Project description:A. Esteban Hernandez-Vargas & Michael Meyer-Hermann. Innate Immune System Dynamics to Influenza Virus. IFAC Proceedings Volumes 45, 18 (2012). The understanding of how influenza virus infection activates the immune system is crucial to designing prophylactic and therapeutic strategies against the infection. Nevertheless, the immune response to influenza virus infection is complex and remains largely unknown. In this paper we focus in the innate immune response to influenza virus using a mathematical model, based on interferon-induced resistance to infection of respiratory epithelial cells and the clearance of infected cells by natural killers. Simulation results show the importance of IFN-I to prevent new infections in epithelial cells and to stop the viral explosion during the first two days after infection. Nevertheless, natural killers response might be the most relevant for the first depletion in viral load due to the elimination of infected cells. Based on the reproductive number, the innate immune response is important to control the infection, although it would not be enough to clear completely the virus. The effective coordination between innate and adaptive immune response is essential for the virus eradication.

Project description:RNA viruses are a major threat to global human health. The life cycles of many highly pathogenic RNA viruses like influenza A virus (IAV) and Lassa virus depends on host mRNA, as viral polymerases cleave 5′m7G-capped host transcripts to prime viral mRNA synthesis (‘cap-snatching’). We hypothesized that start codons within cap-snatched host transcripts could drive the expression of chimeric human-viral coding sequences. Here, we report the existence of this mechanism of gene origination (‘start-snatching’), which creates, depending on the translatability of the viral UTRs, human-virus protein chimeras either as N-terminally extended viral proteins or entirely novel polypeptides by genetic overprinting. We show that both types of chimeric proteins are made in IAV-infected cells, can generate T cell responses and contribute to virulence. Our results indicate that IAV, and likely a multitude of other human-, animal- and plant-viruses, use this host-dependent mechanism to expand their proteome diversity during infection.

Project description:Next-generation proteomics of Vero E6 cells infected by Italy-INMI1 SARS-CoV-2 virus for defining relevant viral peptides for detection. Cells from Day4 post-infection at 0.01 multiplicity of infection. [Original project description]

Project description:Influenza B virus (IBV) is an acute respiratory pathogen that induces phenotypic alterations to the lung epithelium, such as the denudation of the respiratory cilium, during and after IBV infection. It has been assumed that these epithelial changes are non-adaptive, and simply the result of cellular death following lytic virus infection. However, previous reports have shown that not all infected cells are killed after viral infection; some cells can completely clear viral RNA and protein and persist in the host long-term. In this study, we utilized a novel recombinant virus in combination with a Cre recombinase-responsive transgenic mouse model to demonstrate that IBV infection leads to the formation of a population of survivor ciliated cells in the proximal airways of infected mice. We then performed transcriptional profiling on infected and surviving ciliated cell populations to determine how surviving viral infection affected these cells. To specifically profile ciliated cells, we digested mouse lungs and sorted cells based on their expression of CD24 with tdTomato as a marker of infection. We sorted cell populations from the lungs of animals mock infected with PBS (Mock), during active infection (2 DPI), and matched ciliated cell populations at 14 days post-infection that had either experienced direct viral infection (14 DPI Survivor Cell) or those that had never been infected (14 DPI). The resulting data indicate that after surviving infection and clearing the virus, survivor ciliated cells undergo significant transcriptional reprogramming.

Project description:Viral infection can dramatically alter a cell's transcriptome. However, these changes have mostly been studied by bulk measurements on many cells. Here we use single-cell mRNA sequencing to examine the transcriptional consequences of influenza virus infection. We find extremely wide cell-to-cell variation in production of viral gene transcripts -- viral transcripts compose less than a percent of total mRNA in many infected cells, but a few cells derive over half their mRNA from virus. Some infected cells fail to express at least one viral gene, and this gene absence partially explains variation in viral transcriptional load. Despite variation in total viral load, the relative abundances of viral mRNAs are fairly consistent across infected cells. Activation of innate immune pathways is rare, but some cellular genes co-vary in abundance with the amount of viral mRNA. Overall, our results highlight the complexity of viral infection at the level of single cells.

