The soluble form of rat liver alpha-mannosidase is immunologically related to the endoplasmic reticulum membrane alpha-mannosidase

The soluble alpha-mannosidase of rat liver, originally described as a cytoplasmic alpha-mannosidase, has been purified to homogeneity by conventional techniques. The purified enzyme has an apparent molecular weight of 350,000 and is composed of 107-kDa subunits. The soluble alpha-mannosidase has the same enzymatic properties as the endoplasmic reticulum (ER) membrane alpha-mannosidase of rat liver (Bischoff, J., and Kornfeld, R. (1983) J. Biol. Chem. 258, 7909-7910) which is believed to play a role in oligosaccharide processing in the rough ER. Like the membrane-bound ER alpha-mannosidase, the soluble alpha-mannosidase can hydrolyze alpha-linked mannose from both p-nitrophenyl alpha-mannoside (Km = 0.14 mM) and high mannose oligosaccharides, is not inhibited by the mannose analogues swainsonine and 1-deoxymannojirimycin, is stabilized by MnCl2 or CoCl2, and does not bind to concanavalin A-Sepharose. A goat polyclonal antibody raised against the purified soluble alpha-mannosidase specifically recognizes the rat liver membrane-bound ER alpha-mannosidase, leading us to propose that they are two forms of the same enzyme and that the soluble form is derived from the ER membrane alpha-mannosidase by proteolysis. The antibody also cross-reacts with both the soluble and membrane-bound forms of ER alpha-mannosidase activity in cultured Chinese hamster ovary cells and rat H35 hepatoma cells. Since the ER alpha-mannosidase is presumed to be involved in the early steps of oligosaccharide processing, the action of the purified soluble form of the enzyme on high mannose oligosaccharides was examined. Surprisingly, the enzyme released free mannose from oligosaccharides ranging in size from Glc1Man9GlcNAc to Man5GlcNAc with almost equal efficiency. However, a long term incubation of the enzyme with Man9GlcNAc led to the accumulation of Man7GlcNAc and produced only small amounts of Man6GlcNAc and Man5GlcNAc. Structural analysis of these reaction products indicated that the purified soluble form of ER alpha-mannosidase shows little specificity for which mannose residues it removes from Man9GlcNAc. In contrast, as shown in the accompanying paper, the intracellular action of ER alpha-mannosidase on glycoprotein-bound Man9GlcNAc2 is highly specific.     

Characterization of a novel alpha-D-mannosidase from rat brain microsomes

A new alpha-D-mannosidase has been identified in rat brain microsomes. The enzyme was purified 70-100-fold over the microsomal fraction by solubilization with Triton X-100, followed by ion exchange, concanavalin A-Sepharose, and hydroxylapatite chromatography. The purified enzyme is very active towards mannose-containing oligosaccharides and has a pH optimum of 6.0. Unlike rat liver endoplasmic reticulum alpha-D-mannosidase and both Golgi mannosidases IA and IB, which have substantial activity only towards alpha 1,2-linked mannosyl residues, the brain enzyme readily cleaves alpha 1,2-, alpha 1,3-, and alpha 1,6-linked mannosyl residues present in high mannose oligosaccharides. The brain enzyme is also different from liver Golgi mannosidase II in that it hydrolyzes (Man)5GlcNAc and (Man)4GlcNAc without their prior N-acetylglucosaminylation. Moreover, the facts that the ability of the enzyme to cleave GlcNAc(Man)5GlcNAc, the biological substrate for Golgi mannosidase II, is not inhibited by swainsonine, and that p-nitrophenyl alpha-D-mannoside is a poor substrate provide further evidence for major differences between the brain enzyme and mannosidase II. Inactivation studies and the co-purification of activities towards various substrates suggest that a single enzyme is responsible for all the activities found. In view of these results, it seems possible that, in rat brain, a single mannosidase cleaves asparagine-linked high mannose oligosaccharide to form the core Man3GlcNAc2 moiety, which would then be modified by various glycosyl transferases to form complex type glycoproteins.     

