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 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.     

Acid beta-glucosidase: enzymology and molecular biology of Gaucher disease

Human lysosomal beta-glucosidase (D-glucosyl-acylsphingosine glucohydrolase, EC 3.2.1.45) is a membrane-associated enzyme that cleaves the beta-glucosidic linkage of glucosylceramide (glucocerebroside), its natural substrate, as well as synthetic beta-glucosides. Experiments with cultured cells suggest that in vivo this glycoprotein requires interaction with negatively charged lipids and a small acidic protein, SAP-2, for optimal glucosylceramide hydrolytic rates. In vitro, detergents (Triton X-100 or bile acids) or negatively charged ganglioside or phospholipids and one of several "activator proteins" increase hydrolytic rate of lipid and water-soluble substrates. Using such in vitro assay systems and active site-directed covalent inhibitors, kinetic and structural properties of the active site have been elucidated. The defective activity of this enzyme leads to the variants of Gaucher disease, the most prevalent lysosomal storage disease. The nonneuronopathic (type 1) and neuronopathic (types 2 and 3) variants of this inherited (autosomal recessive) disease but panethnic, but type 1 is most prevalent in the Ashkenazi Jewish population. Several missense mutations, identified in the structural gene for lysosomal beta-glucosidase from Gaucher disease patients, are presumably casual to the specifically altered posttranslational oligosaccharide processing or stability of the enzyme as well as the altered in vitro kinetic properties of the residual enzyme from patient tissues.     

High frequency of the Gaucher disease mutation at nucleotide 1226 among Ashkenazi Jews.

Reliable estimates of the frequency of Gaucher disease-producing mutations are not available. The high frequency of Gaucher disease in the Ashkenazi Jewish population is due to the occurrence of a mutation at nucleotide (nt) 1226. We have screened 593 DNA samples from normal Ashkenazi Jews, as well as 62 DNA samples from all our Ashkenazi Jewish patients with Gaucher disease, for the presence of the 1226 mutation. In the 593 presumed normal Ashkenazi Jewish individuals the 1226 mutation was identified in the heterozygous state in 37 and in the homozygous state in two, giving a gene frequency of .035 for the mutation. This 1226 mutation represented 73% of the 124 Gaucher disease alleles in Jewish Gaucher disease patients. Accordingly we estimate that the gene frequency for Gaucher disease among the Ashkenazi Jewish population is .047, which is equivalent to a carrier frequency of 8.9% and a birth incidence of 1:450.     

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.     

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.     

Gaucher disease: A G+1----A+1 IVS2 splice donor site mutation causing exon 2 skipping in the acid beta-glucosidase mRNA.

Gaucher disease is the most frequent lysosomal storage disease and the most prevalent Jewish genetic disease. About 30 identified missense mutations are causal to the defective activity of acid beta-glucosidase in this disease. cDNAs were characterized from a moderately affected 9-year-old Ashkenazi Jewish Gaucher disease type 1 patient whose 80-year-old, enzyme-deficient, 1226G (Asn370----Ser [N370S]) homozygous grandfather was nearly asymptomatic. Sequence analyses revealed four populations of cDNAs with either the 1226G mutation, an exact exon 2 (delta EX2) deletion, a deletion of exon 2 and the first 115 bp of exon 3 (delta EX2-3), or a completely normal sequence. About 50% of the cDNAs were the delta EX2, the delta EX2-3, and the normal cDNAs, in a ratio of 6:3:1. Specific amplification and characterization of exon 2 and 5' and 3' intronic flanking sequences from the structural gene demonstrated clones with either the normal sequence or with a G+1----A+1 transition at the exon 2/intron 2 boundary. This mutation destroyed the splice donor consensus site (U1 binding site) for mRNA processing. This transition also was present at the corresponding exon/intron boundary of the highly homologous pseudogene. This new mutation, termed "IVS2 G+1----A+1," is the first splicing mutation described in Gaucher disease and accounted for about 3.4% of the Gaucher disease alleles in the Ashkenazi Jewish population. The occurrence of this "pseudogene"-type mutation in the structural gene indicates the role of acid beta-glucosidase pseudogene and structural gene rearrangements in the pathogenesis of this disease.     

