Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.1.53 (sialidase)
 2,694 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The sialo compounds in the synaptosomal membranes of young rat brain were specifically labeled in vivo by the intracranial injection of radioactive N-acetylmannosamine. More than 95% of the incorporated label was found in glycosidically bound sialic acid. Specific activities of sialic acid in the synaptic membrane gangliosides G71 (monosialo), GD1a (disialo), and GT1 (trisialo) were similar; labeling in GD1b (disialo) was consistently somewhat higher. The highest specific activity of rat brain sialidase was evenly distributed between "small myelin fragment" and synaptosomal membrane fractions, and ouabain-sensitive (Na+, K+)-ATPase also was concentrated in the latter fraction. The greatest amount of bound sialic acid was found in these subcellular fractions having the highest sialidase activity. A microsomal fraction was discovered to contain a small amount of bound sialic acid with a very high degree of radioactive labeling, but no sialidase. Release of sialic acid from the relatively intact membrane preparations by intrinsic membrane-bound sialidase occurred in two recognizable stages. There was a rapid initial release, complete within 30 min, of approximately equal amounts of lipid- and protein-bound sialic acid, corresponding to roughly half of the enzymatically releasable protein-boudn, and somewhat less than one-third of the lipid-bound, sialic acid. The remainder of the membrane sialidase-susceptible sialic acid was released in a second, slower stage. The intrinsic sialidase released 16 +/- 1% of the total sialoprotein and 31 +/- 1% of the total sialolipid sialic acid. Approximately the same amount of sialic acid is releasable from membrane sialolipid by the action of exogenous Vibrio sialidase; almost twice as much is releasable from sialoglycoprotein by this enzyme as compared with the intrinsic membrane sialidase. Each of the various membrane gangliosides appeared to be equally available to the action of the membrane sialidase. The results of this study indicate that both glycolipid- and glycoprotein-bound sialic acid in the synaptic membrane are releasable in situ by the action of the intrinsic synaptic membrane sialidase, and they suggest that this enzyme may act to modulate the physical properties of the membrane. In addition to influencing the rate of hydrolysis of endogenous membrane sialo compounds by intrinsic sialidase, pH had an effect on availability of protein-bound sialic acid. At acid pH, lipid- and protein-bound sialic acid were similarly available, but near neutral pH, gangliosides appeared to be attacked preferentially.
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PMID:Action of intrinsic sialidase of rat brain synaptic membranes on membrane sialolipid and sialoprotein components in situ. 84 35

Certain enzyme activities for synthesis and degradation of gangliosides and the chemical quantity and incorporation of radioactivity from [14C] galactose into gangliosides have been studied in 3T3 cells and their transformed counterparts at various cell population densities. The chemical quantity of and the incorporation of radioactivity into GD1a ganglioside increased at the early stage of cell contact ("contact response" of ganglisoide), whereas response was not detectable in transformed 3T3 cells at any stage of cell contact. These phenomena were reproduced in five separate qualitative analyses and two quantitative determinations of gangliosides. As the basis of these phenomena, a membrane-bound sialidase activity which acted on gangliosides was suppressed in 3T3 cells at the "touching" stage of cell-to-cell contact. Transformed cells did not display the change of sialidase activity at any stage of cell contact.
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PMID:Cell contact-dependent ganglioside changes in mouse 3T3 gibroblasts and a suppressed sialidase activity on cell contact. 117 Aug 79

A membrane-bound sialidase (EC 3.2.1.18) was found in procyclic trypomastigotes of Trypanosoma brucei. The mammalian stage bloodstream form, however, displayed no sialidase activity. This sialidase is an integral surface protein, linked to the membrane via a glycosylphosphatidylinositol anchor. After osmotic lysis and solubilization with Triton CF-54, the enzyme was purified 1900-fold by gel filtration and ion exchange chromatography. Its size, as determined by conventional and high-performance liquid gel chromatography, is 67 kDa. The sialidase is active over a broad pH and temperature range with optima at pH 6.9 and 35 degrees C, respectively. No loss of activity is observed after 4 freeze-thaw cycles. T. brucei sialidase activity is inhibited by N-(4-nitrophenyl)oxamic acid and 2-deoxy-2,3-didehydro-N-acetylneuraminic acid, the latter, however, being less effective. N-Acetylneuraminic acid shows no inhibitory effect, whereas a variety of metal ions are potent inhibitors. The sialidase is activated by di- and tricarboxylic acids, but inhibited by chloride. Relative hydrolysis rates of various sialic acid-containing compounds reveal that de-O-acetylated bovine submandibular gland mucin is the preferred substrate and that alpha(2-3)-linkages are hydrolyzed faster than alpha(2-6)-linkages.
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PMID:Purification and characterization of a novel sialidase found in procyclic culture forms of Trypanosoma brucei. 151 30

