Influenza virus evades innate and adaptive immunity via the NS1 protein

Both antibodies and T cells contribute to immunity against influenza virus infection. However, the generation of strong Th1 immunity is crucial for viral clearance. Interestingly, we found that human dendritic cells (DCs) infected with influenza A virus have lower allospecific Th1-cell stimulatory abilities than DCs activated by other stimuli, such as lipopolysaccharide and Newcastle disease virus infection. This weak stimulatory activity correlates with a suboptimal maturation of the DCs following infection with influenza A virus. We next investigated whether the influenza A virus NS1 protein could be responsible for the low levels of DC maturation after influenza virus infection. The NS1 protein is an important virulence factor associated with the suppression of innate immunity via the inhibition of type I interferon (IFN) production in infected cells. Using recombinant influenza and Newcastle disease viruses, with or without the NS1 gene from influenza virus, we found that the induction of a genetic program underlying DC maturation, migration, and T-cell stimulatory activity is specifically suppressed by the expression of the NS1 protein. Among the genes affected by NS1 are those coding for macrophage inflammatory protein 1beta, interleukin-12 p35 (IL-12 p35), IL-23 p19, RANTES, IL-8, IFN-alpha/beta, and CCR7. These results indicate that the influenza A virus NS1 protein is a bifunctional viral immunosuppressor which inhibits innate immunity by preventing type I IFN release and inhibits adaptive immunity by attenuating human DC maturation and the capacity of DCs to induce T-cell responses. Our observations also support the potential use of NS1 mutant influenza viruses as live attenuated influenza virus vaccines.     

The relationship between HIV-1 genome RNA dimerization, virion maturation and infectivity

The relationship between virion protein maturation and genomic RNA dimerization of human immunodeficiency virus type 1 (HIV-1) remains incompletely understood. We have constructed HIV-1 Gag cleavage site mutants to enable the steady state observation of virion maturation steps, and precisely study Gag processing, RNA dimerization, virion morphology and infectivity. Within the virion maturation process, the RNA dimer stabilization begins during the primary cleavage (p2-NC) of Pr55 Gag. However, the primary cleavage alone is not sufficient, and the ensuing cleavages are required for the completion of dimerization. From our observations, the increase of cleavage products may not put a threshold on the transition from fragile to stable dimeric RNA. Most of the RNA dimerization process did not require viral core formation, and particle morphology dynamics during viral maturation did not completely synchronize with the transition of dimeric RNA status. Although the endogenous virion RT activity was fully acquired at the initial step of maturation, the following process was necessary for viral DNA production in infected cell, suggesting the maturation of viral RNA/protein plays critical role for viral infectivity other than RT process.     

Migration and maturation of human dendritic cells infected with Toxoplasma gondii depend on parasite strain type

Migration and maturation of human dendritic cells derived from CD34+ progenitor cells (DC) infected by Toxoplasma gondii were studied in an in vitro model. We demonstrated that infection with virulent type I strains RH and ENT or type II low virulent strains PRU and CAL induced DC migration towards MIP-3beta. However, type II strains induced a higher percentage of migrating cells than that induced by type I strains or positive controls (chemical allergen or lipopolysaccharides). Type II strains produced soluble factors responsible of the high migration whereas heat killed tachyzoites did not induced a migration higher than positive controls. We also demonstrated that infection by virulent strains and not by type II stains or heat killed tachyzoites triggers DC maturation. A soluble factor released by type II strains was responsible of the absence of DC maturation. Taken together, these results demonstrated that the interference of T. gondii in the behaviour of DC functions is related to the strain types and can be supported by secretion of soluble factors by the parasite.     

Genetic analysis of the yellow fever virus NS1 protein: identification of a temperature-sensitive mutation which blocks RNA accumulation.

