Molecular basis for dengue virus broad cross-neutralization by humanized monoclonal antibody 513.

Dengue is a widespread viral disease with 3.6 billion people at risk worldwide. Humanized monoclonal antibody (mAb) 513, currently undergoing clinical trials in Singapore, targets an epitope on the envelope protein domain III exposed at the surface of the viral particle. This antibody potently neutralizes all four dengue virus serotypes in a humanized mouse model that recapitulates human dengue infection, without signs of antibody-mediated enhancement of the disease. The crystal structure of single-chain variable fragment (scFv) 513 bound to the envelope protein domain III from dengue virus serotype 4 was used as a template to explore the molecular origins of the broader cross-reactivity and increased in vivo potency of mAb 513, compared to the parent murine mAb 4E11, using molecular dynamics simulations and network analyses. These two methods are a powerful complement to existing structural and binding data and detail specific interactions that underpin the differential binding of the two antibodies. We found that a Glu at position H55 (GluH55) from the second Complementarity Determining Region of the Heavy chain (CDR-H2) which corresponds to Ala in 4E11, is a major contributor to the enhancement in the interactions of mAb 513 compared to 4E11. Importantly, we also validate the importance of GluH55 using site-directed mutagenesis followed by isothermal titration calorimetry measurements.

Corrigendum to "Discovery of novel interacting partners of PSMD9, a proteasomal chaperone: Role of an Atypical and versatile PDZ-domain motif interaction and identification of putative functional modules" [FEBS Open Bio 4 (2014) 571-583].

[This corrects the article DOI: 10.1016/j.fob.2014.05.005.].

Discovery of novel interacting partners of PSMD9, a proteasomal chaperone: Role of an Atypical and versatile PDZ-domain motif interaction and identification of putative functional modules.

PSMD9 (Proteasome Macropain non-ATPase subunit 9), a proteasomal assembly chaperone, harbors an uncharacterized PDZ-like domain. Here we report the identification of five novel interacting partners of PSMD9 and provide the first glimpse at the structure of the PDZ-domain, including the molecular details of the interaction. We based our strategy on two propositions: (a) proteins with conserved C-termini may share common functions and (b) PDZ domains interact with C-terminal residues of proteins. Screening of C-terminal peptides followed by interactions using full-length recombinant proteins, we discovered hnRNPA1 (an RNA binding protein), S14 (a ribosomal protein), CSH1 (a growth hormone), E12 (a transcription factor) and IL6 receptor as novel PSMD9-interacting partners. Through multiple techniques and structural insights, we clearly demonstrate for the first time that human PDZ domain interacts with the predicted Short Linear Sequence Motif (SLIM) at the C-termini of the client proteins. These interactions are also recapitulated in mammalian cells. Together, these results are suggestive of the role of PSMD9 in transcriptional regulation, mRNA processing and editing, hormone and receptor activity and protein translation. Our proof-of-principle experiments endorse a novel and quick method for the identification of putative interacting partners of similar PDZ-domain proteins from the proteome and for discovering novel functions.

Effect of Ser392 phosphorylation on the structure and dynamics of the polybasic domain of ADP ribosylation factor nucleotide site opener protein: a molecular simulation study.

ADP ribosylation factor nucleotide site opener (ARNO) as a guanine nucleotide exchange factor (GEF) activates small GTPases called ADP ribosylation factors (Arfs), which function as molecular switches and regulate a variety of cell biological events. ARNO directly interacts with the transmembrane a2-subunit isoform of the proton-pumping vacuolar ATPase in an acidification-dependent manner, and this interaction plays a crucial role in the regulation of the protein degradation pathway. A recent study reported specific interactions of a2N with the ARNO375-400 peptide corresponding to the polybasic (PB) domain of ARNO, which is a crucial regulatory element in the autoregulation and modulation of Arf-GEF activity. Interestingly, phosphorylation of Ser392 completely abolishes this interaction, and the experimental structure shows significant structural rearrangements. To investigate the effect of Ser392 phosphorylation on the structure and dynamics of the ARNO375-400 peptide, we employed all atom molecular dynamics (MD) simulations of the phosphorylated and unphosphorylated PB domain of the ARNO protein. A Hamiltonian-based replica exchange method called biasing potential replica exchange MD was used to enhance conformational sampling. Simulations predicted that the isolated PB domain is highly flexible, with the C-terminal region of the unphosphorylated state being unstable. In contrast, Ser392 phosphorylation increases the overall stability of the peptide. In agreement with experimental results, our simulations further support the hypothesis that phosphorylation induces disorder to order transitions and provide new insights into the structural dynamics of the PB domain. Phosphorylation of Ser392 appears to stabilize the C-terminal α-helix via formation of salt bridges between phospho-Ser392 and Arg390, Lys395, and Lys396.