N-Acetylneuraminic, 2-deoxy-2,3-didehydro-N-acetylneuraminic acid and the beta anomer of methoxyneuraminic acid (Neu5Ac, Neu5Ac2en, MeONeu) have been used as probes for the catalytic mechanism of the activities of the outer membrane-bound haemagglutinin-neuraminidase (HN) from newcastle disease virus (NDV). Neu5Ac and Neu5Ac2en produced a competitive inhibition of the sialidase (= neuraminidase) activity, whereas MeONeu had no effect on this activity. This lack of inhibition can be explained by the free amino-acid group lacking the acetyl substituent in the MeONeu. Neu5Ac2en produced the highest inhibition. Based on the effect of the inhibitors, a reaction mechanism is suggested. On the other hand, the above mentioned inhibitors of the sialidase activity had no effect on haemagglutinating activity, suggesting different active sites for the both activities.
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PMID:On the inhibition mechanism of the sialidase activity from Newcastle disease virus. 177 91

A lysosomal preparation, obtained from brain homogenate of 17-day-old C57BL mice by centrifugation on a self-generating Percoll linear density gradient, showed relative specific activity (RSA) values for typical lysosomal enzymes of 40-120 and for mitochondria, plasma membrane, and cytosol markers of much lower than 1, a result indicating a high degree of homogeneity. The lysosomal preparation contained a sialidase activity that was assayed radiometrically with ganglioside [3H]GD1a and fluorimetrically with 4-methylumbelliferyl-1-alpha-D-N-acetylneuraminic acid (MUB-NeuAc). The properties of the lysosomal enzyme were compared with those of the plasma membrane-bound sialidase contained in a purified synaptosomal plasma membrane fraction that was prepared from the same homogenate and assayed with the same substrates. The optimal pH was 4.2 for the lysosomal and 5.1 for the plasma membrane-bound enzyme. The apparent Km values for GD1a and MUB-NeuAc were 1.5 X 10(-5) and 4.2 X 10(-5) M, respectively, for the lysosomal enzyme and 2.7 X 10(-4) and 6.3 X 10(-5) M for the plasma membrane-bound one. Triton X-100 had a predominantly inhibitory effect on the lysosomal enzyme, whereas it strongly activated the plasma membrane-bound one. The lysosomal enzyme was highly unstable on storage and freezing and thawing cycles, whereas the plasma membrane-bound one was substantially stable. The RSA value of the lysosomal sialidase in the lysosomal fraction closely resembled that of authentic lysosomal enzymes, whereas the RSA value of plasma membrane-bound sialidase in the plasma membrane fraction was very similar to that of typical plasma membrane markers.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Occurrence in brain lysosomes of a sialidase active on ganglioside. 276 Jun 15

Resident rat peritoneal macrophages express a galactose-recognizing system, which mediates binding and uptake of cells and glycoproteins exposing terminal galactose residues. Here we describe the identification, isolation, and characterization of the corresponding receptor molecule. Using photoaffinity labelling of adherent peritoneal macrophages with the 4-azido-6-125I-salicylic acid derivative of anti-freeze glycoprotein 8 followed by SDS-PAGE and autoradiography, we identified the receptor of these cells as a protein with an apparent molecular mass of 42 kDa. Furthermore, cell surface receptors were radioiodinated by an affinity-supported labelling technique using the conjugate of asialoorosomucoid and lactoperoxidase, followed by extraction and isolation by affinity chromatography. Finally, the native receptor was isolated and analysed. To estimate its binding activity in solutions, a suitable binding assay was developed, using the precipitation of receptor-ligand complex with polyethylene glycol to separate bound from unbound 125I-asialoorosomucoid, which was used as ligand. It is shown that the isolated receptor binds to galactose-exposing particles and distinguishes between sialidase-treated and -untreated erythrocytes, similar to peritoneal macrophages. The binding characteristics of the membrane-bound and the solubilized receptor are described in the following paper of Lee et al.
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PMID:The galactose-recognizing system of rat peritoneal macrophages; identification and characterization of the receptor molecule. 285 Aug 17

The galactose-recognizing system of rat peritoneal macrophages mediates the binding and uptake of desialylated blood cells and glycoproteins. To characterize the specificity of this receptor, binding studies were performed with various galactose derivatives as competitive inhibitors and sialidase-treated erythrocytes or asialoorosomucoid as ligands for receptors, which were either membrane-bound or isolated after solubilization. From the results obtained it can be concluded that galactose is recognized via its hydrophobic and/or hydrophilic regions, formed by the accumulation of OH-functions on one side and of H-atoms on the other ("side effect"), whereas the binding partner or the anomeric configuration of galactose has no significant influence. Although it became apparent that not a single hydroxyl group of the sugar is responsible for binding, the hydroxyl at C-4 seems to be most important, followed by the OH-group at C-3. Those at C-1, C-2 and C-6 do not play a great role. This order of importance ("position effect") was found with galactose, derivatized by methylation or otherwise, and with diastereomers of galactose. Whereas the recognition of a single galactose residue leads to weak binding only, an appropriate arrangement of several of these ligands in one molecule results in an enormous increase in the binding strength of each galactose residue. This "cluster effect" was observed not only with membrane-bound but also with solubilized receptor. However, the binding of asialoorosomucoid by the latter was better inhibited with free galactose, when compared with the membrane-bound receptor.
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PMID:Carbohydrate specificity of the galactose-recognizing receptor of rat peritoneal macrophages. 285 Aug 18

