RESUMEN
The severe acute respiratory syndrome coronavirus accessory protein ORF6 antagonizes interferon signaling by blocking karyopherin-mediated nuclear import processes. Viral nuclear import antagonists, expressed by several highly pathogenic RNA viruses, likely mediate pleiotropic effects on host gene expression, presumably interfering with transcription factors, cytokines, hormones, and/or signaling cascades that occur in response to infection. By bioinformatic and systems biology approaches, we evaluated the impact of nuclear import antagonism on host expression networks by using human lung epithelial cells infected with either wild-type virus or a mutant that does not express ORF6 protein. Microarray analysis revealed significant changes in differential gene expression, with approximately twice as many upregulated genes in the mutant virus samples by 48 h postinfection, despite identical viral titers. Our data demonstrated that ORF6 protein expression attenuates the activity of numerous karyopherin-dependent host transcription factors (VDR, CREB1, SMAD4, p53, EpasI, and Oct3/4) that are critical for establishing antiviral responses and regulating key host responses during virus infection. Results were confirmed by proteomic and chromatin immunoprecipitation assay analyses and in parallel microarray studies using infected primary human airway epithelial cell cultures. The data strongly support the hypothesis that viral antagonists of nuclear import actively manipulate host responses in specific hierarchical patterns, contributing to the viral pathogenic potential in vivo. Importantly, these studies and modeling approaches not only provide templates for evaluating virus antagonism of nuclear import processes but also can reveal candidate cellular genes and pathways that may significantly influence disease outcomes following severe acute respiratory syndrome coronavirus infection in vivo.
Asunto(s)
Redes Reguladoras de Genes/fisiología , Coronavirus Relacionado al Síndrome Respiratorio Agudo Severo/metabolismo , Transducción de Señal/fisiología , Transcripción Genética/fisiología , Proteínas Reguladoras y Accesorias Virales/metabolismo , Transporte Activo de Núcleo Celular/fisiología , Inmunoprecipitación de Cromatina , Biología Computacional/métodos , Cartilla de ADN/genética , Células Epiteliales/metabolismo , Células Epiteliales/virología , Humanos , Pulmón/citología , Análisis por Micromatrices , Proteómica , Reacción en Cadena en Tiempo Real de la Polimerasa , Biología de Sistemas/métodosRESUMEN
Severe acute respiratory syndrome coronavirus (SARS-CoV) infection can cause the development of severe end-stage lung disease characterized by acute respiratory distress syndrome (ARDS) and pulmonary fibrosis. The mechanisms by which pulmonary lesions and fibrosis are generated during SARS-CoV infection are not known. Using high-throughput mRNA profiling, we examined the transcriptional response of wild-type (WT), type I interferon receptor knockout (IFNAR1-/-), and STAT1 knockout (STAT1-/-) mice infected with a recombinant mouse-adapted SARS-CoV (rMA15) to better understand the contribution of specific gene expression changes to disease progression. Despite a deletion of the type I interferon receptor, strong expression of interferon-stimulated genes was observed in the lungs of IFNAR1-/- mice, contributing to clearance of the virus. In contrast, STAT1-/- mice exhibited a defect in the expression of interferon-stimulated genes and were unable to clear the infection, resulting in a lethal outcome. STAT1-/- mice exhibited dysregulation of T-cell and macrophage differentiation, leading to a TH2-biased immune response and the development of alternatively activated macrophages that mediate a profibrotic environment within the lung. We propose that a combination of impaired viral clearance and T-cell/macrophage dysregulation causes the formation of prefibrotic lesions in the lungs of rMA15-infected STAT1-/- mice.
