AN INVESTIGATION ON THE EFFECTS OF INFLUENZA VIRUS INFECTION AS IT PERTAINS TO THE INITIATION OF TRANSLATION

McCoy, Morgan Hager

01 January 2004

Like the majority of host cell mRNAs, the mRNAs of influenza virus are capped and polyadenylated. The NS1 protein of influenza has been implicated as a translational activator for both influenza and reporter gene mRNAs. Data is presented showing that influenza A virus infection resulted in an increased ratio of cap-dependent to cap-independent translation. This ratio increase was largely due to an increase in cap-dependent translation. These experiments employed a bicistronic reporter construct measuring cap-dependent and cap-independent translation in a single sample. Expression of NS1 alone resulted in a small, but reproducible increase in the ratio of cap-dependent to cap-independent translation. Additionally, with use of an NS1 deleted mutant influenza A virus (delNS1) it is shown that infection without NS1 expression produced less of a translation ratio increase compared to wild-type virus infection. Furthermore, expression of NS1 rescued a more wild-type ratio increase in delNS1 infected Vero cells. These results implicate NS1 as playing a role in increasing the ratio of cap-dependent to cap-independent translation in influenza A virus infected cells. Additionally, eIF4E-binding protein-1 (4E-BP1), a member of the protein family that inhibits cap-dependent translation through their inhibition of the cap-binding protein, eukaryotic initiation factor 4E (eIF4E), is shown to be inactivated throughout the majority of the influenza A virus infection process.

PATHOGENESIS OF INFLUENZA A VIRUS: INHIBITION OF MONOCYTE DIFFERETIATION INTO DENDRITIC CELL

Boliar, Saikat

01 January 2009

Dendritic cells (DC) are a heterogeneous population of hematopoietic cells that play a versatile role in orchestrating immune responses against an array of invading pathogens, including influenza virus. These cells reside in lymphoid organs as well as in non-lymphoid tissues such as mucosal surfaces of respiratory and gastro-intestinal system. Recent investigations have suggested that in the steady state, dendritic cells are derived mainly from bone marrow precursor cells without a monocytic intermediate whereas during inflammation or infection, monocytes readily differentiate to generate monocyte derived dendritic cells (MoDC). The ability of virus infected monocytes to differentiate into MoDC was investigated and the results demonstrated that in vitro infection of monocytes with influenza virus impaired their development into MoDC. It was also observed that influenza infection of monocytes, pre-treated with GM-CSF and IL-4 for DC differentiation, was minimally-productive and non-cytopathic. In spite of successful viral genome transcription, viral protein synthesis was restricted at an early stage. However, despite of the limited replication, influenza virus infected monocytes failed to develop the distinctive DC- like morphology when cultured with GM-CSF and IL- 4 as compared to their mock infected counterparts. Infected cells, after 4 days in culture, expressed reduced amounts of CD11c, CD172a (myeloid marker), CD1w2 (CD1b) and CCR5. Influenza virus infected monocytes also retained substantial non-specific esterase activity, a characteristic for monocytes and macrophages. Antigen presentation capability of infected cells was also affected as indicated by decreased endocytosis. Production of IL-12, a pro-inflammatory cytokine and IL-10, a reciprocal inhibitory cytokine, was coordinately modified in influenza virus infected monocytes in order to arrest their differentiation into DCs. At least limited viral replication was necessary to impede the differentiation process completely. However, viral NS1 protein activity, as evidenced with a mutant influenza virus, was not essential for this inhibition. This identified a new strategy by influenza virus to interfere with DC differentiation and evade a virus specific immune response.

Veterinary Medicine

Role of Ly49 Receptors on Natural Killer Cells During Influenza Virus Infection

Mahmoud, Ahmad

23 August 2012

Natural killer (NK) cells are lymphocytes of the innate immune system that play a major role in the destruction of both tumours and virally-infected cells. The cytotoxicity of NK cells is tightly controlled by signals received through activating and inhibitory receptors. NK cells express a variety of inhibitory receptors such as Ly49 receptors. Ly49 receptors bind to class I MHC molecules that expressed on normal cells. Using Ly49-deficient (NKCKD) mice we show that Ly49-KD NK cells successfully recognize and kill influenza virus-infected cells and that NKCKD mice exhibit better survival than wild-type mice. Moreover, influenza virus infection has a propensity to upregulate cell surface expression of MHC-I on murine lung epithelial cells in vivo. Significantly, we demonstrate increased lung damage of WT-mice versus NKCKD mice after influenza virus infection as determined by histological analyses. This data indicated that absence of Ly49 inhibitory NK receptors greatly enhances survival of infected mice.

Influenza Virus

MHC-I

Natural Killer cells

NK cells

Antiviral activity of maca (Lepidium meyenii) against human influenza virus

Del Valle Mendoza, Juana, Pumarola, Tomàs, Alzamora Gonzales, Libertad, Del Valle, Luis J.

