 3548 (in the genomic sequence) in exon 6 in the glucocerebrosidase gene from a patient with Gaucher disease type 3. This mutation caused a substitution of isoleucine for phenylalanine at amino acid residue 213 (of 497 residues in the mature protein). By in vitro expression study in cultured mammalian cells, this mutation resulted in deficient activity of glucocerebrosidase. By allele-specific oligonucleotide hybridization of selectively PCR-amplified DNA from eight unrelated Japanese Gaucher disease patients, this mutant allele was observed in other neuronopathic Japanese Gaucher disease patients, in moderately frequent occurrence (three of six neuronopathic patients). This observation suggests that this allele was one of severe [corrected] alleles which were related to the development of neurological manifestations of Gaucher disease.     

Detection of the frequencies of GBA gene major mutations in patients with Gaucher disease in Ukraine

The molecular diagnostics of 27 from 26 Ukrainian families has been performed. The common mutations in GBA gene (N370S, L444P and 84GG) accounted for up to 58% of all cases: mutation N370S was detected in 42.3% alleles, mutation L444P was observed in 15.4% alleles and mutation 84GG was not found at all. The other mutations were: P178S, W184R and Rec Nci I (in compounds with N370S) in the patients with nonneuronopathic form of Gaucher disease, and the genotypes G377S/c 999G --> A and D409H/R120W/G202R were detected in patients with chronic neuronopathic form of Gaucher disease. The data analysis of the genotype and disease progression in the patients allows confirming the known genotype-phenotype correlation.     

Impaired trafficking of mutants of lysosomal glucocerebrosidase in Gaucher's disease

Gaucher's disease is the most inherited lysosomal storage disorder. Except for a few cases, the broad phenotypic heterogeneity of Gaucher's disease can be neither predicted from defined mutations nor from differences in residual enzyme activity. Here, we analyse the intracellular trafficking of glucocerebrosidase as an underlying mechanism for the expression of the clinical phenotype. Biosynthetic labeling studies combined with immunofluorescence analyses with fibroblasts from patients with the defined mutations N370S, L444P, D409H and G202R unequivocally demonstrate a retarded transport of glucocerebrosidase carrying the mutation N370S and a transport block in the ER of the enzyme with the mutations G202R, L444P and D409H. We asked whether cellular components in the patients' fibroblasts other than glucocerebrosidase are implicated in the onset of the disease. For this, mutant cDNA's corresponding to the phenotypes N370S, G202R and L444P were expressed in the mouse fibroblasts NIH3T3. Essentially similar biochemical and cellular features were revealed as compared to the patients' fibroblasts strongly suggesting that these mutations are exclusively responsible for the characterized phenotypes. Interestingly, the immunoglobulin binding protein (BiP) binds wild type and the mutant N370S but not the G202R and L444P variants suggesting a discriminatory role played by this chaperone associated with the severity of the disease.     

Analysis and classification of 304 mutant alleles in patients with type 1 and type 3 Gaucher disease

Gaucher disease results from the inherited deficiency of the enzyme glucocerebrosidase (EC 3.2.1.45). Although >100 mutations in the gene for human glucocerebrosidase have been described, most genotype-phenotype studies have focused upon screening for a few common mutations. In this study, we used several approaches-including direct sequencing, Southern blotting, long-template PCR, restriction digestions, and the amplification refraction mutation system (ARMS)-to genotype 128 patients with type 1 Gaucher disease (64 of Ashkenazi Jewish ancestry and 64 of non-Jewish extraction) and 24 patients with type 3 Gaucher disease. More than 97% of the mutant alleles were identified. Fourteen novel mutations (A90T, N117D, T134I, Y135X, R170C, W184R, A190T, Y304X, A341T, D399Y, c.153-154insTACAGC, c.203-204insC, c.222-224delTAC, and c.1122-1123insTG) and many rare mutations were detected. Recombinant alleles were found in 19% of the patients. Although 93% of the mutant alleles in our Ashkenazi Jewish type 1 patients were N370S, c.84-85insG, IVS2+1G-->A or L444P, these four mutations accounted for only 49% of mutant alleles in the non-Jewish type 1 patients. Genotype-phenotype correlations were attempted. Homozygosity or heterozygosity for N370S resulted in type 1 Gaucher disease, whereas homozygosity for L444P was associated with type 3. Genotype L444P/recombinant allele resulted in type 2 Gaucher disease, and homozygosity for a recombinant allele was associated with perinatal lethal disease. The phenotypic consequences of other mutations, particularly R463C, were more inconsistent. Our results demonstrate a high rate of mutation detection, a large number of novel and rare mutations, and an accurate assessment of the prevalence of recombinant alleles. Although some genotype-phenotype correlations do exist, other genetic and environmental factors must also contribute to the phenotypes encountered, and we caution against relying solely upon genotype for prognostic or therapeutic judgements.     