The flavivirus NS1 protein is a highly conserved nonstructural glycoprotein that is capable of eliciting protective immunity. NS1 homodimers are secreted from virus-infected mammalian cells, but the protein is also present at the plasma membrane and in the lumen of intracellular vesicles. Based on these properties, it has been speculated that NS1 may function in virus maturation or release. To gain further insight into NS1 function, we used clustered charged-amino-acid-to-alanine mutagenesis to create 28 clustered substitutions in the NS1 protein of yellow fever virus. To screen for conditional mutations, full-length RNAs containing each mutation were assayed for plaque formation at 32 and 39 degrees C after RNA transfection. We found that 9 mutations were lethal, 18 allowed plaque formation at both temperatures, and 1, ts25, was strongly heat sensitive and was unable to form plaques at 39 degrees C. Lethal mutations clustered in the amino-terminal half of NS1, whereas those leading to impaired replication relative to the parent were distributed throughout the protein. High-multiplicity infections at 39 degrees C demonstrated that ts25 was defective for RNA accumulation, leading to depressed viral protein synthesis and delayed virus production. Although ts25 secreted less NS1 than did the parent, temperature shift experiments failed to demonstrate any temperature-dependent differences in polyprotein processing, NS1 stability and secretion, or release of infectious virus. The ts lesion of ts25 was shown to be due to a single alanine substitution for Arg-299, a residue which is conserved among flaviviruses. These results argue that NS1 plays an essential but as yet undefined role in flavivirus RNA amplification.     

NS1 protein secretion during the acute phase of West Nile virus infection

The West Nile virus (WNV) nonstructural protein NS1 is a protein of unknown function that is found within, associated with, and secreted from infected cells. We systematically investigated the kinetics of NS1 secretion in vitro and in vivo to determine the potential use of this protein as a diagnostic marker and to analyze NS1 secretion in relation to the infection cycle. A sensitive antigen capture enzyme-linked immunosorbent assay (ELISA) for detection of WNV NS1 (polyclonal-ACE) was developed, as well as a capture ELISA for the specific detection of NS1 multimers (4G4-ACE). The 4G4-ACE detected native NS1 antigens at high sensitivity, whereas the polyclonal-ACE had a higher specificity for recombinant forms of the protein. Applying these assays we found that only a small fraction of intracellular NS1 is secreted and that secretion of NS1 in tissue culture is delayed compared to the release of virus particles. In experimentally infected hamsters, NS1 was detected in the serum between days 3 and 8 postinfection, peaking on day 5, the day prior to the onset of clinical disease; immunoglobulin M (IgM) antibodies were detected at low levels on day 5 postinfection. Although real-time PCR gave the earliest indication of infection (day 1), the diagnostic performance of the 4G4-ACE was comparable to that of real-time PCR during the time period when NS1 was secreted. Moreover, the 4G4-ACE was found to be superior in performance to both the IgM and plaque assays during this time period, suggesting that NS1 is a viable early diagnostic marker of WNV infection.     

Type III secretion translocation pores of Yersinia enterocolitica trigger maturation and release of pro-inflammatory IL-1beta

Bacteria from the genus Yersinia deliver a number of effectors into host cells via type III secretion (T3S). Injected Yop effectors interfere and prevent pro-inflammatory warning signals by hijacking the host's intracellular machinery. While macrophages infected by wild-type Yersinia enterocolitica did not release mature IL-1beta, macrophages infected by Y. enterocolitica deprived of all effectors released mature IL-1beta. Surprisingly, macrophages infected by Y. enterocolitica deficient for secretion of all T3S proteins, including effectors and translocators, did not release mature IL-1beta. Using different genetic constructs, we show that insertion of T3S translocation pores trigger activation of caspase-1, maturation of proIL-1beta and release of mature IL-1beta, which occurs independently of cell osmotic lysis. These data show that T3S translocation is intrinsically a pro-inflammatory phenomenon. However, in the case of Yersinia, this effect is neutralized by the action of effectors.     

