Enhancement of toxin- and virus-neutralizing capacity of single-domain antibody fragments by N-glycosylation

Single-domain antibody fragments (VHHs) have several beneficial properties as compared to conventional antibody fragments. However, their small size complicates their toxin- and virus-neutralizing capacity. We isolated 27 VHHs binding Escherichia coli heat-labile toxin and expressed these in Saccharomyces cerevisiae. The most potent neutralizing VHH (LT109) was N-glycosylated, resulting in a large increase in molecular mass. This suggests that N-glycosylation of LT109 improves its neutralizing capacity. Indeed, deglycosylation of LT109 decreased its neutralizing capacity three- to fivefold. We also studied the effect of glycosylation of two previously isolated VHHs on their ability to neutralize foot-and-mouth disease virus. For this purpose, these VHHs that lacked potential N-glycosylation sites were genetically fused to another VHH that was known to be glycosylated. The resulting fusion proteins were also N-glycosylated. They neutralized the virus at at least fourfold-lower VHH concentrations as compared to the single, non-glycosylated VHHs and at at least 50-fold-lower VHH concentrations as compared to their deglycosylated counterparts. Thus, we have shown that N-glycosylation of VHHs contributes to toxin- and virus-neutralizing capacity

Cholera Toxin B Subunits Assemble into Pentamers - Proposition of a Fly-Casting Mechanism

The cholera toxin B pentamer (CtxB5), which belongs to the AB5 toxin family, is used as a model study for protein assembly. The effect of the pH on the reassembly of the toxin was investigated using immunochemical, electrophoretic and spectroscopic methods. Three pH-dependent steps were identified during the toxin reassembly: (i) acquisition of a fully assembly-competent fold by the CtxB monomer, (ii) association of CtxB monomer into oligomers, (iii) acquisition of the native fold by the CtxB pentamer. The results show that CtxB5 and the related heat labile enterotoxin LTB5 have distinct mechanisms of assembly despite sharing high sequence identity (84%) and almost identical atomic structures. The difference can be pinpointed to four histidines which are spread along the protein sequence and may act together. Thus, most of the toxin B amino acids appear negligible for the assembly, raising the possibility that assembly is driven by a small network of amino acids instead of involving all of them

COMPARISON OF THE B-PENTAMERS OF HEAT-LABILE ENTEROTOXIN AND VEROTOXIN-1 - 2 STRUCTURES WITH REMARKABLE SIMILARITY AND DISSIMILARITY

We have compared the B-subunit pentamers of Escherichia coli heat-labile enterotoxin (LT) and verotoxin-1 (VT-1). The B-subunits of these bacterial toxins of the AB5 class have virtually no sequence identity and differ considerably in size (69 amino acids in VT-1 versus 103 in LT). They share a number of functional properties: pentamer formation, association with an A-subunit, binding to carbohydrate-containing lipids, and interaction with membranes. The structures of these proteins are very similar in some respects and very different in others. They can be superimposed with an rms deviation of only 1.29 angstrom on the main chain atoms of 52 amino acids (0.98 angstrom on 47 C(alpha)). Seven out of eight secondary structure elements are retained in the two toxins; only the N-terminal helix of LT is absent in VT-1. A disulfide bridge, which is essential for pentamer formation, is found in both structures, but in slightly different locations. However, the VT-1 B-subunit is much shorter on one side of the toxin, where the proposed membrane binding site of both VT-1 and LT is located. The monomer-monomer interface in the pentamer is much larger in LT than in VT-1, making the LT pentamer more stable. The central pores have a different character, and the sugar binding sites are not conserved between the toxins. The evolutionary relationship of the toxins is discussed