Developmental Changes in the Biosynthesis of Sialoglycoprotein Substrates for Intrinsic Synaptic Sialidase

Abstract: N′-Acetyl-d -[6-³H]mannosamine was administered to 13- and 28-day-old rats by intraventricular injection. At various time intervals following the injection, synaptic membranes were prepared and the incorporation of radiolabel into sialic acid residues released from endogenous glycoproteins and gangliosides by intrinsic sialidase determined. Radiolabel was incorporated into synaptic membrane gangliosides and glycoproteins, and at all times tested, >90% of the label was associated with sialic acid. Sialic acid released from endogenous glycoproteins by intrinsic sialidase present in 28-day membranes incorporated only 20–25% as much radiolabel per nmole as sialic acid released by mild acid hydrolysis or by exogenous neuraminidase. In contrast, sialic acid released from glycoproteins present in 13-day-old membranes by intrinsic sialidase, mild acid hydrolysis, or exogenous neuraminidase all were similarly labelled. At both ages the specific radioactivity (cpm/nmol) of sialic acid released from gangliosides by the intrinsic enzyme was similar to the total ganglioside sialic acid released by mild acid hydrolysis. The results identify glycoprotein substrates for intrinsic synaptic membrane sialidase as a distinct metabolic class in the mature brain and suggest the occurrence of a developmentally related change in the metabolism of these glycoproteins.     

Cellular sialic acid level and phenotypic expression in B16 melanoma cells: comparison of spontaneous variations and bromodeoxyuridine- and theophylline-induced changes

The relation of the total cellular content of sialic acid to phenotypic expression of B16 mouse melanoma cells was examined by using phenotype-modifying reagents and more than 10 cloned cell lines with spontaneous phenotypic variations. The sialic acid content changed in a growth phase-dependent manner with a peak in the early log phase of growth. This peak completely disappeared when cells were treated with 5-bromodeoxyuridine (BrdU), suggesting its relation to quasi-normal phenotypes of the treated cells. BrdU treatment also reduced the cellular sialic acid content itself and resulted in the suppression of the activity of tyrosinase, the key enzyme for melanogenesis, and a considerable increase in cell-to-substratum adhesiveness. Treatment with theophylline, in contrast, markedly elevated the sialic acid content, which was accompanied by dramatic increments in tyrosinase activity and pigmentation as well as a slight increase in adhesiveness. The results show a correlation of sialic acid level with tyrosinase expression but not with cell adhesion. From comparison of spontaneous phenotypic variations, the correlation of sialic acid level with tyrosinase activity was confirmed, while there was only a slight correlation with adhesiveness. It is thus suggested that sialylation/desialylation, being reflected as variations in cellular sialic acid content, is implicated in melanoma cell differentiation in terms of tyrosinase expression.     

Neuraminidase in Calf Retinal Outer Segment Membranes

Abstract: An enzyme catalyzing the hydrolysis of sialic acid ( N -acetylneuraminic acid: NeuNAc)-containing glycoconjugates has been found in bovine retinal rod outer segment (ROS) membranes. The enzymatic activity is optimal at pH 4.0 and is stimulated by 0.15% Triton X-100. Total activity was determined by the release of NeuNAc from endogenous and exogenous substrates (GDla). The ROS enzyme preferentially hydrolyses the ROS gangliosides, possibly because they are more accessible than the glycoproteins as substrates for the neuraminidase. Release of NeuNAc from gangliosides leads to important changes in the ganglioside patterns; whereas the amounts of GM1 increased throughout the incubation, the levels of polysialogangliosides GTlb and GD3 diminished owing to their rapid hydrolysis. The finding that gangliosides are hydrolysed more extensively than glycoproteins suggests that endogenous ROS gangliosides may be the principal source of metabolically available sialic acid in ROS. It was also observed that the activity of ROS neuraminidase is not affected by illumination of the membranes.     