Project description:Transcriptome analysis of mock or H1N1 IAV PR8 infected p53WT A549 and p53null A549-KO3 cells by Affymetrix GeneChip Human Transcriptome 2.0 Arrays to achieve a set of genes those are regulated by p53 and responsive to IAV infection. Influenza A virus infection activates cellular p53, however it has not been clear whether this process has pro- or anti- viral effects. In this study, using human isogenic p53 wildtype A549 cells and p53null A549-KO3 cells generated from the CRISPR/Cas9 technology, we report that p53null cells exhibit significantly reduced viral propagation property when infected with influenza A virus (H1N1/A/Puerto Rico/8/34). Here, using genome-wide microarray analysis we revealed that p53 regulates the expression of a large set of interferon-inducible genes, some of which are directly associated with viral infectivity and later experimentally validated to be responsible for p53-regulated IAV infectivity.

Project description:Next-generation proteomics of Vero E6 cells infected by Italy-INMI1 SARS-CoV-2 virus for defining relevant viral peptides for detection. Cells from Day4 post-infection at 0.01 multiplicity of infection.

Project description:Influenza B virus (IBV) is an acute respiratory pathogen that induces phenotypic alterations to the lung epithelium, such as the denudation of the respiratory cilium, during and after IBV infection. It has been assumed that these epithelial changes are non-adaptive, and simply the result of cellular death following lytic virus infection. However, previous reports have shown that not all infected cells are killed after viral infection; some cells can completely clear viral RNA and protein and persist in the host long-term. In this study, we utilized a novel recombinant virus in combination with a Cre recombinase-responsive transgenic mouse model to demonstrate that IBV infection leads to the formation of a population of survivor ciliated cells in the proximal airways of infected mice. To ensure that we were studying ciliated cells with markers that were maintained during viral infection in vivo, we performed single-cell transcriptional profiling on infected and surviving ciliated cell populations. We digested mouse lungs and sorted cells using tdTomato as a marker of infection. We sorted cell populations from the lungs of animals mock infected with PBS (Mock) and during active infection (2 DPI). The resulting data revealed that the marker CD24 is consistently expressed on ciliated cells before and during viral infection.

Project description:This a model from the article: Dynamics of HIV infection of CD4+ T cells. Perelson AS, Kirschner DE, De Boer R. Math Biosci 1993 Mar;114(1):81-125 8096155 , Abstract: We examine a model for the interaction of HIV with CD4+ T cells that considers four populations: uninfected T cells, latently infected T cells, actively infected T cells, and free virus. Using this model we show that many of the puzzling quantitative features of HIV infection can be explained simply. We also consider effects of AZT on viral growth and T-cell population dynamics. The model exhibits two steady states, an uninfected state in which no virus is present and an endemically infected state, in which virus and infected T cells are present. We show that if N, the number of infectious virions produced per actively infected T cell, is less a critical value, Ncrit, then the uninfected state is the only steady state in the nonnegative orthant, and this state is stable. For N > Ncrit, the uninfected state is unstable, and the endemically infected state can be either stable, or unstable and surrounded by a stable limit cycle. Using numerical bifurcation techniques we map out the parameter regimes of these various behaviors. oscillatory behavior seems to lie outside the region of biologically realistic parameter values. When the endemically infected state is stable, it is characterized by a reduced number of T cells compared with the uninfected state. Thus T-cell depletion occurs through the establishment of a new steady state. The dynamics of the establishment of this new steady state are examined both numerically and via the quasi-steady-state approximation. We develop approximations for the dynamics at early times in which the free virus rapidly binds to T cells, during an intermediate time scale in which the virus grows exponentially, and a third time scale on which viral growth slows and the endemically infected steady state is approached. Using the quasi-steady-state approximation the model can be simplified to two ordinary differential equations the summarize much of the dynamical behavior. We compute the level of T cells in the endemically infected state and show how that level varies with the parameters in the model. The model predicts that different viral strains, characterized by generating differing numbers of infective virions within infected T cells, can cause different amounts of T-cell depletion and generate depletion at different rates. Two versions of the model are studied. In one the source of T cells from precursors is constant, whereas in the other the source of T cells decreases with viral load, mimicking the infection and killing of T-cell precursors.(ABSTRACT TRUNCATED AT 400 WORDS) This model was taken from the CellML repository and automatically converted to SBML. The original model was: Perelson AS, Kirschner DE, De Boer R. (1993) - version=1.0 The original CellML model was created by: Ethan Choi mcho099@aucklanduni.ac.nz The University of Auckland This model originates from BioModels Database: A Database of Annotated Published Models (http://www.ebi.ac.uk/biomodels/). It is copyright (c) 2005-2011 The BioModels.net Team. 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. In summary, you are entitled to use this encoded model in absolutely any manner you deem suitable, verbatim, or with modification, alone or embedded it in a larger context, redistribute it, commercially or not, in a restricted way or not.. To cite BioModels Database, please use: Li C, Donizelli M, Rodriguez N, Dharuri H, Endler L, Chelliah V, Li L, He E, Henry A, Stefan MI, Snoep JL, Hucka M, Le Novère N, Laibe C (2010) BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. BMC Syst Biol., 4:92.