Asunto(s)
Fibrosis/etiología , Perfilación de la Expresión Génica , Factor de Transcripción STAT1/deficiencia , Síndrome Respiratorio Agudo Grave/patología , Animales , Fibrosis/genética , Enfermedades Pulmonares/etiología , Enfermedades Pulmonares/genética , Macrófagos/patología , Ratones , Ratones Noqueados , Fenotipo , ARN Mensajero/análisis , Receptor de Interferón alfa y beta/deficiencia , Coronavirus Relacionado al Síndrome Respiratorio Agudo Severo , Síndrome Respiratorio Agudo Grave/inmunología , Células Th2/inmunologíaRESUMEN
Acyl carrier proteins involved in fatty acid biosynthesis have been shown to exhibit a high degree of conformational flexibility, in that they are able to sequester fatty acid intermediates between 4 and 18 carbons in length. This flexibility has been observed in X-ray and NMR structures of acyl carrier proteins attached to different fatty acids. NMR studies comparing decanoyl-ACP and stearoyl-ACP indicated that ACP exhibits more dynamic motions when bound to longer fatty acids. We have used complementary chemical and NMR methods as an approach to improving our understanding of the effect of fatty acid length on the dynamics of acyl carrier protein. A chemical assay of the accessibility of the acyl thioester to solvent revealed a positive correlation between chain length and rate of hydrolysis. Surprisingly, this linear correlation was biphasic, with accelerated hydrolysis observed for fatty acids longer than 15 carbons. To further understand the motions associated with this acceleration, we collected (15)N relaxation dispersion data for 14:0-, 15:0-, and 16:0-ACP. The greatest dispersions were exhibited by residues that form the entrance to the fatty acid binding pocket. In addition, these dispersions were observed to increase with the length of the fatty acid. Because the exchange rates derived from fitting the data to a two-state model varied from residue to residue, a more complex motional model appears to be required to adequately explain the dynamics. Thus, acyl-ACP offers an interesting system for future investigations of complex protein motions on the micro- and millisecond time scales.
Asunto(s)
Proteína Transportadora de Acilo/química , Ácidos Grasos/química , Proteína Transportadora de Acilo/metabolismo , Sitios de Unión , Cristalografía por Rayos X , Escherichia coli/genética , Escherichia coli/metabolismo , Modelos Moleculares , Resonancia Magnética Nuclear Biomolecular , Conformación ProteicaRESUMEN
Several respiratory viruses, including influenza virus and severe acute respiratory syndrome coronavirus (SARS-CoV), produce more severe disease in the elderly, yet the molecular mechanisms governing age-related susceptibility remain poorly studied. Advanced age was significantly associated with increased SARS-related deaths, primarily due to the onset of early- and late-stage acute respiratory distress syndrome (ARDS) and pulmonary fibrosis. Infection of aged, but not young, mice with recombinant viruses bearing spike glycoproteins derived from early human or palm civet isolates resulted in death accompanied by pathological changes associated with ARDS. In aged mice, a greater number of differentially expressed genes were observed than in young mice, whose responses were significantly delayed. Differences between lethal and nonlethal virus phenotypes in aged mice could be attributed to differences in host response kinetics rather than virus kinetics. SARS-CoV infection induced a range of interferon, cytokine, and pulmonary wound-healing genes, as well as several genes associated with the onset of ARDS. Mice that died also showed unique transcriptional profiles of immune response, apoptosis, cell cycle control, and stress. Cytokines associated with ARDS were significantly upregulated in animals experiencing lung pathology and lethal disease, while the same animals experienced downregulation of the ACE2 receptor. These data suggest that the magnitude and kinetics of a disproportionately strong host innate immune response contributed to severe respiratory stress and lethality. Although the molecular mechanisms governing ARDS pathophysiology remain unknown in aged animals, these studies reveal a strategy for dissecting the genetic pathways by which SARS-CoV infection induces changes in the host response, leading to death.