The human respiratory syncytial virus nonstructural protein 1 regulates type I and type II interferon pathways

Respiratory syncytial viruses encode a nonstructural protein (NS1) that interferes with type I and III interferon and other antiviral responses. Proteomic studies were conducted on human A549 type II alveolar epithelial cells and type I interferon-deficient Vero cells (African green monkey kidney cells) infected with wild-type and NS1-deficient clones of human respiratory syncytial virus to identify other potential pathway and molecular targets of NS1 interference. These analyses included two-dimensional differential gel electrophoresis and quantitative Western blotting. Surprisingly, NS1 was found to suppress the induction of manganese superoxide dismutase (SOD2) expression in A549 cells and to a much lesser degree Vero cells in response to infection. Because SOD2 is not directly inducible by type I interferons, it served as a marker to probe the impact of NS1 on signaling of other cytokines known to induce SOD2 expression and/or indirect effects of type I interferon signaling. Deductive analysis of results obtained from cell infection and cytokine stimulation studies indicated that interferon-γ signaling was a potential target of NS1, possibly as a result of modulation of STAT1 levels. However, this was not sufficient to explain the magnitude of the impact of NS1 on SOD2 induction in A549 cells. Vero cell infection experiments indicated that NS1 targeted a component of the type I interferon response that does not directly induce SOD2 expression but is required to induce another initiator of SOD2 expression. STAT2 was ruled out as a target of NS1 interference using quantitative Western blot analysis of infected A549 cells, but data were obtained to indicate that STAT1 was one of a number of potential targets of NS1. A label-free mass spectrometry-based quantitative approach is proposed as a means of more definitive identification of NS1 targets.     

Respiratory syncytial virus interferon antagonist NS1 protein suppresses and skews the human T lymphocyte response

We recently demonstrated that the respiratory syncytial virus (RSV) NS1 protein, an antagonist of host type I interferon (IFN-I) production and signaling, has a suppressive effect on the maturation of human dendritic cells (DC) that was only partly dependent on released IFN-I. Here we investigated whether NS1 affects the ability of DC to activate CD8+ and CD4+ T cells. Human DC were infected with RSV deletion mutants lacking the NS1 and/or NS2 genes and assayed for the ability to activate autologous T cells in vitro, which were analyzed by multi-color flow cytometry. Deletion of the NS1, but not NS2, protein resulted in three major effects: (i) an increased activation and proliferation of CD8+ T cells that express CD103, a tissue homing integrin that directs CD8+ T cells to mucosal epithelial cells of the respiratory tract and triggers cytolytic activity; (ii) an increased activation and proliferation of Th17 cells, which have recently been shown to have anti-viral effects and also indirectly attract neutrophils; and (iii) decreased activation of IL-4-producing CD4+ T cells--which are associated with enhanced RSV disease--and reduced proliferation of total CD4+ T cells. Except for total CD4+ T cell proliferation, none of the T cell effects appeared to be due to increased IFN-I signaling. In the infected DC, deletion of the NS1 and NS2 genes strongly up-regulated the expression of cytokines and other molecules involved in DC maturation. This was partly IFN-I-independent, and thus might account for the T cell effects. Taken together, these data demonstrate that the NS1 protein suppresses proliferation and activation of two of the protective cell populations (CD103+ CD8+ T cells and Th17 cells), and promotes proliferation and activation of Th2 cells that can enhance RSV disease.     

Structural analysis of HIV-1 maturation using cryo-electron tomography

HIV-1 buds form infected cells in an immature, non-infectious form. Maturation into an infectious virion requires proteolytic cleavage of the Gag polyprotein at five positions, leading to a dramatic change in virus morphology. Immature virions contain an incomplete spherical shell where Gag is arranged with the N-terminal MA domain adjacent to the membrane, the CA domain adopting a hexameric lattice below the membrane, and beneath this, the NC domain and viral RNA forming a disordered layer. After maturation, NC and RNA are condensed within the particle surrounded by a conical CA core. Little is known about the sequence of structural changes that take place during maturation, however. Here we have used cryo-electron tomography and subtomogram averaging to resolve the structure of the Gag lattice in a panel of viruses containing point mutations abolishing cleavage at individual or multiple Gag cleavage sites. These studies describe the structural intermediates correlating with the ordered processing events that occur during the HIV-1 maturation process. After the first cleavage between SP1 and NC, the condensed NC-RNA may retain a link to the remaining Gag lattice. Initiation of disassembly of the immature Gag lattice requires cleavage to occur on both sides of CA-SP1, while assembly of the mature core also requires cleavage of SP1 from CA.     

