Glucose suppression of deoxyribose interference in the thiobarbituric acid determination of sialic acid.

Glucose has been demonstrated to suppress the reaction of deoxyribose in the thiobarbituric acid determination of sialic acid. Suppression occurs at the periodate oxidation step in which glucose apparently competes with deoxyribose. This suppression is augmented by sodium chloride and trichloroacetic acid. With these three substances, deoxyribose reactivity can be completely eliminated at concentrations up to 75 μm with only a 25% decrease in sialic acid reactivity.Mixtures of deoxyribose and sialic acid and hydrolyzed extracts of rat organs gave reaction products with an absorption spectrum closely resembling that given by a sialic acid standard. Provided that the spectral characteristics of the colored product from an unknown sample are verified, sialic acid can be determined directly from absorbance at 550 nm without interference by deoxyribose.     

An immobilized bienzyme system for assay of sialic acid

Sialic acid has been assayed enzymatically by an immobilized two-enzyme system. The method includes cleavage of sialic acid to pyruvic acid by N-acetylneuraminic acid (NANA) aldolase and reduction of pyruvic acid by lactate dehydrogenase in the presence of NADH, which is followed photometrically at 349 nm. For the membrane preparation 5 units of lactate dehydrogenase and 1 unit of NANA-aldolase were used. The pH optimum of the reaction using potassium phosphate buffer was 7.0. This two-enzyme membrane remains 100% active for several weeks at 4 degrees C in the assay buffer and remains stable after performing experiments at 45 degrees C.     

A fluorometric procedure for measuring the neuraminidase activity: its application to the determination of this activity in influenza and parainfluenza viruses

A fluorometric procedure for quantitating the amount of N-acetylneuraminic acid enzymatically released by the neuraminidase activity from N-acetylneuraminyl-lactose (sialyl-lactose) has been developed. The liberated lactose is hydrolyzed with beta-galactosidase, and the released galactose is oxidized with galactose dehydrogenase and NAD+; finally, the NADH produced is measured by fluorometry (excitation at 340 nm and analysis of emitted light at 465 nm). The fluorometric assay is about 10-fold more sensitive than the spectrophotometric procedure that measures NADH at 340 nm. It readily measures amounts as little as 2 nmol of sialic acid, and does not require the use of radioactive isotopes. Interferences due to sucrose or other substances, which cause errors in some cases with the use of the periodate-thiobarbiturate method for neuraminidase activity determination, are avoided. The procedure reported here provides a sensitive, rapid, and relatively simple method (feasible with commercialized reagents) for measuring the neuraminidase activity not only in purified samples from different sources but also directly in biological materials such as viruses. The technique has been tested with some viruses recently isolated belonging to Orthomyxoviridae or Paramyxoviridae families, known to be rich in neuraminidase. Reciprocally, this method can also be employed for determining the sialic acid concentration in acylneuraminyl-lactose-containing compounds when using purified neuraminidase for hydrolysis.     

A sensitive assay of sialidase activity with fluorogenic oligosaccharide derivatives

Fluorogenic oligosaccharide derivatives, lactityl-aminopyridine and sialyllactityl-aminopyridines, were synthesized by reductive amination of lactose and sialyllactose with 2-aminopyridine in the presence of sodium cyanoborohydride.Lactityl-aminopyridine showed bluish-white fluorescence at 390 nm by excitation with ultraviolet light at 320 nm, and the intensity of the fluorescence was proportional to the concentration of lactityl-aminopyridine within a range from 20 to 9800 pmole/ml.Two isomers of sialyllactityl-aminopyridine were enzymatically hydrolyzed to sialic acid and lactityl-aminopyridine by the action of both microbial and mammalian sialidases, and their suitability as substrates for sialidase was investigated. The result showed that sialidase activity was determined with about 55-fold higher sensitivity than that of ordinarily used colorimetric methods.     

Stable thiobarbituric acid chromophore with dimethyl sulphoxide. Application to sialic acid assay in analytical de-O-acetylation.

