Chemie und Biologie der Acylneuraminsäuren

Chemical Synthesis of Sialyl N-Glycans and Analysis of Their Recognition by Neuraminidase

The chemical synthesis of a fully sialylated tetraantennary N-glycan has been achieved for the first time by using the diacetyl strategy, in which NHAc is protected as NAc₂ to improve reactivity by preventing intermolecular hydrogen bonds. Another key was the glycosylation to the branched mannose in an ether solvent, which promoted the desired glycosylation by stabilizing the oxocarbenium ion intermediate. Furthermore, high α-selectivity of these glycosylation reactions was realized by utilizing remote participation. Two asymmetrically deuterium labeled sialyl N-glycans were also synthesized by the same strategy. The synthesized N-glycans were used to probe the molecular basis of H1N1 neuraminidase recognition. The asymmetrically deuterated N-glycans revealed a difference in the recognition of sialic acid on each branch. Meanwhile, the tetraantennary N-glycan was used to evaluate the effects of multivalency and steric hinderance by forming branching structures.

Site-specific labelling of the oligosaccharide chains of antibodies

This paper presents a new method for site-specific labelling of antibodies employing enzymatic reactions without oxidizing or reducing agents. IgG was first treated with immobilized sialidase from Clostridium perfringens to cleave bound NeuAc. CMP-9-deoxy-9-salizoyl-NeuAc, an activated sialic acid analogue, was labelled with 131I via the iodogen-method in high yields (> 95%). Then the oligosaccharide chains of antibodies were labelled yield with the radioactive NeuAc analogue by transfer using alpha-2,6-sialyltransferase from rat liver in 50%.

Radioenzymatic determination of CMP-N-acetylsialic acid and free N-acetylsialic acid in biological material

Free N-acetylsialic acid (NeuNAc) and CMP-N-acetylsialic acids (CMP-NeuNAc) are extracted from freeze-clamped or liquid nitrogen-frozen biological material by sequential extraction with cold acetone and acetone/water. [14C]NeuNAc and [14C]CMP-NeuNAc (20,000 dpm each) are added to the frozen material to correct for small losses occurring during the subsequent steps. NeuNAc and CMP-NeuNAc are separated by anion-exchange chromatography. CMP-NeuNAc is hydrolyzed with formic acid and again chromatographed on an ion-exchange column. The NeuNAc-containing fractions (representing free NeuNAc and CMP-NeuNAc) are converted to [14C]CMP-NeuNAc in the presence of [14C]CTP and CMP-NeuNAc synthetase. [14C]CMP-NeuNAc is separated by paper chromatography and the radioactivity measured by liquid scintillation counting. The amount of NeuNAc is calculated from a calibration curve obtained with NeuNAc standards. The small amounts of [14C]NeuNAc and [14C]CMP-NeuNAc added initially do not interfere with the final assay. The method gives reliable values down to 50 pmol/assay, but the sensitivity can be easily increased by a factor of 10. Recoveries, with NeuNAc and CMP-NeuNAc added to biological extracts, were 98.3 and 98.5% for NeuNAc and CMP-NeuNAc, respectively. With this method values of 61.2 +/- 12.8 and 24.4 +/- 5.2 nmol/g wet wt were found in rat liver for free NeuNAc and CMP-NeuNAc, respectively. Values for free NeuNAc found in human blood plasma were 600 +/- 476 and 373 +/- 180 pmol/g plasma for healthy persons and patients with breast cancer, respectively. Free CMP-NeuNAc could not be found in plasma.

Inhibition of in vitro biosynthesis of N-acetylneuraminic acid by N-acyl- and N-alkyl-2-amino-2-deoxyhexoses

The biosynthesis of N-acetylneuraminic acid is markedly inhibited by 2-deoxy-2-propionamido-D-glucose (GlcNProp) and to a much lesser extent by 2-deoxy-2-propionamido-D-mannose (ManNProp), but not by 2-deoxy-2-propionamido-D-galactose and N-methylated derivatives of 2-amino-2-deoxy-D-glucose. 2-Deoxy-2-trimethylamino-D-glucose is a weak inhibitor of 2-acetamido-2-deoxy-D-mannose metabolism. When incubated in a cell-free system from rat liver, GlcNProp gives the 6-phosphate, which is converted into N-propionylneuraminic acid. Evidence is presented which shows that it is the metabolites GlcNProp-6-P and ManNProp-6-P which are the competitive inhibitors, and not GlcNProp itself.

[Elevated serum-sialyltransferase activity in human malignant diseases: a new diagnostic tool? (author's transl)]

Sialyltransferase activity was estimated in serum samples of patients with cancer and controls using immobilized asialo-fetuin as the acceptor and cytidine-5'-monophospho [14C] sialic acid as the donor. The data suggest that increased enzyme activity can be found in more than 80% of the samples from patients with malignant diseases.

[Biology of lectins and their application in clinical biochemistry (author's transl)]

Lectins are proteins or glycoproteins, originally isolated from plant seeds. Characteristics are their ability to bind glycoproteins or glycolipids depending on the carbohydrate residues. The present review describes the structure of the lectins, their binding specificity and their functions with respect to precipitation of glycoproteins, agglutination of cells, transformation of lymphocytes and toxic action. Recently, lectin-analogs have been described in rabbit liver, which are responsible for hepatic uptake of circulating glycoproteins. The regulation of this process is intimately linked to the terminal N-Acetylneuraminic acid (NA-NA). Moreover, its significance is shown during fetal development, oncogenic transformation, immunologic recognition as well as homostasis. Due to the different terminal carbohydrate residues, glycoproteins of adult, fetal or transformed cells can be separated using affinity chromatography. Besides the purification of glycoproteins, lectins are also used for the separation of intact cells. Therefore the use of lectins is recommended for preparative and analytical methods, for the measurements of glycoprotein-turnover and for clinical diagnostics.