A neuraminidase from Streptococcus sanguis that can release O-acetylated sialic acids

The naturally occurring sialic acids can have different types of N- and O-substitutions, resulting in more than 20 known isomers and compounds. Most methods for the detailed study of these various sialic acids require that the molecules be first released from their alpha-glycosidic linkage. When mild acid hydrolysis is used for this purpose, significant destruction of O-substituent groups occur. On the other hand, the presence of O-substituent groups renders the sialic acid molecule partially or completely resistant to the action of the currently known neuraminidase. To circumvent this problem, we searched for a neuraminidase whose activity is not affected by O-substitution. We reasoned that because Streptococcus sanguis from the human oral cavity is continually exposed to O-substituted sialic acids, its extracellular neuraminidase might not be blocked by O-substitution. We therefore purified this enzyme 3100-fold (56% yield) using ammonium sulfate precipitation, N-(p-aminophenyl)oxamic acid-agarose affinity chromatography, and chromatography on quaternary aminoethyl (QAE)-Sephadex, sulfopropyl (SP)-Sephadex, and Sephacryl S-200. The purified preparation is free of other significant glycosidase activities and proteolytic activities. It is capable of quantitatively releasing all the O-acetylated sialic acids that we studied with the single exception of the 4-O-acetylated sialic acid of equine submaxillary mucin. The activity of the enzyme is also not restricted by the type pf sialic acid linkage or the nature of the underlying oligosaccharide. However, it has maximal activity on gangliosides only in the presence of detergents. The general properties of this enzyme are described and its substrate specificities are contrasted with those of the commonly used neuraminidase from Vibrio cholerae.     

Guinea-pig kidney beta-N-acetylgalactosaminyltransferase towards Tamm-Horsfall glycoprotein. Requirement of sialic acid in the acceptor for transferase activity.

A beta-N-acetylgalactosaminyltransferase that preferentially transferred N-acetylgalactosamine to Sd(a-) Tamm-Horsfall glycoprotein was found in guinea-pig kidney microsomal preparations. This enzyme was kidney-specific and was able to transfer the sugar to other glycoproteins, such as fetuin and alpha 1-acidic glycoprotein. The presence of sialic acid in the acceptors was essential for the transferase activity when either glycoproteins or their Pronase glycopeptides were used as acceptors. Two glycopeptides (Tamm-Horsfall glycopeptides I and II) with a different carbohydrate composition were separated by DEAE-Sephacel chromatography from Pronase-digested Tamm-Horsfall glycoprotein. The amount of N-acetylgalactosamine transferred to glycopeptides by the enzyme correlated with their degree of sialylation. Enzymic digestion of N-[14C]acetylgalactosamine-labelled Tamm-Horsfall glycopeptide II showed that the transferred sugar was susceptible to beta-N-hexosaminidase. The amount of sugar cleaved by beta-hexosaminidase was strongly increased when the labelled Tamm-Horsfall glycopeptide II was pretreated with mild acid hydrolysis, a procedure that removed the sialic acid residues. Alkaline borohydride treatment of the labelled Tamm-Horsfall glycopeptide II did not release radioactivity, thus indicating that enzymic glycosylation took place at the N-asparagine-linked oligosaccharide units of Tamm-Horsfall glycoprotein.     

Structure of the lysosomal sphingolipid activator protein 1 by homology with influenza virus neuraminidase

The sphingolipid activator protein 1 (SAP-1) increases the rate of hydrolysis of sphingolipids in the lysosome by apparently bringing together the substrate and the corresponding hydrolytic enzyme. This implies specific recognition of both the substrate and enzyme by SAP-1. However, binding domains in SAP-1 and recognition mechanisms involved are unknown. Amino acid sequence comparison of SAP-1 with influenza virus neuraminidase (EC 3.2.1.18, FLU NA) indicates that functional amino acid residues in or near the sialic acid binding site of FLU NA are also found at equivalent positions in the first 48 N-terminal amino acids of SAP-1. This region of homology allows to propose folding of the SAP-1 polypeptide chain by comparison with known crystallographic structure of FLU NA and identify a potential domain for lysosomal enzyme recognition through sialic acid binding. There is also a region of 10 amino acid residues near the C-terminal end of SAP-1 which has a strong propensity to form an alpha-helix with amphiphilic properties of lipid-binding helices. This domain in SAP-1 is probably responsible for the lipid(substrate)-binding function of SAP-1.     