Purification,cellular levels,and functional domains of lipase maturation factor 1

Over a third of the US adult population has hypertriglyceridemia, resulting in an increased risk of atherosclerosis, pancreatitis, and metabolic syndrome. Lipoprotein lipase (LPL), a dimeric enzyme, is the main lipase responsible for TG clearance from the blood after food intake. LPL requires an endoplasmic reticulum (ER)-resident, transmembrane protein known as lipase maturation factor 1 (LMF1) for secretion and enzymatic activity. LMF1 is believed to act as a client specific chaperone for dimeric lipases, but the precise mechanism by which LMF1 functions is not understood. Here, we examine which domains of LMF1 contribute to dimeric lipase maturation by assessing the function of truncation variants. N-terminal truncations of LMF1 show that all the domains are necessary for LPL maturation. Fluorescence microscopy and protease protection assays confirmed that these variants were properly oriented in the ER. We measured cellular levels of LMF1 and found that it is expressed at low levels and each molecule of LMF1 promotes the maturation of 50 or more molecules of LPL. Thus we provide evidence for the critical role of the N-terminus of LMF1 for the maturation of LPL and relevant ratio of chaperone to substrate.     

The HIV-1 capsid protein C-terminal domain in complex with a virus assembly inhibitor

Immature HIV particles bud from infected cells after assembly at the cytoplasmic side of cellular membranes. This assembly is driven by interactions between Gag polyproteins. Mature particles, each containing a characteristic conical core, are later generated by proteolytic maturation of Gag in the virion. The C-terminal domain of the HIV-1 capsid protein (C-CA) has been shown to contain oligomerization determinants essential for particle assembly. Here we report the 1.7-A-resolution crystal structure of C-CA in complex with a peptide capable of inhibiting immature- and mature-like particle assembly in vitro. The peptide inserts as an amphipathic alpha-helix into a conserved hydrophobic groove of C-CA, resulting in formation of a compact five-helix bundle with altered dimeric interactions. This structure thus reveals the details of an allosteric site in the HIV capsid protein that can be targeted for antiviral therapy.     

Expression and immunoaffinity purification of recombinant dengue virus 2 NS1 protein as a cleavable SUMOstar fusion

Dengue virus (DENV) encoded nonstructural one (NS1) is a 352 amino acid protein that exists in multiple oligomeric states and is conserved within the flavivirus family. Although NS1 has been heavily researched for its diagnostic utility, there is a gap in the understanding of its role in a range of viral processes, including replication and development of clinical pathologies such as vascular leakage. Many of these functions involve unknown interactions with viral and host proteins. This study describes the generation of a mouse monoclonal antibody (mAb 56.2) that reacts with NS1 from DENV1 and 2, and the expression of recombinant SUMOstar-tagged DENV2 NS1 (DENV2 S^∗-NS1) in baculovirus. This is the first time dengue NS1 has been produced as a SUMOstar fusion with the S^∗-tag increasing protein solubility and secretion compared with a non-S^∗-tagged NS1 construct. The protein was readily purified using a mAb 56.2 immunoaffinity column and untagged NS1 was obtained by treatment with tobacco etch virus protease to remove the S^∗-tag. Size exclusion chromatography and glycosylation assays showed that both secreted S^∗-NS1, and cleaved NS1, are hexameric and glycosylated, and will be useful tools in elucidating dengue NS1 protein interactions and functions.     

H5N1亚型禽流感病毒NS1基因在昆虫细胞中的表达

将H5N1亚型禽流感病毒（AIV）NS1基因插入到杆状病毒转移载体pFastBac1中,获得重组转移载体pFastBac1- NS1。将pFastBac1- NS1转化到DH10Bac感受态细胞中,筛选到重组转座子rBacmid-NS1。在脂质体转染试剂介导下将rBacmid-NS1转染对数生长期的Sf9昆虫细胞获得重组杆状病毒rBV-NS1。rBV-NS1感染Sf9细胞后,通过SDS-PAGE、Western blot和ELISA分析表明：获得了分子量为26ku的特异性NS1蛋白;并且该蛋白可与H5N1 AIV攻毒鸭的血清发生特异性免疫反应,而不能与H5N1AIV灭活疫苗免疫鸭的血清发生反应。试验结果表明：NS1在Sf9昆虫细胞中获得了高效表达,具有与天然蛋白相似的免疫活性,并可以作为区分免疫及自然感染个体的鉴别诊断抗原。本实验为建立禽流感病毒自然感染家禽与禽流感灭活苗免疫家禽的鉴别诊断方法奠定基础。     