20 November 2014

Objective: To investigate antiviral activity of maca to reduce viral load in kidney (MDCK) cells infected with influenza type A and B viruses (Flu-A and MFalud-inB-, Dreasrpbeyc ctiavneilny)e. Methods: Maca were extracted with methanol (1:2, v/v). The cell viability and toxicity of the eaxgtariancstts Fwluer-eA e avnaldu aFtleud- oBn v MirDusCeKs cwealsls a usssianyge dm uetshinogd aM TteTs ta sfosar yd. eAtenrtmiviinrainl ga ctthiev itiyn hoifb citoimonp oouf nthdes cytopathic effect on cell culture and multiplex RT-PCR. Results: The methanol extract of maca showed low cytotoxicity and inhibited influenza-induced cytopathic effect significantly, while viral load was reduced via inhibition of viral growth in MDCK infected cells. Maca contains potent inhibitors of Flu-A and Flu-B with a selectivity index [cytotoxic concentration 50%/IC50] of 157.4 and 110.5, respectively. Conclusions: In vitro assays demonstrated that maca has antiviral activity not only against Flu-A (like most antiviral agents) but also Flu-B viruses, providing remarkable therapeutic benefits. / Financial support of this study was provided by AECID grants (PCI: C/033641/10) and AGAUR (MAT2009-11503, MAT2012-36205, 2009SGR-1208). JDVM support was provided by 1st Concurso Incentivo a la Investigación de la Universidad Peruana de Ciencias Aplicadas, Lima, Peru. / Revisión por pares

Influenza virus flu

Antiviral activity

Lepidium meyenii

Maca

THE ROLE OF CD8 T CELL IMMUNODOMINANCE AND REGULATORY T CELLS IN NEONATAL IMMUNITY TO INFLUENZA VIRUS

Heil, Luke

01 January 2019

Neonates are more susceptible to influenza virus infection than adults, resulting in increased morbidity and mortality as well as delayed clearance of the virus. Efforts to improve influenza infection outcomes in neonates typically center on prevention, although current vaccines fall short of complete protection and can only be administered in humans after 6 months of life. We propose that as the neonatal immune system responds differently than the adult immune system, interventions that are efficacious or tolerable in adults cannot be guaranteed to perform the same in neonates. T cell vaccines that target conserved influenza virus epitopes have been proposed for conferring protection to multiple influenza virus strains, but if T cell vaccines will be used in infants and adults, neonates must be able to respond to the same T cell antigens as adults. Mouse pups responded to influenza virus peptide PA224-233 but not NP366-374 during influenza virus infection in contrast to the codominant adult response. Mice infected as pups also generated diminished T cell memory compared to mice infected as adults and displayed skewed immunodominance during secondary infection. Adult bone marrow derived dendritic cells (BMDCs) improved viral clearance when loaded with influenza virus and promoted NP366-374-specific CD8+ T cell responses in infected pups. BMDC peptide vaccination could stimulate PA224-233-specific but not NP366-374-specific CD8+ T cell responses in pups, but, PA224-233 vaccination offered no protection to pups during lethal infection. These data suggest that altered immunodominance must be considered when stimulating CD8+ T cell responses in adults and neonates. Immaturity and active suppression of immune responses are both factors in neonatal vulnerability to disease. Specifically, active suppression of neonatal immunity by regulatory T cells (Tregs) has been proposed as a driving factor in diminished neonatal immunity, but removing these cells can compromise viral defense or increase deleterious inflammation. Mice that lacked Tregs displayed compromised anti-influenza antibody responses and decreased lymph node responses during influenza virus infection. A high proportion of pup Tregs also expressed Gata3. Transgenic pups with a Treg specific Gata3 knockout displayed an increase in Tbet expression in both conventional and regulatory T cells and an increase in IFNγ producing CD4+ T cells in the lungs during infection. These data suggest that Tregs are required for effective humoral responses to influenza virus and that Gata3 expression influences Treg suppressive function in neonates.

Neonates

Influenza virus

T cells

Lung

Immunodominance

vaccine

Medical Immunology

The role of pulmonary dendritic cells in regulating the antigen-specific CD8 T cell response following influenza virus infection