Biosynthesis of intestinal mucins. Sialic acids of sheep colonic epithelial mucin

1. Sheep colonic mucin contains three types of sialic acids, separable from the macrostructure by mild acidic hydrolysis. These are composed chiefly of N-acetyl-and N-glycollyl-neuraminic acid in ratios between 1:1.2 and 1:3.5 for different preparations of the mucin. The third sialic acid appears to be a diacetylated neuraminic acid. 2. A particle-free enzyme preparation, obtained from sheep colonic mucosa by gentle homogenization and high-speed centrifugation, catalyses a series of reactions involving N-acylamino sugars and leading to the formation of sialic acids in vitro: (i) phosphorylation by ATP of d-glucosamine, N-acetyl-and N-glycollyl-d-glucosamine; (ii) conversion of N-acetylglucosamine 6-phosphate into N-acetyl-d-glucosamine 1-phosphate; (iii) formation of sialic acids from phosphoenolpyruvate and N-acetyl- or N-glycollyl-d-glucosamine; (iv) formation of N-acetylneuraminic acid from uridine diphospho-N-acetylglucosamine or from N-acetylmannosamine; (v) incorporation of l-[U-(14)C]serine into the mucin by whole mucosal preparations.     

长双歧杆菌α-唾液酸苷酶在大肠杆菌中的表达及酶学性质

[背景]唾液酸苷酶是一类水解唾液酸糖复合物末端唾液酸残基的糖苷水解酶,广泛存在于动物和微生物中,具有重要的生物学功能.[目的]克隆一个长双歧杆菌(Bifidobacterium longum)唾液酸苷酶基因(blsia42)并在大肠杆菌(Escherichia coli)中表达,探讨该重组酶的酶学性质.[方法]从长双歧...     

Isolation and characterization of sialate 9(4)-O-acetylesterase from influenza C virus

An esterase was isolated from influenza C virus with a specific activity from 1.7-5 U/mg protein, and its substrate specificity was tested with various naturally occurring O-acylated sialic acids, synthetic carbohydrate acetates, and other esters. The enzyme hydrolyses only acetic acid esters at significant rates. The non-natural substrates 4-methyl-umbelliferyl acetate, 4-nitrophenyl acetate, and alpha-naphthyl acetate are cleaved at highest hydrolysis rates, followed by the natural substrate N-acetyl-9-O-acetylneuraminic acid. The esterase also acts on N-glycoloyl-9-O-acetylneuraminic acid and, much slower, on N-acetyl-4-O-acetylneuraminic acid; N-acetyl-7-O-acetylneuraminic acid is not hydrolysed. 2-Deoxy-2,3-didehydro-N-acetyl-9-O-acetylneuraminic acid is also a substrate for this enzyme, however, 6-O-acetylated N-acetylmannosamine and glucose are not. Esterification of the carboxyl function of sialic acids strongly reduces or prevents esterase action on O-acetyl groups. The carboxyl ester is not hydrolysed. The relative cleavage rates also depend on the type of the non-sialic acid part of the molecule. N-Acetyl-9-O-acetylneuraminic acid as component of sialyllactose and rat serum glycoprotein shows hydrolysis rates close to the free form of this sugar, while acetyl ester groups of bovine submandibular gland mucin and rat erythrocytes are hydrolysed at slower rates. Gangliosides and 4-O-acetylated glycoproteins are no substrates for the purified enzyme. A slow hydrolysis is observed by incubation of 9-O-acetylated GD1a with intact influenza C viruses. As other natural acetyl esters (acetyl-CoA and acetylthiocholine iodide) are not hydrolysed, the enzyme can be classified as sialate 9(4)-O-acetylesterase (EC 3.1.1.53).     

