Adriana E. Manzi

Sialic acids are a family of 9-carbon carboxylated sugars, where different substitutions of the backbone define over 30 members. Biological roles of these substitutions have been missed until recently because of their low abundance and lability to conventional isolation/purification methods. This new approach characterizes sialic acids using electrospray ionization-mass spectrometry (ESI-MS) to monitor the HPLC separation of their DMB (1,2-diamino-4,5-methylenedioxy-benzene) derivatives (quinoxalinones). A combination of retention times and spectra characteristics allows definition of the type and position of the various substituents. This approach requires no previous purification, involving a simple derivatization reaction followed by direct injection on the microbore HPLC column. A complete spectrum, including molecular ions and CAD fragments of a sialic acid quinoxalinone, is obtained by injecting 10-20 pmol of the compound. Individual quinoxalinones can be purified by regular RP-HPLC and analyzed by direct-injection ESI-MS or LSIMS. Using this approach, we identified 28 different sialic acids, including the following new species: Neu5Gc9Lt (BSM), anhydro derivatives of Neu5Ac other than the 4,8-anhydro (horse serum hydrolyzates), KDN5(7)Ac and KDN5(7),9Ac2 (amphibian Pleurodeles waltl), four isomers of Neu5Gc8MexAc and three anhydro derivatives of Neu5Gc8Me (glycolipids of the starfish Pisaster brevispinus), and Neu5Ac8S (in addition to Neu5Gc8S, in the glycolipids of the sea urchin Lovenia cordiformis). Results show the usefulness of LC-ESI-MS to study sialic acid diversity, and identification of small amounts of unexpected sialic acids or new members of their family.

We and others previously described the melanoma-associated oncofetal glycosphingolipid antigen 9-O-acetyl-GD3, a disialoganglioside O-acetylated at the 9-position of the outer sialic acid residue. We have now developed methods to examine the biosynthesis and turnover of disialogangliosides in cultured melanoma cells and in Golgi-enriched vesicles from these cells. O-Acetylation was selectively expressed on di- and trisialogangliosides, but not on monosialogangliosides, nor on glycoprotein-bound sialic acids. Double-labeling of cells with [3H]acetate and [14C]glucosamine introduced easily detectable labels into each of the components of the ganglioside molecules. Pulse-chase studies of such doubly labeled molecules indicated that the O-acetyl groups turn over faster than the parent molecule. When Golgi-enriched vesicles from these cells were incubated with [acetyl-3H]acetyl-coenzyme A, the major labeled products were disialogangliosides. [Acetyl-3H]O-acetyl groups were found at both the 7- and the 9-positions, indicating that both 7-O-acetyl GD3 and 9-O-acetyl GD3 were synthesized by the action of O-acetyltransferase(s) on endogenous GD3. Analysis of the metabolically labeled molecules confirmed the existence of both 7- and 9-O-acetylated GD3 in the intact cells. Surprisingly, the major 3H-labeled product of the in vitro labeling reaction was not O-acetyl-GD3, but GD3, with the label exclusively in the sialic acid residues. Fragmentation of the labeled sialic acids by enzymatic and chemical methods showed that the 3H-label was exclusively in [3H]N-acetyl groups. Analyses of the double-labeled sialic acids from intact cells also showed that the 3H-label from [3H]acetate was exclusively in the form of [3H]N-acetyl groups, whereas the 14C-label was at the 4-position. Pulse-chase analysis of the 3H/14C ratio showed that the N-acetyl groups of both GD3 and of the monosialoganglioside GM3 were turning over faster than the parent molecules. Selective periodate oxidation showed that both the inner and outer sialic acid residues of GD3 incorporated 3H-label in the in vitro reaction, and showed similar turnover of N-acetylation in the pulse-chase study. Taken together, these results indicate that both the O- and N-acetyl groups of the sialic acid residues of gangliosides turn over faster than the parent molecules. They also demonstrate a novel re-N-acetylation reaction that predicts the existence of de-N-acetyl gangliosides in melanoma cells.

Polysialic acid (PSA) is an unusual homopolymer of sialic acid (Sia) found on a limited number of animal glycoproteins and in the capsules of certain pathogenic bacteria. The biological properties of PSA are known to vary markedly with the length of the polymer. We confirm here that while the primary linkage unit of PSA (Sia alpha 2-8Sia) is more stable than commoner Sia linkages, PSA with > 3 Sia units is substantially more labile. A "limit digest" of PSA yields fragments of degree of polymerization (DP) = 2 and 3 and little monomeric Sia. In keeping with this, the fragmentation of PSA of DP 4 is non-random, with the internal glycosidic bond being more labile than those at the two ends. The accelerated breakdown of PSA involves an intramolecular mechanism that is not explained by lactone formation, cation effects, or specific secondary structural features. However, it is dependent upon the intactness of internal carboxyl groups, which have an anomalously high pKa. Thus, the instability of PSA appears to result from intramolecular self-cleavage of the glycosidic bonds of internal Sia units, in which the adjacent carboxyl group with a high pKa acts as a proton donor for general acid catalysis. This lability of PSA is seen under mildly acidic conditions that can be encountered in various physiological and pathological situations and thus has potential implications for neuronal adhesion, embryogenesis, and bacterial pathogenicity.

We have shown previously that Golgi-enriched vesicles from the human melanoma cell line Melur can transfer [3H]acetate from [acetyl-3H]acetyl-CoA to endogenous GD3 to form [acetyl-3H]O-acetyl-GD3 (Manzi, A. E., Sjoberg, E. R., Diaz, S., and Varki, A. (1990) J. Biol. Chem. 265, 13091-13103). Applying the same approach in the human melanoma cell line M21, label was found in [acetyl-3H]O-acetyl-GD3 and also in a species co-migrating with unsubstituted GD3 on TLC. Both were sialidase-sensitive and alkali-labile, indicating incorporation as [3H]O-acetyl esters on sialic acids. Immunological reactivity, sialidase sensitivity, chromatographic behavior, and the known ganglioside pattern of M21 cells suggested that the slower migrating species might be [acetyl-3H]O-acetyl-GD2. Sialic acids released from this labeled molecule by sialidase showed esterification with [3H]acetate at both C7 and C9 hydroxyls. Lipid extracts from cells metabolically labeled with [3H]galactose showed a corresponding ganglioside, which upon alkali treatment yielded a species migrating with GD2. Analysis of purified ganglioside by high performance thin layer chromatography immuno-overlays, fast atom bombardment-mass spectrometry in positive and negative ion modes, periodate oxidation resistance, linkage analysis by permethylation and gas chromatography-mass spectrometry, and 500 MHz 1H NMR was consistent with the following structure: 9-O Ac-Neu5Ac alpha 2-8Neu5Ac alpha 2-3(GalNAc beta 1-4) Gal beta 1-4Gluc beta 1-1' ceramide Total gangliosides from M21 were analyzed by high performance thin layer chromatography immuno-overlay with monoclonal antibodies D1.1, JONES, 27A, and 8A2, all known to, or suspected of reacting with 9-O-acetylated gangliosides. The first three bound well to 9-O-acetyl-GD3 and a slower migrating 9-O-acetylated ganglioside, which was distinct from 9-O-acetyl-GD2. Antibody 8A2 reacted weakly with purified 9-O-acetyl-GD2 and strongly with two other 9-O-acetylated gangliosides migrating slower than 9-O-acetyl-GD2. Thus, the family of O-acetylated gangliosides in melanoma cells is much more complex than previously appreciated.