Location of the two catalytic sites in intestinal lactase-phlorizin hydrolase. Comparison with sucrase-isomaltase and with other glycosidases, the membrane anchor of lactase-phlorizin hydrolase.

Lactase-phlorizin hydrolase was isolated by immunoadsorption chromatography from rabbit brush-border membrane vesicles. Inactivation of the enzyme with [3H]conduritol-B-epoxide, a covalent active site-directed inhibitor, labeled glutamates at positions 1271 and 1747. Glu1271 was assigned to lactase, Glu1747 to phlorizin hydrolase activity. In contrast, the nucleophiles in the active sites of sucrase-isomaltase are aspartates (Asp505 and Asp1394). Asp505 is a part of the isomaltase active site and is localized on the larger subunit, which carries the membrane anchor also, while Asp1394 is a part of the active of sucrase. Alignment of these 2 nucleophilic Glu residues in lactase-phlorizin hydrolase and of their flanking regions with published sequences of several other beta-glycosidases allows the classification of the configuration retaining glycosidases into two major families: the "Asp" and the "Glu" glycosidases, depending on the carboxylate presumed to interact with the putative oxocarbonium ion in the transition state. We offer some predictions as to the Glu acting as the nucleophile in the active site of some glycosidases. By hydrophobic photolabeling, the membrane-spanning domain of lactase-phlorizin hydrolase was directly localized in the carboxyl-terminal region thus confirming this enzyme as a monotopic type I protein (i.e. with Nout-Cin orientation) of the brush-border membranes. A simplified version of the Me2+ precipitation method to efficiently and simply prepare brush-border membrane vesicles is also reported.     

Location and characterization of the O-GlcNAcase active site

NCOAT is a bifunctional nucleo-cytoplasmic protein with both O-GlcNAcase and histone acetyltransferase domains. The O-GlcNAcase domain catalyzes the removal of O-linked GlcNAc modifications from proteins and we have found that it resides in the N-terminal third of NCOAT. The recognition of the substrate GlcNAc suggests that the O-GlcNAcase is related in structure and catalytic mechanism to chitinases, hexosaminidases and hyaluronidases. These families of glycosidases all possess a catalytic doublet of carboxylate-containing residues, with one providing an acid-base function, and the second acting to orient and use the N-acetyl group of GlcNAc during catalysis. Indeed, we show that the O-GlcNAcase also possesses the catalytic doublet motif shared among these enzymes and that these two essential residues are aspartic acids at positions 175 and 177, respectively, in mouse NCOAT. In addition, a conserved cysteine at 166 and a conserved aspartic acid at 174 were also found to be necessary for fully efficient enzymatic activity. Given this information, we propose that the O-GlcNAcase active site resembles those of the above glycosidases which carry out the hydrolysis of GlcNAc linkages in a substrate-assisted acid-base manner.     

The 1.9 A structure of alpha-N-acetylgalactosaminidase: molecular basis of glycosidase deficiency diseases

In the lysosome, glycosidases degrade glycolipids, glycoproteins, and oligosaccharides. Mutations in glycosidases cause disorders characterized by the deposition of undegraded carbohydrates. Schindler and Fabry diseases are caused by the incomplete degradation of carbohydrates with terminal alpha-N-acetylgalactosamine and alpha-galactose, respectively. Here we present the X-ray structure of alpha-N-acetylgalactosaminidase (alpha-NAGAL), the glycosidase that removes alpha-N-acetylgalactosamine, and the structure with bound ligand. The active site residues of alpha-NAGAL are conserved in the closely related enzyme a-galactosidase A (alpha-GAL). The structure demonstrates the catalytic mechanisms of both enzymes and reveals the structural basis of mutations causing Schindler and Fabry diseases. As alpha-NAGAL and alpha-GAL produce type O "universal donor" blood from type A and type B blood, the alpha-NAGAL structure will aid in the engineering of improved enzymes for blood conversion.     