Analysis of sialidase and N-acetylneuraminate pyruvate-lyase substrate specificity by high-performance liquid chromatography

A rapid and sensitive assay by high-performance liquid chromatography for determination of the activity and substrate specificity of sialidase (EC 3.2.1.18) and N-acetylneuraminate lyase (EC 4.1.3.3) is described. Sialic acids were separated on a strong anion-exchange resin using 0.75 mM sodium sulfate as elution medium. This method allows the determination of a minimum amount of 200 pg (0.6 pmol) of sialic acid. Usually the enzyme mixtures were directly applied to the column without prior purification of substrates and products. The action of sialidase was studied either by the decrease of sialyllactose concentration or by the amount of sialic acid liberated. The relative hydrolysis rates of N-acetylneuraminyl-alpha(2-3)-lactose, N-glycolylneuraminyl-alpha(2-3)-lactose, N-acetylneuraminyl-alpha(2-6)-lactose, N-acetyl-9-O-acetylneuraminyl-alpha(2-3)-lactose, and N-acetyl-4-O-acetylneuraminyl-alpha(2-3)-lactose by Vibrio cholerae sialidase were 100, 88, 25, 12, and 0, respectively. The activity of N-acetylneuraminate lyase from Clostridium perfringens was determined by measuring the rate of disappearance of sialic acids or the formation of acylmannosamines, which is possible in the same chromatogram. Relative cleavage rates of N-acetylneuraminic acid, N-glycolylneuraminic acid, N-acetyl-9-O-acetylneuraminic acid, N-acetyl-7-O-acetylneuraminic acid, and N-acetyl-4-O-acetylneuraminic acid were found to be 100, 67, 24, 3, and 0, respectively. Comparison of the substrate specificities shows that substituents on the neuraminic acid molecule influence the reactions of both enzymes in a similar way.     

Surface localization of sialic acid on Actinomyces viscosus

This study reports the presence of sialic acid in Actinomyces viscosus strains T14V and T14AV. Mild acid hydrolysis of whole organisms released a compound which reacted positively in the periodate-thiobarbituric acid, direct Ehrlich's and resorcinol assays, and which co-chromatographed on paper with authentic N-acetylneuraminic acid. Strain T14V contained 10-fold greater concentrations of sialic acid than did strain T14AV. Sialic acid content was dependent upon the stage of growth of the culture, reaching a maximum in early stationary phase. Epifluorescence microscopy of fluorescein isothiocyanate (FITC)-conjugated Limulus polyphemus agglutinin (LPA), a lectin specific for sialic acid, revealed a uniform distribution of bound lectin on the surfaces of strains T14V and T14AV. Additional evidence for surface localization was obtained by demonstration of whole-cell agglutination of both strains with LPA. All LPA interactions with A. viscosus were inhibited by the presence of 0.1 M-N-acetylneuraminic acid. Neuraminidases from Clostridium perfringens, Arthrobacter ureafaciens and Vibrio cholerae did not release detectable amounts of sialic acid, but the extracellular enzyme from A. viscosus cleaved amounts equivalent to those obtained by acid hydrolysis. Other laboratory strains (W1053, M100, W859, 5-5S, RC45, ATCC 19246, and 'binder') as well as recent clinical isolates of A. viscosus were agglutinated by LPA and released sialic acid upon mild acid hydrolysis. Surface-available sialic acid has been implicated in the inhibition of alternative complement pathway activation and subsequent opsonophagocytosis. Thus the occurrence of surface sialic acid in A. viscosus may represent a mechanism of pathogenesis for this oral bacterium.     