Cell-specific differences in membrane beta-glucosidase from normal and Gaucher cells.

Two isozymes of membrane-bound beta-glucosidase (beta-D-glucoside glucohydrolase, EC 3.2.1.21) with activity towards 4-methylumbelliferyl-beta-D-glucopyranoside have been identified in human cells. One of these isozymes was found to have a pH optimum of 5.0, a Km of 0.4 mM and to be rapidly inactivated at pH 4.0 ("acid-labile"). The second isozyme had a pH optimum of 4.5, a Km of 0.8 mM and was stable at pH 4.0 ("acid-stable"). Cultured long-term lymphoid lines and peripheral blood leukocytes contained both isozymes while cultured skin fibroblasts contained only the "acid-stable" form in detectable amounts. The specific activity of the "acid-stable" isozyme was severely reduced in cultured skin fibroblasts, cultured long-term lines and peripheral leukocytes from patients with Gaucher's disease. The specific activity of the "acid-labile" enzyme in the latter two cell types was apparently unaffected. The beta-glucosidase activity in all three cell types examined was predominantly particulate but the enzyme could be solubilized with low concentrations of Triton X-100. The solubilized enzyme required sodium taurocholate (0.2%) for maximum activity. Solubilized beta-glucosidase did not exhibit the cell-specific differences in pH optimum and Km shown by the membrane-bound enzyme.     

Analyses of catalytic activity and inhibitor binding of human acid beta-glucosidase by site-directed mutagenesis. Identification of residues critical to catalysis and evidence for causality of two Ashkenazi Jewish Gaucher disease type 1 mutations

Analyses of catalytic properties and inhibitor binding were conducted to investigate the molecular basis of active site function of human acid beta-glucosidases (EC 3.2.1.45) expressed from normal and Gaucher disease Type 1 alleles. Comparative studies were conducted with enzymes expressed from natural (spleen and fibroblasts) alleles or from mutagenized cDNAs in Spodoptera frugiperda (Sf9) cells using the baculovirus expression system. Mutant cDNAs containing Thr43 to Lys43 (beta-GlcThr43----Lys) and Asp358 to Glu358 (beta-GlcAsp358----Glu) substitutions and two cDNAs containing Ashkenazi Jewish Gaucher disease Type 1 mutations, Arg120 to Gln120 (beta-GlcArg120----Gln) and Asn370 to Ser370 (beta-GlcAsn370----Ser) were expressed and the gene products characterized by enzymatic, immunologic, and inhibitor studies. Genotypes at the acid beta-glucosidase locus in selected Gaucher disease Type 1 patients were determined by allele-specific oligonucleotide hybridization of amplified genomic DNA. Compared with normal, recombinant or natural enzymes expressed from beta-GlcAsn370----Ser alleles had about 2-5-fold decreased specific activity based on CRIM (cross-reacting immunologic material). The beta-GlcArg120----Gln cDNA expressed catalytically inactive CRIM in Sf9; consistent with the 9-fold decreased CRIM-specific activity of the natural enzyme from a beta-GlcArg120----Gln/beta-GlcAsn370----Ser genetic compound. The beta-GlcAsp358----Glu cDNA expressed catalytically inactive CRIM in Sf9 cells. The presence of natural or recombinant enzyme expressed from beta-GlcAsn370----Ser alleles was sufficient to confer 3-5-fold increased IC50 values for deoxynojirimycin, glucosylsphingosine, and N-alkyl-glucosylamine derivatives. Progress curves for inhibition by the slow-tight binding N-alkyl-glucosylamines indicated that the beta-Glc-Asn370----Ser mutation did not alter a conformational change induced by these reaction intermediate analogues. These results provide evidence that the beta-GlcArg120----Gln and beta-GlcAsn370----Ser mutations found in Gaucher disease Type 1 patient genomes are the molecular bases of the enzymatic dysfunction. In addition, the region including Arg120 and that encompassing Asp358 and Asn370 contain residues critical to active site formation or participation in the catalytic mechanism.     

