Shihong Qiu

Study of the Assembly of Vesicular Stomatitis Virus N Protein: Role of the P Protein

ABSTRACT To derive structural information about the vesicular stomatitis virus (VSV) nucleocapsid (N) protein, the N protein and the VSV phosphoprotein (P protein) were expressed together in Escherichia coli. The N and P proteins formed soluble protein complexes of various molar ratios when coexpressed. The major N/P protein complex was composed of 10 molecules of the N protein, 5 molecules of the P protein, and an RNA. A soluble N protein-RNA oligomer free of the P protein was isolated from the N/P protein-RNA complex using conditions of lowered pH. The molecular weight of the N protein-RNA oligomer, 513,879, as determined by analytical ultracentrifugation, showed that it was composed of 10 molecules of the N protein and an RNA of approximately 90 nucleotides. The N protein-RNA oligomer had the appearance of a disk with outer diameter, inner diameter, and thickness of 148 ± 10 Å, 78 ± 9 Å, and 83 ± 8 Å, respectively, as determined by electron microscopy. RNA in the complexes was protected from RNase digestion and was stable at pH 11. This verified that N/P protein complexes expressed in E. coli were competent for encapsidation. In addition to coexpression with the full-length P protein, the N protein was expressed with the C-terminal 72 amino acids of the P protein. This portion of the P protein was sufficient for binding to the N protein, maintaining it in a soluble state, and for assembly of N protein-RNA oligomers. With the results provided in this report, we propose a model for the assembly of an N/P protein-RNA oligomer.

An Exposed Domain in the Severe Acute Respiratory Syndrome Coronavirus Spike Protein Induces Neutralizing Antibodies

ABSTRACT Exposed epitopes of the spike protein may be recognized by neutralizing antibodies against severe acute respiratory syndrome (SARS) coronavirus (CoV). A protein fragment (S-II) containing predicted epitopes of the spike protein was expressed in Escherichia coli. The properly refolded protein fragment specifically bound to the surface of Vero cells. Monoclonal antibodies raised against this fragment recognized the native spike protein of SARS CoV in both monomeric and trimeric forms. These monoclonal antibodies were capable of blocking S-II attachment to Vero cells and exhibited in vitro antiviral activity. These neutralizing antibodies mapped to epitopes in two peptides, each comprising 20 amino acids. Thus, this region of the spike protein might be a target for generation of therapeutic neutralizing antibodies against SARS CoV and for vaccine development to elicit protective humoral immunity.

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.

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.

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.

Structural genomics of caenorhabditis elegans: Crystal structure of calmodulin

Introduction. Calmodulin (CaM), a conserved eucaryotic protein, can bind specifically to a large number of intracellular proteins and modulate their activity in response to the Ca concentration. This small 17-kDa acidic protein belongs to a family of homologous calcium-binding proteins that bind Ca through the EF-hand motif (e.g., parvalbumin or troponin C). A compact, calcium-free, apo form of CaM is converted to an extended dumbbellshaped form on binding Ca . The extended conformation of CaM has been by far the most thoroughly studied, especially by X-ray crystallography. It consists of two structurally similar domains separated by a flexible 28-residue helix. Each domain has two EF-hand motifs with bound Ca . The calciuminduced extension of CaM exposes two hydrophobic pockets, one per domain, which represent the binding sites for target proteins. In some protein targets, the CaM-binding region was located to a sequence of 18 amino acids predicted to form an -helix. On binding to the protein target, the central CaM helix unwinds, and the two hydrophobic pockets wrap around the -helix of the protein target. Structural plasticity of the hydrophobic pockets and flexibility of the central helix are thought to account for the ability of CaM to interact with a variety of different targets in a sequence-independent fashion. We have determined the crystal structure of calciumbound CaM from Caenorhabditis elegans (ceCaM) as a part of the Structural Genomics of C. elegans project. Besides the conserved features typical for all CaM’s, the ceCaM structure has the straightest central helix so far observed in CaM’s. This relatively straight helix may be induced by different crystallization conditions and/or by the crystal symmetry.

Characterization of a Mumps Virus Nucleocapsidlike Particle

ABSTRACT The nucleocapsid protein (NP) of mumps virus (MuV), a paramyxovirus, was coexpressed with the phosphoprotein (P) in Escherichia coli. The NP and P proteins form a soluble complex containing RNA. Under a transmission electron microscope, the NP-RNA complex appears as a nucleocapsidlike ring that has a diameter of approximately 20 nm with 13 subunits. There is a piece of single-stranded RNA with a length of 78 nucleotides in the NP-RNA ring. Shorter RNA pieces are also visible. The MuV NP protein may provide weaker protection of the RNA than the NP protein of some other negative-strand RNA viruses, reflecting the degree of NP protein association.

