Zika virus (ZIKV) is an arthropod-borne enveloped virus belonging to the Flavivirus genus in the family Flaviviridae, which also includes the human pathogenic yellow fever, dengue, West Nile and tick-borne encephalitis viruses 1 . Flaviviruses have two structural glycoproteins, prM and E (for precursor membrane and envelope proteins, respectively), which form a heterodimer in the endoplasmic reticulum (ER) of the infected cell and drive the budding of spiky immature virions into the ER lumen. These particles transit through the cellular secretory pathway, during which the trans-Golgi-resident protease furin cleaves prM. This processing is required for infectivity, and results in the loss of a large fragment of prM and reorganization of E on the virion surface. The mature particles have a smooth aspect, with 90 E dimers organized with icosahedral symmetry in a 'herringbone' pattern 2,3 .Three-dimensional cryo-electron microscopy (cryo-EM) structures of the mature ZIKV particles have recently been reported to near atomic resolution (3.8 Å) 4,5 , showing that the virus has essentially the same organization as the other flaviviruses of known structure, such as dengue virus (DENV) 3 and West Nile virus 6,7 . The E protein is about 500 amino acids long, with the 400 N-terminal residues forming the ectodomain essentially folded as β-sheets with three domains, named I, II and III, aligned in a row with domain I at the centre. The conserved fusion loop is at the distal end of the rod in domain II, buried at the E dimer interface. At the C terminus, the E ectodomain is followed by the 'stem' , featuring two α-helices lying flat on the viral membrane (the stem helices), which link to two C-terminal transmembrane α-helices. The main distinguishing feature of the ZIKV virion is an insertion within a glycosylated loop of E (the '150' loop), which protrudes from the mature virion surface 4,5 .Flaviviruses have been grouped into serocomplexes based on cross-neutralization studies with polyclonal immune sera 8 . The E protein is the main target of neutralizing antibodies, and is also the viral fusogen; cleavage of prM allows E to respond to the endosomal pH by undergoing a large-scale conformational change that catalyses membrane fusion and releases the viral genome into the cyotosol. Loss of the precursor fragment of prM lets the E protein fluctuate from its tight packing at the surface of the virion, transiently exposing otherwise buried surfaces. One surface exposed by this 'breathing' is the fusionloop epitope (FLE), which is a dominant cross-reactive antigenic site 9 . Although antibodies to this site can protect by complement-mediated mechanisms, as shown in a mouse model for West Nile virus 10 , they are poorly neutralizing and lead to antibody-dependent enhancement 11-15 , thereby aggravating Flavivirus pathogenesis and complicating the development of safe and effective vaccines.We recently reported the functional and structural characterization of a panel of antibodies isolated from patients with dengue disease 13,16 . ...
Pentameric ligand-gated ion channels mediate fast chemical transmission of nerve signals. The structure of a bacterial proton-gated homolog has been established in its open and locally closed conformations at acidic pH. Here we report its crystal structure at neutral pH, thereby providing the X-ray structures of the two end-points of the gating mechanism in the same pentameric ligand-gated ion channel. The large structural variability in the neutral pH structure observed in the four copies of the pentamer present in the asymmetric unit has been used to analyze the intrinsic fluctuations in this state, which are found to prefigure the transition to the open state. In the extracellular domain (ECD), a marked quaternary change is observed, involving both a twist and a blooming motion, and the pore in the transmembrane domain (TMD) is closed by an upper bend of helix M2 (as in locally closed form) and a kink of helix M1, both helices no longer interacting across adjacent subunits. On the tertiary level, detachment of inner and outer β sheets in the ECD reshapes two essential cavities at the ECD-ECD and ECD-TMD interfaces. The first one is the ligand-binding cavity; the other is close to a known divalent cation binding site in other pentameric ligand-gated ion channels. In addition, a different crystal form reveals that the locally closed and open conformations coexist as discrete ones at acidic pH. These structural results, together with site-directed mutagenesis, physiological recordings, and coarse-grained modeling, have been integrated