Determination of erythrocyte surface sialic acid residues by a new colorimetric method.

The 3-methyl-2-benzothiazolone hydrazone method has been applied to the determination of erythrocyte membrane sialic acid residues. This method requires a mild oxidation of sialic acid which results in the formation of analogs. Their separation by chromatography, after labeling, allows the choice of the best conditions for this oxidation. The concomitant liberated formaldehyde is determined. This method requires no prior release of sialic acid as opposed to the periodate-thiobarbituric method of Warren (1959, J. Biol. Chem., 234, 1971–1975). These two methods have been compared.     

The effect of various fixation procedures on the digestability of sialomucins with neuraminidase

Synopsis The histochemical digestability with neuraminidase of sialomucin in mouse sublingual gland was studied in unfixed and formaldehyde vapour-fixed cryostat sections, and in sections prepared from paraffin-embedded material fixed in several alcohol- or formaldehyde-containing fixatives recommended for mucosubstances.The removal of sialic acid residues from sections treated with neuraminidase was followed histochemically with the following staining methods: Azure A pH 3.5, Alcian Blue pH 2.5, Low Iron Diamine and Alcian Blue pH 2.5 followed by periodic acid-Schiff. When Goland's methanolic cyanuric chloride was used as fixative, only a partial loss of tissue basophilia was evident after enzyme incubation, but in tissues fixed in other ways a complete loss of histochemically detectable sialic acid residues was observed.     

Metabolic labeling of sialic acids in tissue culture cell lines: methods to identify substituted and modified radioactive neuraminic acids

The parent sialic acid N-acetylneuraminic acid can be modified or substituted in various ways, giving rise to a family of more than 25 compounds. The definitive identification of these compounds has previously required isolation of nanomole amounts for mass spectrometry or NMR. We have explored the possibility of using the known metabolic precursors of the sialic acids, particularly N-acetyl-[6-3H]mannosamine, to label and identify various forms of sialic acids in tissue culture cells. Firstly, we defined several variables that affect the labeling of sialic acids with N-acetyl-[6-3H]mannosamine. Secondly, we have devised a simple screening method to identify cell lines that synthesize substituted or modified sialic acids. We next demonstrate that it is possible to definitively identify the natures of the various labeled sialic acids without the use of mass spectrometry, even though they are present only in tracer amounts. The methods used include paper chromatography, analytical de-O-acetylation, periodate release of the 9-3H as [3H]formaldehyde (which is subsequently converted to a specific 3H-labeled chromophore), acylneuraminate pyruvate lyase treatment with identification of [3H]acylmannosamines, gas-liquid chromatography with radioactive detection, and two new high-pressure liquid chromatography methods utilizing the amine-adsorption:ion suppression and ion-pair principles. The use of an internal N-acetyl-[4-14C]neuraminic acid standard in each of these methods assures precision and accuracy. The combined use of these methods now allows the identification of radioactive tracer amounts of the various types of sialic acids in well-defined populations of tissue culture cells; it may also allow the identification of hitherto unknown forms of sialic acids.     

Identification of N-acetyl-4-O-acetylneuraminyl-lactose in echidna milk

The identity of a novel form of sialyl-lactose found in milk of the echidna (Tachyglossus aculeatus) was investigated. The sialyl-lactose yielded equimolar amounts of N-acetylneuraminic acid and lactose during mild acid hydrolysis but was resistant to the action of a bacterial neuraminidase. A viral neuraminidase hydrolysed it to lactose plus a form of sialic acid that reacted positively with thiobarbituric acid reagent but whose chromatographic mobility was greater than that of N-acetylneuraminic acid. Treatment with alkali converted the sialyl-lactose into a substance with the same chromatographic mobility as N-acetylneuraminyl-(2-->3)-lactose and made it susceptible to the action of bacterial neuraminidase. The sialyl-lactose contained one mol of ester (identified as acetyl), and released one mol of formaldehyde during periodate oxidation, per mol of sialic acid. It did not contain N-glycollylneuraminic acid. These results indicate that the sialyl-lactose is N-acetyl-4-O-acetylneuraminyl-(2-->3)-lactose. Echidna milk contained, in addition, a small amount of N-acetylneuraminyl-(2-->3)-lactose.     

Regulation of sialic acid metabolism in Escherichia coli: role of N-acylneuraminate pyruvate-lyase.