Importance of glycosidases in mammalian glycoprotein biosynthesis

Processing glycosidases play an important role in N-glycan biosynthesis in mammalian cells by trimming Glc(3)Man(9)GlcNAc(2) and thus providing the substrates for the formation of complex and hybrid structures by Golgi glycosyltransferases. Processing glycosidases also play a role in the folding of newly formed glycoproteins and in endoplasmic reticulum quality control. The properties and molecular nature of mammalian processing glycosidases are described in this review. Membrane-bound alpha-glucosidase I and soluble alpha-glucosidase II of the endoplasmic reticulum remove the alpha1,2-glucose and alpha1,3-glucose residues, respectively, beginning immediately following transfer of Glc(3)Man(9)GlcNAc(2) to nascent polypeptides. The alpha-glucosidases participate in glycoprotein folding mediated by calnexin and calreticulin by forming the monoglucosylated high mannose oligosaccharides required for the interaction with the chaperones. In some mammalian cells, Golgi endo alpha-mannosidase provides an alternative pathway for removal of glucose residues. Removal of alpha1,2-linked mannose residues begins in the endoplasmic reticulum where trimming of mannose residues in the endoplasmic reticulum has been implicated in the targeting of malfolded glycoproteins for degradation. Removal of mannose residues continues in the Golgi with the action of alpha1, 2-mannosidases IA and IB that can form Man(5)GlcNAc(2) and of alpha-mannosidase II that removes the alpha1,3- and alpha1,6-linked mannose from GlcNAcMan(5)GlcNAc(2) to form GlcNAcMan(3)GlcNAc(2). These membrane-bound Golgi enzymes have been cloned and shown to have very distinct patterns of tissue-specific expression. There are also broad specificity alpha-mannosidases that can trim Man(4-9)GlcNAc(2) to Man(3)GlcNAc(2), and provide an alternative pathway toward complex oligosaccharide formation. Cloning of the remaining alpha-mannosidases will be required to evaluate their specific functions in glycoprotein maturation.     

Substrate specificities of recombinant murine Golgi alpha1, 2- mannosidases IA and IB and comparison with endoplasmic reticulum and Golgi processing alpha1,2-mannosidases

The catalytic domains of murine Golgi alpha1,2-mannosidases IA and IB that are involved in N-glycan processing were expressed as secreted proteins in P.pastoris . Recombinant mannosidases IA and IB both required divalent cations for activity, were inhibited by deoxymannojirimycin and kifunensine, and exhibited similar catalytic constants using Manalpha1,2Manalpha-O-CH3as substrate. Mannosidase IA was purified as a 50 kDa catalytically active soluble fragment and shown to be an inverting glycosidase. Recombinant mannosidases IA and IB were used to cleave Man9GlcNAc and the isomers produced were identified by high performance liquid chromatography and proton-nuclear magnetic resonance spectroscopy. Man9GlcNAc was rapidly cleaved by both enzymes to Man6GlcNAc, followed by a much slower conversion to Man5GlcNAc. The same isomers of Man7GlcNAc and Man6GlcNAc were produced by both enzymes but different isomers of Man8GlcNAc were formed. When Man8GlcNAc (Man8B isomer) was used as substrate, rapid conversion to Man5GlcNAc was observed, and the same oligosaccharide isomer intermediates were formed by both enzymes. These results combined with proton-nuclear magnetic resonance spectroscopy data demonstrate that it is the terminal alpha1, 2-mannose residue missing in the Man8B isomer that is cleaved from Man9GlcNAc at a much slower rate. When rat liver endoplasmic reticulum membrane extracts were incubated with Man9GlcNAc2, Man8GlcNAc2was the major product and Man8B was the major isomer. In contrast, rat liver Golgi membranes rapidly cleaved Man9GlcNAc2to Man6GlcNAc2and more slowly to Man5GlcNAc2. In this case all three isomers of Man8GlcNAc2were formed as intermediates, but a distinctive isomer, Man8A, was predominant. Antiserum to recombinant mannosidase IA immunoprecipitated an enzyme from Golgi extracts with the same specificity as recombinant mannosidase IA. These immunodepleted membranes were enriched in a Man9GlcNAc2to Man8GlcNAc2- cleaving activity forming predominantly the Man8B isomer. These results suggest that mannosidases IA and IB in Golgi membranes prefer the Man8B isomer generated by a complementary mannosidase that removes a single mannose from Man9GlcNAc2.      

Golgi endo-alpha-D-mannosidase from rat liver, a novel N-linked carbohydrate unit processing enzyme

An enzyme has been found in Triton-treated rat liver Golgi membranes which trims Glc1Man9GlcNAc to Man8GlcNAc with the release of Glc alpha 1-3Man. By removing a glucosylmannose disaccharide and yielding only one Man8GlcNAc isomer, this endo-alpha-D-mannosidase provides a processing route alternative to the sequential actions of alpha-glucosidase II and alpha-mannosidase I. The endomannosidase was fully active in the presence of 1-deoxynojirimycin and EDTA which inhibited exoglycosidase release of glucose and mannose, respectively, and these agents were, therefore, included in the standard assay. The specific activity of the endomannosidase was found to be 69-fold greater in Golgi than in rough endoplasmic reticulum (RER) membranes, and Golgi-RER mixing experiments excluded the possibility that the low activity in the RER was the result of some inhibitor present in this fraction. The neutral pH optimum (approximately 7.0) of the enzyme was consistent with a role in N-linked oligosaccharide processing. The existence of an endo-alpha-D-mannosidase pathway for glucose removal could provide an explanation for the incomplete block in oligosaccharide processing which is observed in cells with inhibited or deficient alpha-glucosidase.     