Structure of mouse Golgi alpha-mannosidase IA reveals the molecular basis for substrate specificity among class 1 (family 47 glycosylhydrolase) alpha1,2-mannosidases

Three subfamilies of mammalian Class 1 processing alpha1,2-mannosidases (family 47 glycosidases) play critical roles in the maturation of Asn-linked glycoproteins in the endoplasmic reticulum (ER) and Golgi complex as well as influencing the timing and recognition for disposal of terminally unfolded proteins by ER-associated degradation. In an effort to define the structural basis for substrate recognition among Class 1 mannosidases, we have crystallized murine Golgi mannosidase IA (space group P2(1)2(1)2(1)), and the structure was solved to 1.5-A resolution by molecular replacement. The enzyme assumes an (alphaalpha)(7) barrel structure with a Ca(2+) ion coordinated at the base of the barrel similar to other Class 1 mannosidases. Critical residues within the barrel structure that coordinate the Ca(2+) ion or presumably bind and catalyze the hydrolysis of the glycone are also highly conserved. A Man(6)GlcNAc(2) oligosaccharide attached to Asn(515) in the murine enzyme was found to extend into the active site of an adjoining protein unit in the crystal lattice in a presumed enzyme-product complex. In contrast to an analogous complex previously isolated for Saccharomyces cerevisiae ER mannosidase I, the oligosaccharide in the active site of the murine Golgi enzyme assumes a different conformation to present an alternate oligosaccharide branch into the active site pocket. A comparison of the observed protein-carbohydrate interactions for the murine Golgi enzyme with the binding cleft topologies of the other family 47 glycosidases provides a framework for understanding the structural basis for substrate recognition among this class of enzymes.     

Glycosyl fluorides in enzymatic reactions

Glycosyl fluorides have considerable importance as substrates and inhibitors in enzymatic reactions. Their good combination of stability and reactivity has enabled their use as glycosyl donors with a variety of carbohydrate processing enzymes. Moreover, the installation of fluorine elsewhere on the carbohydrate scaffold commonly modifies the properties of the glycosyl fluoride such that the resultant compounds act as slow substrates or even inhibitors of enzyme action. This review covers the use of glycosyl fluorides as substrates for wild-type and mutant glycosidases and other enzymes that catalyze glycosyl transfer. The use of substituted glycosyl fluorides as inhibitors of enzymes that catalyze glycosyl transfer and as tools for investigation of their mechanism is discussed, including the labeling of active site residues. Synthetic applications in which glycosyl fluorides are used as glycosyl donors in enzymatic transglycosylation reactions for the synthesis of oligo- and polysaccharides are then covered, including the use of mutant glycosidases, the so-called glycosynthases, which are able to catalyze the formation of glycosides without competing hydrolysis. Finally, a short overview of the use of glycosyl fluorides as substrates and inhibitors of phosphorylases and phosphoglucomutase is given.     

Common antigenicity for two glycosidases

Enzyme replacement therapy (ERT) has proven to be an effective therapy for some lysosomal storage disorder (LSD) patients. A potential complication during ERT is the generation of an immune response against the replacement protein. We have investigated the antigenicity of two distantly related glycosidases, alpha-glucosidase (Pompe disease or glycogen storage disease type II, GSD II), and alpha-L-iduronidase (Hurler syndrome, mucopolysaccharidosis type I, MPS I). The linear sequence epitope reactivity of affinity purified polyclonal antibodies to recombinant human alpha-glucosidase and alpha-L-iduronidase was defined, to both glycosidases. The polyclonal antibodies exhibited some cross-reactive epitopes on the two proteins. Moreover, a monoclonal antibody to the active site of alpha-glucosidase showed cross-reactivity with a catalytic structural element of alpha-L-iduronidase. In a previous study, in MPS I patients who developed an immune response to ERT, this same site on alpha-L-iduronidase was highly antigenic and the last to tolerise following repeated enzyme infusions. We conclude that glycosidases can exhibit cross-reactive epitopes, and infer that this may relate to common structural elements associated with their active sites.     

