Structural and functional analysis of NS1 and NS2 proteins of H1N1 subtype

Influenza A virus (H1N1), a genetic reassortment of endemic strains of human, avian and swine flu, has crossed species barrier to human and apparently acquired the capability of human to human transmission. Some strains of H5N1 subtype are highly virulent because NS1 protein inhibits antiviral interferon α/β production. Another protein NS2 mediates export of viral ribonucleoprotein from nucleus to the cytoplasm through export signal. In this paper, we have studied structure-function relationships of these proteins of H1N1 subtype and have determined the cause of their pathogenicity. Our results showed that non-conservative mutations slightly stabilized or destabi- lized structural domains of NS1 or NS1-dsRNA complex, hence slightly increased or decreased the function of NS1 protein and consequently enhanced or reduced the pathogenicity of the H1N1 virus. NS2 protein of different strains carried non-conservative mutations in different domains, resulting in slight loss of function. These mutations slightly decreased the pathogenicity of the virus. Thus, the results confirm the structure-function relationships of these viral proteins.     

呼吸道合胞病毒非结构蛋白NS1、NS2的研究进展

呼吸道合胞病毒(reespiratory syncytial virus,RSV)是引起婴幼儿和老年人下呼吸道感染的重要病原体之一.由于该病毒的致病机理还不太清楚导致目前尚无有效治疗RSV的方法.研究表明,呼吸道合胞病毒的非结构蛋白NS1、NS2具有抗细胞凋亡的作用,同时可以逃避宿主免疫系统(IFN)对病毒的干扰,有利于病毒复制.敲除这两种基因的减毒活疫苗和袁达沉默NS1的小干扰RNA(siRNA)的质粒研究已经取得了一定的进展.对非结构蛋白功能的深入研究有助于了解RSV的致病机理,同时为预防和治疗RSV感染奠定理论基础.     

Dengue virus-specific CD4+ and CD8+ T lymphocytes target NS1, NS3 and NS5 in infected Indian rhesus macaques

Every year, Dengue virus (DENV) infects approximately 100 million people. There are currently several vaccines undergoing clinical studies, but most target the induction of neutralizing antibodies. Unfortunately, DENV infection can be enhanced by subneutralizing levels of antibodies that bind virions and deliver them to cells of the myeloid lineage, thereby increasing viral replication (termed antibody-dependent enhancement [ADE]). T lymphocyte-based vaccines may offer an alternative that avoids ADE. The goal of our study was to describe the cellular immune response generated after primary DENV infection in Indian rhesus macaques. We infected eight rhesus macaques with 10⁵ plaque-forming units (PFU) of DENV serotype 2 (DENV2) New Guinea C (NGC) strain, and monitored viral load and the cellular immune response to the virus. Viral replication peaked at day 4 post-infection and was resolved by day 10. DENV-specific CD4⁺ and CD8⁺ T lymphocytes targeted nonstructural (NS) 1, NS3 and NS5 proteins after resolution of peak viremia. DENV-specific CD4⁺ cells expressed interferon-gamma (IFN-γ) along with tumor necrosis factor-alpha (TNF-α), interleukin-2 (IL-2), and macrophage inflammatory protein-1 beta (MIP-1β). In comparison, DENV-specific CD8⁺ cells expressed IFN-γ in addition to MIP-1β and TNF-α and were positive for the degranulation marker CD107a. Interestingly, a fraction of the DENV-specific CD4⁺ cells also stained for CD107a, suggesting that they might be cytotoxic. Our results provide a more complete understanding of the cellular immune response during DENV infection in rhesus macaques and contribute to the development of rhesus macaques as an animal model for DENV vaccine and pathogenicity studies.     

Ultrastructure of Kunjin virus-infected cells: colocalization of NS1 and NS3 with double-stranded RNA, and of NS2B with NS3, in virus-induced membrane structures.