Evaluation of the role of rat liver Golgi endo-alpha-D-mannosidase in processing N-linked oligosaccharides

Golgi membranes from rat liver have been shown to contain an endo-alpha-D-mannosidase which can convert Glc1Man9GlcNAc to Man8GlcNAc with the release of Glc alpha 1----3Man (Lubas, W. A., and Spiro, R. G. (1987) J. Biol. Chem. 262, 3775-3781). We now report that this enzyme has the capacity to cleave the alpha 1----2 linkage between the glucose-substituted mannose residue and the remainder of the polymannose branch in a wide range of oligosaccharides (Glc3Man9GlcNAc to Glc1Man4GlcNAc) as well as glycopeptides and oligosaccharide-lipids. Whereas the tri- and diglucosylated species (Glc3Man9GlcNAc and Glc2Man9GlcNAc), which yielded Glc3Man and Glc2Man, respectively, were processed more slowly than Glc1Man9GlcNAc, the monoglucosylated components with truncated mannose chains (Glc1Man8GlcNAc to Glc1Man4GlcNAc) were trimmed at an increased rate which was inversely related to the number of mannose residues present. The endomannosidase was not inhibited by a number of agents which are known to interfere with N-linked oligosaccharide processing by exoglycosidases, including 1-deoxynojirimycin, castanospermine, bromoconduritol, 1-deoxymannojirimycin, swainsonine, and EDTA. However, Tris and other buffers containing primary hydroxyl groups substantially decreased its activity. After Triton solubilization, the endomannosidase was observed to be bound to immobilized wheat germ agglutinin, indicating the presence of a type of carbohydrate unit consistent with Golgi localization of the enzyme. The Man8GlcNAc isomer produced by endomannosidase action was found to be processed by Golgi enzymes through a different sequence of intermediates than the rough endoplasmic reticulum-generated Man8GlcNAc variant, in which the terminal mannose of the middle branch is absent. Whereas the latter oligosaccharide is converted to Man5GlcNAc via Man7GlcNAc and Man6GlcNAc at an even rate, the processing of the endomannosidase-derived Man8GlcNAc stalls at the Man6GlcNAc stage due to the apparent resistance to Golgi mannosidase I of the alpha 1,2-linked mannose of the middle branch. The results of our study suggest that the Golgi endomannosidase takes part in a processing route for N-linked oligosaccharides which have retained glucose beyond the rough endoplasmic reticulum; the distinctive nature of this pathway may influence the ultimate structure of the resulting carbohydrate units.     

Characterization of a specific alpha-mannosidase involved in oligosaccharide processing in Saccharomyces cerevisiae

Fractionation of a crude extract from Saccharomyces cerevisiae X-2180 on Sepharose 6B in the presence of 0.5% Triton X-100 resolves two enzyme fractions containing alpha-mannosidase activity. Fraction I which is excluded from the gel contains alpha-mannosidase activity toward both p-nitrophenyl-alpha-D-mannopyranoside and Man9GlcNAc oligosaccharide as substrates, whereas Fraction II which is included in the gel contains only oligosaccharide alpha-mannosidase activity. The latter enzyme is very specific and removes a single mannose residue from Man9GlcNAc, whereas the alpha-mannosidase activity of Fraction I removes several mannose residues from Man9GlcNAc oligosaccharide. High resolution 1H NMR analysis of the Man8GlcNAc formed from Man9GlcNAc in the presence of the alpha-mannosidase of Fraction II showed only a single isomer with the following structure: (see formula; see text) This specific enzyme is most probably involved in processing of oligosaccharide during biosynthesis of mannoproteins. The mannose analog of 1-deoxynojirimycin (50-500 microM), dideoxy-1,5-imino-D-mannitol, inhibits the oligosaccharide alpha-mannosidase activities of Fractions I and II to about the same extent, but has no effect on the nonspecific alpha-mannosidase which acts on p-nitrophenyl-alpha-D-mannopyranoside.     