McGill, Jodi Lynn

01 May 2010

We have recently demonstrated in a model of influenza A virus (IAV) infection that the absence of specific pulmonary DC subsets, including plasmacytoid DC (pDC) and CD8a+ DC, from the lungs leads to a significant decrease in the number of virus-specific CD8 T cells. Reconstitution of the lungs with physiologic numbers of pDC or CD8a+ DC is able to restore the pulmonary IAV-specific CD8 T cell response to near normal levels via a mechanism that is dependent upon direct DC:T cell interactions, DC-expressed MHC I and the presence of viral antigen. Interestingly, however, this rescue is DC subset specific, as reconstitution with purified alveolar and airway DC or alveolar macrophages was unable to rescue the virus-specific CD8 T cell response. Following IAV infection there is an abundance of IAV antigen and MHC I expressing cells present in the lungs, including infected epithelial cells. Given this fact and the inability of all DC subsets to rescue the virus-specific CD8 T cell response, it suggested that there were additional, undefined requirements for pDC- and CD8a+ DC-mediated rescue of the T cell response in the lungs. Further, although it was known that the reduction in virus-specific CD8 T cells in the lungs was a result of increased T cell apoptosis, it remained unclear what pathways of apoptosis were contributing to the increased cell death, and what mechanism pulmonary DC subsets were utilizing to rescue this defect. Here, we demonstrate that in the absence of lung-resident DC subsets, virus-specific CD8 T cells undergo significantly increased levels of apoptosis via both extrinsic activation induced cell death and intrinsic activated cell-autonomous death pathways. Reconstitution of aDC depleted lungs with pulmonary pDC and CD8a+ DC promotes increased T cell expression of the pro-survival molecule Bcl-2 and hence, increased T cell survival and accumulation in the lungs. Our studies herein demonstrate that pulmonary DC subsets utilize a variety of mechanisms to promote the rescue of virus-specific CD8 T cells in the lungs. Blockade of the costimulatory molecules CD70, and in some cases, 4-1BBL and OX40L, ablates the pulmonary DC mediated rescue of CD8 T cell numbers in the lungs, suggesting that late costimulation is one essential mechanism that pulmonary DC use to regulate CD8 T cell immunity following IAV infection. Further, we demonstrate that the absence of DC following IAV infection results in significantly reduced levels of IL-15 in the lungs and that pulmonary DC-mediated rescue of virus-specific CD8 T cell responses in the lungs requires the trans-presentation of IL-15 via DC-expressed IL-15Ra. In addition to the role of pulmonary DC mediated costimulation and IL-15 trans-presentation, we further demonstrate a previously unrecognized role for viral antigen in regulating the accumulation of both pulmonary DC and virus-specific CD8 T cells in the lungs, suggesting that viral load can dictate the nature of the inflammatory environment in the lungs and thus, regulate the character of the ensuing IAV-specific immune response. Collectively, the results detailed here demonstrate a previously unrecognized role for pulmonary DC in regulating primary IAV-specific CD8 T cell immunity, and hence, promoting enhanced viral clearance and recovery from disease.

CD8 T cells

dendritic cells

influenza virus

Immunology of Infectious Disease

Role of Ly49 Receptors on Natural Killer Cells During Influenza Virus Infection

Mahmoud, Ahmad

23 August 2012

Natural killer (NK) cells are lymphocytes of the innate immune system that play a major role in the destruction of both tumours and virally-infected cells. The cytotoxicity of NK cells is tightly controlled by signals received through activating and inhibitory receptors. NK cells express a variety of inhibitory receptors such as Ly49 receptors. Ly49 receptors bind to class I MHC molecules that expressed on normal cells. Using Ly49-deficient (NKCKD) mice we show that Ly49-KD NK cells successfully recognize and kill influenza virus-infected cells and that NKCKD mice exhibit better survival than wild-type mice. Moreover, influenza virus infection has a propensity to upregulate cell surface expression of MHC-I on murine lung epithelial cells in vivo. Significantly, we demonstrate increased lung damage of WT-mice versus NKCKD mice after influenza virus infection as determined by histological analyses. This data indicated that absence of Ly49 inhibitory NK receptors greatly enhances survival of infected mice.

Influenza Virus

MHC-I

Natural Killer cells

NK cells

Functional and structural studies of influenza B virus hemagglutinin

Ni, Fengyun

16 September 2013

Influenza A and B viruses are major causes of seasonal flu epidemics each year. Hemagglutinin (HA) mediates the binding of virus to host cell and the fusion with host membrane. The crystal of HA in complex with antibody that reveals the mechanism by which antibody recognizes HA may not diffract to high resolution, thereby preventing the accurate interpretation of the structural model. The application of normal mode refinement that aims for improving the structure quality at the low resolution is tested. These studies provide some guidelines for future refinement of HA-antibody complex structures. By comparing the residues constituting the base of the receptor binding site of influenza A and B virus HAs, it is found that they share some similarities, except for a Phe at position 95 of influenza B virus hemagglutinin (BHA) versus Tyr in of influenza A virus hemagglutinin (AHA). The recombinant protein BHA containing the F95Y mutation exhibits the increased receptor binding affinity and specificity. However, recombinant viruses with the Phe95Tyr mutation show lower erythrocyte agglutination titer and decreased binding abilities with different cell lines. The replication of the Phe95Tyr mutant virus in mice is also attenuated. These data suggest that the increased receptor binding ability of HA alone is not advantageous to the pathogenesis of the viruses. The structure of BHA2 (a portion of BHA near the C-terminus) at the post-fusion state has been determined to 2.45 Å resolution. This protein forms a hairpin-like conformation rich in -helices. About 70 residues from the N-terminus is a three-stranded coiled coil, and the remaining of the protein packs in anti-parallel against the groove formed by the central helices. In the post-fusion state of BHA2, the helix converted from the B-loop in pre-fusion state contacts the C-terminal fragment of this protein with more hydrophobic interactions as compared to AHA2. This structure illustrates the distinct stabilization strategy employed by BHA2 to form a post-fusion state that resembles that for AHA2. These studies will further the understanding of BHA with respect to its role in receptor binding ability and fusion.

