Miniaturized affinity chromatography: A powerful technique for the isolation of high affinity GAGs sequences prior to their identification by MALDI-TOF MS.

Glycosaminoglycans (GAGS) are involved in many biological processes through interactions with a variety of proteins, including proteases, growth factors, cytokines, chemokines and adhesion molecules. Identifying druggable GAG-protein interactions for therapeutic purposes is a challenge for the analytical community. In this context, this work investigates the use of a new miniaturized monolithic affinity column (poly(GMA-co-MBA) grafted with antithrombin III (AT III)) to specifically capture and elute high affinity sequences contained in low molecular weight heparin (enoxaparin) for further on-line characterization. This miniaturized, high binding capacity affinity column allows the specific capture of high-affinity oligosaccharide chains from Enoxaparin, even at low concentrations and with a minimal consumption of AT III. In addition to purification, this elution process enables preconcentration for direct analysis by capillary zone electrophoresis. It was found that many of oligosaccharide chains in enoxaparin were eliminated and that certain chain sequences were retained and enriched. Direct coupling with MALDI-TOF MS was successfully used to further characterize the specifically retained oligosaccharides where nano-ESI-TOF MS failed. After optimization of the sample preparation and ionization parameters, direct on-line analysis was performed by applying the elution volume released from the miniaturized affinity column (≤1 µL) directly to the MALDI plate. Finally, this original miniaturized analytical workflow coupling miniaturized AT III-affinity chromatography to MALDI-TOF MS detection is able to select, enrich and detect and identify high affinity sequences (mainly DP4 in size length with a high degree of sulfation) from low molecular weight heparin samples. A more specific selection of GAG sequences can be achieved by increasing the ionic strength during the washing step of affinity chromatography. This is consistent with the known binding pattern between heparin and AT III.

Deciphering dynamic combinatorial libraries of glycoclusters with miniaturized weak affinity chromatography coupled with mass spectrometry (nano-FAC-MS).

We report an original methodology based on affinity chromatography coupled with mass spectrometry to decipher the complexity of dynamic combinatorial libraries (DCLs) of glycoclusters. Such libraries are intended to boost the design of potential therapeutic anti-infectious agents targeting Pseudomonas aeruginosa, which is responsible for numerous diseases, mostly found in hospitals as major a cause of nosocomial infections. Dynamic combinatorial chemistry provides a rapid access to an equilibrating mixture of glycocluster candidates through the formation of reversible covalent bonds under thermodynamic control. Identifying each molecule in the complex mixture overcomes challenges due to the dynamic process. Selection of glycoclusters candidates was first realized on a model lectin (Concanavalin A, ConA). Home-made affinity nanocolumns, containing covalently immobilized ConA and have volumes in the microliter range, were used to separate DCLs of glycoclusters with respect to their specific lectin binding properties under buffered aqueous conditions. Miniaturization facilitates the inline coupling with MS detection in such purely aqueous and buffered conditions and reduces target protein consumption. Monolithic lectin-affinity columns prepared by immobilization of ConA were first characterized using a known ligand. The amount of active binding immobilized lectin is 61 ± 5 pmol on 8.5-cm length column. We demonstrated the ability of our approach to evaluate individual dissociation constants of species directly in the complex mixture. The concept was then successfully applied to the screening of DCLs of more complex glycoclusters to identify (by mass spectrometry) and rank the ligands (by relative breakthrough curve delay) according to their affinity for the immobilized lectin in a single experiment.

Miniaturized antithrombin III affinity monolithic columns coupled to TOF-MS for the selective capture and release of fondaparinux a high affinity antithrombin III ligand.

This work explores the capability of antithrombin III-functionalized capillary monolithic columns (in-line coupled with MS detection) to selectively capture, release and detect high affinity binders of antithrombin III (AT III) from oligosaccharides mixtures. The in-situ characterization of home-made AT III affinity columns was done by frontal affinity chromatography coupled to MS detection using fondaparinux as model ligand. Three different preparation methods of miniaturized antithrombin III monolithic affinity columns were optimized and compared. Immobilization of antithrombin III onto Concanavalin A functionalized column is the simplest method but leads to lowest protein density. The two other methods, direct grafting on aldehyde preactivated monoliths and immobilization of biotinylated antithrombin III to streptavidin-functionalized columns, require the presence of fondaparinux to protect the heparin binding site during the grafting process. Up to 1.3 ± 0.3 pmol cm-1 of antithrombin III were immobilized with both methods. The direct coupling of such miniaturized affinity columns to MS-detection was made possible by optimization of the elution step. Ammonia (0.1 M) was chosen as an efficient and MS compatible solvent to elute fondaparinux. Finally, the complete analytical workflow (capture/elution/detection) was demonstrated to allow the selective capture and elution of fondaparinux initially contained in a complex oligosaccharide mixture with a limit of detection of 1 pmol.