Urinary lysosomal hydrolases in mucolipidosis II and mucolipidosis III.

Investigation of the binding characteristics of acid beta-D-galactosidase, N-acetyl-beta-D-glucosaminidase, alpha-D-galactosidase and alpha-L-fucosidase from patients with mucolipidosis II and mucolipidosis III to concanavalin A--Sepharose 4B revealed a 2--10-fold decrease in the proportion of enzyme activities from patients with mucolipidoses II and III that adsorbed on the lectin. Neuraminidase treatment of the unadsorbed enzyme fraction did not significantly increased the proportion of enzyme activities that bound to the concanavalin A--Sepharose 4B. Characterization of acid beta-D-galactosidase from the adsorbed and unadsorbed enzyme fractions of mucolipidosis II and mucolipidosis III patients demonstrated identical apparent Km values of 0.22 mM with respect to 4-methylumbelliferyl beta-D-galactopyranoside, altered pH--activity profiles and heterogeneous isoelectric-focusing patterns. The results of this study support the suggestion of an alteration of a post-translational modification (possibly glycosylation) occurring in mucolipidosis II and mucolipidosis III common to the lysosomal hydrolases that affects the mannoserelated properties of these enzymes.     

Binding of human liver hydrolases by immobilized lectins.

The binding of 22 human liver hydrolase activities by immobilized lectins of six different carbohydrate specificities, namely alpha-D-mannose (glucose), D-N-acetylglucosamine, D-N-acetylgalactosamine, L-fucose, alpha-D-galactose and beta-D-galactose, were examined. Differences in binding among these enzymes and within specific enzymes were observed. For example, the neutral forms of alpha-mannosidase and beta-xylosidase were bound by the Ulex europaeus lectin I (specific for L-fucose), whereas the acidic forms were not. Bandierea simplicifolia lectin (specific for alpha-galactose) bound 65% of beta-glucuronidase activity; recycling experiments demonstrated complete binding of the enzyme that had been eluted with the competitor D-galactose and no binding of the fraction that was not initially bound. These results suggested the presence of two forms of this enzyme. Similar data were obtained for acidic beta-galactosidase activity. These experiments may provide the basis for the expanded use of immobilized lectins for purification and characterization of hydrolases and other glycoproteins.     

Electrophoretic abnormalities of lysosomal enzymes in mucolipidosis fibroblast lines.

Electrophoretic properties of eight lysosomal hydrolases and 36 nonlysosomal enzymes were investigated in cultured fibroblasts from children with the inherited storage disease mucolipidosis II (ML II); fibroblasts from a child with a related disorder, mucolipidosis III (ML III); and two obligate heterozygous cell lines from parents of a ML II child. Cell homogenates of ML II fibroblast lines showed altered mobilities for lysosomal beta-hexosaminidase, acid phosphatase2, and alpha-mannosidase and deficient activity for the esterase-A4 and lysosomal alpha-mannosidase-B electrophoretic phenotypes. Altered mobility was also detected for the nonlysosomal enzyme adenosine deaminase-d. Deficient activities of other lysosomal enzymes were observed as previously reported. In a single ML III fibroblast line, only beta-hexosaminidase showed an abnormal electrophoretic pattern suggesting a difference between these cells and ML II fibroblasts. Thirty-five nonlysosomal enzymes associated with other cellular organelles and metabolic pathways were electrophoretically normal in all mucolipidosis cell lines. Heterozygous ML II cells showed normal expression for all enzymes. Two major patterns of altered lysosomal enzymes and adenosine deaminase were demonstrated in ML II cell lines, suggesting that at least two genetic forms of this disorder may exist. Neuraminidase treatment of ML II homogenates converted altered forms of acid phosphatase2 and adenosine deaminase-d and in two ML II lines, recovered the previously undetected lysosomal alpha-mannosidase band. These results are consistent with the mucolipidosis defect(s) being associated with abnormal post-translatinal processing of multiple lysosomal enzymes and adenosine deaminase-d.     

