Molecular basis for the acid-initiated uncoating of human enterovirus D68

Liu, Yue; Sheng, Ju; Vliet, Arno L. W. van; Buda, Geeta; Kuppeveld, Frank J. M. van; Rossmann, Michael G.

doi:10.1073/pnas.1803347115

Cited by 36 publications

(59 citation statements)

References 86 publications

(104 reference statements)

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“…Hence, VP4 could contribute to the poorly ordered density on the inside of the capsid close to the vertices, attributed primarily to RNA, as well as to the density spanning the capsid. In corroboration of this finding, the presence of a tiny amount of VP4 was recently reported in A-particles of enterovirus D68 induced by acid treatment (49).…”

Section: Fig 1 Legend (Continued)supporting

confidence: 77%

“…The first modeled residue of the VP1 N terminus (Asn 55) lies in close proximity to the unassigned density near the 2-fold axis inside the particle; therefore, the unassigned density could be the VP1 N termini now traversing the capsid and exposed on the surface of the treated capsid similarly to the interpretation for expanded particles of other enteroviruses (Fig. 6D, red arrows in the inset) (20,26,49). In addition, part of this poorly ordered density seen on the exterior could be attributed to a flexible VP3 loop (residues Thr 175 to Asp 183).…”

Section: Fig 1 Legend (Continued)mentioning

confidence: 73%

“…5D). Interestingly, this RNA-capsid interaction is in proximity to the N terminus of VP1 that appears to be extruded from the treated capsid, similarly to the VP1 in expanded poliovirus, coxsackievirus A16, and enterovirus D68 (20,26,49). VP4 could not be identified in the reconstruction, suggesting that it is no longer icosahedrally ordered or the occupancy is much reduced as suggested also by autoradiography.…”

Section: Discussionmentioning

confidence: 86%

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Extracellular Albumin and Endosomal Ions Prime Enterovirus Particles for Uncoating That Can Be Prevented by Fatty Acid Saturation

Ruokolainen

Domanska

Laajala

et al. 2019

J Virol

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There is limited information about the molecular triggers leading to the uncoating of enteroviruses under physiological conditions. Using real-time spectroscopy and sucrose gradients with radioactively labeled virus, we show at 37°C, the formation of albumin-triggered, metastable uncoating intermediate of echovirus 1 without receptor engagement. This conversion was blocked by saturating the albumin with fatty acids. High potassium but low sodium and calcium concentrations, mimicking the endosomal environment, also induced the formation of a metastable uncoating intermediate of echovirus 1. Together, these factors boosted the formation of the uncoating intermediate, and the infectivity of this intermediate was retained, as judged by end-point titration. Cryo-electron microscopy reconstruction of the virions treated with albumin and high potassium, low sodium, and low calcium concentrations resulted in a 3.6-Å resolution model revealing a fenestrated capsid showing 4% expansion and loss of the pocket factor, similarly to altered (A) particles described for other enteroviruses. The dimer interface between VP2 molecules was opened, the VP1 N termini disordered and most likely externalized. The RNA was clearly visible, anchored to the capsid. The results presented here suggest that extracellular albumin, partially saturated with fatty acids, likely leads to the formation of the infectious uncoating intermediate prior to the engagement with the cellular receptor. In addition, changes in mono- and divalent cations, likely occurring in endosomes, promote capsid opening and genome release. IMPORTANCE There is limited information about the uncoating of enteroviruses under physiological conditions. Here, we focused on physiologically relevant factors that likely contribute to opening of echovirus 1 and other B-group enteroviruses. By combining biochemical and structural data, we show that, before entering cells, extracellular albumin is capable of priming the virus into a metastable yet infectious intermediate state. The ionic changes that are suggested to occur in endosomes can further contribute to uncoating and promote genome release, once the viral particle is endocytosed. Importantly, we provide a detailed high-resolution structure of a virion after treatment with albumin and a preset ion composition, showing pocket factor release, capsid expansion, and fenestration and the clearly visible genome still anchored to the capsid. This study provides valuable information about the physiological factors that contribute to the opening of B group enteroviruses.