With dimethyl sulphoxide instead of butanol in the thiobarbituric acid assay for sialic acid, a non-fading chromophore with lambdamax. = 549 nm was produced in a homogeneous solution, allowing dilution of the test mixture in case of high colour yield. This test adapted well to studies on alkaline de-O-acetylation. Bovine and rat submaxillary mucins, and rabbit Tamm-Horsfall urinary sialoproteins contain O-acetyl isomers of neuramine acid that are resistant to the thiobarbituric acid assay. Alkaline de-O-acetylation converted resistant O-acetylneuraminic acid into thiobarbituric acid-reactive sialic acid, and such conversion paralleled de-O-acetylation as measured by the ferric hydroxamate method. The colour increment was similar when the alkaline treatment of bovine submaxillary mucin either preceded or followed the acid hydrolysis. Only alkaline preptreatment was effective with rat submaxillary mucin. By selecting optimal conditions for alkaline de-O-acetylation, O-acetyl isomers can be accurately assessed by the thiobarbituric acid assay.     

Versatile biosynthetic engineering of sialic acid in living cells using synthetic sialic acid analogues.

Sialic acids are critical components of many glycoconjugates involved in biologically important ligand-receptor interactions. Quantitative and structural variations of sialic acid residues can profoundly affect specific cell-cell, pathogen-cell, or drug-cell interactions, but manipulation of sialic acids in mammalian cells has been technically limited. We describe the finding of a previously unrecognized and efficient uptake and incorporation of sialic acid analogues in mammalian cells. We added 16 synthetic sialic acid analogues carrying distinct C-1, C-5, or C-9 substitutions individually to cell cultures of which 10 were readily taken up and incorporated. Uptake of C-5- and C-9-substituted sialic acids resulted in the structural modification of up to 95% of sialic acids on the cell surface. Functionally, binding of murine sialic acid-binding immunoglobulin-like lectin-2 (Siglec-2, CD22) to cells increased after N-glycolylneuraminic acid treatment, whereas 9-iodo-N-acetylneuraminic acid abolished binding. Furthermore, susceptibility to infection by the B-lymphotropic papovavirus via a sialylated receptor was markedly enhanced following pretreatment of host cells with selected sialic acid analogues including 9-iodo-N-acetylneuraminic acid. This novel experimental strategy allows for an efficient biosynthetic engineering of surface sialylation in living cells. It is versatile, extending the repertoire of modification sites at least to C-9 and enables detailed structure-function studies of sialic acid-dependent ligand-receptor interactions in their native context.     

Detection of 2H-1,4-thiazine-5,6-dihydro-3,5-dicarboxylic acid (lanthionine ketimine) in the bovine brain by a fluorometric assay

A new sulfur imino acid, 2H-1,4-thiazine-5,6-dihydro-3,5-dicarboxylic acid (lanthionine ketimine), has been detected in the bovine brain by means of fluorometric and HPLC procedures. The fluorometric assay is based on the fluorescent property of the copper-ketimine interaction product at pH 11.5. Other ketimines do not fluoresce in these conditions. The fluorophore exhibits an excitation maximum at 353 nm and an emission at 462 nm and is stable for at least 24 h. In the test conditions the fluorescence is proportional to the ketimine concentration from 1 to 200 microM. Detection of endogenous lanthionine ketimine has been performed after a simple enrichment procedure (brain deproteinization and extraction with diethyl ether) which minimizes degradative by-reactions of the unstable ketimine. The concentration of this new sulfur imino acid in the brain ranges from 0.5 to 1 nmol/g in three different samples. Identification and quantitations were confirmed by an HPLC procedure which takes advantage of the selective absorption at 380 nm of the phenylisothiocyanate-ketimine adduct. The identification of lanthionine ketimine in nervous tissues may have important metabolic and physiological implications.     