Key role of regulated upon activation normal T-cell expressed and secreted, nonstructural protein1 and myeloperoxidase in cytokine storm induced by influenza virus PR-8 (A/H1N1) infection in A549 bronchial epithelial cells

Influenza virus infection causes severe respiratory disease such as that due to avian influenza (H5N1). Influenza A viruses proliferate in human epithelial cells, which produce inflammatory cytokines/chemokines as a "cytokine storm" attenuated with the viral nonstructural protein 1 (NS1). Cytokine/chemokine production in A549 epithelial cells infected with influenza A/H1N1 virus (PR-8) or nonstructural protein 1 (NS1) plasmid was examined in vitro. Because tumor necrosis factor-α (TNF-α) and regulated upon activation normal T-cell expressed and secreted (RANTES) are predominantly produced from cells infected with PR-8 virus, the effects of mRNA knockdown of these cytokines were investigated. Small interfering (si)TNF-α down-regulated RANTES expression and secretion of RANTES, interleukin (IL)-8, and monocyte chemotactic protein-1 (MCP-1). In addition, siRANTES suppressed interferon (IFN)-γ expression and secretion of RANTES, IL-8, and MCP-1, suggesting that TNF-α stimulates production of RANTES, IL-8, MCP-1, and IFN-γ, and RANTES also increased IL-8, MCP-1, and IFN-γ. Furthermore, administration of TNF-α promoted increased secretion of RANTES, IL-8, and MCP-1. Administration of RANTES enhanced IL-6, IL-8, and MCP-1 production without PR-8 infection. These results strongly suggest that, as an initial step, TNF-α regulates RANTES production, followed by increase of IL-6, IL-8, and MCP-1 and IFNs concentrations. At a later stage, cells transfected with viral NS1 plasmid showed production of a large amount of IL-8 and MCP-1 in the presence of the H(2)O(2)-myeloperoxidse (MPO) system, suggesting that NS1 of PR-8 may induce a "cytokine storm" from epithelial cells in the presence of an H(2)O(2)-MPO system.     

A型流感病毒NS1蛋白结构研究进展

近年来A型流感严重威胁着人类和畜禽的健康,随着研究的深入,人们已经发现A型流感病毒的NS1蛋白对病毒毒力有重要影响,是一个多功能毒力因子、宿主细胞抗病毒免疫抑制子。根据其功能的不同分为效应区和RNA结合域。目前NS1蛋白结构已经解析,使人们可以直观的认识其各个功能位点的作用机制。该文综述了NS1蛋白的结构特征、已知的功能位点及其功能,为在结构水平上研究NS1蛋白的功能提供参考。     

A "lymphokine-like" soluble product that induces proliferation and maturation of B cells appears in the serum-free supernatant of a T cell hybridoma as a consequence of mycoplasmal contamination