In situ radiation-inactivation size of fibroblast membrane-bound acid beta-glucosidase in Gaucher type 1, type 2 and type 3 disease

The radiation-inactivation size of membrane-bound acid beta-glucosidase in cultured skin fibroblasts of four normal individuals, five Gaucher type 1 (non-neuropathic), four Gaucher type 2 (acute neuropathic) and three Gaucher type 3 (sub-acute neuropathic) patients was determined using the radiation-inactivation method. The radiation-inactivation size of the enzyme in the control, Gaucher type 2 and Gaucher type 3 fibroblasts ranged from 94 000 to 128 800, and no statistical significant difference was found in the enzyme size between the normal and Gaucher cells nor among the Gaucher type 2 and type 3 cells. Contrary to the normal, Gaucher type 2 and Gaucher type 3 enzyme, the radiation-inactivation size of membrane-bound acid beta-glucosidase in all of the Gaucher type 1 fibroblasts tested is significantly higher, ranging from 158 400 to 235 300. The size of the control lysosomal enzyme, sphingomyelinase, also determined by the radiation-inactivation method in fibroblasts of normal individuals and patients with the three Gaucher subtypes, was between 70 000 and 74 500 and indistinguishable from each other. Since the molecular weight of acid beta-glucosidase subunit determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis was about 60 000 (Pentchev, P.G., Brady, R.O., Hibbert, S.P., Gal, A.E. and Shapiro, C. (1973) J. Biol. Chem. 248, 5256-5261), the above data suggest that: (i) the normal fibroblast enzyme, as well as the Gaucher type 2 and type 3 mutant enzyme, in the membrane-bound form, exists as a dimer; (ii) the underlying biochemical and genetic defect in non-neuropathic (type 1) and neuropathic (type 2 and type 3) Gaucher disease is very different from each other; and (iii) subunit interaction of the mutant enzyme may be present in Gaucher type 1 fibroblasts, resulting in the formation of a higher-molecular-weight aggregate.     

Uveitis- a rare disease often associated with systemic diseases and infections- a systematic review of 2619 patients

Gaucher disease (OMIM 230800, 230900, 231000), the most common lysosomal storage disorder, is due to a deficiency in the enzyme glucocerebrosidase. Gaucher patients display a wide spectrum of clinical presentation, with hepatosplenomegaly, haematological changes, and orthopaedic complications being the predominant symptoms. Gaucher disease is classified into three broad phenotypes based upon the presence or absence of neurological involvement: Type 1 (non-neuronopathic), Type 2 (acute neuronopathic), and Type 3 (subacute neuronopathic). Nearly 300 mutations have been identified in Gaucher patients, with the majority being missense mutations. Though studies of genotype-to-phenotype correlations have revealed significant heterogeneity, some consistent patterns have emerged to inform prognostic and therapeutic decisions. Recent research has highlighted a potential role for Gaucher disease in other comorbidities such as cancer and Parkinson's Disease. In this review, we will examine the potential relationship between Gaucher disease and the synucleinopathies, a group of neurodegenerative disorders characterized by the development of intracellular aggregates of ??-synuclein. Possible mechanisms of interaction will be discussed.     

Mutation screening of 17 Japanese patients with neuropathic Gaucher disease

Using PCR and PCR-single strand conformation polymorphism (SSCP) we have identified gene mutations in 17 Japanese patients with neuropathic Gaucher disease (type 2, 9 cases; type 3, 8 cases). The L444P, F213I, D409H, and 1447 del 20 and 1447 ins TG mutations accounted for eight (type 2, 6; type 3, 2), seven (type 2, 2; type 3, 5), three (type 3), and three (type 2) alleles, respectively. Three alleles were unique. Ten alleles (type 2, 5; type 3, 5) could not be identified. The genotypes, D409H/?, L444P/?, L444P/F213I, and F213I/?, were identified in three, three, two, and two patients, respectively. Six patients had a unique genotype and none of the mutant alleles could be identified in one patient. The data indicate that the genotypes in Japanese patients with neuropathic Gaucher disease are found to be heterogeneous and the genotype prevalence and mutated alleles are unique.     

Gaucher disease types 1, 2, and 3: differential mutations of the acid beta-glucosidase active site identified with conduritol B epoxide derivatives and sphingosine.

