Structure of a Dengue Virus Envelope Protein Late-Stage Fusion Intermediate

Klein, Daryl E.; Choi, Jason Lee; Harrison, Stephen C.

doi:10.1128/jvi.02957-12

Cited by 127 publications

(155 citation statements)

References 26 publications

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“…However, the inclusion of Pr-M in subunit vaccines has been questioned, since recent evidence indicates that anti-Pr antibodies can enhance infection by promoting internalization of immature viruses (Dejnirattisai et al, 2010;Rodenhuis-Zybert et al, 2010). Also, the stem and anchor regions of E were shown to affect E expression in the absence of viral infection (Klein et al, 2013).…”

Section: Discussionmentioning

confidence: 99%

Secretion of dengue virus envelope protein ectodomain from mammalian cells is dependent on domain II serotype and affects the immune response upon DNA vaccination

Slon-Campos

Poggianella

Marchese

et al. 2015

Journal of General Virology

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Dengue virus (DENV) is currently among the most important human pathogens and affects millions of people throughout the tropical and subtropical regions of the world. Although it has been a World Health Organization priority for several years, there is still no efficient vaccine available to prevent infection. The envelope glycoprotein (E), exposed on the surface on infective viral particles, is the main target of neutralizing antibodies. For this reason it has been used as the antigen of choice for vaccine development efforts. Here we show a detailed analysis of factors involved in the expression, secretion and folding of E ectodomain from all four DENV serotypes in mammalian cells, and how this affects their ability to induce neutralizing antibody responses in DNA-vaccinated mice. Proper folding of E domain II (DII) is essential for efficient E ectodomain secretion, with DIII playing a significant role in stabilizing soluble dimers. We also show that the level of protein secreted from transfected cells determines the strength and efficiency of antibody responses in the context of DNA vaccination and should be considered a pivotal feature for the development of E-based DNA vaccines against DENV.

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Section: Discussionmentioning

confidence: 99%

Secretion of dengue virus envelope protein ectodomain from mammalian cells is dependent on domain II serotype and affects the immune response upon DNA vaccination

Slon-Campos

Poggianella

Marchese

et al. 2015

Journal of General Virology

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“…The DENV envelope (E) glycoprotein is required for viral binding and entry into cells (8,9). E protein is also the main target of neutralizing antibodies (10).…”

Section: Importancementioning

confidence: 99%

Mapping the Human Memory B Cell and Serum Neutralizing Antibody Responses to Dengue Virus Serotype 4 Infection and Vaccination

Nivarthi

Kose

Sapparapu

et al. 2017

J Virol

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The four dengue virus (DENV) serotypes are mosquito-borne flaviviruses responsible for dengue fever and dengue hemorrhagic fever. People exposed to DENV develop antibodies (Abs) that strongly neutralize the serotype responsible for infection. Historically, infection with DENV serotype 4 (DENV4) has been less common and less studied than infections with the other three serotypes. However, DENV4 has been responsible for recent large and sustained epidemics in Asia and Latin America. The neutralizing antibody responses and the epitopes targeted against DENV4 have not been characterized in human infection. In this study, we mapped and characterized epitopes on DENV4 recognized by neutralizing antibodies in people previously exposed to DENV4 infections or to a live attenuated DENV4 vaccine. To study the fine specificity of DENV4 neutralizing human antibodies, B cells from two people exposed to DENV4 were immortalized and screened to identify DENV-specific clones. Two human monoclonal antibodies (MAbs) that neutralized DENV4 were isolated, and their epitopes were finely mapped using recombinant viruses and alanine scan mutation array techniques. Both antibodies bound to quaternary structure epitopes near the hinge region between envelope protein domain I (EDI) and EDII. In parallel, to characterize the serum neutralizing antibody responses, convalescence-phase serum samples from people previously exposed to primary DENV4 natural infections or a monovalent DENV4 vaccine were analyzed. Natural infection and vaccination also induced serum-neutralizing antibodies that targeted similar epitope domains at the EDI/II hinge region. These studies defined a target of neutralizing antigenic site on DENV4 targeted by human antibodies following natural infection or vaccination.IMPORTANCE The four serotypes of dengue virus are the causative agents of dengue fever and dengue hemorrhagic fever. People exposed to primary DENV infections develop long-term neutralizing antibody responses, but these principally recognize only the infecting serotype. An effective vaccine against dengue should elicit long-lasting protective antibody responses to all four serotypes simultaneously. We and others have defined antigenic sites on the envelope (E) protein of viruses of dengue virus serotypes 1, 2, and 3 targeted by human neutralizing antibodies. The