Domain selection combined with improved cloning strategy for high throughput expression of higher eukaryotic proteins

BackgroundExpression of higher eukaryotic genes as soluble, stable recombinant proteins is still a bottleneck step in biochemical and structural studies of novel proteins today. Correct identification of stable domains/fragments within the open reading frame (ORF), combined with proper cloning strategies, can greatly enhance the success rate when higher eukaryotic proteins are expressed as these domains/fragments. Furthermore, a HTP cloning pipeline incorporated with bioinformatics domain/fragment selection methods will be beneficial to studies of structure and function genomics/proteomics.ResultsWith bioinformatics tools, we developed a domain/domain boundary prediction (DDBP) method, which was trained by available experimental data. Combined with an improved cloning strategy, DDBP had been applied to 57 proteins from C. elegans. Expression and purification results showed there was a 10-fold increase in terms of obtaining purified proteins. Based on the DDBP method, the improved GATEWAY cloning strategy and a robotic platform, we constructed a high throughput (HTP) cloning pipeline, including PCR primer design, PCR, BP reaction, transformation, plating, colony picking and entry clones extraction, which have been successfully applied to 90 C. elegans genes, 88 Brucella genes, and 188 human genes. More than 97% of the targeted genes were obtained as entry clones. This pipeline has a modular design and can adopt different operations for a variety of cloning/expression strategies.ConclusionThe DDBP method and improved cloning strategy were satisfactory. The cloning pipeline, combined with our recombinant protein HTP expression pipeline and the crystal screening robots, constitutes a complete platform for structure genomics/proteomics. This platform will increase the success rate of purification and crystallization dramatically and promote the further advancement of structure genomics/proteomics.

Structure and Function of the N-Terminal Domain of the Vesicular Stomatitis Virus RNA Polymerase

ABSTRACT Viruses have various mechanisms to duplicate their genomes and produce virus-specific mRNAs. Negative-strand RNA viruses encode their own polymerases to perform each of these processes. For the nonsegmented negative-strand RNA viruses, the polymerase is comprised of the large polymerase subunit (L) and the phosphoprotein (P). L proteins from members of the Rhabdoviridae, Paramyxoviridae, and Filoviridae share sequence and predicted secondary structure homology. Here, we present the structure of the N-terminal domain (conserved region I) of the L protein from a rhabdovirus, vesicular stomatitis virus, at 1.8-Å resolution. The strictly and strongly conserved residues in this domain cluster in a single area of the protein. Serial mutation of these residues shows that many of the amino acids are essential for viral transcription but not for mRNA capping. Three-dimensional alignments show that this domain shares structural homology with polymerases from other viral families, including segmented negative-strand RNA and double-stranded RNA (dsRNA) viruses. IMPORTANCE Negative-strand RNA viruses include a diverse set of viral families that infect animals and plants, causing serious illness and economic impact. The members of this group of viruses share a set of functionally conserved proteins that are essential to their replication cycle. Among this set of proteins is the viral polymerase, which performs a unique set of reactions to produce genome- and subgenome-length RNA transcripts. In this article, we study the polymerase of vesicular stomatitis virus, a member of the rhabdoviruses, which has served in the past as a model to study negative-strand RNA virus replication. We have identified a site in the N-terminal domain of the polymerase that is essential to viral transcription and that shares sequence homology with members of the paramyxoviruses and the filoviruses. Newly identified sites such as that described here could prove to be useful targets in the design of new therapeutics against negative-strand RNA viruses.

A High Throughput Platform for Eukaryotic Genes

The objective of structural proteomics is to determine the structures of all protein folds found in nature and develop a public resource to organize and analyze protein structures and fold families. High throughput (HTP) methods, which can process multiple samples in parallel, saving both time and cost, play important roles in achieving this goal. Using C. elegans and human as model organisms, a HTP cloning and expression pipeline was developed for structural proteomics that required production of a large number of recombinant proteins, applying the Gateway cloning/expression technology and utilizing a stepwise automation strategy on an integrated robotic platform. This system can process up to 384 unique samples in parallel and successfully automates most aspects of gene cloning and protein expression analysis, from PCR to protein solubility profiling.