Microsomal membranes isolated from calf brain contain a sialidase which cleaves ganglioside substrates naturally occurring within these membranes as well as exogenously added [3H]ganglioside GD1a. Micelles of [3H]ganglioside GD1a bind to the microsomal membranes in two steps. The first step, called adsorption, is fast and reversible by treatment with trypsin; the second step, called uptake, is slower and not reversible. The product of the enzymic degradation, [3H]ganglioside GM1, is exclusively located in the ganglioside pool taken up by the sialidase-bearing membranes, and not in the trypsin-releasable pool. Electron spin resonance (ESR) studies using a spin-labelled analogue of ganglioside GD1a indicate that the ganglioside uptake by microsomal membranes is accompanied by the disappearance of the micellar structure and by the 'dilution' of the probe molecules with membrane lipids. These findings suggest that exogenously added ganglioside substrate inserts into the microsomal membrane before it is recognized as substrate by the membrane-bound sialidase. Therefore, the influence of pH, ionic strength and membrane-fluidizing agents on the degradation rate measured with exogenous ganglioside GD1a does not only reflect kinetic parameters of the enzymic reaction itself but also the velocity of ganglioside insertion. Increasing ionic strength reduces the degradation rate. The acceleration of insertion with falling pH values shifts the measured pH optimum of the ganglioside degradation to lower values (pH 3.6) and masks the substantial residual sialidase activity at pH 5-7. The membrane-fluidizing alcohol n-hexanol greatly accelerates ganglioside insertion as well as ganglioside degradation. The latter was clearly demonstrated by studying the hydrolysis of endogenous ganglioside substrates, and is due to a decrease of the apparent Km value and an increase in the Vmax value. The Vmax value was also enhanced by freezing and thawing of the microsomal membranes.
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PMID:The influence of ganglioside insertion into brain membranes on the rate of ganglioside degradation by membrane-bound sialidase. 299 92

The pharmacokinetic interaction of an affinity-purified 125I-labeled tetanotoxin fraction with guinea pig brain synaptosomal preparations was investigated. Binding of tetanotoxin was time- and temperature-dependent, was proportional to protein concentration, and was saturable at about 8 X 10(-9) M as estimated by a solid-surface binding assay. Binding was optimal at pH 6.5 under low ionic strength buffer and was almost entirely blocked by gangliosides or antitoxin. In analogy to intact nerve cells, binding of toxin to membranes resulted in a tight association operationally defined as sequestration. Binding and sequestration were abolished after membrane pretreatment with sialidase. The enzyme could not dissociate the membrane-bound toxin formed at 4 or 37 degrees C under low ionic strength conditions, which is in part compatible with internalization as defined in nerve cell cultures. In the latter system the toxin could be removed at 4 degrees C but not at 37 degrees C. Binding was significantly reduced upon pretreatment of guinea pig brain membranes by a variety of hydrolytic enzymes. Trypsin and chymotrypsin inhibited binding between 55% and 68% while bacterial protease abolished it by 91-95%. The effect was species-specific as it was not seen in rat or bovine synaptosomes. Collagenase and hyaluronidase had little or no inhibitory effect when applied to synaptosomes (27% and 9%) but inhibited binding to synaptic vesicles by 56% and 49%, respectively. Phospholipases A2 and C caused 42-43% inhibition of binding in vesicles and less than 22% in synaptosomes.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Affinity-purified tetanus neurotoxin interaction with synaptic membranes: properties of a protease-sensitive receptor component. 302 42

Normal human fibroblasts have two extreme modes of existence in culture, quiescent and proliferative. The growth and division of these cells are usually well regulated by the action of various endogenously generated stimulators and inhibitors. We have speculated that an extracellular sialidase may be involved in the regulation of growth and that inhibition of this activity might decrease or abolish cell growth. To test this hypothesis, we have incubated preconfluent cultures of fibroblasts in the presence and absence of a potent sialidase inhibitor, 2-deoxy-2,3-dehydro-N-acetylneuraminic acid. Treatment of cells with this inhibitor resulted in the inhibition of an extracellular sialidase activity for up to 24 h and had a marked growth inhibitory effect in a concentration-dependent manner. The effect of the inhibitor on cell proliferation was specific and reversible. During a chase period of 48 h after pulse labeling cells with [3H]N-acetylmannosamine and [14C]serine, there was a 15% decrease of [3H]sialic acid in the membrane-bound GM3 with 80 microM inhibitor in the medium, as compared with a 32% decrease in the controls. Our results suggest that an extracellular sialidase may participate in cell-surface modifications that accompany (or control) the changes observed when cells traverse the cell cycle, from the quiescent to the proliferative phase.
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PMID:Growth control of human foreskin fibroblasts and inhibition of extracellular sialidase activity by 2-deoxy-2,3-dehydro-N-acetylneuraminic acid. 339 28


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