Broad-range Glycosidase Activity Profiling

Plants produce hundreds of glycosidases. Despite their importance in cell wall (re)modeling, protein and lipid modification, and metabolite conversion, very little is known of this large class of glycolytic enzymes, partly because of their post-translational regulation and their elusive substrates. Here, we applied activity-based glycosidase profiling using cell-permeable small molecular probes that react covalently with the active site nucleophile of retaining glycosidases in an activity-dependent manner. Using mass spectrometry we detected the active state of dozens of myrosinases, glucosidases, xylosidases, and galactosidases representing seven different retaining glycosidase families. The method is simple and applicable for different organs and different plant species, in living cells and in subproteomes. We display the active state of previously uncharacterized glycosidases, one of which was encoded by a previously declared pseudogene. Interestingly, glycosidase activity profiling also revealed the active state of a diverse range of putative xylosidases, galactosidases, glucanases, and heparanase in the cell wall of Nicotiana benthamiana. Our data illustrate that this powerful approach displays a new and important layer of functional proteomic information on the active state of glycosidases.Carbohydrates are present in all kingdoms of life and are particularly prominent in plants (1). Plants produce carbohydrates as one of their major constituents through their photosynthetic activity. The simplest synthesized forms of carbohydrates are monosaccharide sugars such as glucose, which provides energy for various cellular activities. Carbohydrates also exist in very complex forms. Monosaccharide sugars are attached to one another through covalent glycosidic linkage, which generates di-, oligo-, and polysaccharides. Carbohydrates also attach to non-carbohydrate species (lipids, proteins, hormones) through a glycosidic linkage to form glycoconjugates (2).Glycosidic bonds are hydrolyzed by a group of enzymes termed glycosyl hydrolases (GHs)¹ or glycosidases (3). Because of the tremendous carbohydrate diversity, there are a vast variety of glycosidases, including glucosidases, xylosidases, and galactosidases, that preferentially hydrolyze their respective glycoside substrates. In general, the number of glycosidase-related genes in plants (for instance, Arabidopsis) is relatively high when compared with that in other sequenced organisms (for instance, human) (4). This signifies the unique importance of glycosidases in plants as opposed to other organisms. Based on protein sequence similarities, glycosidases are classified into different GH families. Members of the same GH family share a common mechanism of glycosidic bond cleavage (5).Mechanistically, glycosidases are classified as retaining or inverting enzymes (6). To hydrolyze the glycosidic bond, both retaining and inverting enzymes carry two catalytic glutamate or aspartate residues (or both) (7). Of these two catalytic residues, one acts as a proton donor and the other as a nucleophile/base. The distance between these catalytic residues in the active site of the glycosidases determines the mechanism of hydrolysis. Retaining enzymes have two catalytic residues separated by a distance of ∼5.5 Å, and their hydrolysis mechanism retains the net anomeric configuration of the C1 atom in the sugar molecule. In contrast, inverting enzymes have catalytic residues that are ∼10 Å apart, and these enzymes invert the overall anomeric configuration of the C1 carbon atom in the released sugar (8).Both retaining and inverting glycosidases are present abundantly in plants. The genome of Arabidopsis thaliana encodes for 400 glycosidases, of which 260 are retaining enzymes and 140 are inverting enzymes. Genetic, molecular, and biochemical approaches revealed that glycosidases are localized in different cellular compartments and are important for various biological processes. The majority of plant glycosidases reside in the cell wall, and these enzymes can play major roles in cell wall restructuring (9). Other characterized glycosidases reside in other compartments to regulate glycosylation of proteins and hormones. Despite the importance of GH enzymes, physiological and biochemical functions are assigned to only a few glycosidases (9).Activity-based protein profiling (ABPP) is a powerful tool for monitoring the active state of multiple enzymes without knowledge of their natural substrates (10, 11). ABPP involves chemical probes that react with active site residues in an activity-dependent manner. Thus ABPP displays the availability and reactivity of active site residues in proteins, which are hallmarks for enzyme activity (12). ABPP is particularly attractive because the profiling can be done without purifying the enzymes and can be performed in cell extracts or in living cells. Another key advantage of ABPP is that the activities of large multigene enzyme families can be monitored using broad-range probes. ABPP has had a significant impact on plant science. After the introduction of probes for papain-like cysteine proteases (13, 14), these probes revealed increased protease activities in the tomato and maize apoplasts during immune responses (15, 16) and that these immune proteases are targeted by unrelated inhibitors secreted by fungi, oomycetes, and nematodes (17–24). Likewise, probes for the proteasome displayed unexpected increased proteasome activity during immune responses (25) and revealed that the bacterial effector molecule syringolin A targets the nuclear proteasome (26). We anticipate that more regulatory mechanisms will be discovered through the use of probes introduced for serine hydrolases, metalloproteases, vacuolar processing enzymes, ATP binding proteins, and glutathione transferases (27–32).Cyclophellitol-aziridine-based probes were previously used in animal proteomes to target retaining glucosidases (33). Here we established and applied glycosidase profiling in plants. We discovered that cyclophellitol-aziridine-based probes targeted an unexpectedly broad range of glycosidases representing members of at least seven different GH families. We used these probes to study the active state of glycosidases present in living cells, in different organs and plant species, and in the apoplast of Nicotiana benthamiana.     

