Potent neutralization of staphylococcal enterotoxin B by synergistic action of chimeric antibodies.

Staphylococcal enterotoxin B (SEB), a shock-inducing exotoxin synthesized by Staphylococcus aureus, is an important cause of food poisoning and is a class B bioterrorism agent. SEB mediates antigen-independent activation of a major subset of the T-cell population by cross-linking T-cell receptors (TCRs) with class II major histocompatibility complex (MHC-II) molecules of antigen-presenting cells, resulting in the induction of antigen independent proliferation and cytokine secretion by a significant fraction of the T-cell population. Neutralizing antibodies inhibit SEB-mediated T-cell activation by blocking the toxin's interaction with the TCR or MHC-II and provide protection against the debilitating effects of this superantigen. We derived and searched a set of monoclonal mouse anti-SEB antibodies to identify neutralizing anti-SEB antibodies that bind to different sites on the toxin. A pair of non-cross-reactive, neutralizing anti-SEB monoclonal antibodies (MAbs) was found, and a combination of these antibodies inhibited SEB-induced T-cell proliferation in a synergistic rather than merely additive manner. In order to engineer antibodies more suitable than mouse MAbs for use in humans, the genes encoding the VL and VH gene segments of a synergistically acting pair of mouse MAbs were grafted, respectively, onto genes encoding the constant regions of human Igkappa and human IgG1, transfected into mammalian cells, and used to generate chimeric versions of these antibodies that had affinity and neutralization profiles essentially identical to their mouse counterparts. When tested in cultures of human peripheral blood mononuclear cells or splenocytes derived from HLA-DR3 transgenic mice, the chimeric human-mouse antibodies synergistically neutralized SEB-induced T-cell activation and cytokine production.

Genetic and fluorescence studies of affinity maturation in related antibodies.

Affinity maturation, the process by which an organism's response to infection becomes more specific and more effective over time, occurs after somatic hypermutation of antibody genes in B-cells. This increase in affinity might be a result of the evolution of either specific interactions between antigen and antibody over time (enthalpic factors) or antibody binding site rigidification (entropic factors) or both. Here, monoclonal antibodies, derived from antibodies elicited at different points in the murine immune response after inoculation with the same diketone hapten, have been characterized both genetically and functionally. Though this hapten has previously been shown to produce the catalytic aldolase antibody 38C2, antibodies described here are not catalytic and unlike 38C2, form no covalent enzyme-substrate complex. Thus, they provide a system in which to assess contributions to the evolution of binding affinity. The genes for these non-catalytic antibodies have been sequenced and analyzed both with regard to their relationships to germ line genes, to each other, and to two commercially available catalytic aldolase antibodies. Consequences of particular mutations for antigen binding behavior are discussed. The protein products of these genes have been expressed, purified, and binding properties measured by two complementary techniques: the hapten-induced quenching of the native antibody fluorescence and the changes in the anisotropy of Prodan (6-propionyl-2-(dimethylamino)naphthalene), a fluorescent hapten analogue. Differences in binding affinity are related back to differences in the lengths and amino acid sequences of the complementary determining region 3 (CDR3) binding loop. Taken together with our earlier results on binding site heterogeneity from tryptophan lifetime analysis [Mohan, G.S., Chiu, P.T., Southern, C.A., O'Hara, P.B., 2004. Steady-state and multifrequency phase fluorometry studies of binding site flexibility in related antibodies. J. Phys. Chem. A 108, 7871-7877], affinity appears to be modulated by a combination of entropic and enthalpic factors, and not dominated by one or the other. Because these antibodies are not related to the same germ line gene, however, these results do not provide evidence for the dominance of enthalpy or entropy in evolving binding affinity in this system.