A new fluorometric assay method for quinolinic acid

A new fluorometric assay method for quinolinic acid is introduced in this study. Quinolinic acid-hydrazine complex, a stable fluorescent compound, is formed after heating quinolinic acid with hydrazine at 215–220°C for 2 min. Fluorescence excitation and emission maxima of the complex are at 285 and 380 nm, respectively. This assay method is rapid and rather sensitive. It takes about 30 min to ascertain the amount of quinolinic acid as low as 50 ng. Specificity of this method is high among biological compounds. An ultrasensitive assay method for uinolinic acid (as low as 20 pg) with diphenylhydrazine instead of hydrazine is also found. After separating the quinolinic acid-diphenylhydrazine complex from residual diphenylhydrazine, this ultrasensitive assay method may be practically applicable.     

Fluorimetric microassay of DNA using a modified thiobarbituric acid assay

A method for the rapid, specific measurement of minute amounts of DNA is presented. The method is sensitive to about 20 ng of DNA, which is equivalent to approximately 3000 mammalian cells. The method employs enzymatic liberation of desoxyribose with DNase and phosphodiesterase. The liberated desoxyribose is reacted with thiobarbituric acid to yield a fluorescing compound with an excitation maximum at 532 nm and an emission maximum at 549 nm, measured with a fluorimeter. The entire procedure is accomplished within a few hours. The result is linear up to about 1 μg DNA or 3 × 10⁵ lymphocytes.     

Demonstration of sialic acid groups in the glomerular basement membrane of the rat with phosphotungstic acid at low pH

Summary This paper reports an unrecognized aspect of phosphotungstic acid staining at low pH. It provides an on-section staining method in which sialic acid-containing molecules can be demonstrated in the laminae rarae of the rat glomerular basement membrane. The staining in the basement membrane became negative after perfusion with the following cations: protamine sulphate, hexadimethrine, Alcian Blue, Ruthenium Red and Toluidine Blue. Blocking ws not achieved with Alcian Blue at about pH 1. The staining was also abolished after mild methylation and demethylation restored the contrast. This is suggestive of the involvement of carboxyl groups. Prior digestion with pronase, trypsin and neuraminidase rendered the laminae rarae negative, whereas hyaluronidase, chondroitinase ABC and crude heparinase were without effect. This indicates that sialic acid groups are detected by this method and that heparan sulphate does not interfere. The staining of the epithelial plasma membrane, also carrying sialic acid groups, remained positive after neuraminidase treatment. It is presumed that this method can be applied successfully for detecting changes in the sialic acid content of the laminae rarae in rat glomerular basement membranes under normal and pathological conditions.     

2-alpha-(N-dansyl-4-aminophenylthio)-N-acetyl-9-O-acetylneuraminic acid. A new specific and highly sensitive substrate in sialate-O-acetylesterase assay.

2-alpha-(N-Dansyl-4-aminophenylthio)-N-acetyl-9-O-acetylneuraminic acid (10) was prepared as a new specific and highly sensitively detectable sialate-9-O-acetyl-esterase substrate. It is built up from a sialidase-stable aminophenyl-alpha-thioketoside of N-acetylneuraminic acid. By labeling this thioketoside with dansyl chloride a fluorescent neuraminic acid derivative was prepared which allows determinations down to the picomol range. Regioselective acetylation with trimethylorthoacetate results in the corresponding 9-O-acetyl derivative. After incubation with esterase from bovine brain the hydrolysis products were separated on a HPLC column and fluorimetrically detected at 334 nm excitation and 564 nm emission. The Km value of 2.5 mM was in the range between the values of the completely unspecific methylumbelliferyl acetate and the less sensitively detectable N-acetyl-9-O-acetylneuraminic acid which have been used up to now as standard substrates.     