Structural and functional analyses of a glycoside hydrolase family 5 enzyme with an unexpected β-fucosidase activity

We present characterization of PbFucA, a family 5 glycoside hydrolase (GH5) from Prevotella bryantii B(1)4. While GH5 members typically are xylanases, PbFucA shows no activity toward xylan polysaccharides. A screen against a panel of p-nitrophenol coupled sugars identifies PbFucA as a β-D-fucosidase. We also present the 2.2 ? resolution structure of PbFucA and use structure-based mutational analysis to confirm the role of catalytically essential residues. A comparison of the active sites of PbFucA with those of family 5 and 51 glycosidases reveals that while the essential catalytic framework is identical between these enzymes, the steric contours of the respective active site clefts are distinct and likely account for substrate discrimination. Our results show that members of this cluster of orthologous group (COG) 5520 have β-D-fucosidase activities, despite showing an overall sequence and structural similarity to GH-5 xylanases.     

Computational site‐directed mutagenesis studies of the role of the hydrophobic triad on substrate binding in cholesterol oxidase

Cholesterol oxidase (ChOx) is a flavoenzyme that oxidizes and isomerizes cholesterol (CHL) to form cholest‐4‐en‐3‐one. Molecular docking and molecular dynamics simulations were conducted to predict the binding interactions of CHL in the active site. Several key interactions (E361‐CHL, N485‐FAD, and H447‐CHL) were identified and which are likely to determine the correct positioning of CHL relative to flavin‐adenine dinucleotide (FAD). Binding of CHL also induced changes in key residues of the active site leading to the closure of the oxygen channel. A group of residues, Y107, F444, and Y446, known as the hydrophobic triad, are believed to affect the binding of CHL in the active site. Computational site‐directed mutagenesis of these residues revealed that their mutation affects the conformations of key residues in the active site, leading to non‐optimal binding of CHL and to changes in the structure of the oxygen channel, all of which are likely to reduce the catalytic efficiency of ChOx. Proteins 2017; 85:1645–1655. © 2017 Wiley Periodicals, Inc.     

The catalytic mechanism of Drosophila alcohol dehydrogenase: evidence for a proton relay modulated by the coupled ionization of the active site Lysine/Tyrosine pair and a NAD+ ribose OH switch

The ionization properties of the active site residues in Drosophila lebanonensis alcohol dehydrogenase (DADH) were investigated theoretically by using an approach developed to account for multiple locations of the hydrogen atoms of the titratable and polar groups. The electrostatic calculations show that (a) the protonation/deprotonation transition of the binary complex of DADH is related to the coupled ionization of Tyr151 and Lys155 in the active site and (b) the pH dependence of the proton abstraction is correlated with a reorganization of the hydrogen bond network in the active site. On this basis, a proton relay mechanism for substrate dehydrogenation is proposed in which the O2' ribose hydroxyl group from the coenzyme has a key role and acts as a switch. The proton relay chain includes the active site catalytic residues, as well as a chain of eight water molecules that connects the active site with the bulk solvent.     

Relationships between functional subclasses and information contained in active‐site and ligand‐binding residues in diverse superfamilies

To investigate the relationships between functional subclasses and sequence and structural information contained in the active‐site and ligand‐binding residues (LBRs), we performed a detailed analysis of seven diverse enzyme superfamilies: aldolase class I, TIM‐barrel glycosidases, α/β‐hydrolases, P‐loop containing nucleotide triphosphate hydrolases, collagenase, Zn peptidases, and glutamine phosphoribosylpyrophosphate, subunit 1, domain 1. These homologous superfamilies, as defined in CATH, were selected from the enzyme catalytic‐mechanism database. We defined active‐site and LBRs based solely on the literature information and complex structures in the Protein Data Bank. From a structure‐based multiple sequence alignment for each CATH homologous superfamily, we extracted subsequences consisting of the aligned positions that were used as an active‐site or a ligand‐binding site by at least one sequence. Using both the subsequences and full‐length alignments, we performed cluster analysis with three sequence distance measures. We showed that the cluster analysis using the subsequences was able to detect functional subclasses more accurately than the clustering using the full‐length alignments. The subsequences determined by only the literature information and complex structures, thus, had sufficient information to detect the functional subclasses. Detailed examination of the clustering results provided new insights into the mechanism of functional diversification for these superfamilies. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Pepper beta-galactosidase 1 (PBG1) plays a significant role in fruit ripening in bell pepper (Capsicum annuum)