Effect of the co-existence of galactosyl and phosphomannosyl residues on β-hexosaminidase on the processing and transport of the enzyme in mucolipidosis I fibroblasts

Cultured fibroblasts from patients with the lysosomal storage disease, mucolipidosis II, produce complex glycosylated lysosomal enzymes which are preferentially excreted presumably due to the absence of specific phosphomannosyl recognition residues needed for intracellular retention. Complex glycosylated hydrolases are also produced by fibroblasts from patients with mucolipidosis I but an abnormal excretion is not apparent in this disorder. Intra- and extracellular distribution, lectin binding, and specific endocytosis were criteria used to compare the properties of intra- and extracellular β-hexosaminidase derived from mucolipidosis I and normal fibroblast cultures. Mucolipidosis I fibroblasts did not hyperexcrete β-hexosaminidase when maintained in serum-free medium. Using the specifity of ricin binding to terminal galactosyl residues, the most galactosylated forms of the enzyme derived from mucolipidosis I cell extracts and culture fluids were found in the mucolipidosis I cell extracts (50% of total enzyme). Mucolipidosis I-excreted β-hexosaminidase which was eluted from ricin-120-Sepharose, was a high-uptake form in endocytosis experiments while unbound enzyme was a low-uptake form. These data suggest that β-hexosaminidase molecules contained phosphomanosyl residues necessary for receptor-mediated endocytosis as well as galactosyl residues on the same molecule. The co-existence of complex chains with high-mannose chains did not interfere with the phosphomannose-mediated endocytosis of β-hexosaminidase nor with the retention of endogenous enzyme. We can speculate that since complex oligosaccharide chains in the mucolipidosis I cellular enzyme persist due to a sialidase deficiency, more extensive sialylation of cellular enzyme in normal fibroblasts probably occurs at some point during post-translational processing. However, the presence of sialidase in normal cells initiates complex chain trimming in the lysosomes resulting in a less glycosylated end product.     

A study of highly purified mucolipidosis III urinary N-acetyl-beta-D-hexosaminidase B.

Highly purified N-acetyl-beta-D-hexosaminidase B from normal urine and urine of a patient with mucolipidosis III was used to determine whether it has undergone any of the alterations associated with this genetic defect. Examination by sodium dodecyl sulphate/polyacrylamide gel electrophoresis showed that both the enzyme preparations contained protein components with apparent Mr values of 55 000 and 28 000. No differences in the binding and apparent KI (50%) to concanavalin A of the normal and mucolipidosis III enzymes were detected. However, the patient's N-acetyl-beta-D-hexosaminidase B had a slightly greater affinity for the lectin from Ricinus communis than did the normal enzyme. Two-dimensional tryptic peptide maps of the corresponding normal and the patient's N-acetyl-beta-D-hexosaminidase B subunits showed considerable homology. These results indicate that N-acetyl-beta-D-hexosaminidase b does not undergo the significant carbohydrate alterations characteristic of other acid hydrolases in mucolipidosis III.     

Vacuolization of mucolipidosis type II mouse exocrine gland cells represents accumulation of autolysosomes

We previously reported that mice deficient in UDP-GlcNAc:lysosomal enzyme GlcNAc-1-phosphotransferase (mucolipidosis type II or Gnptab -/- mice), the enzyme that initiates the addition of the mannose 6-phosphate lysosomal sorting signal on acid hydrolases, exhibited extensive vacuolization of their exocrine gland cells, while the liver, brain, and muscle appeared grossly unaffected. Similar pathological findings were observed in several exocrine glands of patients with mucolipidosis II. To understand the basis for this cell type-specific abnormality, we analyzed these tissues in Gnptab -/- mice using a combined immunoelectron microscopy and biochemical approach. We demonstrate that the vacuoles in the exocrine glands are enlarged autolysosomes containing undigested cytoplasmic material that accumulate secondary to deficient lysosomal function. Surprisingly, the acid hydrolase levels in these tissues ranged from normal to modestly decreased, in contrast to skin fibroblasts, which accumulate enlarged lysosomes and/or autolysosomes also but exhibit very low levels of acid hydrolases. We propose that the lysosomal defect in the exocrine cells is caused by the combination of increased secretion of the acid hydrolases via the constitutive pathway along with their entrapment in secretory granules. Taken together, our results provide new insights into the mechanisms of the tissue-specific abnormalities seen in mucolipidosis type II.     