The subcellular location of the nonstructural proteins NS1, NS2B, and NS3 in Vero cells infected with the flavivirus Kunjin was investigated using indirect immunofluorescence and cryoimmunoelectron microscopy with monospecific antibodies. Comparisons were also made by dual immunolabelling using antibodies to double-stranded RNA (dsRNA), the putative template in the flavivirus replication complex. At 8 h postinfection, the immunofluorescent patterns showed NS1, NS2B, NS3, and dsRNA located in a perinuclear rim with extensions into the peripheral cytoplasm. By 16 h, at the end of the latent period, all patterns had changed to some discrete perinuclear foci associated with a thick cytoplasmic reticulum. By 24 h, this localization in perinuclear foci was more apparent and some foci were dual labelled with antibodies to dsRNA. In immuno-gold-labelled cryosections of infected cells at 24 h, all antibodies were associated with clusters of induced membrane structures in the perinuclear region. Two important and novel observations were made. First, one set of induced membranes comprised vesicle packets of smooth membranes dual labelled with anti-dsRNA and anti-NS1 or anti-NS3 antibodies. Second, adjacent masses of paracrystalline arrays or of convoluted smooth membranes, which appeared to be structurally related, were strongly labelled only with anti-NS2B and anti-NS3 antibodies. Paired membranes similar in appearance to the rough endoplasmic reticulum were also labelled, but less strongly, with antibodies to the three nonstructural proteins. Other paired membranes adjacent to the structures discussed above enclosed accumulated virus particles but were not labelled with any of the four antibodies. The collection of induced membranes may represent virus factories in which translation, RNA synthesis, and virus assembly occur.     

Proteins from the prokaryotic nucleoid. High-resolution 1H NMR spectroscopic study of Escherichia coli DNA-binding proteins NS1 and NS2

The 1H-NMR spectra of the two Escherichia coli basic, low-Mr (approximately equal to 9000) DNA-binding proteins NS1 and NS2 and of their native complex NS were studied at 400 MHz and a number of resonances and resonance peaks were assigned. As in the case of some eukaryotic histones, the presence of a large number of high-field perturbed Phe resonances, several shielded and deshielded methyl resonances and backbone NH protons quite inaccessible to the solvent clearly indicate the existence of extensive tertiary and, even more so, quaternary structures involving hydrophobic interactions. These structures are lost upon heating, but readily reform upon cooling. Spectral differences between NS1, NS2 and NS and the greater thermal stability of NS indicate that molecules of the heterologous subunits (NS1 and NS2) aggregate (dimerize) preferentially in comparison to the self-aggregation of the homologous subunits. Unlike those of the eukaryotic histones, the tertiary and quaternary structures of NS are insensitive to extensive variations of the ionic strength.     

A型流感病毒NS1蛋白羧基端PL结构域影响NS1在细胞核内的定位

A型流感病毒NS1蛋白羧基端4个氨基酸可以与PDZ结构域(the domain of PSD95,Dig and ZO-1)相结合,称为PL结构域(PDZ ligand domain)．对不同亚型或毒株的流感病毒而言,其NS1蛋白PL结构域的组成存在比较大的差异．有研究发现这种差异能够影响NS1与宿主细胞蛋白的相互作用进而影响病毒的致病力．为进一步探讨PL结构域对NS1蛋白生物学特性的影响,首先构建出4种不同亚型流感病毒(H1N1、H3N2、H5N1、H9N2)来源的NS1绿色荧光蛋白表达质粒．在此基础上,对野生型H3N2病毒NS1表达质粒进行人工改造,将其PL结构域缺失或者替换为其他亚型流感病毒的PL结构域,制备出4种重组NS1蛋白表达质粒．通过比较上述不同NS1蛋白在HeLa细胞中的定位情况发现,只有野生型H3N2病毒的NS1蛋白可以定位于核仁当中,而野生型H1N1、H5N1、H9N2病毒的NS1蛋白以及PL结构域缺失或替代的H3N2病毒NS1蛋白都不能定位于核仁．而通过比较上述NS1蛋白在流感病毒易感的MDCK细胞中的定位,进一步发现所有这些蛋白均不定位于核仁．上述结果表明：PL结构域的不同可以明显影响NS1蛋白在HeLa细胞核内的定位和分布,这有可能造成其生物学功能的差异．同时,NS1蛋白在细胞核内的定位还与宿主细胞的来源有着密切关系．     

Genetic interaction of flavivirus nonstructural proteins NS1 and NS4A as a determinant of replicase function

Nonstructural protein 1 (NS1) of yellow fever virus (YF) is a glycoprotein localized to extracytoplasmic compartments within infected cells. We have previously shown that NS1 can be supplied in trans and is required for viral RNA replication, a process thought to occur in membrane-bound cytoplasmic complexes. Here we report that the NS1 gene from a related virus, dengue virus (DEN), is unable to function in the process of YF RNA replication. This virus-specific incompatibility leads to a lack of initial minus-strand accumulation, suggesting that DEN NS1 is unable to productively interact with the YF replicase. Based on a YF deletion mutant that requires NS1 in trans, a genetic screen for suppressor mutants was used to select virus variants able to utilize DEN NS1. In three independent selections, a single mutation was mapped to the NS4A gene, which encodes a putative transmembrane replicase component. This mutation, as well as several additional mutations, was engineered into the NS1-deficient genome and confirmed a genetic interaction between NS1 and NS4A. These findings suggest a potential mechanism for integrating NS1 into the cytoplasmic process of RNA replication.     