Asunto(s)
Envejecimiento/inmunología , Citocinas/genética , Síndrome de Dificultad Respiratoria/inmunología , Síndrome de Dificultad Respiratoria/mortalidad , Síndrome Respiratorio Agudo Grave/complicaciones , Coronavirus Relacionado al Síndrome Respiratorio Agudo Severo/inmunología , Regulación hacia Arriba , Animales , Citocinas/inmunología , Muerte , Modelos Animales de Enfermedad , Femenino , Expresión Génica , Humanos , Pulmón/inmunología , Pulmón/patología , Glicoproteínas de Membrana/inmunología , Ratones , Ratones Endogámicos BALB C , Síndrome de Dificultad Respiratoria/genética , Síndrome de Dificultad Respiratoria/virología , Coronavirus Relacionado al Síndrome Respiratorio Agudo Severo/aislamiento & purificación , Coronavirus Relacionado al Síndrome Respiratorio Agudo Severo/fisiología , Síndrome Respiratorio Agudo Grave/genética , Síndrome Respiratorio Agudo Grave/inmunología , Síndrome Respiratorio Agudo Grave/virología , Glicoproteína de la Espiga del Coronavirus , Proteínas del Envoltorio Viral/inmunologíaRESUMEN
Pulmonary exposure to Francisella tularensis is associated with severe lung pathology and a high mortality rate. The lack of induction of classical inflammatory mediators, including IL1-ß and TNF-α, during early infection has led to the suggestion that F. tularensis evades detection by host innate immune surveillance and/or actively suppresses inflammation. To gain more insight into the host response to Francisella infection during the acute stage, transcriptomic analysis was performed on lung tissue from mice exposed to virulent (Francisella tularensis ssp tularensis SchuS4). Despite an extensive transcriptional response in the lungs of animals as early as 4 hrs post-exposure, Francisella tularensis was associated with an almost complete lack of induction of immune-related genes during the initial 24 hrs post-exposure. This broad subversion of innate immune responses was particularly evident when compared to the pulmonary inflammatory response induced by other lethal (Yersinia pestis) and non-lethal (Legionella pneumophila, Pseudomonas aeruginosa) pulmonary infections. However, the unique induction of a subset of inflammation-related genes suggests a role for dysregulation of lymphocyte function and anti-inflammatory pathways in the extreme virulence of Francisella. Subsequent activation of a classical inflammatory response 48 hrs post-exposure was associated with altered abundance of Francisella-specific transcripts, including those associated with bacterial surface components. In summary, virulent Francisella induces a unique pulmonary inflammatory response characterized by temporal regulation of innate immune pathways correlating with altered bacterial gene expression patterns. This study represents the first simultaneous measurement of both host and Francisella transcriptome changes that occur during in vivo infection and identifies potential bacterial virulence factors responsible for regulation of host inflammatory pathways.
Asunto(s)
Francisella tularensis/genética , Francisella tularensis/fisiología , Regulación Bacteriana de la Expresión Génica , Interacciones Huésped-Patógeno/inmunología , Neumonía/inmunología , Neumonía/microbiología , Animales , Femenino , Francisella tularensis/patogenicidad , Perfilación de la Expresión Génica , Pulmón/inmunología , Pulmón/metabolismo , Pulmón/microbiología , Linfocitos/inmunología , Masculino , Ratones , Ratones Endogámicos BALB C , Neumonía/genética , Factores de Tiempo , Transcripción Genética , Tularemia/genética , Tularemia/inmunologíaRESUMEN
RIG-I is a cytosolic pathogen recognition receptor that initiates immune responses against RNA viruses. Upon viral RNA recognition, antiviral signaling requires RIG-I redistribution from the cytosol to membranes where it binds the adaptor protein, MAVS. Here we identify the mitochondrial targeting chaperone protein, 14-3-3ε, as a RIG-I-binding partner and essential component of a translocation complex or "translocon" containing RIG-I, 14-3-3ε, and the TRIM25 ubiquitin ligase. The RIG-I translocon directs RIG-I redistribution from the cytosol to membranes where it mediates MAVS-dependent innate immune signaling during acute RNA virus infection. 14-3-3ε is essential for the stable interaction of RIG-I with TRIM25, which facilitates RIG-I ubiquitination and initiation of innate immunity against hepatitis C virus and other pathogenic RNA viruses. Our results define 14-3-3ε as a key component of a RIG-I translocon required for innate antiviral immunity.