To elucidate the genetic heterogeneity in Gaucher disease, the residual beta-glucosidase in cultured fibroblasts from affected patients with each of the major phenotypes was investigated in vitro and/or in viable cells by inhibitor studies using the covalent catalytic site inhibitors, conduritol B epoxide or its bromo derivative, and the reversible cationic inhibitor, sphingosine. These studies delineated three distinct groups (designated A, B, and C) of residual activities with characteristic responses to these inhibitors. Group A residual enzymes had normal I50 values (i.e., the concentration of inhibitor that results in 50% inhibition) for the inhibitors and normal or nearly normal t1/2 values for conduritol B epoxide. All neuronopathic (types 2 and 3) and most non-Jewish nonneuronopathic (type 1) patients had group A residual activities and, thus, could not be distinguished by these inhibitor studies. Group B residual enzymes had about four- to fivefold increased I50 values for the inhibitors and similarly increased t1/2 values for conduritol B epoxide. All Ashkenazi Jewish type 1 and only two non-Jewish type 1 patients had group B residual activities. The differences in I50 values between groups A and B also were confirmed by determining the uninhibited enzyme activity after culturing the cells in the presence of bromo-conduritol B epoxide. Group C residual activity had intermediate I50 values for the inhibitors and represented a single Afrikaner type 1 patient: this patient was a genetic compound for the group A (type 2) and group B (type 1) mutations. These inhibition studies indicated that: Gaucher disease type 1 is biochemically heterogeneous, neuronopathic and non-Jewish nonneuronopathic phenotypes cannot be reliably distinguished by these inhibitor studies, and the Ashkenazi Jewish form of Gaucher disease type 1 results from a unique mutation in a specific active site domain of acid beta-glucosidase that leads to a defective enzyme with a decreased Vmax.     

Clinical and Molecular Characteristics of Japanese Gaucher Disease

Clinical signs and symptoms of Gaucher disease are more severe in Japanese than in Jewish and other non-Japanese patients. A higher percentage of bone crises and splenectomy was demonstrated by Japanese patients, and there were five fatalities among patients with type 1 Gaucher disease. Additionally, neonatal Gaucher disease, clinically characterized by hydrops foetalis, was observed. Japanese patients with type 2 and type 3 disease also demonstrate clinical heterogeneity. About 100 alleles of patients with Japanese Gaucher disease were examined for genotype determination with the PCR and SSCP methods. About 18 different mutations, including several novel mutations in Japanese patients, were identified. The most common mutations in Japanese patients were 1448C(L444P), accounting for 41 (41%) of alleles. The second most prevalent mutation was 754A(F2131), accounting for 14 (14%) of alleles. Other alleles identified included the 1324C, IVS2 and other mutations. Unidentified alleles comprised 16% of the total number of alleles studied. To date, neither the 1226G (N370S) nor the 84GG mutation has been identified in the Japanese population, although these mutations account for about 70% and 10% of the mutations in Jewish and other non-Japanese populations, respectively. The phenotype-genotype correlation in Japanese patients is more complex compared with that of the Jewish population. In Japanese patients, the 1448C mutation, in either heteroallelic or homoallelic forms, exhibits both neurological and non-neurological phenotypes. Japanese patients with the 754A mutation also exhibit both neuronopathic and non-neuronopathic disease. On the other hand, patients with the D409H mutation show only type 3 neurological disease, and those with the 1447–1466 del 20 ins TG mutation have the severe, neonatal neurological form of Gaucher disease. The 1503T allele was present only in patients with type 1 non-neurological disease. However, since this correlation was observed only in young patients, we do not as yet know the final phenotypic outcome of this mutation. Probably, Japanese patients with Gaucher disease have few mutations that exhibit non-neurological signs and symptoms.     

Posttranslational processing of human lysosomal acid beta-glucosidase: a continuum of defects in Gaucher disease type 1 and type 2 fibroblasts.