The use of 1-deoxymannojirimycin to evaluate the role of various alpha-mannosidases in oligosaccharide processing in intact cells

The mannose analogue, 1-deoxymannojirimycin, which inhibits Golgi alpha-mannosidase I but not endoplasmic reticulum (ER) alpha-mannosidase has been used to determine the role of the ER alpha-mannosidase in the processing of the asparagine-linked oligosaccharides on glycoproteins in intact cells. In the absence of the inhibitor, the predominant oligosaccharide structures found on the ER glycoprotein 3-hydroxy-3-methylglutaryl-CoA reductase in UT-1 cells are single isomers of Man6GlcNAc and Man8GlcNAc. In the presence of 150 microM 1-deoxymannojirimycin, the Man8GlcNAc2 isomer accumulates indicating that the 1-deoxymannojirimycin-resistant ER alpha-mannosidase is responsible for the conversion of Man9GlcNAc2 to Man8GlcNAc2 on reductase. The processing of Man8GlcNAc2 to Man6GlcNAc2, however, must be attributed to a 1-deoxymannojirimycin-sensitive alpha-mannosidase. When cells were radiolabeled with [2-(3)H]mannose for 15 h in the presence of 1-deoxymannojirimycin and then further incubated for 3 h in nonradioactive medium without inhibitor, the Man8GlcNAc2 oligosaccharides which accumulated during the labeling period were partially trimmed to Man6GlcNAc. This finding suggests that a second alpha-mannosidase, sensitive to 1-deoxymannojirimycin, resides in the crystalloid ER and is responsible for trimming the reductase oligosaccharide chain from Man8GlcNAc2 to Man6GlcNAc2. To determine if ER alpha-mannosidase is responsible for trimming the oligosaccharides of all glycoproteins from Man9GlcNAc to Man8GlcNAc, the total asparagine-linked oligosaccharides of rat hepatocytes labeled with [2-(3)H]mannose in the presence or absence of 1.0 mM 1-deoxymannojirimycin were examined. the inhibitor prevented the formation of complex oligosaccharides and caused a 30-fold increase in the amount of Man9GlcNAc2 and a 13-fold increase in the amount of Man8GlcNAc2 present on secreted glycoproteins. This result suggests that only one-third of the secreted glycoproteins is initially processed by ER alpha-mannosidase, and two-thirds are processed by Golgi alpha-mannosidase I or another 1-deoxymannojirimycin-sensitive alpha-mannosidase. The inhibitor caused only a 2.6-fold increase in the amount of Man9GlcNAc2 on cellular glycoproteins suggesting that a higher proportion of these glycoproteins are initially processed by the ER alpha-mannosidase. We conclude that some, but not all, hepatocyte glycoproteins are substrates for ER alpha-mannosidase which catalyzes the removal of a specific mannose residue from Man9GlcNAc2 to form a single isomer of Man8GlcNAc2.     

Structural heterogeneity in the Man8-13GlcNAc oligosaccharides from log-phase Saccharomyces yeast: a one- and two-dimensional 1H NMR spectroscopic study.

Previously, Man8-14GlcNAc oligosaccharides were isolated from highly purified Saccharomyces cerevisiae invertase and shown by one-dimensional 1H NMR spectroscopy and alpha 1,2-linkage-specific mannosidase digestion to constitute a homologous series of nearly homogeneous compounds, which appeared to define the intermediates in oligosaccharide core synthesis in yeast (Trimble, R.B. and Atkinson, P.H. (1986) J. Biol. Chem., 261, 9815-9824). To evaluate whether invertase oligosaccharides reflected global core processing of yeast glycans, the soluble glycoprotein pool of disrupted log-phase cells was digested with endo-beta-N-acetyl-glucosaminidase H and Man8-13GlcNAc were isolated by Bio-Gel P-4 chromatography. Although analysis of each size class by one-dimensional 400 MHz and two-dimensional 500 MHz phase-sensitive COSY 1H NMR spectroscopy revealed considerable structural heterogeneity in all but Man8GlcNAc, the major positional isomer in Man9-13GlcNAc (approximately 50%) was identical to that previously elucidated on invertase. The heterogeneity resided in four families of oligosaccharides: (i) Glc3Man9GlcNAc----Man8 GlcNAc trimming intermediates; (ii) alpha-mannosidase degradation products of the principal isomers; (iii) mannan elongation intermediates; (iv) core structures with the alpha 1,2-linked mannose usually removed by the processing alpha-mannosidase. The potential for the vacuolar alpha-mannosidase (AMS1 gene product) to generate heterogeneity in vitro was confirmed by isolating oligosaccharides from AMS1 and ams1 yeast strains in the presence of a Man13GlcNAc[3H]-ol marker (where GlcNAc[3H]-ol is N-acetylglucosamin [1-3H]itol). Degradation of the Man13GlcNAc[3H]-ol to Man9-12GlcNAc[3H]-ol occurred in the former, but not in the latter. A role for the vacuolar alpha-mannosidase in generating at least some heterogeneity in vivo was inferred from the 1H NMR spectrum of the AMS1 Man11GlcNAc pool, which showed more structural isomerism than seen in the spectrum of a comparable ams1 Man11GlcNAc preparation. Thus, the principal biosynthetic pathway of inner core mannan in Saccharomyces is defined by the Man8-13GlcNAc oligosaccharides found on external invertase, while structural heterogeneity in these size classes results from precursor processing in the endoplasmic reticulum, core extension in the Golgi and metabolic degradation in the vacuole.     