A wavelength dependent mechanism for rose bengal-sensitized photoinhibition of red cell acetylcholinesterase

A 2-fold enhancement in the efficiency of rose bengal-photosensitized inhibition of red cell acetylcholinesterase activity was observed upon excitation of the dye in the ultraviolet (UV) (313 nm) compared to irradiation in the visible (514 or 550 nm). The measurements of efficiency of photosensitized enzyme inhibition were based on the effect produced when the same number of photons are absorbed by rose bengal (RB) at each wavelength. The mechanism for this unexpected enhancement of RB photosensitization upon UV excitation was investigated. The yield of singlet oxygen (O2(1 delta g], detected by time-resolved luminescence at 1270 nm, was independent of excitation wavelength for RB. Radicals were produced upon irradiation of RB at 313 nm but not at 514 nm as detected by bleaching of N,N-dimethylnitrosoaniline (RNO). Irradiation of RB at 313 nm but not at 514 nm appeared to cause homolytic cleavage of carbon-iodine bonds in the dye because iodine radicals, I, detected as I2 were produced with a quantum yield of 0.0041 +/- 0.0005 upon excitation in the UV. Photolysis of I2 in the presence of RNO caused bleaching of the RNO absorption at 440 nm, apparently resulting from reaction of I with RNO. Thus, the enhanced photosensitization upon UV excitation of RB is attributed to formation of I and/or RB. These results indicate that radicals, produced with low relative yield but having high reactivity compared to O2(1 delta g), can contribute to photosensitized enzyme inhibition and may represent an alternative mechanism for photodynamic therapy.     

Simple fluorimetric method for quantification of sialic acids in glycoproteins

A simple and rapid fluorimetric method was developed for detection and quantitative analysis of sialic acids in glycoproteins. Sialic acid residues in glycoproteins were specifically oxidized with periodate at 0 degrees C for 45 min. Formaldehyde generated from carbon 9 (C-9) of sialic acid was converted specifically to fluorescent dihydropyridine derivative with acetoacetanilide and ammonia at room temperature for 10 min. The reaction products indicate intense fluorescence with excitation and emission maxima at 388 and 471 nm, respectively. When the reaction was conducted in approximately a 1-ml volume, the linearity of the calibration exhibited between 2 and 180 microg of bovine fetuin, or between 0.3 and 27 nmol of N-acetylneuraminic acid, as a model glycoprotein. The limit of detection, based on three times the standard deviation of the reagent blank, was 0.5 microg of fetuin. The proposed method was applied to determination of sialic acids in various glycoprotein samples. This proposed method is simple and obviates the heating and extraction steps. It is highly specific to sialic acids in glycoproteins and indicates no fluorescence of neutral glycoproteins.     

Dual-photon excitation of albumin

Fluorescence emission after two-photon excitation at 580 nm is observed in albumin by means of Nd:YAG laser at room temperature. The two-photon excitation spectral range 550-590 nm was obtained. The experimental results show that albumin fluorescence originates from tryptophan residues.     

A spectrophotometric assay for trans-cinnamic acid 4-hydroxylase activity.

trans-Cinnamic acid 4-hydroxylase (trans-cinnamic acid, NADPH: oxygen oxidoreductase [4-hydroxylating]) can be rapidly and precisely assayed by the spectrophotometric measurement of the production of 4-hydroxy-trans-cinnamic acid at 340 nm after acidification of the reaction mixture and subsequent readjustment to pH 11. For the assay of crude extracts and other preparations with high intrinsic absorption at 340 nm, the assay can be modified by extraction of the 4-hydroxy-trans-cinnamic acid from the acidified assay mixture through diethyl ether into alkali before spectrophotometric estimation. trans-Cinnamic acid 2-hydroxylase can be routinely detected and assayed in the same extract.     

Long-wavelength fluorescence of tyrosine and tryptophan solutions

We report in this paper the presence of fluorescence bands of tryptophan and tyrosine solutions centered above 550 nm. This long-wavelength fluorescence is of much lower intensity, (0.4-2.7)%, than the UV fluorescence of these aromatic aminoacids. The basic characteristic of these fluorescence bands are: (a) tyrosine: lambda em = 600 nm with two excitation peaks centered at 453 nm and 550 nm (b) tryptophan: lambda em = 675 nm with two excitation peaks centered at 455 and 560 nm. It has been found that irradiation of tyrosine solutions with a potent UV lamp promotes an important increase of absorption at 310 nm and above 400 nm.     

