Single molecule studies of antibody-antigen interaction strength versus intra-molecular antigen stability.

We investigated molecular recognition of antibodies to membrane-antigens and extraction of the antigens out of membranes at the single molecule level. Using dynamic force microscopy imaging and enzyme immunoassay, binding of anti-sendai antibodies to sendai-epitopes genetically fused into bacteriorhodopsin molecules from purple membranes were detected under physiological conditions. The antibody/antigen interaction strength of 70-170 pN at loading rates of 2-50 nN/second yielded a barrier width of x = 0.12 nm and a kinetic off-rate (corresponding to the barrier height) of k(off) = 6s(-1), respectively. Bacteriorhodopsin unfolding revealed a characteristic intra-molecular force pattern, in which wild-type and sendai-bacteriorhodopsin molecules were clearly distinguishable in their length distributions, originating from the additional 13 amino acid residues epitope in sendai purple membranes. The inter-molecular antibody/antigen unbinding force was significantly lower than the force required to mechanically extract the binding epitope-containing helix pair out of the membrane and unfold it (126 pN compared to 204 pN at the same loading rate), meeting the expectation that inter-molecular unbinding forces are weaker than intra-molecular unfolding forces responsible for stabilizing native conformations of proteins.

Immuno-atomic force microscopy of purple membrane.

The atomic force microscope is a useful tool for imaging native biological structures at high resolution. In analogy to conventional immunolabeling techniques, we have used antibodies directed against the C-terminus of bacteriorhodopsin to distinguish the cytoplasmic and extracellular surface of purple membrane while imaging in buffer solution. At forces > or = 0.8 nN the antibodies were removed by the scanning stylus and the molecular topography of the cytoplasmic purple membrane surface was revealed. When the stylus was retracted, the scanned membrane area was relabeled with antibodies within 10 min. The extracellular surface of purple membrane was imaged at 0.7 nm resolution, exhibiting a major and a minor protrusion per bacteriorhodopsin monomer. As confirmed by immuno-dot blot analysis and sodium dodecyl sulfate-gel electrophoresis, labeling of the purple membrane was not observed if the C-terminus of bacteriorhodopsin was cleaved off by papain.

Following single antibody binding to purple membranes in real time.

Antibody binding to surface antigens in membranes is the primary event in the specific immune defence of vertebrates. Here we used force microscopy to study the dynamics of antibody recognition of mutant purple membranes from Halobacterium salinarum containing a genetically appended anti-Sendai recognition epitope. Ligation of individual anti-Sendai antibodies to their antigenic epitopes was observed over time. Their increase in number within a small selected area revealed an apparent kinetic on-rate. The membrane-bound antibodies showed many different conformations that ranged from globular to V- and Y-like shapes. The maximum distance of two Fab fragments of the same antibody was observed to be approximately 18 nm, indicating an overall strong intrinsic flexibility of the antibody hinge region. Fab fragments of bound anti-Sendai antibodies were allocated to antigenic sites of the purple membrane, allowing the identification and localization of individual recognition epitopes on the surface of purple membranes.