Mutation of Arg(273) to Leu alters the specificity of the yeast N-glycan processing class I alpha1,2-mannosidase

Class I alpha1,2-mannosidases (glycosyl hydrolase family 47) involved in the processing of N-glycans during glycoprotein maturation have different specificities. Enzymes in the endoplasmic reticulum of yeast and mammalian cells remove a single mannose from Man(9)GlcNAc(2) to form Man(8)GlcNAc(2) isomer B (lacking the alpha1, 2-mannose residue of the middle alpha1, 3-arm), whereas other alpha1,2-mannosidases, including Golgi alpha1,2-mannosidases IA and IB, can convert Man(9)GlcNAc(2) to Man(5)GlcNAc(2). In the present work, it is demonstrated that with a single mutation in its catalytic domain (Arg(273) --> Leu) the yeast endoplasmic reticulum alpha1,2-mannosidase acquires the ability to transform Man(9)GlcNAc to Man(5)GlcNAc. High resolution proton nuclear magnetic resonance analysis of the products shows that the order of removal of mannose from Man(9)GlcNAc is different from that of other alpha1, 2-mannosidases that remove four mannose from Man(9)GlcNAc. These results demonstrate that Arg(273) is in part responsible for the specificity of the endoplasmic reticulum alpha1,2-mannosidase and that small differences in non-conserved amino acids interacting with the oligosaccharide substrate in the active site of class I alpha1, 2-mannosidases are responsible for the different specificities of these enzymes.     

Saccharomyces cerevisiae alpha1,6-mannosyltransferase has a catalytic potential to transfer a second mannose molecule

In yeast, the N-linked oligosaccharide modification in the Golgi apparatus is initiated by alpha1,6-mannosyltransferase (encoded by the OCH1 gene) with the addition of mannose to the Man(8)GlcNAc(2) or Man(9)GlcNAc(2) endoplasmic reticulum intermediates. In order to characterize its enzymatic properties, the soluble form of the recombinant Och1p was expressed in the methylotrophic yeast Pichia pastoris as a secreted protein, after truncation of its transmembrane region and fusion with myc and histidine tags at the C-terminus, and purified using a metal chelating column. The enzymatic reaction was performed using various kinds of pyridylaminated (PA) sugar chains as acceptor, and the products were separated by high performance liquid chromatography. The recombinant Och1p efficiently transferred a mannose to Man(8)GlcNAc(2)-PA and Man(9)GlcNAc(2)-PA acceptors, while Man(5)GlcNAc(2)-PA, which completely lacks alpha1,2-linked mannose residues, was not used as an acceptor. At high enzyme concentrations, a novel product was detected by HPLC. Analysis of the product revealed that a second mannose was attached at the 6-O-position of alpha1,3-linked mannose branching from the alpha1,6-linked mannose that is attached to beta1,4-linked mannose of Man(10)GlcNAc(2)-PA produced by the original activity of Och1p. Our results indicate that Och1p has the potential to transfer two mannoses from GDP-mannose, and strictly recognizes the overall structure of high mannose type oligosaccharide.     

Overexpression of the Golgi-localized enzyme alpha-mannosidase IIx in Chinese hamster ovary cells results in the conversion of hexamannosyl-N-acetylchitobiose to tetramannosyl-N-acetylchitobiose in the N-glycan-processing pathway.