Trisialoganglioside synthesis by a chicken brain sialyltransferase. Comparative study with the similar reaction for the synthesis of disialoganglioside.

An enzyme preparation from embryonic chicken brain catalyzes the transfer of sialic acid from CMP-N-acetylneuraminic acid to ceramide-Glc-Gal(NeuAc-NeuAc)-GalNAc-Gal (GDlb) to form ceramide-Glc-Gal(NeuAc-NeuAc)-GalNAc-Gal-NeuAc (GTlb). The sialyltransferase activity was measured during the development of the embryo, the subcellular distribution of this activity was determined and several kinetic properties of the reaction were examined. A comparative study with the similar reaction involved in the transfer of sialic acid to the terminal galactose in ceramide-Glc-Gal(NeuAc)-GalNAc-Gal (GMl) was made. The results obtained in this comparative study suggest that the transfer of sialic acid in both reactions is catalyzed by the same enzyme.     

Specific alkylation of a histidine residue in carnitine acetyltransferase by bromoacetyl-l-carnitine

Incubation of carnitine acetyltransferase with low concentrations of bromoacetyl-l-carnitine causes a rapid and irreversible loss of enzyme activity; one mol of inhibitor can inactivate one mol of enzyme. Bromoacetyl-d-carnitine, iodoacetate or iodoacetamide are ineffective. l-Carnitine protects the transferase from bromoacetyl-l-carnitine. Investigation shows that the enzyme first reversibly binds bromoacetyl-l-carnitine with an affinity similar to that shown for the normal substrate acetyl-l-carnitine; this binding is followed by an alkylation reaction, forming the carnitine ester of a monocarboxymethyl-protein, which is catalytically inactive. The carnitine is released at an appreciable rate by spontaneous hydrolysis, and the resulting carboxymethyl-enzyme is also inactive. Total acid hydrolysis of enzyme after treatment with 2-[(14)C]bromoacetyl-l-carnitine yields N-3-carboxy[(14)C]methylhistidine as the only labelled amino acid. These findings, taken in conjunction with previous work, suggest that the single active centre of carnitine acetyltransferase contains a histidine residue.     

Immunological studies in ulcerative colitis: extract, fractionation, and immunological characterization of germ-free rat colon antigen

Intestinal mucins from germ-free rats contained antigens reactive with sera from patients with ulcerative colitis, in addition to human blood group A- and H-like antigens. A crude antigen extract was obtained by phenol-water extraction at 65 °C. Two intestinal glycoproteins were purified from the extract by fractionated ethanol precipitation, ion-exchange chromatography, and gel filtration. The two glycoproteins (2aI and 4aIIb) were homogeneous in regard to electrical charge and molecular size. Both were glycoproteins of the blood group substance type. Component 2aI was very rich in N-acetylgalactosamine and threonine and low in N-acetylglucosamine and sialic acid(s). It had strong blood group A-like activity, weak blood group H activity, and no colon antigen activity as defined by patients' sera. Component 4aIIb was rich in sialic acid(s). About 40% of the sera from patients with ulcerative colitis reacted with this component. No blood group A- or H-like activity could be demonstrated. Colon antigen activity was sensitive to periodate oxidation, but resistant to boiling at neutral pH. It was very sensitive to acid hydrolysis. In fact, colon antigen activity was significantly reduced when subjected to weak acid hydrolysis under conditions which only appeared to release sialic acids.     

