Fluorescent tagging of free oligosaccharides by reductive amination permits sensitive detection and fractionation of these molecules. To expand the scope of this approach, we have synthesized a fluorescent reagent, 2-amino-(6-amidobiotinyl)pyridine. This reagent can tag oligosaccharides under nondegradative conditions with high efciency. The resulting adducts show excellent fractionation by reversephase HPLC with sensitive detection in the low picomole range. When combined with sequential exoglycosidase digestion, stepwise sequencing of the sugar chains is possible. The biotinyl group can also be used to recover the sugar chain from reaction mixtures. The high-affinity interaction of the biotinyl group with multivalent avidin or streptavidin can be used to create the functional equivalent of neoglycoproteins carrying multiple copies of oligosaccharides of dermed structure. These complexes allow the production of IgG antibodies directed against the oligosaccharide chain. They can also harness the power of (strept)avidin-biotin technology for the detection and isolation of oligosaccharide-specific receptors from native sources of recombinant libraries.Many important biological roles of oligosaccharides involve their interaction with specific receptors (1-4). Discovery and exploration of such interactions require comprehensive structural analyses of oligosaccharides, which necessitate their release and fractionation into structurally distinct species. Critical to the fractionation of oligosaccharides is their sensitive and specific detection. However, detection by UV absorption is neither sensitive nor specific, metabolic labeling (5) has limited applicability, and chemical labeling (6, 7) or pulsed-amperometric detection (8) exposes the sugar chains to strongly basic conditions. Also, the last method requires specialized equipment. Alternatively, free oligosaccharides can be tagged via reductive amination with neutral (9, 10) or acidic (11)(12)(13) (18). This can also harness the well-known power of avidin-biotin technology (19). However, as with neoglycoproteins, the underivatized oligosaccharide or glycopeptide must first be purified to homogeneity, prior to biotin coupling. Another approach to studying oligosaccharide biology is to obtain monospecific antibodies (20-23). However, immune responses to free sugar chains are T-cell-independent, and most antibodies are low-affinity IgMs (23), which are technically difficult to work with and likely to show nonspecific cross-reactivity (22). To obtain high-affinity IgG antibodies, the oligosaccharide must be covalently coupled to carrier proteins (20, 23), i.e., neoglycoproteins. Thus, each current approach to the tagging, fractionation, and biological study of oligosaccharides has its own advantages and limitations. Here, we report a reagent for making fluorescent oligosaccharide adducts that allows a more versatile approach to their subsequent study.
