Synthesis and anti-influenza virus evaluation of triterpene-sialic acid conjugates.

We are interested in new non-natural glycosides with sialic acid conjugates and their biological activities. We report the synthesis of eleven non-natural occurring glycosides, which are triterpene (glycyrrhetinic acid and its derivatives)-sialic acid conjugates, and their inhibitory activities against influenza virus sialidases and influenza virus multiplication in MDCK host cells. Deoxoglycyrrhetol-sialic acid conjugates (6d and 6e) and oleanolic acid-sialic acid conjugates (7d and 7e) showed strong inhibitory activities against three subtypes of influenza virus sialidases. These four compounds (6d, 6e, 7d and 7e) showed clear inhibition to influenza virus multiplication but not to MDCK host cell survival.

Photoaffinity labeling of sialidase with a biotin-conjugated phenylaminodiazirine derivative of 2,3-didehydro-2-deoxy-N-acetylneuraminic acid.

A biotin-conjugated photoactivatable phenylaminodiazirine derivative of 2,3-didehydro-2-deoxy-N-acetylneuraminic acid (DANA) was synthesized to identify sialidase. The free carboxylic group and N-acetyl substituent of sialic acid, which are important for recognition and enzymatic activity of sialidase, were conserved by the photolabeling compound as confirmed using analytical methods. The synthesized compound and DANA competitively inhibited starfish sialidase with a Ki value of 7.6 microM and 4.6 microM, respectively. Photo incorporation of the labeling compound to sialidase increased with irradiation time; 90% photo incorporation was achieved with more than 10-min irradiation, and labeling was completely inhibited by the addition of a competitive inhibitor. Starfish sialidase purified using high-performance gel filtration chromatography was subjected to photoaffinity labeling. A 50-kDa band was revealed to contain the sialidase active site by the photolabeling compound, and labeling was completely hindered in presence of the competitive inhibitor. Labeling specificity was ensured by the addition of the heat-deactivated standard protein chymotrypsinogen A to the reaction mixture.

Identification and characterization of cathepsin D in a highly purified sialidase from starfish A. pectinifera.

A sialidase [EC 3.2.1.18] from the ovary of starfish Asterina pectinifera was isolated and highly purified by preparative PAGE. The SDS-PAGE separation of the purified enzyme revealed two natures of protein bands, upper (50 kDa) and a lower (47 kDa). To identify the protein, N-terminal amino acid sequence of the upper band was done. The sequence matched with the N-terminal amino acid sequence of human lysosomal mature cathepsin D and cathepsin D activity was also found in all the preparation steps. Protease inhibitor pepstatin A inhibited the proteolysis activity of cathepsin D against a synthetic substrate. The two enzymes sialidase and cathepsin D were separated from each other by using high-performance gel-filtration chromatography. The Western blot analysis and isoelectric focusing showed the co-purified cathepsin D is a 50 kDa protein with a PI value of 4.2.

Development of sensitive chemical and immunochemical methods for detecting sulfated sialic acids and their application to glycoconjugates from sea urchin sperm and eggs.

Sulfated sialic acid (SiaS) is a unique sialic acid (Sia) derivative in which an additional anionic group is attached to a carboxylated monosaccharide. Very little is known about the occurrence and biologic function of SiaS, due to the limitations of analytical methods to detect it in minute amounts. In this study, to develop methods and probes for detecting and pursuing the functions of SiaS, we developed sensitive chemical and immunochemical detection methods. First, we synthesized as model compounds 4-methylumbelliferyl glycosides of 8-O- and 9-O-sulfated Sia consisting of N-acetylneuraminic acid (Neu5Ac), N-glycolylneuraminic acid (Neu5Gc), and deaminoneuraminic acid (Kdn). Second, we applied fluorometric high performance liquid chromatography (HPLC) analysis to these synthetic glycosides. After acid hydrolysis of the samples, the liberated SiaS were labeled with a fluorescent reagent, 1,2-diamino-4,5-methylenedioxybenzene, and analyzed on fluorometric HPLC. We established an optimal elution condition for successful separation of 8-O- and 9-O-sulfated Neu5Ac, Neu5Gc, and Kdn on HPLC. Third, we generated a monoclonal antibody (mAb) 2C4 against SiaS using sea urchin egg components as the immunogen. mAb.2C4 recognizes both 8-O-sulfated Neu5Ac (Neu5Ac8S) and Neu5Gc8S, whereas the previously prepared mAb.3G9 only recognizes Neu5Ac8S. Finally, using the fluorometric HPLC and monoclonal antibodies, we demonstrated that glycoconjugates from sea urchin sperm exclusively contained Neu5Ac8S, whereas those from eggs contained Neu5Gc8S. Furthermore, we clarified the quantitative differences in the SiaS content in eggs and sperm from two different species of sea urchins. Immunostaining using mAb.2C4 showed that Neu5Gc8S is localized in the cortical granules in unfertilized eggs, whereas it is localized in the outer surface of the fertilization layer as well as in the inner surface of fertilized eggs. Thus, 8-O-sulfation is dependent on the species, gametic cell-type, site-localization of the eggs, and glycoconjugates.