Sialic acid concentrations in plants are in the range of inadvertent contamination

The long held but challenged view that plants do not synthesize sialic acids was re-evaluated using two different procedures to isolate putative sialic acid containing material from plant tissues and cells. The extracts were reacted with 1,2-diamino-4,5-methylene dioxybenzene and the fluorescently labelled 2-keto sugar acids analysed by reversed phase and normal phase HPLC and by HPLC–electrospray tandem mass spectrometry. No N-glycolylneuraminic acid was found in the protein fraction from Arabidopsis thaliana MM2d cells. However, we did detect 3-deoxy-d-manno-octulosonic acid and trace amounts (3–18 pmol/g fresh weight) of a compound indistinguishable from N-acetylneuraminic acid by its retention time and its mass spectral fragmentation pattern. Thus, plant cells and tissues contain five orders of magnitude less sialic acid than mammalian tissues such as porcine liver. Similar or lower amounts of N-acetylneuraminic acid were detected in tobacco cells, mung bean sprouts, apple and banana. Yet even yeast and buffer blanks, when subjected to the same isolation procedures, apparently contained the equivalent of 5 pmol of sialic acid per gram of material. Thus, we conclude that it is not possible to demonstrate unequivocally that plants synthesize sialic acids because the amounts of these sugars detected in plant cells and tissues are so small that they may originate from extraneous contaminants.     

Visual behaviour of the greenhouse whitefly, Trialeurodes vaporariorum

ABSTRACT. The behaviour of Trialeurodes vaporariorum (Westwood) (Homoptera, Aleyrodidae) in violet and green light (400 and 550 nm) was examined using several responses. Under 400 nm the whiteflies took-off more readily and walked faster than under 500 nm. In flight, they oriented towards 400 nm when simultaneously illuminated with equal quanta of 550 and 400 nm light. The ecological significance of this behaviour is discussed, and it is concluded that in nature flying adults would orient towards the sky (i.e. c. 400 nm) but would tend to land on a green plant because plants reflect maximally at 550 nm. Once landed on a suitable food-plant the position on that plant where the insect finally feeds and reproduces is probably also determined by visual stimuli, since whiteflies will walk to the shaded side of a leaf regardless of whether that is below or above.     

Selective synthesis and labeling of the polysialic acid capsule in Escherichia coli K1 strains with mutations in nanA and neuB.

The enzymes required for polysialic acid capsule synthesis in Escherichia coli K1 are encoded by region 2 neu genes of the multigenic kps cluster. To facilitate analysis of capsule synthesis and translocation, an E. coli K1 strain with mutations in nanA and neuB, affecting sialic acid degradation and synthesis, respectively, was constructed by transduction. The acapsular phenotype of the mutant was corrected in vivo by exogenous addition of sialic acid. By blocking sialic acid degradation, the nanA mutation allows intracellular metabolite accumulation, while the neuB mutation prevents dilution by the endogenous sialic acid pool and allows capsule synthesis to be controlled experimentally by the exogenous addition of sialic acid to the growth medium. Complementation was detected by bacteriophage K1F adsorption or infectivity assays. Polysialic acid translocation was observed within 2 min after addition of sialic acid to the growth medium, demonstrating the rapidity in vivo of sialic acid transport, activation, and polymerization and translocation of polysaccharide to the cell surface. Phage adsorption was not inhibited by chloramphenicol, demonstrating that de novo protein synthesis was not required for polysialic acid synthesis or translocation at 37 degrees C. Exogenous radiolabeled sialic acid was incorporated exclusively into capsular polysaccharide. The polymeric nature of the labeled capsular material was confirmed by gel permeation chromatography and susceptibility of sialyl polymers to K1F endo-N-acylneuraminidase. The ability to experimentally manipulate capsule expression provides new approaches for investigating polysialic acid synthesis and membrane translocation mechanisms.