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The cryo-EM structure of immature Zika virus shows partially ordered capsid proteins and reveals differences between pre-epidemic and epidemic strains at protein interfaces within the trimeric spikes. The current Zika virus (ZIKV) epidemic is characterized by severe pathogenicity in both children and adults. Sequence changes in ZIKV since its first isolation are apparent when pre-epidemic strains are compared with those causing the current epidemic. However, the residues that are responsible for ZIKV pathogenicity are largely unknown. Here we report the cryo-electron microscopy (cryo-EM) structure of the immature ZIKV at 9-Å resolution. The cryo-EM map was fitted with the crystal structures of the precursor membrane and envelope glycoproteins and was shown to be similar to the structures of other known immature flaviviruses. However, the immature ZIKV contains a partially ordered capsid protein shell that is less prominent in other immature flaviviruses. Furthermore, six amino acids near the interface between pr domains at the top of the spikes were found to be different between the pre-epidemic and epidemic ZIKV, possibly influencing the composition and structure of the resulting viruses.

Enterovirus D68 (EV-D68) belongs to a group of enteroviruses that contain a single positive-sense RNA genome surrounded by an icosahedral capsid. Like common cold viruses, EV-D68 mainly causes respiratory infections and is acid-labile. The molecular mechanism by which the acid-sensitive EV-D68 virions uncoat and deliver their genome into a host cell is unknown. Using cryoelectron microscopy (cryo-EM), we have determined the structures of the full native virion and an uncoating intermediate [the A (altered) particle] of EV-D68 at 2.2- and 2.7-Å resolution, respectively. These structures showed that acid treatment of EV-D68 leads to particle expansion, externalization of the viral protein VP1 N termini from the capsid interior, and formation of pores around the icosahedral twofold axes through which the viral RNA can exit. Moreover, because of the low stability of EV-D68, cryo-EM analyses of a mixed population of particles at neutral pH and following acid treatment demonstrated the involvement of multiple structural intermediates during virus uncoating. Among these, a previously undescribed state, the expanded 1 (“E1”) particle, shows a majority of internal regions (e.g., the VP1 N termini) to be ordered as in the full native virion. Thus, the E1 particle acts as an intermediate in the transition from full native virions to A particles. Together, the present work delineates the pathway of EV-D68 uncoating and provides the molecular basis for the acid lability of EV-D68 and of the related common cold viruses.

Eastern equine encephalitis virus (EEEV) is a mosquito-transmitted alphavirus that can cause severe encephalitis in humans and horses with a high case fatality rate. There are no licensed EEEV vaccines or therapeutics for human use, warranting the need to better understand the human immune response against EEEV. Here we present a cryo-EM reconstruction of the chimeric virus, Sindbis (SINV)/EEEV, in complex with a potently neutralizing and efficacious intact human IgG1 antibody in a mouse model of infection and disease. This antibody requires bivalency to recognize a quaternary epitope on the E2 glycoprotein and cross-links two virus spikes across the icosahedral two-fold axis through a unique binding mode. Kinetic analysis of the binding interaction provides insights into this distinguishing feature. Mechanistically, the antibody inhibits viral entry into cells through blockade of receptor binding and early fusion events but does not block egress, thereby, exclusively targeting an epitope found on intact virions. The discovery of the quaternary epitope and unique binding mode recognized by this antibody together advance our understanding of the complexity of antibody-antigen interactions and can aid in vaccine design to elicit recognition of distinct epitopes of clinically relevant alphaviruses. Structural analyses of antibody-virus complexes offer critical insights into immune recognition mechanisms. In this report, we present how a patient-derived IgG recognizes a quaternary epitope on EEEV particles through strictly bivalent interactions.

Eastern equine encephalitis virus (EEEV), a mosquito-borne icosahedral alphavirus found mainly in North America, causes human and equine neurotropic infections. EEEV neurovirulence is influenced by the interaction of the viral envelope protein E2 with heparan sulfate (HS) proteoglycans from the host’s plasma membrane during virus entry. Here, we present a 5.8-Å cryoelectron microscopy (cryo-EM) structure of EEEV complexed with the HS analog heparin. “Peripheral” HS binding sites were found to be associated with the base of each of the E2 glycoproteins that form the 60 quasi-threefold spikes (q3) and the 20 sites associated with the icosahedral threefold axes (i3). In addition, there is one HS site at the vertex of each q3 and i3 spike (the “axial” sites). Both the axial and peripheral sites are surrounded by basic residues, suggesting an electrostatic mechanism for HS binding. These residues are highly conserved among EEEV strains, and therefore a change in these residues might be linked to EEEV neurovirulence.