In Escherichia coli, synthesis of sialic acid is not regulated by allosteric inhibition mediated by cytidine 5'-monophospho-N-acetylneuraminic acid (CMP-NeuNAc). Evidence for the lack of metabolic control by feedback inhibition was demonstrated by measuring the intracellular level of sialic acid and CMP-NeuNAc in mutants defective in sialic acid polymerization and in CMP-NeuNAc synthesis. Polymerization-defective mutants could not synthesize the polysialic acid capsule and accumulated ca. 25-fold more CMP-NeuNAc than the wild type. Mutants unable to activate sialic acid because of a defect in CMP-NeuNAc synthetase accumulated ca. sevenfold more sialic acid than the wild type. An additional threefold increase in sialic acid levels occurred when a mutation resulting in loss of N-acylneuraminate pyruvate-lysase (sialic acid aldolase) was introduced into the CMP-NeuNAc synthetase-deficient mutant. The aldolase mutation could not be introduced into the polymerization-defective mutant, suggesting that any further increase in the intracellular CMP-NeuNAc concentration was toxic. These results show that sialic acid aldolase can regulate the intracellular concentration of sialic acid and therefore the concentration of CMP-NeuNAc. We conclude that regulation of aldolase, mediated by sialic acid induction, is necessary not only for dissimilating sialic acid (E.R. Vimr and F. A. Troy, J. Bacteriol. 164:845-853, 1985) but also for modulating the level of metabolic intermediates in the sialic acid pathway. In agreement with this conclusion, an increase in the intracellular sialic acid concentration was correlated with an increase in aldolase activity. Direct evidence for the central role of aldolase in regulating the metabolic flux of sialic adid in E. coli was provided by the finding that exogenous radiolabeled sialic acid was specifically incorporated into sialyl polymer in aldolase-negative strain but not in the wild type.     

Attenuation of beta-amyloid induced toxicity by sialic acid-conjugated dendrimeric polymers

beta-amyloid (Abeta) is the primary protein component of senile plaques in Alzheimer's disease and is believed to be associated with neurotoxicity in the disease. We and others have shown that Abeta binds with relatively high affinity to clustered sialic acid residues on cell surfaces and that removal of cell surface sialic acids attenuate Abeta toxicity. In the current work, we have prepared sialic acid conjugated dendrimeric polymers and assessed the ability of these sialic acid conjugated dendrimers to prevent Abeta toxicity. Flow cytometry was used to analyze viability of SH-SY5Y neuroblastoma cells and the effects of soluble and clustered sialic acid mimics on Abeta cell toxicity. Soluble sialic acid attenuation of Abeta induced toxicity was effective only at high sialic acid concentrations and low Abeta concentration. The sialic acid conjugated dendrimeric polymers were able to attenuate Abeta toxicity at micromolar concentrations, or approximately three orders of magnitude lower concentrations than the soluble sialic acid. The toxicity prevention properties of the sialic acid modified dendrimers were a function of dendrimer size. This work may lead to the development of new classes of therapeutics for the prevention of Abeta toxicity.     

Differential distribution of sialic acid in alpha2,3 and alpha2,6 linkages in the apical membrane of cultured epithelial cells and tissues.

We used lectin cytochemistry and confocal microscopy to examine the distribution of sialic acid in epithelial cells. Maackia amurensis lectin and Sambuccus nigra agglutinin were used to detect alpha2,3 and alpha2,6 sialic acid, respectively. In Caco-2, HT-29 5M12, and MCF-7 cells, which express sialic acid mainly in one type of linkage, the majority of the signal was observed in the apical membrane. In cells that bound both lectins, alpha2,3 sialic acid was distributed apically, whereas alpha2,6 sialic acid showed a broader distribution. In IMIM-PC-1 cultures, alpha2,3 sialic acid was detected mainly in the apical membrane, whereas alpha2,6 sialic acid was more abundant in the basolateral domain of polarized cells. In these cells, treatment with GalNAc-O-benzyl led to reduced alpha2,3 levels and to an increase and redistribution of alpha2,6 to the apical domain. Similarly, sialic acid was predominantly expressed apically in all epithelial tissues examined. In conclusion, (a) sialic acid is mainly distributed to the apical membrane of epithelial cells, (b) there is a hierarchy in the distribution of sialic acids in polarized epithelial cells, i.e., alpha2,3 is preferred to alpha2,6 in the apical membrane, and (c) IMIM-PC-1 cells are a good model in which to study the regulation of the levels and distribution of sialic acids.     

