Synergic complement-mediated bactericidal activity of monoclonal antibodies with distinct specificity.

The classical complement pathway is triggered when antigen-bound immunoglobulins bind to C1q through their Fc region. While C1q binds to a single Fc with low affinity, a higher avidity stable binding of two or more of C1q globular heads initiates the downstream reactions of the complement cascade ultimately resulting in bacteriolysis. Synergistic bactericidal activity has been demonstrated when monoclonal antibodies recognize nonoverlapping epitopes of the same antigen. The aim of the present work was to investigate the synergistic effect between antibodies directed toward different antigens. To this purpose, we investigated the bactericidal activity induced by combinations of monoclonal antibodies (mAbs) raised against factor H-binding protein (fHbp) and Neisserial Heparin-Binding Antigen (NHBA), two major antigens included in Bexsero, the vaccine against Meningococcus B, for prevention from this devastating disease in infants and adolescents. Collectively, our results show that mAbs recognizing different antigens can synergistically activate complement even when each single Mab is not bactericidal, reinforcing the evidence that cooperative immunity induced by antigen combinations can represent a remarkable added value of multicomponent vaccines. Our study also shows that the synergistic effect of antibodies is modulated by the nature of the respective epitopes, as well as by the antigen density on the bacterial cell surface.

Crystal structure and nuclear magnetic resonance analyses of the SAND domain from glucocorticoid modulatory element binding protein-1 reveals deoxyribonucleic acid and zinc binding regions.

The glucocorticoid-modulatory element-binding proteins, GMEB1 and GMEB2, are ubiquitous, multifunctional DNA-binding proteins with important roles in the modulation of transcription upon steroid hormone activation. The GMEB proteins have intrinsic transactivation ability, but also control the glucocorticoid response via direct binding to the glucocorticoid receptor. They are also mandatory host proteins for Parvovirus replication. Here we present the 1.55 A resolution crystal structure of a central portion of GMEB1, encompassing its SAND domain, which shares 80% sequence identity with the GMEB2 SAND domain. We demonstrate that this domain, also present in numerous proteins implicated in chromatin-associated transcriptional regulation, is necessary and sufficient to bind the glucocorticoid-modulatory element (GME) DNA target. We use nuclear magnetic resonance (NMR) and binding studies to map the DNA recognition surface to an alpha-helical region exposing the conserved KDWK motif. Using site-directed mutagenesis, key residues for DNA binding are identified. In contrast to the previously determined NMR structure of the Sp100b SAND domain, we find that the GMEB1 SAND domain also comprises a zinc-binding motif. Although the zinc ion is not necessary for DNA binding, it is found to determine the C-terminal conformation of the GMEB1 SAND domain. We also show that homologous zinc-binding motifs exist in a subset of SAND domain proteins and probe the roles of this novel motif.