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Section: Fig 1 Legend (Continued)supporting

confidence: 77%

Section: Fig 1 Legend (Continued)mentioning

confidence: 73%

Section: Discussionmentioning

confidence: 86%

See 1 more Smart Citation

Extracellular Albumin and Endosomal Ions Prime Enterovirus Particles for Uncoating That Can Be Prevented by Fatty Acid Saturation

Ruokolainen

Domanska

Laajala

et al. 2019

J Virol

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“…It is generally accepted that the interfaces between pentamer subunits are major sites of structural rearrangement during capsid uncoating. For example, studies have widely documented the formation of pores at these interfaces [67][68][69][70][71][72][73] or the loss of one or more pentamer subunit(s) [53,58,74,75] upon exposure of the picornavirus capsid to denaturing conditions. To identify the hotspot residues that are critical to the binding specificity and stability of the pentamer interfaces, complexes of two opposing protomers at the two-fold axis and two adjacent protomers at the three-fold axis were analysed.…”

Section: Discussionmentioning

confidence: 99%

The In Silico Prediction of Hotspot Residues that Contribute to the Structural Stability of Subunit Interfaces of a Picornavirus Capsid

Upfold

Ross

Bishop

et al. 2020

Viruses

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The assembly of picornavirus capsids proceeds through the stepwise oligomerization of capsid protein subunits and depends on interactions between critical residues known as hotspots. Few studies have described the identification of hotspot residues at the protein subunit interfaces of the picornavirus capsid, some of which could represent novel drug targets. Using a combination of accessible web servers for hotspot prediction, we performed a comprehensive bioinformatic analysis of the hotspot residues at the intraprotomer, interprotomer and interpentamer interfaces of the Theiler’s murine encephalomyelitis virus (TMEV) capsid. Significantly, many of the predicted hotspot residues were found to be conserved in representative viruses from different genera, suggesting that the molecular determinants of capsid assembly are conserved across the family. The analysis presented here can be applied to any icosahedral structure and provides a platform for in vitro mutagenesis studies to further investigate the significance of these hotspots in critical stages of the virus life cycle with a view to identify potential targets for antiviral drug design.

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“…Unlike mature native virions (160S particles), whose capsids form a closed surface, the expanded 135S particles have holes in the capsid at the icosahedral 2-fold and quasi-3-fold axes. These openings permit the externalization of the membraneinteractive N-terminal extension of capsid protein VP1 [11,14] in poliovirus and in the 135S particles of other enteroviruses [19][20][21][22][23][24][25][26] and presumably VP4, which is myristoylated [27]. In vitro studies with model membranes have shown that these polypeptide chains are responsible for anchoring the virus to the host cell membrane [11,28].…”

Section: Introductionmentioning

confidence: 99%

Cryo-EM structures reveal two distinct conformational states in a picornavirus cell entry intermediate

et al. 2020

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The virions of enteroviruses such as poliovirus undergo a global conformational change after binding to the cellular receptor, characterized by a 4% expansion, and by the opening of holes at the two and quasi-threefold symmetry axes of the capsid. The resultant particle is called a 135S particle or A-particle and is thought to be on the pathway to a productive infection. Previously published studies have concluded that the membrane-interactive peptides, namely VP4 and the N-terminus of VP1, are irreversibly externalized in the 135S particle. However, using established protocols to produce the 135S particle, and single particle cryo-electron microscopy methods, we have identified at least two unique states that we call the early and late 135S particle. Surprisingly, only in the "late" 135S particles have detectable levels of the VP1 N-terminus been trapped outside the capsid. Moreover, we observe a distinct density inside the capsid that can be accounted for by VP4 that remains associated with the genome. Taken together our results conclusively demonstrate that the 135S particle is not a unique conformation, but rather a family of conformations that could exist simultaneously.

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Molecular basis for the acid-initiated uncoating of human enterovirus D68

Cited by 36 publications

References 86 publications

Extracellular Albumin and Endosomal Ions Prime Enterovirus Particles for Uncoating That Can Be Prevented by Fatty Acid Saturation

Extracellular Albumin and Endosomal Ions Prime Enterovirus Particles for Uncoating That Can Be Prevented by Fatty Acid Saturation

The In Silico Prediction of Hotspot Residues that Contribute to the Structural Stability of Subunit Interfaces of a Picornavirus Capsid

Cryo-EM structures reveal two distinct conformational states in a picornavirus cell entry intermediate

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