A DENV-2-type-specific monoclonal antibody binds to the DENV-complex-reactive antigenic site on envelope protein domain 3.

The Dengue virus (DENV) envelope (E) protein is the major component of the viral surface and is structurally subdivided into three domains, ED1, ED2 and ED3. ED3 elicits potent neutralizing antibodies and contains two major antigenic sites: the DENV-type-specific and DENV-complex-reactive antigenic sites. Each site is composed of a limited subset of residues that are required for monoclonal antibody (mAb) binding. Here we show that DENV-2-type-specific mAb 9A3D-8 utilizes the functionally critical residues K307, V308, K310, I312, P332, L387, L389 and N390 for ED3 binding. Surprisingly, this DENV-type-specific epitope is predicted to overlap with the ED3 DENV-complex-reactive antigenic site on the viral surface. Further, this unique binding site enables mAb 9A3D-8 to neutralize virus infectivity at relatively low occupancy of virions compared to other ED3 mAbs identified to date. Together, the data in this study indicate that this is a new DENV-2-type-specific antigenic site on ED3.

Functional analysis of dengue virus (DENV) type 2 envelope protein domain 3 type-specific and DENV complex-reactive critical epitope residues.

The dengue virus (DENV) envelope protein domain 3 (ED3) is the target of potent virus neutralizing antibodies. The DENV-2 ED3 contains adjacent type-specific and DENV complex-reactive antigenic sites that are composed of a small number of residues that were previously demonstrated to be critical for antibody binding. Site-directed mutagenesis of a DENV-2 16681 infectious clone was used to mutate critical residues in the DENV-2 type-specific (K305A and P384A) and DENV complex-reactive (K310A) antigenic sites. The K305A mutant virus multiplied like the parent virus in mosquito and mammalian cells, as did the P384A mutant virus, which required a compensatory mutation (G330D) for viability. However, the K310A mutant virus could not be recovered. The DENV-2 type-specific critical residue mutations K305A and P384A+G330D reduced the ability of DENV-2 type-specific, but not DENV complex-reactive, mAbs to neutralize virus infectivity and this was directly correlated with mAb binding affinity to the rED3 mutants.

Conservation of the DENV-2 type-specific and DEN complex-reactive antigenic sites among DENV-2 genotypes.

The envelope (E) protein is composed of three domains (ED1, ED2 and ED3) with ED3 targeted by the most potent neutralizing antibodies. DENV-2 strains can be divided into six genotypes. Comparison of ED3 of representative strains of the six genotypes revealed that there are nine variable residues that are specific to a given genotype. Recombinant ED3s (rED3s) of six different DENV-2 strains representing all nine variable residues were expressed, and their reactivity against a panel of two DENV-2 type-specific and three DENV complex-reactive monoclonal antibodies (mAbs) were compared. The differences in binding affinity to the rED3s representing different DENV-2 genotypes were relatively small, with the exception of type-specific-mAb 3H5 that showed up to 10-fold differences in binding between genotypes. Overall the binding differences did not lead to detectable differences in neutralization. Based on these results, DENV-2 ED3-specific neutralizing antibodies will likely be effective against DENV-2 strains from all six genotypes.

Mutations of an antibody binding energy hot spot on domain III of the dengue 2 envelope glycoprotein exploited for neutralization escape.

Previous crystallographic studies have identified a total of 11 DENV-2 envelope protein domain III (ED3) residues (K305, F306, K307, V308, V309, K310, I312, Q325, P364, K388, and N390) that interacted, through both side- and main-chain contacts, with the Fab of a dengue virus (DENV) subcomplex-specific neutralizing monoclonal antibody (MAb) 1A1D-2 (Lok et al., 2008). Here, we used DENV-2 recombinant ED3 mutants of the MAb 1A1D-2 structural epitope residues to determine the functional epitope of this MAb. The side-chains of residues K307, K310 and I312 were determined to be functionally critical for MAb binding, and thus constitute a hot spot of binding energy for MAb 1A1D-2 on the DENV-2 ED3. Overall, these findings demonstrate that only a subset of the amino acid residue side-chains within the structural epitope of MAb 1A1D-2 define a functional epitope on the DENV-2 ED3 that is essential for MAb binding and neutralization escape.

The genome of epsilon15, a serotype-converting, Group E1 Salmonella enterica-specific bacteriophage.

The genome sequence of the Salmonella enterica serovar Anatum-specific, serotype-converting bacteriophage epsilon15 has been completed. The nonredundant genome contains 39,671 bp and 51 putative genes. It most closely resembles the genome of phiV10, an Escherichia coli O157:H7-specific temperate phage, with which it shares 36 related genes. More distant relatives include the Burkholderia cepacia-specific phage, BcepC6B (8 similar genes), the Bordetella bronchiseptica-specific phage, BPP-1 (8 similar genes) and the Photobacterium profundum prophage, P Pphipr1 (6 similar genes). epsilon15 gene identifications based on homologies with known gene families include the terminase small and large subunits, integrase, endolysin, two holins, two DNA methylase enzymes (one adenine-specific and one cytosine-specific) and a RecT-like enzyme. Genes identified experimentally include those coding for the serotype conversion proteins, the tail fiber, the major capsid protein and the major repressor. epsilon15's attP site and the Salmonella attB site with which it interacts during lysogenization have also been determined.