Mucolipidosis III beta-N-acetyl-D-hexosaminidase A. Purification and properties

Mucolipidosis III acid hydrolases possess an altered carbohydrate recognition marker needed for their lysosomal localization. As a result of this alteration, a portion of these enzymes is secreted from the cell to the extracellular spaces. The structural changes that may have occurred to one of these secreted enzymes, beta-N-acetyl-d-hexosaminidase A (EC 3.2.1.52) were investigated. Normal and mucolipidosis III urinary beta-N-acetyl-d-hexosaminidase A were purified to apparent homogeneity by using affinity [Sepharose-2-acetamido-N-(epsilon-aminocaproyl)-2-deoxy-beta- d-glucopyranosylamine] and ion-exchange (DEAE- and CM-cellulose) chromatography. Sodium dodecyl sulphate/polyacrylamide-slab-gel electrophoresis showed that both enzymes had similar subunit patterns consisting of apparent mol.wts. of 68000, 60000-58000, 55000 and 29000. Differences, however, were noted in the relative proportions of the protein bands where the normal urinary beta-N-acetyl-d-hexosaminidase A contained predominantly the smaller subunits, whereas the mucolipidosis III enzyme had a predominance of the larger subunits. The binding of mucolipidosis III beta-N-acetyl-d-hexosaminidase A to Ricinus communis lectin and concanavalin A with and without endo-beta-N-acetyl-d-glucosaminidase H treatment indicated that the mutation leads to a modification of a portion of the normally occurring high-mannose-type oligosaccharide units to the complex-type. This was further supported by carbohydrate compositional analysis, which revealed a mannose/galactose ratio of 2.1 for the mucolipidosis III beta-N-acetyl-d-hexosaminidase A compared with a ratio of 3.5 for the normal enzyme. Our results indicate that as a result of their inability to be properly localized to the lysosome the majority of the mucolipidosis III lysosomal hydrolase high-mannose oligosaccharide units are further processed to the complex-type before secretion of predominantly higher-molecular-weight subunits from the cell.     

Apparently normal extracellular acidic alpha-mannosidase in fibroblast cultures from patients with mannosidosis.

Fibroblasts from patients with mannosidosis, cultured in medium supplemented with fetal calf serum from which acidic alpha-mannosidase (alpha-D-mannoside mannohydrolase, E.C.3.2.1.24) has been removed, secreted a normal amount of apparently unaffected acidic alpha-mannosidase into fetal calf serum-free medium. Both the intracellular and extracellular acidic alpha-mannosidase activities were completely precipitated by antiserum to placenta alpha-mannosidase B. In contrast to the heat-lability of the intracellular acidic alpha-mannosidase and its low affinity for artificial mannoside substrate, the extracellular enzyme exhibited both normal thermostability and normal kinetics. Mixing experiments with the intercellular enzymes suggested that the decreased activity in the patients' fibroblasts is not the effect of an inhibitor or absence of an activator. However, incubation of the mannosidosis extracellular enzyme with either normal or patient cell lysate resulted in a partial loss of activity, whereas an additive value was observed with the normal extracellular enzyme. In contrast to normal culture medium, the medium from mannosidosis cell culture was unable to enhance the rate of reduction of intracellular radioactivity in mucolipidosis type II fibroblasts precultured in the presence of radiolabeled mannose. These findings suggest that the defect in mannosidosis is expressed only after the enzyme has been delivered to lysosomes and presumably undergone some form of processing there.     

Transport and processing of beta-hexosaminidase in normal and mucolipidosis-II cultured fibroblasts. Effect of monensin and nigericin.