During bell pepper (Capsicum annuum L.) fruit ripening, beta-galactosidase activity increased markedly as compared with other glycosidases. We purified 77.5 kDa exo-1,4-beta-D-galactanase from red bell pepper fruit classified as beta-galactosidase II. A marked decrease in galactose content appeared during fruit ripening, especially in the pectic fraction. The purified enzyme hydrolyzed a considerable amount of galactose residues in this fraction. We isolated bell pepper beta-galactosidase (PBG1) cDNA. This PBG1 protein contained the putative active site, G-G-P-[LIVM]-x-Q-x-E-N-E-[FY], belonging to glycosyl hydrolase family 35. Quantitative RT-PCR revealed that the expression of PBG1 in red fruit was significantly stronger than that from any other tissues. Moreover, expression of PBG1 occurred prior to that of pepper endo-polygalacturonase 1 (PPG1), the major fruit-ripening enzyme. Based on these results, it appears that the hydrolysis of galactose residues in pectic substances is the first event in the ripening process in bell pepper fruit.     

A familiar motif in a new context: the catalytic mechanism of hydroxyisourate hydrolase

Hydroxyisourate hydrolase is a recently discovered enzyme that participates in the ureide pathway in soybeans. Its role is to catalyze the hydrolysis of 5-hydroxyisourate, the product of the urate oxidase reaction. There is extensive sequence homology between hydroxyisourate hydrolase and retaining glycosidases; in particular, the conserved active site glutamate residues found in retaining glycosidases are present in hydroxyisourate hydrolase as Glu 199 and Glu 408. However, experimental investigation of their roles, as well as the catalytic mechanism of the enzyme, have been precluded by the instability of 5-hydroxyisourate. Here, we report that diaminouracil serves as a slow, alternative substrate and can be used to investigate catalysis by hydroxyisourate hydrolase. The activity of the E199A protein was reduced 400-fold relative to wild-type, and no activity could be detected with the E408A mutant. Steady-state kinetic studies of the wild-type protein revealed that the pH-dependence of V(max) and V/K describe bell-shaped curves, consistent with the hypothesis that catalysis requires two ionizable groups in opposite protonation states. Addition of 100 mM azide accelerated the reaction catalyzed by the wild-type enzyme 8-fold and the E199A mutant 20-fold but had no effect on the E408A mutant. These data suggest that Glu 408 acts as a nucleophile toward the substrate forming a covalent anhydride intermediate, and Glu 199 facilitates formation of the intermediate by serving as a general acid and then activates water for hydrolysis of the intermediate. Thus, the mechanism of hydroxyisourate hydrolase is strikingly similar to that of retaining glycosidases, even though it catalyzes hydrolysis of an amide bond.     

The synthesis of a novel thio-linked disaccharide of chondroitin as a potential inhibitor of polysaccharide lyases

A thio-linked disaccharide based on the structure of the glycosaminoglycan chondroitin was synthesized as a potential inhibitor of chondroitin AC lyase from Flavobacterium heparinum for structural analysis of the active site. Instead it was found to be a slow substrate, thereby demonstrating that lyases, in contrast to glycosidases, can cleave thioglycoside links between sugars.     

Steered molecular dynamics simulations reveal important mechanisms in reversible monoamine oxidase B inhibition

The monotopic membrane protein monoamine oxidase B (MAO B) is an important drug target for Parkinson's disease. In order to design more specific, and thereby more effective, inhibitors for this enzyme, it is necessary to determine what factors govern inhibitor specificity and the inhibitor binding process, including the roles of the lipid bilayer, the active site loop, and several key residues within the binding pocket. Atomistic molecular dynamics simulations of MAO B either embedded in a lipid bilayer or free in solution have been performed. The simulations suggest that the bilayer controls the availability of the active site cavity by regulating the degree of fluctuation in two key loops that form the greater part of the active site entrance (residues 85-110 and 155-165). In turn, the enzyme itself causes local thinning and a decrease in area per lipid of the surrounding bilayer environment. Additional MD simulations of MAO B in complex with seven different reversible inhibitors followed by nonequilibrium steered MD simulations of the inhibitor unbinding have also been performed. The simulations demonstrate that the average energy of interaction between inhibitor and MAO B residues during inhibitor egress is an effective indicator of inhibitor strength and is also useful for identifying key residues that govern inhibitor specificity. These data provide researchers with valuable tools for designing effective MAO B inhibitors as well as outline a method that can be translated to the study of other enzyme-inhibitor complexes.     