to propose a model of the gating transition pathway.X-ray crystallography | allostery | signal transduction | cys-loop receptor P entameric ligand-gated ion channels (pLGICs) are a superfamily of membrane receptors that mediate fast chemical transmission of nerve signals in the central and peripheral nervous system (1). These allosteric receptors couple neurotransmitter (agonist) binding in the extracellular domain (ECD) to the opening of the ionic pore located in the transmembrane domain (TMD). There are two classes in pLGIC, with either cationic channels (acetylcholine -nAChR -and 5HT3 receptors) or anionic ones (glycine and GABA receptors). The molecular understanding of their allosteric transitions is a central issue in the pharmacology of pLGICs, as it would allow the rational design of novel orthosteric and allosteric ligands. Recently reported full-length structures of several prokaryotic and eukaryotic members of the family have provided significant insights into the conserved architecture of these receptors (2-5). Nevertheless, little is known about the structural events that link the binding/unbinding of agonist to the opening/closure of the channel gate. To understand the gating mechanism, the structures of the same receptor in different allosteric states are needed at atomic resolution. Here we report two crystal structures of wildtype GLIC, a proton-gated bacterial ion channel from Gloeobacter violaceus (6) at two different pHs, above and below pH 50 .GLIC structure wa...
2Dengue disease is caused by four different flavivirus 1 serotypes, which infect 390 million people yearly with 25% symptomatic cases 2 and for which no licensed vaccine is available. Recent phase III vaccine trials showed partial protection, and in particular no protection for dengue virus serotype 2 (DENV--2) 3,4 . Structural studies so far have characterized only epitopes recognized by serotype specific human antibodies 5,6 . We recently isolated human antibodies potently neutralizing all four DENV serotypes 7 . Here we describe the X--ray structures of four of these broadly neutralizing antibodies (bnAbs) in complex with the envelope glycoprotein E from DENV--2, revealing that the recognition determinants are at a serotype conserved site at the E dimer interface, including the exposed main chain of the E fusion loop 8 and the two conserved glycan chains.This "E--dimer dependent epitope" (EDE) is also the binding site for the viral glycoprotein prM during virus maturation in the secretory pathway of the infected cell 9 , explaining its conservation across serotypes and highlighting an Achilles heel of the virus with respect to antibody neutralization. These findings will be instrumental for devising novel immunogens to protect simultaneously against all four serotypes of dengue virus.Exposed at the surface of infectious mature DENV particles, protein E is the sole target of neutralizing antibodies. It displays an icosahedral arrangement in which 90 E dimers completely coat the viral surface 10,11 and which is sensitive to the environmental pH. Upon entry of DENV into cells via receptor--mediated endocytosis, the acidic 3 endosomal environment triggers an irreversible fusogenic conformational change in E that leads to fusion of viral and endosomal membranes 1 . The structure of the isolated E dimer has been determined by X--ray crystallography using the soluble ectodomain (sE) 8,12 . Protein E is relatively conserved, displaying about 65% amino acid sequence identity when comparing the most distant DENV serotypes. In particular, there are two conserved N--linked glycosylation sites at positions N67 and N153. To examine its interaction with the antibodies, we selected four highly potent bnAbs identified in the accompanying work: 747(4) A11 and 747 B7 (EDE2 group, requiring glycosylation at position N153 for efficient binding) and 752--2 C8 and 753(3) C10 (EDE1 group, binding regardless of the glycosylation at N153) 7 -referred to as A11, B7, C8 and C10 from hereon. The EDE2 bnAbs were isolated from the same patient (who had a secondary infection with DENV--2), and are somatic variants of the same IgG clone, derived from the IGHV3--74 and IGLV2--23 germ lines. The heavy chain has a very long (26 amino acids, IMGT convention) complementarity--determining region 3 (CDR H3). The EDE1 bnAbs were isolated from different patients and derive from (EDE1 C8, the patient appeared to have a primary infection of undetermined serotype) and IGHV1--3* and IGLV2--14 (EDE1 C10, from a patient with secondary DENV--1 infecti...
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