Gaucher disease. III. Substrate specificity of glucocerebrosidase and the use of nonlabeled natural substrates for the investigation of patients.

A reproducible and convenient method for assaying glucocerebrosidase activity using the natural substrates has been developed. From the insoluble pellet fraction of cultured skin fibroblast homogenates, released glucose was measured enzymically using hexokinase coupled with the glucose-6-phosphate dehydrogenase (G6PD) and nicotinamide adenine dinucleotide phosphate (NADP) system. Optimal enzyme assay conditions required both Triton X-100 and sodium taurocholate, pH 4.8. Glucocerebrosidase activities from three patients with type 1 Gaucher disease were 17.5%, 15.8%, and 11.2% of normal (normal = 198 +/- 14 nmol/hr per mg protein, n = 3). The first patient had normal beta-glucosidase activity with the artificial fluorogenic umbelliferone substrate. Interference with the accuracy of the glucose-dependent assay system by either glycolytic or gluconeogenic enzyme activites was not detected under these experimental conditions, and when substrates with long fatty-acid chain lengths (C = 22) were used, markedly decreased glucocerebrosidase activity occurred in both normal individuals and patients. The apparent Km's for the natural substrates were 0.56 +/- 0.05 mM for controls and 2.2-3.3 mM for Gaucher fibroblasts. These data further support the hypothesis that a structurally altered and catalytically deficient enzyme is synthesized in patients with type 1 Gaucher disease and illustrate the value of the natural substrate in investigating patients.     

Failure of alglucerase infused into Gaucher disease patients to localize in marrow macrophages.

BACKGROUND: Gaucher disease is a common glycolipid storage disease, caused by a deficiency of lysosomal beta-glucosidase (glucocerebrosidase). Alglucerase is a form of glucocerebrosidase enriched with terminal mannose moieties, so as to "target" the preparation to the high-affinity macrophage receptor in patients with Gaucher disease. Our earlier in vitro studies indicated that alglucerase was bound by cells other than macrophages by a widely distributed, low-affinity mannose receptor. MATERIALS AND METHODS: Bone was removed at surgery from six patients with Gaucher disease; in three cases, bone was obtainable both when the patient was untreated and after receiving an infusion of alglucerase. Four samples of bone were obtained from patients without Gaucher disease and served as controls. A bone marrow aspirate was obtained from another patient with Gaucher disease immediately after enzyme infusion. Marrow beta-glucosidase activity and chitotriosidase (a macrophage marker) was determined on all samples. RESULTS: Even with the large bolus doses used for the treatment of Gaucher disease by some, scarcely any beta-glucosidase activity was found in marrow samples; the amount of the enzyme was much less than would have been anticipated had the enzyme been evenly distributed to all body cells. CONCLUSIONS: Alglucerase is not targeted to marrow macrophages. Its unquestioned therapeutic effectiveness must be due either to its activity at some site other than marrow macrophages or to the fact that the doses administered are so enormous that even a small fraction is sufficient to achieve a therapeutic effect.     

Use of activators and inhibitors to define the properties of the active site of normal and Gaucher disease lysosomal beta-glucosidase

