Jun Tsao

Cryo-EM Model of the Bullet-Shaped Vesicular Stomatitis Virus

VSV in 3D Rhabdoviruses are a family of negative-stranded RNA viruses that includes rabies virus, which have a characteristic bullet shape. Though structures of individual rhabdovirus proteins have been reported, how these are organized into a bullet shape has remained unclear. Now, Ge et al. (p. 689) report a cryo-electron microscopy structure of a model rhabdovirus, vesicular stomatitis virus. The structural data and examination of mutants allows modeling of virion assembly. The structure of a negative-strand RNA virus suggests how bullet-shaped rhabdoviruses assemble. Vesicular stomatitis virus (VSV) is a bullet-shaped rhabdovirus and a model system of negative-strand RNA viruses. Through direct visualization by means of cryo–electron microscopy, we show that each virion contains two nested, left-handed helices: an outer helix of matrix protein M and an inner helix of nucleoprotein N and RNA. M has a hub domain with four contact sites that link to neighboring M and N subunits, providing rigidity by clamping adjacent turns of the nucleocapsid. Side-by-side interactions between neighboring N subunits are critical for the nucleocapsid to form a bullet shape, and structure-based mutagenesis results support this description. Together, our data suggest a mechanism of VSV assembly in which the nucleocapsid spirals from the tip to become the helical trunk, both subsequently framed and rigidified by the M layer.

Crystal Structure of the Cytoskeleton-associated Protein Glycine-rich (CAP-Gly) Domain*

Cytoskeleton-associated proteins (CAPs) are involved in the organization of microtubules and transportation of vesicles and organelles along the cytoskeletal network. A conserved motif, CAP-Gly, has been identified in a number of CAPs, including CLIP-170 and dynactins. The crystal structure of the CAP-Gly domain ofCaenorhabditis elegans F53F4.3 protein, solved by single wavelength sulfur-anomalous phasing, revealed a novel protein fold containing three β-sheets. The most conserved sequence, GKNDG, is located in two consecutive sharp turns on the surface, forming the entrance to a groove. Residues in the groove are highly conserved as measured from the information content of the aligned sequences. The C-terminal tail of another molecule in the crystal is bound in this groove.

Structural studies on the authentic mumps virus nucleocapsid showing uncoiling by the phosphoprotein

Significance In this paper, we reveal several insights into how mumps virus (MuV) replicates its RNA genome. The MuV genomic RNA is packaged by the nucleocapsid protein (N), forming a helical structure called the nucleocapsid. The nucleocapsid is the template for RNA synthesis. MuV genomes cannot be copied unless the viral polymerase (vRdRp) can read the sequestered RNA. The MuV phosphoprotein (P) appears to play a central role in this process. In this paper, we provide the first evidence, to our knowledge, of P inducing the nucleocapsid to uncoil. MuV P uses two separate domains to promote viral RNA synthesis. One domain attaches to the nucleocapsid while the other domain relaxes the helical structure to allow vRdRp to easily read the viral genome. Mumps virus (MuV) is a highly contagious pathogen, and despite extensive vaccination campaigns, outbreaks continue to occur worldwide. The virus has a negative-sense, single-stranded RNA genome that is encapsidated by the nucleocapsid protein (N) to form the nucleocapsid (NC). NC serves as the template for both transcription and replication. In this paper we solved an 18-Å–resolution structure of the authentic MuV NC using cryo-electron microscopy. We also observed the effects of phosphoprotein (P) binding on the MuV NC structure. The N-terminal domain of P (PNTD) has been shown to bind NC and appeared to induce uncoiling of the helical NC. Additionally, we solved a 25-Å–resolution structure of the authentic MuV NC bound with the C-terminal domain of P (PCTD). The location of the encapsidated viral genomic RNA was defined by modeling crystal structures of homologous negative strand RNA virus Ns in NC. Both the N-terminal and C-terminal domains of MuV P bind NC to participate in access to the genomic RNA by the viral RNA-dependent-RNA polymerase. These results provide critical insights on the structure-function of the MuV NC and the structural alterations that occur through its interactions with P.

Access to RNA Encapsidated in the Nucleocapsid of Vesicular Stomatitis Virus

ABSTRACT The genomic RNA of negative-strand RNA viruses, such as vesicular stomatitis virus (VSV), is completely enwrapped by the nucleocapsid protein (N) in every stage of virus infection. During viral transcription/replication, however, the genomic RNA in the nucleocapsid must be accessible by the virus-encoded RNA-dependent RNA polymerase in order to serve as the template for RNA synthesis. With the VSV nucleocapsid and a nucleocapsid-like particle (NLP) produced in Escherichia coli, we have found that the RNA in the VSV nucleocapsid can be removed by RNase A, in contrast to what was previously reported. Removal of the RNA did not disrupt the assembly of the N protein, resulting in an empty capsid. Polyribonucleotides were reencapsidated into the empty NLP, and the crystal structures were determined. The crystal structures revealed variable degrees of association of the N protein with a specific RNA sequence.

