Project description:Heldt2012 - Influenza Virus Replication The model describes the life cycle of influenza A virus in a mammalian cell including the following steps: attachment of parental virions to the cell membrane, receptor-mediated endocytosis, fusion of the virus envelope with the endosomal membrane, nuclear import of vRNPs, viral transcription and replication, translation of the structural viral proteins, nuclear export of progeny vRNPs and budding of new virions. It also explicitly accounts for the stabilization of cRNA by viral polymerases and NP and the inhibition of vRNP activity by M1 protein binding. In short, the model focuses on the molecular mechanism that controls viral transcription and replication. This model is described in the article: Modeling the intracellular dynamics of influenza virus replication to understand the control of viral RNA synthesis. Heldt FS, Frensing T, Reichl U. J Virol. Abstract: Influenza viruses transcribe and replicate their negative-sense RNA genome inside the nucleus of host cells via three viral RNA species. In the course of an infection, these RNAs show distinct dynamics, suggesting that differential regulation takes place. To investigate this regulation in a systematic way, we developed a mathematical model of influenza virus infection at the level of a single mammalian cell. It accounts for key steps of the viral life cycle, from virus entry to progeny virion release, while focusing in particular on the molecular mechanisms that control viral transcription and replication. We therefore explicitly consider the nuclear export of viral genome copies (vRNPs) and a recent hypothesis proposing that replicative intermediates (cRNA) are stabilized by the viral polymerase complex and the nucleoprotein (NP). Together, both mechanisms allow the model to capture a variety of published data sets at an unprecedented level of detail. Our findings provide theoretical support for an early regulation of replication by cRNA stabilization. However, they also suggest that the matrix protein 1 (M1) controls viral RNA levels in the late phase of infection as part of its role during the nuclear export of viral genome copies. Moreover, simulations show an accumulation of viral proteins and RNA toward the end of infection, indicating that transport processes or budding limits virion release. Thus, our mathematical model provides an ideal platform for a systematic and quantitative evaluation of influenza virus replication and its complex regulation. With the current parameter set, the model reproduces an infection at a multiplicity of infection (MOI) of 10. Figure 2A of the paper is reproduced here, with parameters kDegRnp and kSynP changed to zeros. Initial conditions and parameter changes that were used to obtain specific figures in the article can be found in Table A2. The model has the correct value for kAttLo as 4.55e-04. The value of this parameter mentioned as 4.55e-02 in Table 1 of the paper is incorrect. This is checked with the author. This model is hosted on BioModels Database and identified by: MODEL1307270000 . To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:<p>The overall purpose of this study is to investigate the host genetic factors in response to influenza virus infection, with the focus on influenza vaccination in the first substudy "Adult Influenza Vaccine Genetics" and with the focus on influenza natural infection and other acute respiratory infections (ARIs) in the second substudy "Acute Viral Respiratory Infection Genetics". In the first substudy, healthy adults were enrolled in 2008 (male cohort) and 2010 (female cohort) and immunized with seasonal influenza vaccine. In the second substudy, healthy adults were invited to enroll to be followed for acute respiratory illness through two consecutive influenza seasons 2009-2010 and 2010-2011. Peripheral blood genomic DNA samples were collected from all the subjects, and time-series RNA and serum samples were obtained pre- and post- immunization/infection. Genotyping was carried out on peripheral blood genomic DNA samples using Illumina HumanOmniExpress-12 v1 arrays. Peripheral blood RNA samples obtained at each visit were analyzed using Illumina Human HT-12 (for all the samples) and HiSeq 2000 (for 130 samples in the "Acute Viral Respiratory Infection Genetics" study). Serum specimens were tested using hemagglutination-inhibition (HAI) antibody assay for Influenza H1N1, H3N2, and Influenza B strains.</p> <p>A detailed description of each substudy is provided under their own pages below and via the grouping tool in the right-hand box: <ul> <li><a href="./study.cgi?study_id=phs000635">phs000635</a> Adult Influenza Vaccine Genetics</li> <li><a href="./study.cgi?study_id=phs001031">phs001031</a> Acute Viral Respiratory Infection Genetics</li> </ul> </p>

Project description:To study the impact of influenza infection on gene expression changes in the colon, mice were intra-nasally infected with 30 plaque forming units of the mouse-adapted H3N2 IAV strain Scotland/20/1974. PBS-treated mice served as controls. The colons were collected 7 days post-infection.