The major processing steps in the maturation of the lysosomal hydrolase, acid beta-glucosidase, were examined in fibroblasts from normal individuals and from patients with types 1 and 2 Gaucher disease. In pulse-chase studies with normal fibroblasts, remodeling of N-linked oligosaccharides resulted in the temporal appearance of three molecular-weight forms of acid beta-glucosidase. An initial 64-kDa form, containing high mannose-type oligosaccharide side chains, was processed quantitatively, within 24 h, to a sialylated 69-kDa form. During the subsequent 96 h, some of the 69-kDa form is processed to 59 kDa. Glycosidase digestion studies revealed that the increase in the apparent molecular weight of the normal enzyme from 64 kDa to 69 kDa resulted primarily from the addition to sialic acid residues in the Golgi apparatus. The polypeptide backbone of both the 64-kDa and 69-kDa forms was 55.3 kDa. Processing of acid beta-glucosidase in fibroblasts from three of four type 1 (nonneuronopathic) Ashkenazi Jewish Gaucher disease patients was nearly normal. With fibroblasts from one Ashkenazi Jewish and three non-Jewish type 1 as well as from two type 2 (acute neuronopathic) Gaucher disease patients, only a 64-kDa form of acid beta-glucosidase was detected. Inefficient and incomplete processing to the 69-kDa form was found in one type 2 cell line (GM2627). These results indicate that no firm correlation exists between the type or degree of abnormal processing of acid beta-glucosidase in fibroblasts and the phenotype of Gaucher disease.     

Gaucher disease: The effects of phosphatidylserine on glucocerebrosidase from normal and Gaucher fibroblasts

Summary Glucocerebroside -glucosidase (glucocerebrosidase) activity was assayed from cultured fibroblasts of normal individuals, and patients with type 1 (non-neuropathic), type 2 (acute neuropathic), and type 3 (subacute neuropathic) form of Gaucher disease. Residual glucocerebrosidase activity of patients was 8.9 to 17.4% of normal controls, and there was no clear correlation between the level of residual enzyme activity and the different clinical subtypes of the disease. When membrane-bound glucocerebrosidase activity was assayed in the presence of crude brain lipid extracts or purified phosphatidylserine, enzyme from both the normal and type 1 Gaucher fibroblasts was stimulated dramatically (35–60% by crude extracts, 85–90% by phosphatidylserine). This stimulation was not observed with fibroblast glucocerebrosidase of an infantile type 2 and two juvenile type 3 Gaucher patients. The presence of inhibitors of glucocerebrosidase in these type 2 and type 3 Gaucher cells was not detected. Contrary to the mutant enzyme from these Gaucher fibroblasts, glucocerebrosidase from fibroblasts of two adult type 3 Gaucher patients with cerebral involvement was stimulated substantially (72–85%) by phosphatidylserine. When membrane-bound glucocerebrosidase from fibroblasts of the infantile type 2 and juvenile type 3 patients was solubilized with sodium cholate (1% w/v) and delipidated, the phospholipid stimulation of enzyme activity was restored. These findings suggest that considerable clinical and biochemical heterogeneity exists among patients with neuropathic Gaucher disease and that phosphatidylserine activation cannot be used as a reliable indicator in predicting future onset of neurodegeneration in Gaucher patients. The possibility of an aberrant binding of mutant glucocerebrosidase to the lysosomal membrane in juvenile type 3 form of Gaucher disease is discussed.     

TNF-alpha levels and TNF-alpha gene polymorphism in type I Gaucher disease

The objective of this pilot study was to determine the levels of Tumor Necrosis Factor (TNF)-alpha and TNF-alpha gene polymorphism as a marker of inflammation among patients with type I Gaucher disease as well as to ascertain the relationship between this cytokine and parameters of disease severity and other measures of inflammation. Levels of TNF-alpha and genotyping for the -308 G-->A polymorphism in the promoter of the TNF-alpha gene were performed in 17 patients with type I Gaucher disease. TNF-alpha levels were compared with the promoter gene polymorphism, and with hematological and other clinical parameters of Gaucher disease. Eight patients (47.1%) were homozygotes (A/A) for the TNF-alpha polymorphism, six patients (35.3%) had the wild type (G/G), and three patients (17.6%) were heterozygotes (G/A). A significant correlation was found between serum TNF-alpha levels and TNF-alpha genotypes for homozygotes versus heterozygotes patients (p = 0.02), with patients homozygous for the polymorphism having the lower levels of serum TNF-alpha relative to heterozygotes with the highest levels. No correlation was found between TNF-alpha genotypes and chitotriosidase levels, a putative biochemical marker for Gaucher disease severity. Because a significant correlation was found between homozygosity for a common promoter polymorphism of TNF-alpha and milder expression i.e. non-neuronopathic form, of Gaucher disease (versus the neuronopathic forms), this may be suggestive of an association between genetic variability in TNF-alpha and phenotypic expression in Gaucher disease. Larger studies will be required.     

Characterization of mutations in Gaucher patients by cDNA cloning.