Golgi alpha-mannosidase II is an enzyme that processes the intermediate oligosaccharide Gn(1)M(5)Gn(2) to Gn(1)M(3)Gn(2) during biosynthesis of N-glycans. Previously, we isolated a cDNA encoding a protein homologous to alpha-mannosidase II and designated it alpha-mannosidase IIx. Here, we show by immunocytochemistry that alpha-mannosidase IIx resides in the Golgi in HeLa cells. When coexpressed with alpha-mannosidase II, alpha-mannosidase IIx colocalizes with alpha-mannosidase II in COS cells. A protein A fusion of the catalytic domain of alpha-mannosidase IIx hydrolyzes a synthetic substrate, 4-umbelliferyl-alpha-D-mannoside, and this activity is inhibited by swainsonine. [(3)H]glucosamine-labeled Chinese hamster ovary cells overexpressing alpha-mannosidase IIx show a reduction of M(6)Gn(2) and an accumulation of M(4)Gn(2). Structural analysis identified M(4)Gn(2) to be Man alpha 1-->6(Man alpha 1-->2Man alpha 1-->3)Man beta 1-->4GlcNAc beta 1-->4GlcNAc. The results suggest that alpha-mannosidase IIx hydrolyzes two peripheral Man alpha 1-->6 and Man alpha 1-->3 residues from [(Man alpha 1-->6)(Man alpha 1-->3)Man alpha 1-->6](Man alpha 1-->2Man alpha 1-->3)Man beta 1-->4GlcNAc beta 1-->4GlcNAc, during N-glycan processing.     

N-Glycan processing by a lepidopteran insect alpha1,2-mannosidase

Protein glycosylation pathways are relatively poorly characterized in insect cells. As part of an overall effort to address this problem, we previously isolated a cDNA from Sf9 cells that encodes an insect alpha1,2-mannosidase (SfManI) which requires calcium and is inhibited by 1-deoxymannojirimycin. In the present study, we have characterized the substrate specificity of SfManI. A recombinant baculovirus was used to express a GST-tagged secreted form of SfManI which was purified from the medium using an immobilized glutathione column. The purified SfManI was then incubated with oligosaccharide substrates and the resulting products were analyzed by HPLC. These analyses showed that SfManI rapidly converts Man(9)GlcNAc(2)to Man(6)Glc-NAc(2)isomer C, then more slowly converts Man(6)GlcNAc(2)isomer C to Man(5)GlcNAc(2). The slow step in the processing of Man(9)GlcNAc(2)to Man(5)GlcNAc(2)by SfManI is removal of the alpha1,2-linked mannose on the middle arm of Man(9)GlcNAc(2). In this respect, SfManI is similar to mammalian alpha1,2-mannosidases IA and IB. However, additional HPLC and(1)H-NMR analyses demonstrated that SfManI converts Man(9)GlcNAc(2)to Man(5)GlcNAc(2)primarily through Man(7)GlcNAc(2)isomer C, the archetypal Man(9)GlcNAc(2)missing the lower arm alpha1,2-linked mannose residues. In this respect, SfManI differs from mammalian alpha1,2-mannosidases IA and IB, and is the first alpha1,2-mannosidase directly shown to produce Man(7)GlcNAc(2)isomer C as a major processing intermediate.     

Processing of MOPC 315 immunoglobulin A oligosaccharides: evidence for endoplasmic reticulum and trans Golgi alpha 1,2-mannosidase activity

The processing of asparagine-linked oligosaccharides on the alpha- chains of an immunoglobulin A (IgA) has been investigated using MOPC 315 murine plasmacytoma cells. These cells secrete IgA containing complex-type oligosaccharides that were not sensitive to endo-beta-N- acetylglucosaminidase H. In contrast, oligosaccharides present on the intracellular alpha-chain precursor were of the high mannose-type, remaining sensitive to endo-beta-N-acetylglucosaminidase H despite a long intracellular half-life of 2-3 h. The major [3H]mannose-labeled alpha-chain oligosaccharides identified after a 20-min pulse were Man8GlcNAc2 and Man9GlcNAc2. Following chase incubations, the major oligosaccharide accumulating intracellularly was Man6GlcNAc2, which was shown to contain a single alpha 1,2-linked mannose residue. Conversion of Man6GlcNAc2 to complex-type oligosaccharides occurred at the time of secretion since appreciable amounts of Man5GlcNAc2 or further processed structures could not be detected intracellularly. The subcellular locations of the alpha 1,2-mannosidase activities were studied using carbonyl cyanide m-chlorophenylhydrazone and monensin. Despite inhibiting the secretion of IgA, these inhibitors of protein migration did not effect the initial processing of Man9GlcNAc2 to Man6GlcNAc2. Furthermore, no large accumulation of Man5GlcNAc2 occurred, indicating the presence of two subcellular locations of alpha 1,2-mannosidase activity involved in oligosaccharide processing in MOPC 315 cells. Thus, the first three alpha 1,2-linked mannose residues were removed shortly after the alpha-chain was glycosylated, most likely in rough endoplasmic reticulum, since this processing occurred in the presence of carbonyl cyanide m-chlorophenylhydrazone. However, the removal of the final alpha 1,2-linked mannose residue as well as subsequent carbohydrate processing occurred just before IgA secretion, most likely in the trans Golgi complex since processing of Man6GlcNAc2 to Man5GlcNAc2 was greatly inhibited in the presence of monensin.     