Project description:Ihh expression is required for intestinal stem cell niche development. Loss of Ihh leads to disruption of intestinal stem cell niche, which leads to abnormal stem cell development and epithelial cell differentiation. 3 paired control (C) and mutant (M) mice here harvested. Their colon tissues were analyzed using Affymetrix Mouse Gene 1.0ST array Control and VilCre;Ihhflox/flox mice were harvested at p12 There are 3 pairs (total 6) samples: M1 and C1 are littermates M2 and C2 are littermates M3 and C3 are littermates

Project description:To investigate whether influenza A virus (IV) infection impairs alveolar protein clearance we analyzed AEC and BAL cells of IV-infected mice. We performed gene expression profiling analysis using data obtained from RNA-seq of AEC and BAL cells after 5 days of IV infection.

Project description:Human intestinal epithelial organoid models are rapidly emerging as novel experimental tools to investigate intestinal epithelial biology. A necessary aspect of organoid use is the passaging of cells and long term maintenance in culture. DNA methylation has been demonstrated to play a key role in regulating gene expression and cellular function. Here we explore the effect of culture duration, proinflammatory cytokine stimulation and differentiation on organoid DNA methylation. The experiment consists of RNA-seq of intestinal organoid cultures from paediatric ileum and colon.

Project description:To investigate whether SPARCL1 affects lung macrophage polarization in vivo RNA sequencing (RNA-seq) of isolated lung macrophages (CD45+Ly6G-CD64+F4/80+) on day 20 post-influenza infection was used to further examine the consequences of EC overexpression of Sparcl1.

Project description:The GATM gene shows strong transcriptional regulation during influenza infection and increased GATM transcription correlates with peak viral titers in the lung. In order to investigate an in vivo role for GATM during influenza infection, we created a peptide-conjugated phosphorodiamidate morpholino oligomer (PPMO) to disrupt GATM translation. In our study, mice received a GATM-specific PPMO or scrambled PPMO once per day for two days, and then were subsequently infected with an H1N1 (A/California/04/2009) strain of IAV or PBS as a mock infection control. Mouse lungs were harvested three days post-infection and analyzed via RNA sequencing.

Project description:Influenza virus infection leads to global cardiac proteome remodeling during convalescence MTD project_description "Influenza virus infections lead to more than 500,000 hospitalizations in the U.S. every year. Patients with cardiovascular diseases have been shown to be at high risk of influenza mediated cardiac complications. Importantly, recent reports have provided clinical data supporting a direct link between laboratory-confirmed influenza virus infection and adverse cardiac events. However, the molecular mechanisms of how influenza virus infection induces detrimental cardiac changes, even after resolution of the pulmonary infection, is completely unknown.

Project description:Analysis of the cystic fibrosis gene Cftr in the colon and small intestine of Cftr-deficient murine model. The hypothesis was loss of Cftr altered expression of genes important in intestinal homeostasis and oncogenic signaling pathways. The results identified potential roles of Cftr in up- or down-regulating major gene clusters that belong to groups of immune response, ion channel, intestinal stem cell and other growth regulators. Total RNA was isolated from the normal intestine of three Apc wildtype Cftr wildtype and three Apc Cftr-deficient mice. For the colon intestinal epithelia from the same region of the distal colon of each mouse was separated from the rest of the intestine prior to RNA isolation. Therefore RNA was obtained from only epithelial cells. For the small intestine, a section of the mid-duodenum from each mouse was sheared of villi prior to RNA isolation. Therefore RNA was obtained from whole duodenum (minus villi), containing epithelia cells but also stromal and other cells. RNA Seq was then conducted on all samples, with at least two replicates for each biological sample.