Region-directed mutagenesis of residues surrounding the active site nucleophile in beta-glucosidase from Agrobacterium faecalis.

The active site nucleophile of the beta-glucosidase of Agrobacterium faecalis has recently been identified by the use of inhibitors. A combination of site-directed and in vitro enzymatic mutagenesis was carried out on the beta-glucosidase to probe the structure of the active site region. Forty-three point mutations were generated at 22 different residues in the region surrounding the active site nucleophile, Glu358. Only five positions were identified which affected enzyme activity indicating that only a few key residues are important to enzyme activity, thus the enzyme can tolerate a number of single residue changes and still function. The importance of Glu358 to enzymatic function has been confirmed and other residues important to enzyme structure or function have been identified.     

The structure and mechanism of the type II dehydroquinase from Streptomyces coelicolor

The structure of the type II DHQase from Streptomyces coelicolor has been solved and refined to high resolution in complexes with a number of ligands, including dehydroshikimate and a rationally designed transition state analogue, 2,3-anhydro-quinic acid. These structures define the active site of the enzyme and the role of key amino acid residues and provide snap shots of the catalytic cycle. The resolution of the flexible lid domain (residues 21-31) shows that the invariant residues Arg23 and Tyr28 close over the active site cleft. The tyrosine acts as the base in the initial proton abstraction, and evidence is provided that the reaction proceeds via an enol intermediate. The active site of the structure of DHQase in complex with the transition state analog also includes molecules of tartrate and glycerol, which provide a basis for further inhibitor design.     

Characterization of a beta-glycosidase highly active on disaccharides and of a beta-galactosidase from Tenebrio molitor midgut lumen

The midgut of the yellow mealworm, Tenebrio molitor L. (Coleoptera: Tenebrionidae) larvae has four beta-glycosidases. The properties of two of these enzymes (betaGly1 and betaGly2) have been described elsewhere. In this paper, the characterization of the other two glycosidases (betaGly3 and betaGly4) is described. BetaGly3 has one active site, hydrolyzes disaccharides, cellodextrins, synthetic substrates and beta-glucosides produced by plants. The enzyme is inhibited by amygdalin, cellotriose, cellotetraose and cellopentaose in high concentrations, probably due to transglycosylation. betaGly3 hydrolyzes beta 1,4-glycosidic linkages with a catalytic rate independent of the substrate polymerization degree (k(int)) of 11.9 s(-1). Its active site is formed by four subsites, where subsites +1 and -1 bind glucose residues with higher affinity than subsite +2. The main role of betaGly3 seems to be disaccharide hydrolysis. BetaGly4 is a beta-galactosidase, since it has highest activity against beta-galactosides. It can also hydrolyze fucosides, but not glucosides, and has Triton X-100 as a non-essential activator (K(a)=15 microM, pH 4.5). betaGly4 has two active sites that can hydrolyze p-nitrophenyl beta-galactoside (NPbetaGal). The one hydrolyzing NPbetaGal with more efficiency is also active against methylumbellipheryl beta-D-galactoside and lactose. The other active site hydrolyzes NPbetaFucoside and binds NPbetaGal weakly. BetaGly4 hydrolyzes hydrophobic substrates with high catalytical efficiency and is able to bind octyl-beta-thiogalactoside in its active site with high affinity. The betaGly4 physiological role is supposed to be the hydrolysis of galactolipids that are found in membranes from vegetal tissues. As the enzyme has a hydrophobic site where Triton X-100 can bind, it might be activated by membrane lipids, thus becoming fully active only at the surface of cell membranes.     

Glycosidases are present on the surface of Drosophila melanogaster spermatozoa

We investigated the presence of enzymes on the surface of Drosophila melanogaster spermatozoa that might bind to the carbohydrate residues of the egg shell. Spectrophotometric and fluorimetric studies were used on whole spermatozoa to assay galactosyltransferase and glycosidase activities. No galactosyltransferase is present on the sperm surface, whereas two glycosidases, β-N-acetylglucosaminidase (GlcNAc′ase) and α-mannosidase (Man′ase), have been evidenced. They have an optimal pH of 6–6.5 and 4, respectively. The same glycosidases were detected as soluble forms probably secreted by the seminal vesicle epithelium. We suggest that these enzymes might be involved in the recognition of α-mannose and β-N-acetylglucosamine residues present on the egg shell at the site of sperm entry. Mol. Reprod. Dev. 48:276–281, 1997. © 1997 Wiley-Liss, Inc.