Developmental regulation of asparagine-linked oligosaccharide synthesis in Dictyostelium discoideum

In the preceding report we demonstrated that the expression of two developmentally regulated alpha-mannosidase activities is induced in Dictyostelium discoideum during its differentiation from single-cell amoebae to multicellular organism (Sharkey, D. J., and Kornfeld, R. (1991) J. Biol. Chem. 266, 18477-18484). These activities, designated membrane alpha-mannosidase I (MI) and membrane alpha-mannosidase II (MII), were shown to have several properties in common with rat liver Golgi alpha-mannosidases I and II, respectively, suggesting that MI and MII may play a role in the processing of asparagine-linked oligosaccharides in developing D. discoideum. In this study we analyzed the structures of the asparagine-linked oligosaccharides synthesized by D. discoideum at various stages of development to determine the timing and extent of asparagine-linked oligosaccharide processing. Cells were labeled with [2-3H] mannose, and then total cellular glycoproteins were digested with Pronase to generate glycopeptides that were fractionated on concanavalin A-Sepharose. Glycopeptides from each fraction were digested with endoglycosidase H, both before and after desulfation by solvolysis, and the released, neutral oligosaccharides were sized by high pressure liquid chromatography. At early stages of development, D. discoideum contain predominantly large high mannose-type oligosaccharides (Man9GlcNAc and Man8GlcNAc). Some of these are modified by GlcNAc residues attached beta 1-4 to the mannose-linked alpha 1-6 to the beta-linked core mannose (the "intersecting" position), as well as by fucose, sulfate, and phosphate. In contrast, the oligosaccharides found at late stages of development (18-24 h) have an array of sizes from Man9GlcNAc to Man3GlcNAc. These are still modified by GlcNAc, fucose, sulfate, and phosphate, but the percent of larger high mannose oligosaccharides that are modified with GlcNAc in the intersecting position decreases after 6 h of development, in parallel with the decrease in the intersecting GlcNAc transferase activity. Similarly, the changes in the size of asparagine-linked oligosaccharides synthesized during development correlate well with the appearance of MI and MII activities and suggest that these developmentally regulated alpha-mannosidase activities function in the processing of these oligosaccharides. This is supported further by the observation that oligosaccharide processing was inhibited in late stage cells labeled in the presence of either deoxymannojirimycin, an inhibitor of MI, or swainsonine, an inhibitor of MII.     

In vitro hydrolysis of oligomannose-type sugar chains by an alpha-1,2-mannosidase from microsomes of developing castor bean cotyledons.

An alpha-1,2-mannosidase involved in the processing of N-linked oligosaccharides was prepared from the microsomal fraction of developing castor bean cotyledons. The processing alpha-mannosidase was solubilized with 1.0% Triton X-100 and purified by ion-exchange chromatography followed by two gel filtration steps. The enzyme obtained could convert Man9GlcNAc2-PA to Man5GlcNAc2-PA, but this enzyme was inactive with Man5GlcNAc2-PA, Man4GlcNAc2-PA, and p-nitrophenyl-alpha-D-mannopyranoside. The enzyme was optimally active between pH 5.5-6.0. The processing mannosidase was inhibited by deoxymannojirimycin, EDTA, and Tris ions but not by swainsonine. Structural analyses of the mannose-trimming intermediates produced by the alpha-mannosidase revealed that specific intermediates were formed during conversion of Man9GlcNAc2-PA to Man5GlcNAc2-PA.     