Structure determination of monoclinic canine parvovirus

The three-dimensional structure of the single-stranded DNA canine parvovirus has been determined to 3.25 A resolution. Monoclinic crystals belonging to space group P2(1) (a = 263.1, b = 348.9, c = 267.2 A, beta = 90.82 degrees) were selected for data collection using primarily the Cornell High Energy Synchrotron Source and oscillation photography. There was one icosahedral particle per crystallographic asymmetric unit, giving 60-fold redundancy. The particle orientations in the unit cell were determined with a rotation function. The rough positions of the particles in the unit cell were estimated by considering the packing of spheres into the P2(1) crystal cell. More accurate particle centers were determined from Harker peaks in a Patterson function. Hollow-shell models were used to compute phases to 20 A resolution. The radii of the models were based on packing considerations, the fit of spherical shells to the low-resolution X-ray data and low-angle solution scattering data. The phases were extended to 9 A resolution using molecular replacement real-space averaging. These were then used to determine the heavy-atom position of a K2PtBr6 derivative, for which only 5% of the theoretically observable reflections had been recorded. The center of gravity of the 60 independent heavy-atom sites gave an improved particle center position. Single isomorphous replacement phases to 8 A resolution were then calculated with the platinum derivative. These were used to initiate phase improvement and extension to 3.25 A resolution using density averaging and Fourier back-transformation in steps of one reciprocal lattice point at a time. The resulting electron density map was readily interpretable and an atomic model was built into the electron density map on a PS390 graphics system using the FRODO program. The R factor prior to structure refinement for data between 5.0 and 3.25 A was 36%.

Ab Initio Phase Determination for Viruses with High Symmetry: a Feasibility Study

Conditions that would permit the complete structure determination of spherical viruses that have high internal symmetry were examined starting only from an initial spherical shell model. Problems were considered that might arise due to the following. 1. Creation of centric phases due to the simple shell model and its position in the unit cell. The centric symmetry can generally be broken on averaging an initial electron density map based on observed structure amplitudes, provided that the internal molecular symmetry is sufficiently non-parallel to the crystallographic symmetry. 2. Choice of the average model shell radius. Some incorrect radii led to the Babinet opposite solution (electron density is negative instead of positive). Phases derived from other models with incorrect radii failed to converge to the correct solution. 3. Error in structure amplitude measurements. 4. Lack of a complete data set. 5. Error in positioning the initial spherical-shell model within the crystal unit cell. It was found that an error of 1.6 A caused noticeable phasing error at a resolution greater than 20 A.

Structural comparisons of the nucleoprotein from three negative strand RNA virus families.

Structures of the nucleoprotein of three negative strand RNA virus families, borna disease virus, rhabdovirus and influenza A virus, are now available. Structural comparisons showed that the topology of the RNA binding region from the three proteins is very similar. The RNA was shown to fit into a cavity formed by the two distinct domains of the RNA binding region in the rhabdovirus nucleoprotein. Two helices connecting the two domains characterize the center of the cavity. The nucleoproteins contain at least 5 conserved helices in the N-terminal domain and 3 conserved helices in the C-terminal domain. Since all negative strand RNA viruses are required to have the ribonucleoprotein complex as their active genomic templates, it is perceivable that the (5H+3H) structure is a common motif in the nucleoprotein of negative strand RNA viruses.

Ab initio phase determination for spherical viruses: parameter determination for spherical‐shell models

The structure determination of canine parvovirus depended on the extension of phases calculated initially from a spherical-shell model [Tsao, Chapman, Wu, Agbandje, Keller & Rossmann (1992). Acta Cryst. B48, 75-88]. Such ab initio phasing holds the promise of obviating initial experimental phasing by isomorphous or molecular replacement, thereby expediting the structure determinations of spherical virus capsids. In this paper, it is shown how parameters such as radii, DNA density and particle positions may be determined and refined from diffraction data with sufficient precision to start phase extension from 20 A resolution for a virus of approximately 122 A radius.

Common Mechanism for RNA Encapsidation by Negative-Strand RNA Viruses

ABSTRACT The nucleocapsid of a negative-strand RNA virus is assembled with a single nucleocapsid protein and the viral genomic RNA. The nucleocapsid protein polymerizes along the length of the single-strand genomic RNA (viral RNA) or its cRNA. This process of encapsidation occurs concomitantly with genomic replication. Structural comparisons of several nucleocapsid-like particles show that the mechanism of RNA encapsidation in negative-strand RNA viruses has many common features. Fundamentally, there is a unifying mechanism to keep the capsid protein protomer monomeric prior to encapsidation of viral RNA. In the nucleocapsid, there is a cavity between two globular domains of the nucleocapsid protein where the viral RNA is sequestered. The viral RNA must be transiently released from the nucleocapsid in order to reveal the template RNA sequence for transcription/replication. There are cross-molecular interactions among the protein subunits linearly along the nucleocapsid to stabilize its structure. Empty capsids can form in the absence of RNA. The common characteristics of RNA encapsidation not only delineate the evolutionary relationship of negative-strand RNA viruses but also provide insights into their mechanism of replication. IMPORTANCE What separates negative-strand RNA viruses (NSVs) from the rest of the virosphere is that the nucleocapsid of NSVs serves as the template for viral RNA synthesis. Their viral RNA-dependent RNA polymerase can induce local conformational changes in the nucleocapsid to temporarily release the RNA genome so that the viral RNA-dependent RNA polymerase can use it as the template for RNA synthesis during both transcription and replication. After RNA synthesis at the local region is completed, the viral RNA-dependent RNA polymerase processes downstream, and the RNA genome is restored in the nucleocapsid. We found that the nucleocapsid assembly of all NSVs shares three essential elements: a monomeric capsid protein protomer, parallel orientation of subunits in the linear nucleocapsid, and a (5H + 3H) motif that forms a proper cavity for sequestration of the RNA. This observation also suggests that all NSVs evolved from a common ancestor that has this unique nucleocapsid.

Preliminary X-ray crystallographic analysis of canine parvovirus crystals☆

The first diffraction pattern of a crystalline single-stranded DNA virus has been obtained. Canine parvovirus was crystallized in a monoclinic P21 unit cell with a = 264.4 A, b = 350.3 A, c = 267.8 A and beta = 90.86 degrees (1 A = 0.1 nm). The diffraction pattern extends to at least 2.8 A resolution. Packing of the particles suggests that they have a diameter around 257 A, in excellent agreement with the reported molecular weight of 5.5 x 10(6).