Mutated cDNA clones containing the entire coding sequence of human glucocerebrosidase were isolated from libraries originated from Gaucher patients. Sequence analysis of a mutated cDNA derived from a type II Gaucher patient revealed a C-to-G transversion causing a substitution of an arginine for a proline at residue 415. This change creates a new cleavage site for the enzyme HhaI in the mutated cDNA. Allele-specific oligonucleotide hybridization made it possible to show that this mutation exists in the genomic DNA of the patient. From a cDNA library originated from a type I Gaucher patient, a mutated allele was cloned that contains a T-to-C transition causing a substitution of proline for leucine at residue 444 and creating a new NciI site. This mutation is identical to that described by S. Tsuji and colleagues in genomic DNA from type I, type II, and type III patients. Since the new NciI site generates RFLP, it was used to test the existence of this mutated allele in several Gaucher patients by Southern blot analysis. This allele was found in type I (Jewish and non-Jewish), type II, and type III Gaucher patients. These findings led us to conclude that the patient suffering from type II disease (denoted GM1260) carried both mutations described above. Any one of the amino acid changes described reduces the glucocerebrosidase activity as tested by transfection of COS cells with expression vectors harboring the mutated cDNAs. The base changes in the two mutated cDNAs do not affect the electrophoretic mobility of the corresponding polypeptides on an SDS polyacrylamide gel.     

Impaired autophagosomes and lysosomes in neuronopathic Gaucher disease

Gaucher disease is an inherited autosomal recessive disease caused by mutations of acid β-glucosidase, a lysosomal hydrolase specific for degradation of glucosylceramide and glucosylsphingosine in the glycosphingolipid metabolic pathway. Clinically, Gaucher disease is classified into three types: type 1 is a visceral disease, whereas types 2 and 3 are acute and chronic neuronopathic variants, respectively. In types 2 and 3, the CNS pathology displays neuronal inclusions and neuron death. The underlying mechanism(s) by which the glycosphingolipid storage leads to this pathology is not fully understood. A mouse model whose phenotype mimicked that of the human neuronopathic variants was generated in our lab. In the brain of this model, abnormal autophagosomes and lysosomes implicate autophagy in the neuronal degeneration of Gaucher disease.     

Molecular genetic analysis of neurologic diseases]

With the recent progress in molecular genetics, our understanding of neurologic diseases on molecular basis has improved tremendously. Molecular analyses of gene mutations in hereditary neurologic diseases bring us not only the identification of mutations but also better understanding of molecular mechanisms involved in the neurologic diseases. We have identified a missense mutation (444Leu----Pro) in glucocerebrosidase gene of a type 2 Gaucher patient. The mutant glucocerebrosidase carrying 444Pro is unstable and degraded rapidly before the mutant protein is targetted to lysosomes. Detailed analysis on the 444Leu----Pro mutations among three phenotypes (types 1, 2 and 3) of Gaucher disease, it has been demonstrated that patients homozygous for the mutation frequently have the neurologic involvement (types 1 and 2). Very recently we have identified a mutation in tRNA(Lys) gene of mitochondrial genome of patients with myoclonus epilepsy associated with ragged-red fibers. The pathophysiologic mechanism with the tRNA(Lys) mutation is considered to be based on the impaired function of tRNA(Lys).     

Comparative study on glucocerebrosidase in spleens from patients with Gaucher disease.

In Gaucher disease (glucosylceramide lipidosis), deficiency of glucocerebrosidase causes pathological storage of glucosylceramide, particularly in the spleen. A comparative biochemical and immunological analysis has therefore been made of glucocerebrosidase in spleens from normal subjects (n = 4) and from Gaucher disease patients with non-neuronopathic (n = 5) and neuronopathic (n = 5) phenotypes. The spleens from all Gaucher disease patients showed markedly decreased glucocerebrosidase activity. Discrimination of different phenotypes of Gaucher disease was not possible on the basis of the level of residual enzyme activity, or by measurements, using the immunopurified enzyme, of kinetic constants, pI or molecular mass forms. A severe decrease was found in the specific activity of glucocerebrosidase purified to homogeneity from the spleen of a patient with the non-neuronopathic phenotype of Gaucher disease, as compared with that of the enzyme purified from the spleen of a normal subject. This finding was confirmed by an immunological method developed for accurate assessment of the relative enzyme activity per molecule of glucocerebrosidase protein. The method revealed that the residual enzyme in the spleens of all investigated patients with a non-neuronopathic course of Gaucher disease had a more than 7-fold decreased activity of glucocerebrosidase (measured in the presence of taurocholate) per molecule of enzyme, and that the concentration of glucocerebrosidase molecules in the spleens of these patients was near normal. Observations made with immunoblotting experiments were consistent with these findings. In contrast, in the spleens of patients with neuronopathic phenotypes of Gaucher disease, the concentration of glucocerebrosidase molecules was severely decreased.