The univalent-cation ionophores monensin (4.0 microM) and nigericin (0.5 microM) inhibited the abnormal excretion of beta-hexosaminidase from mucolipidosis-II cultured fibroblasts by 62 and 76% respectively, with a corresponding intracellular accumulation of the enzyme. As shown by lectin binding, the enzyme which accumulated in monensin-treated cells did not contain galactose residues, whereas the corresponding enzyme from nigericin-treated cells was galactosylated. The results suggest that monensin acts at an early point in the process of hydrolase glycosylation, and nigericin acts later, both presumably within the Golgi region, allowing the accumulation of different glycosylated forms of the enzyme. The intra- and extra-cellular distribution of beta-hexosaminidase in ionophore-treated normal cells was essentially unchanged, whereas concanavalin A precipitability of excreted enzyme was increased and its ability to be taken up by deficient fibroblasts was decreased. The bivalent-cation ionophore A23187 (1 microM) reduced beta-hexosaminidase excretion from mucolipidosis-II cells by 82% and by 96% when used with EGTA (1 mM). However, there was no intracellular accumulation of enzyme, suggesting that the effect of this ionophore was restricted to the inhibition of synthesis. It therefore appears that the actual transport of beta-hexosaminidase in mucolipidosis-II cells is affected by univalent-cation ionophores in a selective manner. These findings suggest that individual ionophores could be used to identify the sites of hydrolase oligosaccharide processing in the Golgi region by causing intermediate glycosylated forms of the transported hydrolase to accumulate in a specific Golgi compartment preceding the blocking site of the ionophore.     

Multiple carbohydrate-cleaving specificities in human acidic and neutral glycosidases.

The common identity of human acidic beta-D-glucosidase (beta-D-glucoside glucohydrolase, EC 3.2.1.21) and beta-D-xylosidase (1,4-beta-D-xylan xylohydrolase, EC 3.2.1.37) as one enzyme and that of acidic beta-D-galactosidase (beta-D-galactoside galactohydrolase, EC 3.2.1.23), beta-D-fucosidase (no allotted EC number) and alpha-L-arabinosidase (alpha-L-arabinofuranoside arabinohydrolase, EC 3.2.1.55) as another enzyme is indicated by similar binding patterns of glycosidase activities of each enzyme to various lectins. by similar ratios between their intra- and extracellular levels in normal and I-cell fibroblasts and by their deficiencies in liver tissues from patients with Gaucher disease and GM1 gangliosidosis, respectively. A third enzyme, neutral beta-D-galactosidase, purified to homogeneity from human liver has been shown to possess all these five glycosidase activities at neutral pH. These neutral enzymic activities were not bound by any of the lectins examined and found to be reduced in liver and spleen of a patient with neutral beta-D-galactosidase deficiency. An additional form of beta-D-xylosidase with optimal activity at pH 7.4 was bound by the fucose-binding lectin from Ulex eurpaeus while no binding was observed for the acidic (pH 4.8) and neutral (pH 7.0) beta-D-xylosidase activities of the multiple glycosidase enzymes.     

Binding of hydrolases from wheat aleurone to concanavalin A- and wheat-germ agglutinin-sepharose

We have studied the ability of hydrolases (acid phosphatase and glycosidases) from the aleurone layers of resting wheat grains to interact with Con A- and WGA-Sepharose as a way to examine their glycoprotein nature. Aliquots (6–85% depending on the enzyme) of all the enzymes interacted with Con A-Sepharose. The major part of α-mannosidase activity (85%) was present in this form. Aliquots (2–20% depending on the enzyme) of the following four enzymes, β-galactosidase, α-mannosidase, β-N-acetylglucosaminidase and acid phosphatase, interacted with WGA-Sepharose. All the enzymes were found in forms which were unable to interact with either lectin. No forms of hydrolases interacting with both lectins were found in the crude extract. The specific activities of most of the enzymes recovered from the lectin-Sepharose gels were greater than those measured in the crude extract. In particular, the highest specific activities were found for β-N-acetylglucosaminidase and β-galactosidase recovered from WGA-Sepharose. Different lectin-binding forms of hydrolases were compared with respect to pH optimum and stability under various conditions (heat and guanidine hydrochloride treatments). The lectin-binding pattern of the hydrolases released in the incubation medium by the aleurone layers was similar to that reported above for the enzymes extracted from these tissues, suggesting that none of the hydrolase forms found in the aleurone layers is selectively released during incubation of these tissues.     