Sialyltransferase activities of aging diploid fibroblasts

Sialyltransferase activity and cell-cell adhesion rates of aging WI-38 cells were studied to determine the possible basis for a previously described decrease in membrane bound sialic acid and loss of proliferation of senescent cells. Ectosialyltransferase was demonstrated on the surface of both young and old WI-38 cells. The sialyltransferase assays consist of an enzyme source which is either the surface of intact cells (ectoenzyme) or a Triton X-100 cell homogenate, the nucleotide sialic acid donor (cytidine $\text{monophosphate}\text{-N-}\text{acetylneuraminic}$ acid), and an asialo-acceptor which may be endogenous to the enzyme preparation or may be added exogenously. When sialyltransferase activity is measured in the absence of exogenous acceptors, there is a greater amount of sialic acid transferred by old cells. However, when exogenous acceptors are provided, the amount of transfer is stimulated to a greater extent in young cells equalizing the amount of sialic acid incorporated into young and old cells. This suggests that there are fewer asialoglycoproteins and that acceptor concentration is a limiting factor in assays of young cell sialyltransferase. The end result of this may be the previously described decreased amount of membrane-bound sialic acid of old cells. A change in the adhesiveness of old cells described which may be related to the altered cell surface.     

Arylsulphatases in human brain: purification and characterization of an isoluble arylsulphatase

After solubilization with 0.5% (w/v) lysolecithin an arylsulphatase was purified 30-fold from human brain. By this procedure, 82% of the activity was recovered in the 100,000 g supernatant fluid. Solubilization of the enyzme was dependent on lysolecithin concentration but not on the time of incubation. The enzyme was purified using ethanol and ammonium sulphate fractionations. The purified protein showed a single band on acrylamide gel electrophoresis in two different buffer systems. On ultracentrifugation, a sharp symmetrical peak was obtained with a s_20,w value of 5.4 and an apparent molecular weight of 103,000 daltons was calculated. A molecular weight of 105,000 daltons was obtained by sucrose density gradient. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis showed the presence of two subunit species with molecular weights of 47,000 and 25,000 daltons. The enzyme was unstable at 04°C but could be stored in a frozen state without much loss of activity. 4-Methylumbelliferone-sulphate was used as substrate in these studies and the product, methylumbelliferone, was quantified fluorometrically. The enzyme had an optimum pH of 6.8. A higher activity was exhibited in imidazole buffer than in acetate buffer. Enzyme activity was linear up to 30 min of incubation. The enzyme showed a K_m of 37.7 μm for 4-methylumbelliferone-sulphate. Ammonium sulphate at 5 mm produced a slight activation of the enzyme. Borate, silver and sulphite ions inhibited enzyme activity, whereas p-chloromercuribenzoate, and cyanide, arsenite, fluoride and phosphate ions caused very little inhibition. The chemical enzymatic hydrolysis of the native enzyme revealed the presence of 2 mol of sialic acid per mole of the enzyme. Enzymatic removal of sialic acid did not affect the activity of the enzyme; therefore, the sialic acid moiety was not required for enzyme activity.     

Properties of endogenous,membrane-associated sialidase activity (N-acetylneuraminidase) of the goldfish visual system

The endogenous sialidase (N-acetylneuraminidase) activity of membranes prepared from goldfish retina and optic tectum displays characteristics similar to those reported for neural plasma membrane sialidases of other organisms. Endogenous membrane sialidase activity was found to be optimal at ph 4.0, and maximal release was obtained at 37-50 degrees C, above which temperature thermal instability of the preparations was observed. Optic nerve crush, which results in regeneration of retinal ganglion cell axons, did not result in significant changes in measured endogenous membrane sialidase activity in either the retina or the optic tectum. Enzymatic hydrolysis of membrane sialoglycolipid (ganglioside) accounted for about 70% of the total sialic acid released. Ganglioside GM1 accumulated as the major lipid product in both retina and tectum, indicating that the inner sialosylgalactosyl linkage in the ganglio oligosaccharide series was resistant to hydrolysis by the endogenous enzyme.     

