Novel multifunctional glycan probes to elucidate specificities of diverse glycan recognition systems

Glycan microarrays of sequence-defined glycans are the most widely used approach for high-throughput studies of interactions of glycans with glycan binding proteins. Currently nitrocellulose (NC) coated or N-hydroxysuccinimide (NHS) functionalized glass slides are the two most commonly used surfaces for immobilizing glycan probes as noncovalent and covalent arrays, respectively. The mode of glycan presentation can have an influence on the microarray readouts and is an important consideration in the glycan recognition knowledgebase. Here we present the development of glycan probes, tagged with a novel type of tri-functional Fmoc-amino-azido (FAA) linker, which can be readily converted into lipid-tagged or amino-terminating glycan probes for generating neoglycolipid (NGL)-based noncovalent arrays as well as covalent arrays. The azido functionality in the FAA glycan probes provides a means to ‘light up’ the glycans via biorthogonal ‘Click’ chemistry so that they become ‘scanner-readable’ on the covalent arrays, which represents an advance in array quality control. Here analyses were carried out with a diverse set of 36 glycan binding proteins (GBPs) to compare the performance of 44 glycans presented in a liposomal formulation as noncovalent arrays on NC coated slides and on two types of NHS slides as covalent arrays. With most of anti-glycan antibodies and plant lectins investigated, there were negligible or subtle differences in the binding detected in different arrays. However, there were some striking differences observed between the covalent and noncovalent arrays. These include binding of Lotus Tetragonolobus Lectin (LTL) on the covalent but not the noncovalent arrays, and a clear preference observed for glycans on the noncovalent array in the binding of adhesins (VP1 proteins) of two human polyomaviruses JCPyV and BKPyV, and the human immune lectins Siglecs 7 and 9. Subtle yet significant differences in the binding to low affinity glycan ligands were also observed with three bacterial toxins in different arrays. These results revealed interesting insights into the binding behaviour of different GBPs on the noncovalent and covalent arrays and highlight the importance to consider different array platforms in elucidating glycan mediated interactions. The FAA glycan probes can be readily rendered fluorescent via ‘Click’ chemistry in solution, enabling the detection of GBPs at the surface of cells. ![Figure][1] A new trifunctional linker can present glycans on different array surfaces for analyses of soluble glycan binding proteins or as fluorescent probes for binding by proteins at the surface of cells. ### Competing Interest Statement The authors have declared no competing interest. [1]: pending:yes