The serum-free supernatant of a cloned murine T cell hybridoma supports the proliferation and maturation to Ig secretion of purified B cells (mu+ cells) from BALB/c nu/nu mice, but has no effect on the proliferation of nylon wool-selected BALB/c nu/+ splenic T cells. Although the supernatant activates B cells without co-stimulation, it synergizes with anti-mu for the proliferative response. The induction of B cell proliferation and maturation to Ig secretion is directly related to contamination of the hybridoma by Mycoplasma hyorhinis. Hybridoma cells freed of mycoplasma by detergent treatment fail to produce active supernatant, and reinfection of the treated cells reconstitutes the activity. Furthermore, deliberate infection of a mycoplasma-free unrelated T cell hybridoma, as well as the monocytic cell line P388D1, results in the production of supernatants with B cell proliferating activity. Mycoplasma organisms isolated from the supernatant induce B cell proliferation without subsequent maturation to Ig secretion. Gel filtration chromatography of the supernatant from mycoplasma-contaminated hybridoma cells yields two peaks of activity. The first peak, found at the exclusion limit of the gel, results in B cell proliferation without maturation and may be attributed to mycoplasma organisms. The second peak (average m.w. 90,000) results in B cell proliferation as well as differentiation to Ig secretion. A "lymphokine-like" soluble product released by Mycoplasma hyorhinis is most likely responsible for this B cell activation, because fractionation of the supernatant from deliberately contaminated P388D1 cells gives essentially the same results, and gel filtration of mycoplasma-free supernatants does not generate any active fractions. The possibility should be considered that mycoplasma-derived soluble products may be among the many factors controlling in vitro B cell growth and maturation.     

Differential trafficking of soluble and integral membrane secretory granule-associated proteins

The posttranslational processing enzyme peptidylglycine alpha-amidating monooxygenase (PAM) occurs naturally in integral membrane and soluble forms. With the goal of understanding the targeting of these proteins to secretory granules, we have compared the maturation, processing, secretion, and storage of PAM proteins in stably transfected AtT-20 cells. Integral membrane and soluble PAM proteins exit the ER and reach the Golgi apparatus with similar kinetics. Biosynthetic labeling experiments demonstrated that soluble PAM proteins were endoproteolytically processed to a greater extent than integral membrane PAM; this processing occurred in the regulated secretory pathway and was blocked by incubation of cells at 20 degrees C. 16 h after a biosynthetic pulse, a larger proportion of soluble PAM proteins remained cell-associated compared with integral membrane PAM, suggesting that soluble PAM proteins were more efficiently targeted to storage granules. The nonstimulated secretion of soluble PAM proteins peaked 1-2 h after a biosynthetic pulse, suggesting that release was from vesicles which bud from immature granules during the maturation process. In contrast, soluble PAM proteins derived through endoproteolytic cleavage of integral membrane PAM were secreted in highest amount during later times of chase. Furthermore, immunoprecipitation of cell surface-associated integral membrane PAM demonstrated that very little integral membrane PAM reached the cell surface during early times of chase. However, when a truncated PAM protein lacking the cytoplasmic tail was expressed in AtT-20 cells, > 50% of the truncated PAM-1 protein reached the cell surface within 3 h. We conclude that the trafficking of integral membrane and soluble secretory granule-associated enzymes differs, and that integral membrane PAM proteins are less efficiently retained in maturing secretory granules.     

Inhibition of gp160 and CD4 maturation in U937 cells after both defective and productive infections by human immunodeficiency virus type 1.

Our results demonstrate that the formation of intracellular complexes between the envelope glycoprotein precursor gp160 of human immunodeficiency virus type 1 and CD4 is a major event, leading to the disappearance of CD4 at the cell surface of infected U937 cells. Using both productively and defectively infected clones of U937 cells, we assessed the effect of CD4-gp160 intracellular association on the maturation of both proteins. Pulse-chase labeling followed by sequential immunoprecipitation was used to analyze the processing of both free and associated CD4 and gp160, and the results showed that the trimming, proteolytic cleavage, and degradation of gp160 were completely abrogated after intracellular binding to CD4. Similarly, the maturation process which normally transforms 80% of CD4 to a partially endoglycosidase H-resistant species was also impaired subsequent to the formation of these complexes. A comparison of gp160 maturation either in free form or as a CD4 complex revealed that neither inefficient transport nor degradation of gp160 can account for the observed blockage of CD4 maturation. Moreover, this impairment was independent of gp120 and gp41, since a defective clone of human immunodeficiency virus type 1-infected cells, unable to cleave gp160, showed binding of CD4 and inhibition of CD4 transport and maturation with the same efficiency as occurred in productively infected cells. Expression of gp160 is thus necessary and sufficient to cause CD4 receptor down-modulation for both productively and defectively infected cells.