The primary virulence factors of many pathogenic bacteria are secreted protein toxins which bind to glycolipid receptors on host cell surfaces. The binding specificities of three such toxins for different glycolipids, mainly from the ganglioside series, were determined by surface plasmon resonance (SPR) using a liposome capture method. Unlike microtiter plate and thin layer chromatography overlay assays, the SPR/liposome methodology allows for real time analysis of toxin binding under conditions that mimic the natural cell surface venue of these interactions and without any requirement for labeling of toxin or receptor. Compared to conventional assays, the liposome technique showed more restricted oligosaccharide specificities for toxin binding. Cholera toxin demonstrated an absolute requirement for terminal galactose and internal sialic acid residues (as in G M1 ) with tolerance for substitution with a second internal sialic acid (as in G D1b ). Escherichia coli heat-labile enterotoxin bound to G M1 and tolerated removal or extension of the internal sialic acid residue (as in asialo-G M1 and G D1b , respectively) but not substitution of the terminal galactose of G M1 . Tetanus toxin showed a requirement for two internal sialic acid residues as in G D1b . Extension of terminal galactose with a single sialic acid was tolerated to some extent. The SPR analyses also yielded rate and affinity constants which are not attainable by conventional assays. Complex binding profiles were observed in that the association and dissociation rate constants varied with toxin:receptor ratios. The sub-nanomolar affinities of cholera toxin and heat-labile enterotoxin for liposome-anchored gangliosides were attributable largely to very slow dissociation rate constants. The SPR/liposome technology should have general applicability in the study of glycolipid-protein interactions and in the evaluation of reagents designed to interfere with these interactions.The protein toxins produced by many pathogenic bacteria are among the best characterized virulence factors. These toxins typically bind to oligosaccharide receptors on host cell surfaces (1). Many belong to the AB 5 family of toxins which are comprised of an enzymatically active and toxic A-subunit and five B-subunits which form the receptor binding portion of the molecule. In most instances the five B-subunits are identical and allow for pentameric attachment to the cell surface receptors. Crystal structures of five AB 5 toxins or their B-pentamers, three complexed with carbohydrate receptors, have been reported. These are cholera toxin (2, 3), Escherichia coli heatlabile toxin (4 -6), shiga toxin (7), shiga-like toxin (8), and pertussis toxin (9). However, this wealth of structural data has not answered all questions relating to the oligosaccharide-binding specificities of these molecules. For example, there is some controversy as to the nature of the functional receptor of LT. Although structurally very similar to CT, LT shows subtle differences in receptor binding specificity (1...
High-resolution structures reveal how a germline antibody can recognize a range of clinically relevant carbohydrate epitopes. The germline response to a carbohydrate immunogen can be critical to survivability, with selection for antibody gene segments that both confer protection against common pathogens and retain the flexibility to adapt to new disease organisms. We show here that antibody S25-2 binds several distinct inner-core epitopes of bacterial lipopolysaccharides (LPSs) by linking an inherited monosaccharide residue binding site with a subset of complementarity-determining regions (CDRs) of limited flexibility positioned to recognize the remainder of an array of different epitopes. This strategy allows germline antibodies to adapt to different epitopes while minimizing entropic penalties associated with the immobilization of labile CDRs upon binding of antigen, and provides insight into the link between the genetic origin of individual CDRs and their respective roles in antigen recognition.
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