Asunto(s)
Proteínas 14-3-3/metabolismo , Antivirales/metabolismo , ARN Helicasas DEAD-box/metabolismo , Proteínas de la Membrana/metabolismo , Chaperonas Moleculares/metabolismo , Factores de Transcripción/metabolismo , Ubiquitina-Proteína Ligasas/metabolismo , Línea Celular , Proteína 58 DEAD Box , Hepacivirus/inmunología , Humanos , Modelos Biológicos , Unión Proteica , Mapeo de Interacción de Proteínas , Receptores Inmunológicos , Proteínas de Motivos TripartitosRESUMEN
Acyl carrier protein (ACP) is a cofactor in a variety of biosynthetic pathways, including fatty acid metabolism. Thus, it is of interest to determine structures of physiologically relevant ACP-fatty acid complexes. We report here the NMR solution structures of spinach ACP with decanoate (10:0-ACP) and stearate (18:0-ACP) attached to the 4'-phosphopantetheine prosthetic group. The protein in the fatty acid complexes adopts a single conformer, unlike apo- and holo-ACP, which interconvert in solution between two major conformers. The protein component of both 10:0- and 18:0-ACP adopts the four-helix bundle topology characteristic of ACP, and a fatty acid binding cavity was identified in both structures. Portions of the protein close in space to the fatty acid and the 4'-phosphopantetheine were identified using filtered/edited NOESY experiments. A docking protocol was used to generate protein structures containing bound fatty acid for 10:0- and 18:0-ACP. In both cases, the predominant structure contained fatty acid bound down the center of the helical bundle, in agreement with the location of the fatty acid binding pockets. These structures demonstrate the conformational flexibility of spinach ACP and suggest how the protein changes to accommodate its myriad binding partners.
Asunto(s)
Proteína Transportadora de Acilo/química , Proteína Transportadora de Acilo/metabolismo , Decanoatos/química , Spinacia oleracea/química , Estearatos/química , Sitios de Unión , Decanoatos/metabolismo , Modelos Moleculares , Resonancia Magnética Nuclear Biomolecular , Panteteína/análogos & derivados , Panteteína/química , Panteteína/metabolismo , Estructura Cuaternaria de Proteína , Serina/metabolismo , Soluciones , Estearatos/metabolismoRESUMEN
Acyl carrier proteins (ACPs) are important protein cofactors in fatty acid biosynthesis, but their acylated forms have not been well-studied. To permit detailed nuclear magnetic resonance studies of acylated spinach ACP isoform I, we have developed a new expression plasmid for recombinant production of the apo-protein and modified protocols for purifying the protein product and acylating it to form acyl-ACP. To solve plasmid stability problems associated with growth in minimal media, the ampicillin resistance gene from pSACP-2a was replaced with the tetA(C) gene from pBR322. The resulting plasmid, pSACP-2t, supported overexpression of apo-ACP in Escherichia coli BL21(DE3) cells in M9 medium containing 15NH4Cl as the sole nitrogen source. Apo-ACP was purified to homogeneity by means of polyethylene glycol precipitation and anion exchange. Two in vitro synthetic routes were used to produce acyl-ACPs. In one route, apo-ACP was converted to the holo form and the acyl form by a published protocol that employs a discrete enzymatic reaction for each step. As an alternative route to produce decanoyl-ACP, apo-ACP was directly converted to the acyl form by using holo-ACP synthase along with the non-natural substrate decanoyl-CoA. Two-dimensional 1H-15N NMR spectroscopy of decanoyl-ACP and stearoyl-ACP revealed that changes in the length of the covalently attached fatty acid do not affect the secondary structure of the protein but do influence the local conformation and dynamics.