Influenza A virus (IAV) has two envelope glycoproteins, hemagglutinin (HA) and neuraminidase (NA). HA binds to sialic acids at the terminals of glycochains on the host cell surface as virus receptors. NA shows sialidase activity, which cleaves sialic acids from the terminals of glycochains. A new subtype (antigenicities of HA and NA) of IAV for humans has pandemic potential. We investigated t...

BACKGROUND Previous studies have demonstrated that DC differentially regulate influenza A virus (IAV)-specific CD8 T cell responses in vivo during high and low dose IAV infections. Furthermore, in vitro infection of DC with IAV at low versus high multiplicities of infection (MOI) results in altered cytokine production and a reduced ability to prime naïve CD8 T cell responses. Flow cytometric de...

A series of aminoglucoglycerolipids derivatives had been synthesized, including 6'-acylamido-glucoglycerolipids 1a-1f and corresponding 2'-acylamido-glucoglycerolipids 2a-2c bearing different fatty acids, glucosyl diglycerides 3a-3e bearing different functional groups at C-6' and ether-linked glucoglycerolipids 4a-4c with double-tailed alkyl alcohol. The anti-influenza A virus (IAV) activity wa...

Cellular protein interaction networks are integral to host defence and immune signalling pathways, which are often hijacked by viruses via protein interactions. However, the comparative virus-host protein interaction networks and how these networks control host immunity and viral infection remain to be elucidated. Here, we mapped protein interactomes between human host and several influenza A v...

Innate sensing of nucleic acids lies at the heart of antiviral immunity. During viral infection, dying cells may also release nucleic acids into the tissue microenvironment. It is unknown what effect such host signals have on the quality or duration of the immune response to viruses. In this study, we uncovered an immune-regulatory pathway that tempers the intensity of the host response to infl...

RATIONALE Pulmonary infections can impair alveolar fluid clearance (AFC), contributing to formation of lung edema. Effects of influenza A virus (IAV) on AFC are unknown. OBJECTIVES To determine effects of IAV infection on AFC, and to identify intercellular signaling mechanisms underlying influenza-mediated inhibition of AFC. METHODS BALB/c mice were infected intranasally with influenza A/WS...

Influenza A virus (IAV) infects a remarkably wide variety of avian and mammalian hosts. Evolution finely hones IAV genes to optimally infect and be transmitted in a particular host species. Sporadically, IAV manages to jump between species, introducing novel antigenic strains into the new host population that wreak havoc until herd immunity develops. IAV adaptation to new hosts typically involv...

The viral infection of higher vertebrates elicits potent innate and adaptive host immunity. However, an excessive or inappropriate immune response also may lead to host pathology that often is more severe than the direct effects of viral replication. Therefore, several mechanisms exist that regulate the magnitude and class of the immune response. Here, we have examined the potential involvement...

Influenza A virus (IAV) is a dangerous virus equipped with the potential to evoke widespread pandemic disease. The 2009 H1N1 pandemic highlights the urgency for developing effective therapeutics against IAV infection. Vaccination is a major weapon to combat IAV and efforts to improve current regimes are critically important. Here, we will review the role of dendritic cells (DCs), a pivotal cell...

Influenza A virus (IAV) is recognized to cause severe pulmonary illnesses in humans, particularly in elderly and children. One of the features associated with IAV infection is an excessive lung inflammation due to an uncontrolled immune response. The nucleotide-binding oligomerization domain 2 (NOD2) receptor is known to recognize ssRNA viruses such as IAV, but its role in the inflammatory proc...