A novel capsid protein network allows the characteristic inner membrane structure of Marseilleviridae giant viruses

Marseilleviridae is a family of the new order of giant viruses, which exhibit a characteristic inner membrane. Here, we investigated the entire structure of tokyovirus, a species of Marseillevirus at 7.7 Å resolution using 1 MV high-voltage cryo-EM and single particle analysis. The minor capsid lattice formed by five proteins, shows a novel structure compared to other icosahedral giant viruses. Under the minor capsid proteins, scaffold proteins connect two five-fold vertices and interact with the inner membrane. Previously reported giant viruses utilise “tape measure” proteins, proposed to control its capsid size, which could not be identified in tokyovirus, but scaffold proteins appear to perform a similar role. A density on top of the major capsid protein was identified, which suggested to be a 14kDa glycoprotein. Our observations suggest that the icosahedral particle of Marseilleviridae is constructed with a novel capsid protein network, which allows the characteristic inner membrane structure.

Antigenic and Cryo-Electron Microscopy Structure Analysis of a Chimeric Sapovirus Capsid

ABSTRACTThe capsid protein (VP1) of all caliciviruses forms an icosahedral particle with two principal domains, shell (S) and protruding (P) domains, which are connected via a flexible hinge region. The S domain forms a scaffold surrounding the nucleic acid, while the P domains form a homodimer that interacts with receptors. The P domain is further subdivided into two subdomains, termed P1 and P2. The P2 subdomain is likely an insertion in the P1 subdomain; consequently, the P domain is divided into the P1-1, P2, and P1-2 subdomains. In order to investigate capsid antigenicity, N-terminal (N-term)/S/P1-1 and P2/P1-2 were switched between two sapovirus genotypes GI.1 and GI.5. The chimeric VP1 constructs were expressed in insect cells and were shown to self-assemble into virus-like particles (VLPs) morphologically similar to the parental VLPs. Interestingly, the chimeric VLPs had higher levels of cross-reactivities to heterogeneous antisera than the parental VLPs. In order to better understand the antigenicity from a structural perspective, we determined an intermediate-resolution (8.5-Å) cryo-electron microscopy (cryo-EM) structure of a chimeric VLP and developed a VP1 homology model. The cryo-EM structure revealed that the P domain dimers were raised slightly (∼5 Å) above the S domain. The VP1 homology model allowed us predict the S domain (67–229) and P1-1 (229–280), P2 (281–447), and P1-2 (448–567) subdomains. Our results suggested that the raised P dimers might expose immunoreactive S/P1-1 subdomain epitopes. Consequently, the higher levels of cross-reactivities with the chimeric VLPs resulted from a combination of GI.1 and GI.5 epitopes.IMPORTANCEWe developed sapovirus chimeric VP1 constructs and produced the chimeric VLPs in insect cells. We found that both chimeric VLPs had a higher level of cross-reactivity against heterogeneous VLP antisera than the parental VLPs. The cryo-EM structure of one chimeric VLP (Yokote/Mc114) was solved to 8.5-Å resolution. A homology model of the VP1 indicated for the first time the putative S and P (P1-1, P2, and P1-2) domains. The overall structure of Yokote/Mc114 contained features common among other caliciviruses. We showed that the P2 subdomain was mainly involved in the homodimeric interface, whereas a large gap between the P1 subdomains had fewer interactions.

Synthesis and Mechanical Properties of Conventionally Cast Icosahedral Particle-Reinforced Al-Mn(-Cu)-Be-Si Alloys

The microstructure of the Al-Mn(-Cu)-Be-Si alloys analyzed by X-ray diffraction and TEM consisted of icosahedral (i) quasicrystal particles embedded in aAl matrix. The conjoint addition of Si and Be elements enabled the i-phase formation in Æ10 mm specimens prepared by conventional casting technique. The size, volume fraction and stability of the i-phase were found to be dependent on the Mn content. The addition of 2 at.% Cu did not affect the formation and stability of the i-phase but contributed significantly to the enhancement of the mechanical properties.

Nodavirus Coat Protein Imposes Dodecahedral RNA Structure Independent of Nucleotide Sequence and Length

ABSTRACT The nodavirus Flock house virus (FHV) has a bipartite, positive-sense RNA genome that is packaged into an icosahedral particle displaying T=3 symmetry. The high-resolution X-ray structure of FHV has shown that 10 bp of well-ordered, double-stranded RNA are located at each of the 30 twofold axes of the virion, but it is not known which portions of the genome form these duplex regions. The regular distribution of double-stranded RNA in the interior of the virus particle indicates that large regions of the encapsidated genome are engaged in secondary structure interactions. Moreover, the RNA is restricted to a topology that is unlikely to exist during translation or replication. We used electron cryomicroscopy and image reconstruction to determine the structure of four types of FHV particles that differed in RNA and protein content. RNA-capsid interactions were primarily mediated via the N and C termini, which are essential for RNA recognition and particle assembly. A substantial fraction of the packaged nucleic acid, either viral or heterologous, was organized as a dodecahedral cage of duplex RNA. The similarity in tertiary structure suggests that RNA folding is independent of sequence and length. Computational modeling indicated that RNA duplex formation involves both short-range and long-range interactions. We propose that the capsid protein is able to exploit the plasticity of the RNA secondary structures, capturing those that are compatible with the geometry of the dodecahedral cage.

Structure Determination of Echovirus 1

The atomic structure of echovirus 1 (a member of the enterovirus genus of the picornavirus family) has been determined using cryo-crystallography and refined to 3.55 Å resolution. Echovirus 1 crystallizes in space group P22121 with a = 352.45, b = 472.15 and c = 483.20 Å. The crystals contain one full virus particle in the asymmetric unit allowing for 60-fold noncrystallographic symmetry averaging. The diffraction pattern shows strong pseudo-B-centering with reflections with h + l = 2n + 1 being systematically weak or absent below about 6 Å resolution. The size of the unit cell and presence of pseudo-B-centering placed strong constraints on the allowed packing of the icosahedral particle in the crystal lattice. These constraints greatly facilitated the determination of the orientation and position of the virus by reducing the dimensionality of the search, but interactions between the crystallographic and noncrystallographic symmetries rendered the choice of space group ambiguous until very late in the structure determination. This structure determination provides a striking example of the power of packing analysis in molecular replacement and illustrates how subtle interactions between crystallographic and noncrystallographic symmetries can be resolved.

Proteolytic Control of Bacteriophage HK97 Capsid Maturation.

HK97 is a tailed temperate bacteriophage of E. coli that builds an icosahedral capsid using steps that include regulated assembly, proteolysis, radical conformational changes and the formation of novel covalent bonds (Fig. 1). This pathway is being exploited as a model system to explore how the formation of multiprotein complexes can be regulated by each of these mechanisms. We have identified and purified at least four intermediates (Prohead I, Prohead II, Head I and Head II) and examined them by cryo-electron microscopy and three dimensional reconstruction procedures (Fig. 2). Comparison of particle reconstructions at resolution of about 25 - 30 A have lead to major insights into the causes and purposes of the regulated changes that we have also characterized biochemically and genetically.Prohead I consists of 420 copies of the 42 kDa gp5 capsid protein arranged as 72 blister-shaped morphological capsomers in a thick walled hollow T=7 icosahedral particle with a diameter of -470 Å.