Lysosomal beta-glucosidase ('glucocerebrosidase') in peripheral blood lymphocyte and spleen extracts from normal individuals and Ashkenazi-Jewish Gaucher disease type-1 patients were investigated using several modifiers of glucosyl ceramide hydrolysis. The negatively charged lipids, phosphatidylserine and taurocholate, had differential effects on the hydrolytic rates of the normal and Gaucher disease enzymes from either source. With the normal enzyme, either negatively charged lipid (up to 1 mmol/l) increased the reaction rates, while decreasing hydrolytic rates were obtained at greater concentrations. In comparison, the peak activities of the Gaucher enzymes were observed at about 2-3 mmol/l or 5-8 mmol/l of phosphatidylserine or taurocholate, respectively. These negatively charged lipids altered only the velocity of the reactions; the apparent Km values were not affected. Taurocholate or phosphatidylserine also facilitated the interaction of the normal enzyme with conduritol B epoxide, a covalent inhibitor of the catalytic site. Compared to the normal enzyme, the Ashkenazi-Jewish Gaucher type-1 enzyme required about 5-fold greater concentrations of conduritol B epoxide for 50% inhibition. Neutral or cationic acyl-beta-glucosides were found to be competitive or noncompetitive inhibitors of the enzymes, respectively. Alkyl beta-glucosides were competitive (or linear-mixed type) inhibitors of the normal splenic or lymphocyte enzyme with competitive inhibition constants (Ki) inversely related to the chain length. With octyl and dodecyl beta-glucoside nearly normal competitive Ki values were obtained with the splenic enzymes from Gaucher patients. These Ki values were not influenced by increasing phosphatidylserine or taurocholate concentrations. In contrast, the cationic lipids, sphingosyl-1-O-beta-D-glucoside (glucosyl sphingosine) and its N-hexyl derivative, were noncompetitive inhibitors whose apparent Ki values for the normal enzyme were 30 and 0.25 mumol/l, respectively. The Ki values for these sphingosyl glucosides were about increased 5 times for the Gaucher type-1 enzymes from Ashkenazi-Jewish Gaucher disease type-1 patients. The Ki values of glucosyl sphingosine for the normal or mutant enzymes were directly related to increasing concentrations of phosphatidylserine or taurocholate. This latter site appears to be specifically altered by a mutation in the structural gene for lysosomal beta-glucosidase in the Ashkenazi-Jewish form of type-1 Gaucher disease.     

The major defect in Ashkenazi Jews with Tay-Sachs disease is an insertion in the gene for the alpha-chain of beta-hexosaminidase

The Ashkenazi Jewish population is enriched for carriers of a fatal form of Tay-Sachs disease, an inherited disorder caused by mutations in the alpha-chain of the lysosomal enzyme, beta-hexosaminidase A. Until recently it was presumed that Tay-Sachs patients from this ethnic isolate harbored the same alpha-chain mutation. This was disproved by identification of a splice junction defect in the alpha-chain of an Ashkenazi patient which could be found in only 20-30% of the Ashkenazi carriers tested. In this study we have isolated the alpha-chain gene from an Ashkenazi Jewish patient, GM515, with classic Tay-Sachs disease who was negative for the splice junction defect. Sequence analysis of the promoter region, exon and splice junctions regions, and polyadenylation signal area revealed a 4-base pair insertion in exon 11. This mutation introduces a premature termination signal in exon 11 which results in a deficiency of mRNA in Ashkenazi patients. A dot blot assay was developed to screen patients and heterozygote carriers for the insertion mutation. The lesion was found in approximately 70% of the carriers tested, thereby distinguishing it as the major defect underlying Tay-Sachs disease in the Ashkenazi Jewish population.     

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.     

Studies on sphingomyelinase and beta-glucosidase activities in Niemann-Pick disease variants. Phosphodiesterase activities measured with natural and artificial substrates

Cultured fibroblasts were studied from 12 cases of Niemann-Pick disease group C. In 11, sphingomyelinase and glucocerebrosidase (and beta-glucosidase) activities were reduced to around 50% of those of controls. On isoelectric focusing, all 12 strains lacked sphingomyelinase activity in the major cathodic region (pI 8.0). The defect was also demonstrated with the artificial phosphodiester substrates bis(4-methylumbelliferyl) phosphate and 4-methylumbelliferyl pyrophosphate diester. In control fibroblasts and those heterozygous for types A or B or group C Niemann-Pick disease, the major sphingomyelinase peak electrofocused at pI 8.0. No direct interaction could be demonstrated by mixing experiments between group C Niemann-Pick extracts and those of type A disease or Gaucher disease. Profiles for beta-glucosidase activity appeared normal in Niemann-Pick group C fibroblasts. No reduction of sphingomyelinase or glucocerebrosidase activities was found in Niemann-Pick group C liver, nor any attenuation of cathodic sphingomyelinase activity in the affected tissue. Results suggest that sphingomyelinase expression differs in fibroblasts and liver. Enzyme defects associated with Niemann-Pick disease group C were only observed in cultured cells.     