The purification and characterization of mannosidase IA from rat liver Golgi membranes

Rat liver Golgi membranes contain two alpha 1,2-specific mannosidases (IA and IB) (Tulsiani, D. R. P., Hubbard, S. C., Robbins, P. W., and Touster, O. (1982) J. Biol. Chem. 257, 3660-3668). Mannosidase IA has now been purified to apparent homogeneity by detergent extraction and (NH4)2SO4 precipitation, followed by Sephacryl S-300, ion-exchange, and hydroxylapatite chromatography. The enzyme was homogeneous by nondenaturing polyacrylamide gel electrophoresis with different gel concentrations, and Ferguson plot analysis indicated an Mr of 230,000 for the native enzyme. Although electrophoresis under denaturing conditions generally gave a subunit Mr of 57,000, electrophoresis of less than 1 microgram of protein yielded a faint doublet of Mr 57,000 and 58,000. Thus, the enzyme appears to be a tetramer with four very similar subunits. The enzyme bound to concanavalin A-Sepharose 4B only when it was kept in contact with the lectin for 16 h. Endoglycosidase H treatment resulted in loss of its binding to the lectin, without leading to a detectable change in the size of the enzyme subunit. On electrophoretic gels, the enzyme gave a faint positive stain with periodic acid-Schiff's base. The enzyme contained about 0.9% hexose by direct analysis. It did not bind to affinity resins specific for neuraminic acid, galactose, or N-acetylglucosamine. All these studies suggest that the enzyme is a glycoprotein containing only one or two clusters of high mannose oligosaccharide. Mannosidase IA is active toward oligosaccharides containing alpha 1,2-linked mannosyl residues. [3H]Man9GlcNAc, [3H] Man8GlcNAc, [3H]Man7GlcNAc, and [3H]Man6GlcNAc are good substrates. Man9GlcNAc, the best substrate, yields Man8, Man7, and Man6 derivatives with structures suggesting that the sequence of release of mannose residues is rather specific. Immunoprecipitation studies using polyclonal antibody (IgG) prepared against homogeneous mannosidase IA cross-reacted with mannosidase IB, a result suggesting that these two enzymes share antigenic determinants. However, no cross-reactivity was observed with rat liver cytosolic and lysosomal alpha-D-mannosidases or with Golgi mannosidase II.     

Effect of substrate structure on the activity of Man9-mannosidase from pig liver involved in N-linked oligosaccharide processing.

Man9-mannosidase, an alpha 1,2-specific enzyme located in the endoplasmic reticulum and involved in N-linked-oligosaccharide processing, has been isolated from crude pig-liver microsomes and its substrate specificity studied using a variety of free and peptide-bound high-mannose oligosaccharide derivatives. The purified enzyme displays no activity towards synthetic alpha-mannosides, but removes three alpha 1,2-mannose residues from the natural Man9-(GlcNAc)2 substrate (M9). The alpha 1,2-mannosidic linkage remaining in the M6 intermediate is cleaved about 40-fold more slowly. Similar kinetics of hydrolysis were determined with Man9-(GlcNAc)2 N-glycosidically attached to the hexapeptide Tyr-Asn-Lys-Thr-Ser-Val (GP-M9), indicating that the specificity of the enzyme is not influenced by the peptide moiety of the substrate. The alpha 1,2-mannose residue which is largely resistant to hydrolysis, was found to be attached in both the M6 and GP-M6 intermediate to the alpha 1,3-mannose of the peripheral alpha 1,3/alpha 1,6-branch of the glycan chain. Studies with glycopeptides varying in the size and branching pattern of the sugar chains, revealed that the relative rates at which the various alpha 1,2-mannosidic linkages were cleaved, differed depending on their structural complexity. This suggests that distinct sugar residues in the aglycon moiety may be functional in substrate recognition and binding. Reduction or removal of the terminal GlcNAc residue of the chitobiose unit in M9 increased the hydrolytic susceptibility of the fourth (previously resistant) alpha 1,2-mannosidic linkage significantly. We conclude from this observation that, in addition to peripheral mannose residues, the intact chitobiose core represents a structural element affecting Man9-mannosidase specificity. A possible biological role of the enzyme during N-linked-oligosaccharide processing is discussed.     

Purification of soluble alpha1,2-mannosidase from Candida albicans CAI-4

A soluble alpha-mannosidase from Candida albicans CAI-4 was purified by conventional methods of protein isolation. Analytical electrophoresis of the purified preparation revealed two polypeptides of 52 and 27 kDa, the former being responsible for enzyme activity. The purified, 52 kDa enzyme trimmed Man9GlcNAc2, producing Man8GlcNAc2 isomer B and mannose, and was inhibited preferentially by 1-deoxymannojirimycin. These properties are consistent with an endoplasmic reticulum-resident alpha1,2-mannosidase of the glycosyl hydrolase family 47. Moreover, a proteolytic activity responsible for converting the 52 kDa alpha-mannosidase into a polypeptide of 43 kDa retaining full enzyme activity, was demonstrated in membranes of ATCC 26555, but not in CAI-4 strain.