I-Cell disease: Activities of lysosomal enzymes toward natural and synthetic substrates

Cultured skin fibroblasts from a patient with I-Cell disease (mucolipidosis II) were assayed for a number of lysosomal enzymes using both natural and synthetic substrates. The cells from this patient were found to have very low activity for galactosylceramide β-galactosidase, lactosylceramide β-galactosidases (using two assay methods that measure different enzymes), G_M1 ganglioside β-galactosidase and sphingomyelinase. Glucosylceramide β-glucosidase activity was found to be normal. Acid hydrolase activities toward many synthetic substrate were measured and all except β-glucosidase and acid phosphatase were found to be extremely low (as has been reported by others). Acid phosphatase and β-glucosidase were in the low normal range. These studies expand on previously published reports on I-Cell disease that only present data from synthetic substrates, and also report the fibroblast culture deficiencies of galactosyl-ceramide β-galactosidase (the Krabbe disease enzyme) and sphingomyelinase (the Niemann-Pick disease enzyme) activities for the first time. Those two enzymes do not have a readily available synthetic analog to assay. Acid β-galactosidase activity measured with both the 4-methylumbelliferyl derivative and G_M1 ganglioside was partially deficient in leukocytes prepared from this patient. New methods for measuring 4-methylumbelliferyl-β-D-glucoside and glucosylceramide β-glucosidase activities are also presented.     

Affinity labelling of enzymes with triazine dyes. Isolation of a peptide in the catalytic domain of horse-liver alcohol dehydrogenase using Procion blue MX-R as a structural probe

The incorporation of [3H]leucine and [32P]phosphate into three lysosomal enzymes, cathepsin D, beta-hexosaminidase and arylsulfatase A by fibroblasts from six patients affected with mucolipidosis III was determined. In the mutant cells the incorporation of 32P in the enzymes was reduced by 70-97% as compared to controls. The residual phosphorylation of lysosomal enzymes is definitely higher than in fibroblasts from patients with mucolipidosis II, where apparently non-phosphorylated enzymes are formed. In mucolipidosis III the major part of the newly formed enzymes accumulated extracellularly and the cellular enzymes were recovered mainly in their processed forms. In mucolipidosis III arylsulfatase A and the processed forms of cathepsin D exhibited a heterogeneity that was not observed in controls. beta-Hexosaminidase and cathepsin D secreted by mucolipidosis III fibroblasts contained only a small amount of phosphorylated oligosaccharides with either one or two phosphate groups per oligosaccharide. As in controls the major fraction of phosphate was present as acid-labile phosphodiester resistant to alkaline phosphatase. The residual phosphorylation of lysosomal enzymes may be related to the partial intracellular retention and processing of these enzymes in fibroblasts from patients with mucolipidosis III.     

Mucolipidosis I: Increased sialic acid content and deficiency of an α-N-acetylneuraminidase in cultured fibroblasts

Extracts of fibroblasts derived from a patient with mucolipidosis I exhibited a fivefold increase in sialic acid content as compared to those of normal cells. About 80% of this sialic acid was linked to other molecules. Using neuraminlactose as a substrate, mucolipidosis I fibroblasts were found to be severely deficient in an “acid” α-N-acetylneuraminidase. Since other lysosomal hydrolase activities were normal, we hypothesize that the basic metabolic lesion in mucolipidosis I lies in a defective degradation of sialic acid-containing compounds due to the genetic deficiency of a neuraminidase.     