Human acid beta-glucosidase: affinity purification of the normal placental and Gaucher disease splenic enzymes on N-alkyl-deoxynojirimycin-sepharose

Two sepharose-bound 1-deoxynojirimycin N-alkyl derivatives, N-(9-carboxynonyl)- and N-(11-carboxyundecyl)-deoxynojirimycin, were used for the affinity purification of acid beta-glucosidase (beta-Glc) from normal and type-1 Ashkenazi Jewish Gaucher disease (AJGD) sources. The capacities of these nondegradable inhibitor supports were 0.5 and 0.75 mg of normal beta-Glc/ml of settled gel, respectively. The purified normal enzyme (14-18% yield) had a specific activity of 1.6 X 10(6) nmol/h/mg protein and was homogeneous as evidenced by a single protein species of Mr = 67,000 on sodium dodecylsulfate-polyacrylamide gel electrophoresis and reverse phase high-performance liquid chromatography (HPLC). Microsequencing demonstrated a single N terminus, and the sequence of the first 22 N-terminal amino acids was colinear with that predicted from the beta-Glc cDNA. Amino acid composition analyses of beta-Glc revealed a high content (35%) of hydrophobic amino acids. The N-decyl-deoxynojirimycin support facilitated the purification of the residual enzyme from type-1 AJGD spleen to about 7,500-fold in four steps with a yield of about 11%. These new affinity supports provided improved stability, capacity and/or specificity compared to other affinity or HPLC methods for purifying this lysosomal glycosidase.     

The occurrence of two immunologically distinguishable beta-glucocerebrosidases in human spleen

The beta-glucosidase activity in spleen from control subjects and patients with different clinical phenotypes of Gaucher's disease was characterized. The occurrence of a soluble non-specific beta-glucosidase with a neutral pH optimum and two membrane-associated beta-glucocerebrosidases with an acid pH optimum was demonstrated. The two beta-glucocerebrosidases can be distinguished on the basis of their ability to react with anti-(placental beta-glucocerebrosidase) antibodies bound to protein-A--Sepharose 4B beads. One of the splenic beta-glucocerebrosidases (form I) is precipitated by the immobilized antibodies and the other (form II) is not. The two forms also differ in binding affinity to concanavalin A, degree of stimulation of enzymic activity by taurocholate and isoelectric point. In contrast, the Km values of the two beta-glucocerebrosidases for natural and artificial substrates are similar and both are inhibited by conduritol B-epoxide. In spleen from three patients with type 1, one patient with type 2 and one patient with type 3 Gaucher's disease form I beta-glucocerebrosidase was found to be clearly deficient, whereas the activity of form II was 25-50% of that in control spleen. The non-specific, neutral beta-glucosidase was not deficient in these Gaucher spleens. The distinct biochemical and immunological properties of non-specific beta-glucosidase and the fact that normal levels of the enzyme are present in patients with Gaucher's disease indicate, in confirmation of previous reports, that non-specific beta-glucosidase is not related to beta-glucocerebrosidase.     

beta-Glucoside hydrolase activity of normal and glucosylceramidotic cultured human skin fibroblasts.