Construction of an in vitro trans-sialylation system: surface display of Corynebacterium diphtheriae sialidase on Saccharomyces cerevisiae

Sialidases can be used to transfer sialic acids from sialoglycans to asialoglycoconjugates via the trans-glycosylation reaction mechanism. Some pathogenic bacteria decorate their surfaces with sialic acids which were often scavenged from host sialoglycoconjugates using their surface-localized enzymes. In this study, we constructed an in vitro trans-sialylation system by reconstructing the exogenous sialoglycoconjugate synthesis system of pathogens on the surfaces of yeast cells. The nanH gene encoding an extracellular sialidase of Corynebacterium diphtheriae was cloned into the yeast surface display vector pYD1 based on the Aga1p–Aga2p platform to immobilize the enzyme on the surface of the yeast Saccharomyces cerevisiae. The surface-displayed recombinant NanH protein was expressed as a fully active sialidase and also transferred sialic acids from pNP-α-sialoside, a sialic acid donor substrate, to human-type asialo-N-glycans. Moreover, this system was capable of attaching sialic acids to the glycans of asialofetuin via α(2,3)- or α(2,6)-linkage. The cell surface-expressed C. diphtheriae sialidase showed its potential as a useful whole cell biocatalyst for the transfer of sialic acid as well as the hydrolysis of N-glycans containing α(2,3)- and α(2,6)-linked sialic acids for glycoprotein remodeling.     

Effect of removing sialic acids from endothelium on the adherence of circulating platelets in arteries in vivo

The contribution of the net negative charge excess due to sialic acids on endothelium in preventing adhesion of circulating platelets in vivo was investigated in anaesthetized rabbits. Platelets in the rabbit's circulation were selectively labelled with radioactive 5-hydroxytryptamine in vivo. Segments of carotid arteries temporarily isolated from the circulation were perfused with one or other of two commercial preparations of neuraminidase; the opposite carotid artery was perfused similarly without the enzyme, as control. A neuraminidase preparation from Behringwerke free of proteolytic activity released sialic acid into the perfusate with a peak concentration after 10-15 min which decreased gradually later. A neuraminidase preparation from Sigma that contained demonstrable proteolytic activity released sialic acid similarly during the first hour and thereafter more sialic acid in a second peak. After blood flow through the carotids had been restored the adhesion of labelled platelets in the artery perfused with neuraminidase was compared with that in the artery perfused without the enzyme. The radioactivities were significantly higher in carotids that had been perfused with neuraminidase than in those that had been perfused without the enzyme. Neuraminidase perfusion had no effect on the production of prostacyclin by the carotids. Perfusion with acetylsalicylic acid before neuraminidase increased the adhesion of platelets significantly. It is concluded that diminution in electrostatic repulsion between circulating platelets and vascular endothelium from which the net negative charge excess due to sialic acids has been removed increases the adhesion of circulating platelets, irrespective of the production of prostacyclin by the arterial walls, and that inhibition of prostacyclin production augments this adhesion of platelets.     

The acid and enzymic hydrolysis of O-acetylated sialic acid residues from rabbit Tamm–Horsfall glycoprotein

Rabbit Tamm-Horsfall glycoprotein and bovine submaxillary glycoprotein were both found to contain sialic acid residues which are released at a slow rate by the standard conditions of acid hydrolysis. These residues are also resistant to neuraminidases from Vibrio cholerae and Clostridium perfringens. This behaviour was attributed to the presence of O-acetylated sialic acid, since the removal of O-acetyl groups by mild alkaline treatment normalized the subsequent release of sialic acid from rabbit Tamm-Horsfall glycoprotein by acid and by enzymic hydrolysis. Determination of the O-acetyl residues in rabbit Tamm-Horsfall glycoprotein indicated that on average two hydroxyl groups of sialic acid are O-acetylated, and these were located on the polyhydroxy side-chain of sialic acid or on C-4 and C-8. These findings confirm the assumption that certain O-acetylated forms of sialic acid are not substrates for bacterial neuraminidases. Several explanations have been suggested to explain the effect of O-acetylation of the side-chain on the rate of acidcatalysed hydrolysis of sialic acid residues.