Erythrocyte membrane bound and plasma sialic acid during aging

Sialic acid, a nine-carbon sugar, is an acetylated derivative of neuraminic acid predominantly found in vertebrates, a few higher invertebrates, and certain types of bacteria. Red blood cells (RBCs) have a net negative surface charge and this bulk charge is due to ionized sialic acid. Decreased surface charge and sialic acid content have been reported in older erythrocytes, and it is postulated that the decreased electro-negativity may be related to cell senescence. In the present study we report the RBC and plasma sialic acid content during aging in rats. Our results show a significant decrease in RBC sialic acid content and increase in plasma sialic acid as a function of rat aging. The decreased sialic acid in erythrocyte membrane with increasing rat age presents a good biomarker of the aging process. The elevated plasma sialic acid may be a manifestation of several factors including increased expression of acute phase proteins and increased damage to various organs.     

Evidence for sialic acid on the nicotinic acetylcholine receptor from Torpedo marmorata

The nicotinic acetylcholine receptor from Torpedo marmorata was treated with neuraminidase. Direct determination of sialic acid released gave about 1 mole sialic acid per mole receptor. Lectin binding studies of the sugars accessible on the receptor molecule were performed after sialic acid hydrolysis. They indicated that the terminal sialic acid is linked to a galactose residue.The present findings confirm the presence of one terminal sialic acid residue per receptor molecule.     

Turnover of Free Sialic Acid, CMP-Sialic Acid, and Bound Sialic Acid In Rat Brain

Abstract: Adult male rats were injected intraventricularly with N-[³H]acetylmannosamine. After different time intervals the rats were killed and free sialic acid, CMP-sialic acid, lipid- and protein-bound sialic acid were isolated from brain and the specific radioactivities determined. Maximal specific radioactivity was reached after approximately 4 h for CMP-sialic acid, after 10–12 h for free sialic acid and after approximately 42 h for lipid-and protein-bound sialic acid. After some days the specific radioactivities of all four pools were the same and decreased equally, with a calculated turnover rate of approximately 3.5 weeks. The conclusion was that this phenomenon was the result of reutilisation of sialic acid and/or precursors. Therefore, the calculated turnover is not the turnover of bound sialic acid, but merely the rate of leakage of sialic acid and/or precursors out of the brain, so that no real turnover can be measured by this method. The first few hours after injection the specific radioactivity of CMP-sialic acid rose above that of free sialic acid. It is supposed that a compartmentalization exists of free sialic acid. The newly synthesized sialic acid molecules are not secreted into the cytoplasmic pool but are preferentially used for the synthesis of CMP-sialic acid. The results and conclusions are discussed in view of the general problems concerning turnover measurements of glycoconjugates.     

Inhibition of alkaline phosphatase by sialic acid.

The interaction of human organ alkaline phosphatases (orthophosphoric-monoester phosphohydrolases (alkaline optimum), EC 3.1.3.1) with sugars was studied. Hexosamines, N-acetylneuraminic acid (NANA or sialic acid), N-acetylmuramic acid and N-acetylglycolylneuraminic acid inhibited human organ alkaline phosphatase activities. Of these, sialic acid was the most effective inhibitor. The pH profiles for the enzymes in the absence and presence of sialic acid were similar. The sialic acid - enzyme complex was more heat stable than the free enzyme between 20 and 45 degrees C. Lineweaver-Burk plots of 1/v versus 1/S at various concentrations of sialic acid showed intersecting straight lines indicating that the mechanism of inhibition was a mixed type. The Ki value obtained from the plots of 1/v versus the square of sialic acid concentration was 0.07 mM for the hepatic, sialidase-treated hepatic, and intestinal alkaline phosphatases. The respective Hill coefficients varied somewhat with the alkaline phosphatase isoenzyme. Hyperbolic curves were obtained when the percentage of remaining activity was plotted against the substrate concentration at different concentrations of sialic acid. The Hill coefficient was lowered in the presence of sialic acid. The sialidase-treated hepatic enzymes used gave the most effective conversion. Partial denaturation of the enzyme with urea, or pronase digestion had a little if any effect on the sialic acid inhibition with constant time.     