Analysis of Mucolipidosis II/III GNPTAB Missense Mutations Identifies Domains of UDP-GlcNAc:lysosomal Enzyme GlcNAc-1-phosphotransferase Involved in Catalytic Function and Lysosomal Enzyme Recognition

UDP-GlcNAc:lysosomal enzyme GlcNAc-1-phosphotransferase tags newly synthesized lysosomal enzymes with mannose 6-phosphate recognition markers, which are required for their targeting to the endolysosomal system. GNPTAB encodes the α and β subunits of GlcNAc-1-phosphotransferase, and mutations in this gene cause the lysosomal storage disorders mucolipidosis II and III αβ. Prior investigation of missense mutations in GNPTAB uncovered amino acids in the N-terminal region and within the DMAP domain involved in Golgi retention of GlcNAc-1-phosphotransferase and its ability to specifically recognize lysosomal hydrolases, respectively. Here, we undertook a comprehensive analysis of the remaining missense mutations in GNPTAB reported in mucolipidosis II and III αβ patients using cell- and zebrafish-based approaches. We show that the Stealth domain harbors the catalytic site, as some mutations in these regions greatly impaired the activity of the enzyme without affecting its Golgi localization and proteolytic processing. We also demonstrate a role for the Notch repeat 1 in lysosomal hydrolase recognition, as missense mutations in conserved cysteine residues in this domain do not affect the catalytic activity but impair mannose phosphorylation of certain lysosomal hydrolases. Rescue experiments using mRNA bearing Notch repeat 1 mutations in GNPTAB-deficient zebrafish revealed selective effects on hydrolase recognition that differ from the DMAP mutation. Finally, the mutant R587P, located in the spacer between Notch 2 and DMAP, was partially rescued by overexpression of the γ subunit, suggesting a role for this region in γ subunit binding. These studies provide new insight into the functions of the different domains of the α and β subunits.     

The structure of Ap(4)A hydrolase complexed with ATP-MgF(x) reveals the basis of substrate binding

Ap(4)A hydrolases are Nudix enzymes that regulate intracellular dinucleoside polyphosphate concentrations, implicating them in a range of biological events, including heat shock and metabolic stress. We have demonstrated that ATP x MgF(x) can be used to mimic substrates in the binding site of Ap(4)A hydrolase from Lupinus angustifolius and that, unlike previous substrate analogs, it is in slow exchange with the enzyme. The three-dimensional structure of the enzyme complexed with ATP x MgF(x) was solved and shows significant conformational changes. The substrate binding site of L. angustifolius Ap(4)A hydrolase differs markedly from the two previously published Nudix enzymes, ADP-ribose pyrophosphatase and MutT, despite their common fold and the conservation of active site residues. The majority of residues involved in substrate binding are conserved in asymmetrical Ap(4)A hydrolases from pathogenic bacteria, but are absent in their human counterparts, suggesting that it might be possible to generate compounds that target bacterial, but not human, Ap(4)A hydrolases.     

An InCytes from MBC Selection: Mice Lacking Mannose 6-Phosphate Uncovering Enzyme Activity Have a Milder Phenotype than Mice Deficient for N-Acetylglucosamine-1-Phosphotransferase Activity

The mannose 6-phosphate (Man-6-P) lysosomal targeting signal on acid hydrolases is synthesized by the sequential action of uridine 5′-diphosphate-N-acetylglucosamine: lysosomal enzyme N-acetylglucosamine-1-phosphotransferase (GlcNAc-1-phosphotransferase) and GlcNAc-1-phosphodiester α-N-acetylglucosaminidase (“uncovering enzyme” or UCE). Mutations in the two genes that encode GlcNAc-1-phosphotransferase give rise to lysosomal storage diseases (mucolipidosis type II and III), whereas no pathological conditions have been associated with the loss of UCE activity. To analyze the consequences of UCE deficiency, the UCE gene was inactivated via insertional mutagenesis in mice. The UCE −/− mice were viable, grew normally and lacked detectable histologic abnormalities. However, the plasma levels of six acid hydrolases were elevated 1.6- to 5.4-fold over wild-type levels. These values underestimate the degree of hydrolase hypersecretion as these enzymes were rapidly cleared from the plasma by the mannose receptor. The secreted hydrolases contained GlcNAc-P-Man diesters, exhibited a decreased affinity for the cation-independent mannose 6-phosphate receptor and failed to bind to the cation-dependent mannose 6-phosphate receptor. These data demonstrate that UCE accounts for all the uncovering activity in the Golgi. We propose that in the absence of UCE, the weak binding of the acid hydrolases to the cation-independent mannose 6-phosphate receptor allows sufficient sorting to lysosomes to prevent the tissue abnormalities seen with GlcNAc-1-phosphotranferase deficiency.     