Cultured human skin fibroblasts from normal and glucosylceramidotic subjects are found to contain one beta-glucoside hydrolase as compared with multiple enzymes in other tissues. The fibroblast enzyme has an approximate molecular weight of 150,000 under isotonic conditions, as determined by gel filtration. It occurs as a large aggregate at low ionic strength. Ceramide, 4-methylumbelliferyl, and p-nitrophenyl beta-glucosides are active as substrates. The enzyme in whole cell homogenates is membrane-bound and is solubilized by a combination of Triton X-100 and sodium taurocholate. It has a pH optimum at 4.2 and no demonstrable divalent cation requirement. The cultured fibroblast beta-glucosidase displays close similarity to one of the forms of beta-glucosidase in human spleen, specifically that form which is affected in Gaucher's disease. 4-Methylumbelliferyl beta-glucosidase activity in homozygous fibroblasts from infantile and adult forms of Gaucher's disease are reduced to 9 and 14%, respectively, of normal fibroblast activity. The residual activity in the lipidotic cells shows increased heat lability, but cannot be distinguished from that in normal cells with respect to gel exclusion properties, Michaelis constant, and pH dependence.     

In utero diagnosis of Gaucher disease.

Beta-Glucosidase activity measured by synthetic substrate at pH 4.6 was low in the cultured amniotic cells from two pregnant women at risk for juvenile and adult type Gaucher disease. The diagnosis was confirmed by showing a low activity of beta-glucosidase in the skin fibroblasts with a synthetic substrate or in the spleen with a natural substrate, and by ascertaining the presence of Gaucher cells in the fetal tissues. However, considerable activity of beta-glucosidase measured with synthetic substrate was found in the liver of both affected fetuses and in the spleen of one. It is advisable that the determination of beta-glucosidase to confirm prenatal diagnosis of Gaucher disease be done either in the cultured skin fibroblasts or in the spleen, and if in the spleen, with a natural substrate rather than a synthetic one.     

Human acid beta-glucosidase. Use of conduritol B epoxide derivatives to investigate the catalytically active normal and Gaucher disease enzymes

Human acid beta-glucosidase (glucosylceramidase; EC 3.2.1.45) cleaves the glycosidic bonds of glucosyl ceramide and synthetic beta-glucosides. Conduritol B epoxide (CBE) and its brominated derivative are mechanism-based inhibitors which bind covalently to the catalytic site of acid beta-glucosidase. Procedures using brominetritiated CBE and monospecific anti-human placental acid beta-glucosidase IgG were developed to determine the molar concentrations of functional acid beta-glucosidase catalytic sites in pure placental enzyme preparations from normal sources; kcat values then were calculated from Vmax = [Et]kcat using glucosyl ceramide substrates with dodecanoyl (2135 +/- 45 min-1) and hexanoyl (3200 +/- 410 min-1) fatty acid acyl chains and 4-alkyl-umbelliferyl beta-glucoside substrates with methyl (2235 +/- 197 min-1), heptyl (1972 +/- 152 min-1), nonyl (2220 +/- 247 min-1), and undecyl (773 +/- 44 min-1) alkyl chains. The respective kcat values for acid beta-glucosidase in a crude normal splenic preparation were about 60% of these values. In comparison, the kcat values of the mutant splenic acid beta-glucosidase from two Type 1 Ashkenazi Jewish Gaucher disease (AJGD) patients were about 1.5-3-fold decreased and had Km values for each substrate which were similar to those for the normal acid beta-glucosidase. The interaction of the normal and Type 1 AJGD enzymes with CBE in a 1:1 stoichiometry conformed to a model with reversible EI complexes formed prior to covalent inactivation. With CBE, the equal kmax values (maximal rate of inactivation) for the normal (0.051 +/- 0.009 min-1) and Type 1 AJGD (0.058 +/- 0.016 min-1) enzymes were consistent with the minor differences in kcat. In contrast, the Ki value (dissociation constant) (839 +/- 64 microM) for the Type 1 AJGD enzymes was about 5 times the normal Ki value (166 +/- 57 microM). These results indicated that the catalytically active Type 1 AJGD acid beta-glucosidase had nearly normal hydrolytic capacity and suggested an amino acid substitution in or near the acid beta-glucosidase active site leading to an in vivo instability of the mutant enzymatic activity.