X-ray structures of NS1 effector domain mutants

The influenza A virus nonstructural protein NS1 is a multifunctional dimeric protein that acts as a potent inhibitor of the host cellular antiviral state. The C-terminal effector domain of NS1 binds host proteins, including CPSF30, and is a target for the development of new antiviral drugs. Here we present crystallographic structures of two mutant effector domains, W187Y and W187A, of influenza A/Udorn/72 virus. Unlike wild-type, the mutants behave exclusively as monomers in solution based on gel filtration data and light scattering. The W187Y mutant is able to bind CPSF30 with a binding affinity close to the wild-type protein; that is, it retains a receptor site for aromatic ligands nearly identical to the wild-type. Therefore, this monomeric mutant protein could serve as a drug target for a high throughput inhibitor screening assays, since its binding pocket is unoccupied in solution and potentially more accessible to small molecule ligands.     

抗登革病毒NS1单抗的制备及检测NS1方法的建立

制备抗登革病毒NS1蛋白单克隆抗体,建立检测NS1的ELISA方法。表达1~4型登革病毒NS1蛋白,将1型NS1蛋白纯化后免疫BALB/c小鼠,通过杂交瘤技术制备单克隆抗体。经ELISA、Western blotting、间接免疫荧光筛选和鉴定单克隆抗体,进行纯化和HRP标记。通过鉴定每两株单抗之间是否存在竞争作用,选择非竞争单抗组合并建立NS1捕获法ELISA。结果获得7株高滴度抗NS1单抗,捕获法ELISA可以检出10ng/mL NS1。原核表达登革病毒NS1蛋白制备的单抗可以和天然病毒抗原反应,NS1捕获法ELISA可以用于登革病毒感染检测。     

NS1-Binding Protein (NS1-BP): a Novel Human Protein That Interacts with the Influenza A Virus Nonstructural NS1 Protein Is Relocalized in the Nuclei of Infected Cells

We used the yeast interaction trap system to identify a novel human 70-kDa protein, termed NS1-binding protein (NS1-BP), which interacts with the nonstructural NS1 protein of the influenza A virus. The genetic interaction was confirmed by the specific coprecipitation of the NS1 protein from solution by a glutathione S-transferase–NS1-BP fusion protein and glutathione-Sepharose. NS1-BP contains an N-terminal BTB/POZ domain and five kelch-like tandem repeat elements of ~50 amino acids. In noninfected cells, affinity-purified antibodies localized NS1-BP in nuclear regions enriched with the spliceosome assembly factor SC35, suggesting an association of NS1-BP with the cellular splicing apparatus. In influenza A virus-infected cells, NS1-BP relocalized throughout the nucleoplasm and appeared distinct from the SC35 domains, which suggests that NS1-BP function may be disturbed or altered. The addition of a truncated NS1-BP mutant protein to a HeLa cell nuclear extract efficiently inhibited pre-mRNA splicing but not spliceosome assembly. This result could be explained by a possible dominant-negative effect of the NS1-BP mutant protein and suggests a role of the wild-type NS1-BP in promoting pre-mRNA splicing. These data suggest that the inhibition of splicing by the NS1 protein may be mediated by binding to NS1-BP.     