Higher reactivity of apolipoprotein B-100 and alpha-tocopherol compared to sialic acid moiety of low-density lipoprotein (LDL) in radical reaction

Radical reaction of low-density lipoprotein (LDL) is a key step in atherogenesis and causes both a decrease in the sialic acid moiety and modification of apolipoprotein B-100 (apoB). Although apoB modification (cross-link and fragmentation) increases in atherosclerosis, the change in apoB-bound sialic acid in atherosclerosis is controversial. To elucidate the physiological implications of desialylation of LDL by radical reaction, the reactivity of sialic acid of LDL was compared with that of apoB, which underwent facile fragmentation in radical reactions. ApoB was determined by immunoblot analysis with anti-apoB antiserum, and the sialic acid moiety was measured by blot analysis with a biotin-bound lectin [biotin-SSA from Japanese elderberry (Sambucus sieboldiana)] specific to sialic acid. When human LDL was oxidized with Cu(2+) at 37 degrees C, apoB and apoB-attached sialic acid decreased simultaneously. Comparison of the staining bands with anti-apoB and with biotin-SSA shows that sialic acid moieties still remain on fragmented apoB proteins, indicating that the decrease in sialic acid is much slower than that of apoB fragmentation. In addition, human plasma was oxidized with 400 microM of Cu(2+) at 37 degrees C. Similar analysis indicates that the decrease in sialic acid attached to apoB also results from the fragmentation of apoB. This study indicates that the fragmentation of apoB proceeds at a much faster rate than the decrease in sialic acid content when a free radical reaction is induced in isolated LDL as well as in plasma LDL exposed to Cu(2+)-induced oxidative stress. On the basis of these results, the modification of apoB is much more sensitive than the decrease in sialic acid as an indicator of oxidative stress.     

Identification of an inducible catabolic system for sialic acids (nan) in Escherichia coli.

Escherichia coli K-12 and K-12 hybrid strains constructed to express a polysialic acid capsule, the K1 antigen, were able to efficiently use sialic acid as a sole carbon source. This ability was dependent on induction of at least two activities: a sialic acid-specific transport activity, and an aldolase activity specific for cleaving sialic acids. Induction over basal levels required sialic acid as the apparent inducer, and induction of both activities was repressed by glucose. Induction also required the intracellular accumulation of sialic acid, which could be either added exogenously to the medium or accumulated intracellularly through biosynthesis. Exogenous sialic acid appeared to be transported by an active mechanism that did not involve covalent modification of the sugar. Mutations affecting either the transport or degradation of sialic acid prevented its use as a carbon source and have been designated nanT and nanA, respectively. These mutations were located by transduction near min 69 on the E. coli K-12 genetic map, between argG and glnF. In addition to being unable to use sialic acid as a carbon source, aldolase-negative mutants were growth-inhibited by this sugar. Therefore, the intracellularly accumulated sialic acid was toxic in aldolase-deficient E. coli strains. The dual role of aldolase in dissimilating and detoxifying sialic acids is consistent with the apparent multiple controls on expression of this enzyme.     

Attenuation of β-amyloid induced toxicity by sialic acid-conjugated dendrimeric polymers

β-amyloid (Aβ) is the primary protein component of senile plaques in Alzheimer's disease and is believed to be associated with neurotoxicity in the disease. We and others have shown that Aβ binds with relatively high affinity to clustered sialic acid residues on cell surfaces and that removal of cell surface sialic acids attenuate Aβ toxicity. In the current work, we have prepared sialic acid conjugated dendrimeric polymers and assessed the ability of these sialic acid conjugated dendrimers to prevent Aβ toxicity. Flow cytometry was used to analyze viability of SH-SY5Y neuroblastoma cells and the effects of soluble and clustered sialic acid mimics on Aβ cell toxicity. Soluble sialic acid attenuation of Aβ induced toxicity was effective only at high sialic acid concentrations and low Aβ concentration. The sialic acid conjugated dendrimeric polymers were able to attenuate Aβ toxicity at micromolar concentrations, or approximately three orders of magnitude lower concentrations than the soluble sialic acid. The toxicity prevention properties of the sialic acid modified dendrimers were a function of dendrimer size. This work may lead to the development of new classes of therapeutics for the prevention of Aβ toxicity.     