Anti-influenza virus activity of biflavonoids.

Ginkgetin was found to inhibit the influenza virus sialidase. Ginkgetin-sialic acid conjugates showed a significant survival effect in the influenza-virus-infected mice.

Oral ingestion of mannose alters the expression level of deaminoneuraminic acid (KDN) in mouse organs.

Deaminoneuraminic acid (KDN) is a unique member of the sialic acid family. We previously demonstrated that free KDN is synthesized de novo from mannose as its precursor sugar in trout testis, and that the amount of intracellular KDN increases in mouse B16 melanoma cells cultured in mannose-rich media [Angata et al. (1999) J. Biol. Chem. 274, 22949-56; Angata et al. (1999) Biochem. Biophys. Res. Commun. 261, 326-31]. In the present study, we first demonstrated a mannose-induced increase in intracellular KDN in various cultured mouse and human cell lines. These results led us to examine whether KDN expression in mouse organs is altered by exogenously administered mannose. Under normal feeding conditions, intracellular free KDN was present at very low levels (19-48 pmol/mg protein) in liver, spleen, and lung, and was not detected in kidney or brain. Oral ingestion of mannose, both short-term (90 min) and long-term (2 wk), resulted in an increase of intracellular KDN up to 60-81 pmol/mg protein in spleen and lung and 6.9-18 pmol/mg protein in kidney and brain; however, no change was observed in liver. The level of KDN in organs appears not to be determined only by the KDN 9-phosphate synthase activity, but might also be affected by other enzymes that utilize mannose 6-phosphate as a substrate as well as the enzymes that breakdown KDN, like KDN-pyruvate lyase. In blood, the detectable amount of free KDN did not change on oral ingestion of mannose. These findings indicate that mannose in the diet affects KDN metabolism in various organs, and provide clues to the mechanism of altered KDN expression in some tumor cells and aged organs.

Hypoxic culture induces expression of sialin, a sialic acid transporter, and cancer-associated gangliosides containing non-human sialic acid on human cancer cells.

Tumor hypoxia figures heavily in malignant progression by altering the intracellular glucose metabolism and inducing angiogenic factor production, thus, selecting and expanding more aggressive cancer cell clones. Little is known, however, regarding hypoxia-induced antigenic changes in cancers. We investigated the expression of N-glycolyl sialic acid (NeuGc)-G(M2), a cancer-associated ganglioside containing non-human sialic acid, NeuGc, in human cancers. Cancer tissues prepared from patients with colon cancers frequently expressed NeuGc-G(M2), whereas it was virtually absent in nonmalignant colonic epithelia. Studies on cultured cancer cells indicated that the non-human sialic acid was incorporated from culture medium. Hypoxic culture markedly induced mRNA for a sialic acid transporter, sialin, and this accompanied enhanced incorporation of NeuGc as well as N-acetyl sialic acid. Transfection of cells with sialin gene conferred accelerated sialic acid transport and induced cell surface expression of NeuGc-G(M2). We propose that the preferential expression of NeuGc-G(M2) in cancers is closely associated with tumor hypoxia. Hypoxic culture of tumor cells induces expression of the sialic acid transporter, and enhances the incorporation of non-human sialic acid from the external milieu. A consequence of this is the acquisition of cancer-associated cell surface gangliosides, typically G(M2), containing non-human sialic acid (NeuGc), which is not endogenously synthesized through CMP-N-acetyl sialic acid hydroxylase because humans lack the gene for the synthetic enzyme. As hypoxia is associated with diminished response to radiotherapy and chemotherapy, NeuGc-G(M2) is a potential therapeutic target for hypoxic cancer cells.

Effects of inorganic anions on the activation of acid sialidases.

An acid sialidase partially purified from porcine liver was activated by incubation at 37 degrees C under acidic pH. This activation was dependent on pH, time and temperature, but not inhibited by amastatin, an inhibitor of aminopeptidase A, in contrast to the case of human placental sialidase. The effects of inorganic anions on the two sialidases from porcine liver and from human placenta were investigated. Among the anions tested, halide ions, especially chloride and bromide ions, markedly enhanced the activation of the two sialidases. However, nitrate, sulfate, sulfite and pyrosulfite ions rarely affected the activation of sialidase from porcine liver, while all of them enhanced the activation of human placental sialidase. The activation of the enzyme from porcine liver was depressed at concentrations of greater than 100 mM of sodium chloride, whereas the enzyme from human placenta was held at maximum activation until 1 M sodium chloride. These results suggest the possibility of the participation of enzyme functions different from that of human placental sialidase in the activation process of sialidase.