Project description:This a model from the article: Dynamics of HIV infection of CD4+ T cells. Perelson AS, Kirschner DE, De Boer R. Math Biosci 1993 Mar;114(1):81-125 8096155 , Abstract: We examine a model for the interaction of HIV with CD4+ T cells that considers four populations: uninfected T cells, latently infected T cells, actively infected T cells, and free virus. Using this model we show that many of the puzzling quantitative features of HIV infection can be explained simply. We also consider effects of AZT on viral growth and T-cell population dynamics. The model exhibits two steady states, an uninfected state in which no virus is present and an endemically infected state, in which virus and infected T cells are present. We show that if N, the number of infectious virions produced per actively infected T cell, is less a critical value, Ncrit, then the uninfected state is the only steady state in the nonnegative orthant, and this state is stable. For N > Ncrit, the uninfected state is unstable, and the endemically infected state can be either stable, or unstable and surrounded by a stable limit cycle. Using numerical bifurcation techniques we map out the parameter regimes of these various behaviors. oscillatory behavior seems to lie outside the region of biologically realistic parameter values. When the endemically infected state is stable, it is characterized by a reduced number of T cells compared with the uninfected state. Thus T-cell depletion occurs through the establishment of a new steady state. The dynamics of the establishment of this new steady state are examined both numerically and via the quasi-steady-state approximation. We develop approximations for the dynamics at early times in which the free virus rapidly binds to T cells, during an intermediate time scale in which the virus grows exponentially, and a third time scale on which viral growth slows and the endemically infected steady state is approached. Using the quasi-steady-state approximation the model can be simplified to two ordinary differential equations the summarize much of the dynamical behavior. We compute the level of T cells in the endemically infected state and show how that level varies with the parameters in the model. The model predicts that different viral strains, characterized by generating differing numbers of infective virions within infected T cells, can cause different amounts of T-cell depletion and generate depletion at different rates. Two versions of the model are studied. In one the source of T cells from precursors is constant, whereas in the other the source of T cells decreases with viral load, mimicking the infection and killing of T-cell precursors.(ABSTRACT TRUNCATED AT 400 WORDS) This model was taken from the CellML repository and automatically converted to SBML. The original model was: Perelson AS, Kirschner DE, De Boer R. (1993) - version=1.0 The original CellML model was created by: Ethan Choi mcho099@aucklanduni.ac.nz The University of Auckland This model originates from BioModels Database: A Database of Annotated Published Models (http://www.ebi.ac.uk/biomodels/). It is copyright (c) 2005-2011 The BioModels.net Team. 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. In summary, you are entitled to use this encoded model in absolutely any manner you deem suitable, verbatim, or with modification, alone or embedded it in a larger context, redistribute it, commercially or not, in a restricted way or not.. To cite BioModels Database, please use: Li C, Donizelli M, Rodriguez N, Dharuri H, Endler L, Chelliah V, Li L, He E, Henry A, Stefan MI, Snoep JL, Hucka M, Le Novère N, Laibe C (2010) BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. BMC Syst Biol., 4:92.