Bovine respiratory syncytial virus nonstructural proteins NS1 and NS2 cooperatively antagonize alpha/beta interferon-induced antiviral response

The functions of bovine respiratory syncytial virus (BRSV) nonstructural proteins NS1 and NS2 were studied by generation and analysis of recombinant BRSV carrying single and double gene deletions. Whereas in MDBK cells the lack of either or both NS genes resulted in a 5,000- to 10,000-fold reduction of virus titers, in Vero cells a moderate (10-fold) reduction was observed. Interestingly, cell culture supernatants from infected MDBK cells were able to restrain the growth of NS deletion mutants in Vero cells, suggesting the involvement of NS proteins in escape from cytokine-mediated host cell responses. The responsible factors in MDBK supernatants were identified as type I interferons by neutralization of the inhibitory effect with antibodies blocking the alpha interferon (IFN-alpha) receptor. Treatment of cells with recombinant universal IFN-alpha A/D or IFN-beta revealed severe inhibition of single and double deletion mutants, whereas growth of full-length BRSV was not greatly affected. Surprisingly, all NS deletion mutants were equally repressed, indicating an obligatory cooperation of NS1 and NS2 in antagonizing IFN-mediated antiviral mechanisms. To verify this finding, we generated recombinant rabies virus (rRV) expressing either NS1 or NS2 and determined their IFN sensitivity. In cells coinfected with NS1- and NS2-expressing rRVs, virus replication was resistant to doses of IFN which caused a 1,000-fold reduction of replication in cells infected with wild-type RV or with each of the NS-expressing rRVs alone. Thus, BRSV NS proteins have the potential to cooperatively protect an unrelated virus from IFN-alpha/beta mediated antiviral responses. Interestingly, BRSV NS proteins provided a more pronounced resistance to IFN in the bovine cell line MDBK than in cell lines of other origins, suggesting adaptation to host-specific antiviral responses. The findings described have a major impact on the design of live recombinant BRSV and HRSV vaccines.     

Cleavage of dengue virus NS1-NS2A requires an octapeptide sequence at the C terminus of NS1.

The length of amino acid sequence at the NS1-NS2A juncture of dengue virus that is required for specific cleavage effected by the cis-acting function of NS2A was identified by deletion analysis. Recombinant DNA sequences of NS1-NS2A, each containing a deletion in NS1 followed by a sequence of 3 to 20 amino acids at the C terminus of NS1 preceding the cleavage site, were constructed and expressed with vaccinia virus as a vector. The NS1 product of recombinant vaccinia virus-infected cells was immunoprecipitated and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The occurrence of cleavage between NS1 and NS2A was indicated by the appearance of shortened NS1. Failure to cleave this site yielded a large NS1-NS2A fusion protein. This analysis indicated that a minimum length of eight amino acids at the NS1 C terminus preceding the NS1-NS2A juncture is required for cleavage to take place. Comparison of this eight-amino-acid sequence of the NS1 C terminus of dengue type 4 virus with the analogous sequences of 12 other flaviviruses suggests that the consensus cleavage site sequence is as follows: (table; see text)     

Stable non-synonymous substitutions on NS gene (NS1 and NS2 proteins) of Qinghai Lake H5N1 influenza virus (Clade 2.2) after successive passages in Muscovy ducks

Although worldwide concern has been raised since the large-scale outbreak of highly pathogenic avian influenza in wild birds at Qinghai Lake,China in 2005,the factors responsible for the ability to kill waterfowl remain unclear. The why and how questions of the H5N1 virus species-jump into its reservoir host need to be answered. In this report we test the pathogenicity and adaptation of Qinghai Lake (Clade 2.2) isolate to Muscovy ducks for further understanding of this virus. The isolate was highly pathogen...     

Dynamics and interactions of parvoviral NS1 protein in the nucleus

Nuclear positioning and dynamic interactions of viral proteins with nuclear substructures play essential roles during infection with DNA viruses. Visualization of the intranuclear interactions and motility of the parvovirus replication protein (NS1) in living cells gives insight into specific parvovirus protein-cellular structure interactions. Confocal analysis of highly synchronized infected Norden Laboratory Feline Kidney cells showed accumulation of nuclear NS1 in discrete interchromosomal foci. NS1 fused with enhanced yellow fluorescence protein (NS1-EYFP) provided a marker in live cells for dynamics of NS1 traced by photobleaching techniques. Fluorescence Recovery after Photobleaching suggested that the NS1 protein is not freely diffusing but undergoes transient interactions with nuclear compartments. Fluorescence Loss in Photobleaching demonstrated for the first time the shuttling of a parvoviral protein between the nucleus and the cytoplasm as assayed with NS1-EYFP. Finally, time-lapse imaging of infected cells revealed that the intranuclear distribution of NS1-EYFP evolves dramatically starting from the formation of NS1 foci and proceeding to a homogenous distribution extending throughout the nucleus.