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“…In crystal structures of dengue virus trimers containing N-terminal portions of the stem, only the first stem residues (up to amino acid 404 [TBEV numbering]) exhibited intra-and intermolecular interactions with DII, whereas the remaining residues were disordered (14). A loop in DIII, however, was in a different conformation in these structures compared to the stemless trimer (14). This may be due to crystallizing of the trimers at different pHs (14) but could also indicate that the presence of the (25,26).…”

mentioning

confidence: 99%

“…H2 has been resolved in the 3.5-Å structure of dengue virus only recently (12). With the exception of the first few amino acids following the C terminus of the E ectodomain (13,14), details of the stem in the context of the postfusion trimer are presently unknown. In X-ray crystallographic analyses of truncated dengue virus sE trimers that included N-terminal portions of the stem, most of the stem parts were disordered (14).…”

mentioning

confidence: 99%

“…With the exception of the first few amino acids following the C terminus of the E ectodomain (13,14), details of the stem in the context of the postfusion trimer are presently unknown. In X-ray crystallographic analyses of truncated dengue virus sE trimers that included N-terminal portions of the stem, most of the stem parts were disordered (14). The objective of our work was to generate experimental evidence for interactions of the stem with the core of the postfusion E trimer.…”

mentioning

confidence: 99%

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The Membrane-Proximal “Stem” Region Increases the Stability of the Flavivirus E Protein Postfusion Trimer and Modulates Its Structure

Stiasny

Kiermayr

Bernhart

et al. 2013

J Virol

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The flavivirus fusion protein E contains a "stem" region which is hypothesized to be crucial for driving fusion. This sequence element connects the ectodomain to the membrane anchor, and its structure in the trimeric postfusion conformation is still poorly defined. Using E trimers of tick-borne encephalitis virus with stem truncations of different lengths, we show that the Nterminal part of the stem increases trimer stability and also modulates the trimer structure outside the stem interaction site. Flaviviruses, members of a genus in the family Flaviviridae, comprise a number of medically relevant viruses, such as dengue virus, yellow fever virus, Japanese encephalitis virus, West Nile virus, and tick-borne encephalitis virus (TBEV) (1). These small enveloped viruses infect cells by receptor-mediated endocytosis and acidic-pH-induced membrane fusion in endosomes (2, 3). The fusion reaction is mediated by the major envelope protein E, a class II fusion protein (4), which contains three domains (DI, DII, and DIII), a membrane-proximal region (the so-called "stem"), and the carboxy-terminal transmembrane anchor (Fig. 1A).The current flavivirus fusion model ( Fig. 1A to C) is based on atomic structures of truncated dimeric prefusion and trimeric postfusion structures of E that lack the stem-anchor region (soluble E [sE]). According to this model, the E dimers dissociate into monomers at acidic pH, leading to the exposure of the fusion peptide (FP) and its insertion into the outer leaflet of the target membrane ( Fig. 1B) (5). Membrane merger has been proposed to be driven by the relocation of DIII and a subsequent "zippering" reaction of the stem along DII, thus yielding a hairpin-like postfusion trimer with the FPs and transmembrane domains at the same end of the molecule ( Fig. 1C; reviewed in references 4 and 6). In accord with this model, soluble forms of DIII containing part of the stem and stem-derived peptides inhibited fusion (7-10).As shown by cryo-electron microscopy (cryo-EM) of dengue virions, the prefusion stem consists of two amphipathic helices (H1 and H3) that lie flat on the viral membrane and flank an additional short perimembrane helix (H2) (11, 12) ( Fig. 1A and D, lower panels). H2 has been resolved in the 3.5-Å structure of dengue virus only recently (12). With the exception of the first few amino acids following the C terminus of the E ectodomain (13,14), details of the stem in the context of the postfusion trimer are presently unknown. In X-ray crystallographic analyses of truncated dengue virus sE trimers that included N-terminal portions of the stem, most of the stem parts were disordered (14). The objective of our work was to generate experimental evidence for interactions of the stem with the core of the postfusion E trimer. For this purpose, we analyzed E trimers of TBEV with different C-terminal truncations using two approaches: (i) we assessed the impact of the presence of the stem as well as parts thereof on the thermostability of E trimers, and (ii) we examined possible influences ...

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Structure of a Dengue Virus Envelope Protein Late-Stage Fusion Intermediate

Cited by 127 publications

References 26 publications

Secretion of dengue virus envelope protein ectodomain from mammalian cells is dependent on domain II serotype and affects the immune response upon DNA vaccination

Secretion of dengue virus envelope protein ectodomain from mammalian cells is dependent on domain II serotype and affects the immune response upon DNA vaccination

Mapping the Human Memory B Cell and Serum Neutralizing Antibody Responses to Dengue Virus Serotype 4 Infection and Vaccination

The Membrane-Proximal “Stem” Region Increases the Stability of the Flavivirus E Protein Postfusion Trimer and Modulates Its Structure

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