Alphaviruses can cause severe human arthritis and encephalitis. During virus infection, structural changes of viral glycoproteins in the acidified endosome trigger virus–host membrane fusion for delivery of the capsid core and RNA genome into the cytosol to initiate virus translation and replication. However, mechanisms by which E1 and E2 glycoproteins rearrange in this process remain unknown. Here, we investigate prefusion cryoelectron microscopy (cryo-EM) structures of eastern equine encephalitis virus (EEEV) under acidic conditions. With models fitted into the low-pH cryo-EM maps, we suggest that E2 dissociates from E1, accompanied by a rotation (∼60°) of the E2-B domain (E2-B) to expose E1 fusion loops. Cryo-EM reconstructions of EEEV bound to a protective antibody at acidic and neutral pH suggest that stabilization of E2-B prevents dissociation of E2 from E1. These findings reveal conformational changes of the glycoprotein spikes in the acidified host endosome. Stabilization of E2-B may provide a strategy for antiviral agent development.

Zika virus (ZIKV), a mosquito-borne human flavivirus that causes microcephaly and other neurological disorders, has been a recent focus for the development of flavivirus vaccines and therapeutics. We report here a 4.0 Å resolution structure of the mature ZIKV in complex with ADI-30056, a ZIKV-specific human monoclonal antibody (hMAb) isolated from a ZIKV infected donor with a prior dengue virus infection. The structure shows that the hMAb interactions span across the E protein dimers on the virus surface, inhibiting conformational changes required for the formation of infectious fusogenic trimers similar to the hMAb, ZIKV-117. Structure-based functional analysis, and structure and sequence comparisons, identified ZIKV residues essential for neutralization and crucial for the evolution of highly potent E protein crosslinking Abs in ZIKV. Thus, this epitope, ZIKV’s “Achilles heel”, defined by the contacts between ZIKV and ADI-30056, could be a suitable target for the design of therapeutic antibodies.

Nucleobases, purines and pyrimidines, along with their precursors are central to nucleic acid biochemistry, a process essential for all forms of life. Not only do they play a role in metabolism of phospholipids, carbohydrates and glycoproteins, they have a pronounced role in synthesis of secondary metabolites in addition to serving as energy source. In maize (Zea mays), ZmAZG (azaguanine-like transporter family), one of the several nucleobase transporters, plays a major role in ensuring the movement of nucleobases between and within cells and between the organelles and cytoplasm. With an aim to characterize these transporters in Zea mays, this research was conducted. The study focused on identifying the substrate specificity and binding properties of the three putative members of the AZG-like family of Zea mays; ZmAZG1, ZmAZG2 and ZmAZG3. Transgenic yeast cells, deficient in their native nucleobase transporter, were assayed for their ability to uptake a panel of radiolabeled nucleobases to reveal the transport profiles of the heterologously-expressed ZmAZG transporters. The results showed that ZmAZG1 facilitates the transport of uracil, xanthine and hypoxanthine whereas ZmAZG2 and ZMAZG3 transport adenine, guanine, cytosine, hypoxanthine and xanthine. The kinetic properties of AZG-like transporters were further revealed using homologous competition between radiolabeled nucleobase and varying concentrations of same cold competitor, heterologous competition of radiolabeled nucleobase against a concentration series of various cold nucleobases, and heterologous competition between radiolabeled hypoxanthine as a substrate and an array of non-radioactive cold nucleobase competitors. Effects of protonophores and Na+ pump inhibitors on the function of the ZmAZG transporters revealed that they are proton-driven symporters. Moreover, all three ZmAZG transporters continually transported [3H]-hypoxanthine over a period of two hours without reaching a saturation point suggesting their pivotal role in hypoxanthine transport. Additionally, ZmAZG2 complemented the missing azaguanine-like transporter function in a transgenic homozygous double knock-out Arabidopsis mutant Atazg1-1/Atazg1-1, Atazg2-1/Atazg2-1 providing in planta confirmation of being a proton-driven symporter. These findings shed light on the significant role the AZG-like transporters play in maize growth and development.