Biochemical studies on lymphoblastoid cells with inherited N-acetyl-glucosamine 1-phosphotransferase deficiency (I-cell disease)

Lymphoblastoid cells transformed by Epstein-Barr virus from peripheral lymphocytes of normal individuals and I-cell disease (ICD) patients were used for the enzymic study of lysosomal hydrolases and N-acetylglucosamine 1-phosphotransferase. ICD lymphoblastoid cells secreted a larger amount of hydrolases into medium than normal cells, although the intracellular hydrolases were not deficient in ICD cells. The stimulating effect of 10 mM ammonium chloride on secretion of hydrolases was found only with normal cells, and not with ICD cells, indicating that the hydrolase molecule bearing mannose 6-phosphate was secreted. The ICD lymphoblastoid cells retained the enzymologic characteristics of both lysosomal hydrolases and N-acetylglucosamine 1-phosphotransferase seen in ICD fibroblasts, which allows us to study the pathophysiology of ICD in cells other than fibroblasts.     

Five related Lebanese individuals with high plasma lysosomal hydrolases: a new defect in mannose-6-phosphate receptor recognition?

Five healthy related individuals in 3 generations of a Lebanese family have been found to have highly elevated plasma lysosomal enzyme levels inherited as a dominant Mendelian trait. The same enzymes in other extracellular fluids were within normal limits. While the pattern and extent of plasma enzyme elevation was similar to that found in mucolipidoses II and III, the physicochemical properties of the elevated enzymes were different from those of both control and I-cell disease plasma. Secretion of lysosomal hydrolases into cell media by fibroblasts from one of the individuals was increased two to seven times more than that from controls. The results suggest faulty recognition between lysosomal hydrolases and mannose-6-phosphate receptors. This could be caused by a defect either in the phosphodiesterase that normally uncovers mannose-6-phosphate hydrolase markers or in the mannose-6-phosphate receptor itself.     

Diversity and biocatalytic potential of epoxide hydrolases identified by genome analysis

Epoxide hydrolases play an important role in the biodegradation of organic compounds and are potentially useful in enantioselective biocatalysis. An analysis of various genomic databases revealed that about 20% of sequenced organisms contain one or more putative epoxide hydrolase genes. They were found in all domains of life, and many fungi and actinobacteria contain several putative epoxide hydrolase-encoding genes. Multiple sequence alignments of epoxide hydrolases with other known and putative alpha/beta-hydrolase fold enzymes that possess a nucleophilic aspartate revealed that these enzymes can be classified into eight phylogenetic groups that all contain putative epoxide hydrolases. To determine their catalytic activities, 10 putative bacterial epoxide hydrolase genes and 2 known bacterial epoxide hydrolase genes were cloned and overexpressed in Escherichia coli. The production of active enzyme was strongly improved by fusion to the maltose binding protein (MalE), which prevented inclusion body formation and facilitated protein purification. Eight of the 12 fusion proteins were active toward one or more of the 21 epoxides that were tested, and they converted both terminal and nonterminal epoxides. Four of the new epoxide hydrolases showed an uncommon enantiopreference for meso-epoxides and/or terminal aromatic epoxides, which made them suitable for the production of enantiopure (S,S)-diols and (R)-epoxides. The results show that the expression of epoxide hydrolase genes that are detected by analyses of genomic databases is a useful strategy for obtaining new biocatalysts.