influenza virus

hemagglutinin

normal mode refinement

receptor binding

fusion

Study on health effects of bird's nest

Chen, I-Jen

12 August 2011

Bird¡¦s nest is the saliva from the Colloclia that have a lot of mucin and sialic acid. However the sialic acid is an important intermediate of influenza virus infection. In 2006, Guo et al was confirmed the Inhibitory effect of bird¡¦s nest extract on influenza virus infection. But the anti-virus component has not been isolated and purified. First, the bird's nest used in this study was proved to be a pure bird¡¦s nest by SDS-PAGE, sialic acid content and protein content. Qualification analysis by SDS-PAGE showed sample possessed three bands at about 50 kDa, 100 kDa and 150 kDa, by Warren assay showed sample possessed a sialic acid content about 10% of dry weight, by Kjeldahl method showed sample possessed a protein content about 50% of dry weight, and by fluorescence analysis in 365 nm showed sample emitted a blue-white light. According to the criteria on previous studies, the sample was considered to be a real and pure bird¡¦s nest. Subsequently, the sample was applied to pronase digestion and then separated by Bio-gel P2 for size exclusion chromatography. All fractions were performed carbohydrate analysis including sialic acid. In lectin blotting, Maackia amurensis agglutinin (MAA) lectin can interact with the fraction that suggest the structure of sialic acid is sialic acid-2,3 galactose in bird¡¦s nest. And carbohydrate membrane array to demonstrate the influenza virus of H5N1 and H1N1 can bind the fractions that suggest the antivirus effect of bird¡¦s nest. These fractions will be further analyzed by neutralization assay to study their antivirus effects in vitro.

carbohydrate membrane array

Neu5Ac

bird¡¦s nest

Tn

influenza virus

Regulation of Ion Channel Physiology in Airway Epithelial cells in response to Influenza A Virus Infection

2013 August 1900

Epithelial cells lining the upper airways are characterized by low sodium absorption and elevated chloride secretion. Together, the movement of these ions creates the osmotic drive to hydrate the airways. Recent studies indicate that influenza is capable of directly modulating the vectorial transport of sodium and chloride ions. However, the direct impact of influenza has not been studied with respect to potassium channels. This is significant because potassium conductance creates the driving force for chloride secretion. Disruptions to this process leads to edema formation in the lungs and can subsequently cause Acute Respiratory Distress Syndrome. Additionally, it has been demonstrated that the induction of pro-inflammatory cytokines in infected cells may contribute to altered ion channel function, further exacerbating edema formation. The purpose of this study was to assess the direct and indirect effects of influenza virus infection on potassium and chloride ion channel function in a secretory epithelial cell model. In order to assess the direct effects we exposed polarized epithelial cell monolayers to varying doses of H1N1 virus. Potassium and chloride channel function was measured by means of short-circuit current in an Ussing chamber. The immune response to viral infection was determined by RT-qPCR and Bioplex suspension array. Virus conditioned media (CM), and IL-8 were used to characterize the indirect effects on non-infected cells. We observed an increase in chloride secretion, consistent with edema formation, when 60% of the epithelium was infected, and after CM treatment. This observation correlated with increased potassium channel conductance through the calcium-activated (KCNN4) and cAMP-activated potassium channels (KCNQ1), which was ameliorated upon specific inhibition of these channels. The data suggest that the mixture of pro-inflammatory cytokines induced by viral infection directly up-regulate these potassium channels. However, treatment with IL-8 also appears to increase chloride secretion, although the underlying mechanism remains to be determined, as it is not mediated through KCNN4 and KCNQ1. We conclude that the strong induction of cytokines in infected cells act in a paracrine manner on non-infected cells to increase potassium channel conductance. This up-regulation of potassium channels subsequently drives an increase in chloride secretion, leading to fluid build-up in the lungs and edema formation.

Airway epithelium

ion channels

CFTR

KCNN4

KCNQ1

influenza virus

cytokines