Studies of lysosomal sialic acid metabolism: retention of sialic acid by Salla disease lysosomes

Purified rat liver lysosomes were incubated in 0.2 M sialic acid resulting in an increase in lysosomal free sialic acid of 3.8 +/- 1.5 nmol/unit beta hexosaminidase. Sialic acid loss by these lysosomes was stimulated 2-3 fold by 25 mM sodium phosphate. Loss of sialic acid by lysosomes from cultured human diploid fibroblasts was similar to that observed in rat liver lysosomes while loss of sialic acid by lysosomes from cultured fibroblasts from a patient with infantile Salla disease occurred much more slowly. Salla disease appears to be the consequence of defective lysosomal transport of sialic acid and is analogous to cystinosis, a disorder of lysosomal amino acid transport.     

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.     

Panagrellus redivivus and Caenorhabditis elegans: evidence for the absence of sialic acids

Complementary experiments were performed to indicate the presence or absence of sialic acids in axenically cultured Panagrellus redivivus and Caenorhabditis elegans. Competitive displacement experiments with radiolabeled Limax flavus agglutinin demonstrated the presence of sialic acid in nematodes grown in medium which contained liver extract as a growth factor but the absence of sialic acid when heme was substituted for liver extract. This finding suggested that sialic acid present in the liver medium was responsible for conflicting results of other studies. Transmission electron microscopy of thin sections from nematodes labeled with an LFA-ferritin conjugate revealed no label to the surface area of the cephalic chemosensilla. Fluorometric analysis with a modification of the thiobarbituric acid assay was negative for sialic acid. Analyses by gas chromatography-mass spectrometry, sensitive to the high picomole range, were also negative for sialic acid. Taken together the results provide evidence for the absence of sialic acid in P. redivivus and C. elegans using the most sensitive and diagnostic technique currently available.     

Attachment of Mycoplasma pulmonis to rat and mouse synovial cells cultured in vitro

The attachment of Mycoplasma pulmonis m53 organisms to mouse and rat synovial cells was examined by using the organisms and the synovial cells treated in various ways. M. pulmonis treated with trypsin attached to the synovial cells, but the organisms treated with pronase, formaldehyde, glutaraldehyde, or heat did not. These findings suggest that the sites for binding M. pulmonis to the mouse and rat synovial cells are of polypeptide nature. Treatment of M. pulmonis with sialic acid and treatment of the synovial cell sheets with neuraminidase did not affect the attachment. The synovial cell surface for receptors M. pulmonis organisms would be different from those on respiratory cells or erythrocytes for M. pneumoniae or M. gallisepticum. Even nonviable organisms and M. pulmonis membranes attached to the mouse or rat synovial cells. The nature of the receptor of mouse synovial cells would be different from that of rat cells, since rat cells were affected by treatment with formaldehyde or glutaraldehyde, but mouse cells were not.     

Cytochalasin B and the sialic acids of Ehrlich ascites cells

The effect of cytochalasin B (CB) on the electrophoretic mobility and density of ionized sialic acid groups at the surface of Ehrlich ascites cells was examined together with a biochemical assay of the total sialic acid content of treated and control cells. Sialic acid assays indicated that CB-treated cells had a greater amount of total sialic acid and sialic acid sensitive to neuraminidase than control cells/cell. Equal amounts of sialic acid were removable by neuraminidase treatment from control cells and cells pretreated with neuraminidase and subsequently cultured with CB. The electrophoresis results showed a decrease in electrophoretic mobility in the presence of CB which could be reversed by growth in CB-free medium. Neuraminidase treatment did not make a significant additional reduction in the mobility of CB-treated cells. CB also prevented the recovery of electrophoretic mobility of neuraminidase treated cells. The results suggest that while CB does not inhibit sialic acid synthesis, it does alter the expression of ionized sialic acid groups at the electrokinetic surface. CB-containing culture media could be re-utilized several times suggesting that CB is not significantly bound or metabolized by Ehrlich ascites cells.     

On the role of sialic acid in the rheological properties of mucus.

The importance of sialic acid in the rheological properties of mucus has been investigated. Both bovine cervical mucus, which is a gel, and the structural glycoprotein derived from it were studied before and after treatment with neuraminidase which selectively cleaves terminal sialic acid residues. The storage modulus, viscosity and circular dichroism spectrum were all essentially changed after removal of the sialic acid. These results would indicate that removal of sialic acid does not affect the physical structure of the glycoprotein and it is concluded that sialic acid has no significant role in the rheological properties of cervical mucus.