Rebecca Brockman-Schneider scite author profile

Influenza A viruses cause recurrent outbreaks of local or global scale with potentially severe consequences for human health and the global economy. Recently, a new strain of influenza A virus was detected that causes disease in and transmits among humans, probably owing to little or no pre-existing immunity to the new strain. On June 11, 2009, the WHO declared that the infections caused by the new strain had reached pandemic proportion. Characterized as an influenza A virus of the H1N1 subtype, the genomic segments of the new strain were most closely related to swine viruses1. Most human infections with swine-origin H1N1 influenza viruses (S-OIVs) appear to be mild; however, more than 50% of hospitalized individuals do not have underlying health issues, attesting to the pathogenic potential of S-OIVs. To better assess the risk posed by the new virus, we characterized one of the first US S-OIV isolates, A/California/04/09 (H1N1; CA04), as well as several other S-OIV isolates, in vitro and in vivo. In mice and ferrets, CA04 and other S-OIV isolates tested replicate more efficiently than a currently circulating human H1N1 virus. In addition, CA04 replicates efficiently in nonhuman primates, causes more severe pathologic lesions in the lungs of infected mice, ferrets, and nonhuman primates than a currently circulating human H1N1 virus, and transmits among ferrets. In specific-pathogen free miniature pigs, CA04 replicates without clinical symptoms. The assessment of human sera from different age groups suggests that infection with human H1N1 viruses antigenically closely related to viruses circulating in 1918 confers neutralizing antibody activity to CA04. Finally, we show that CA04 is sensitive to approved and experimental antiviral drugs, suggesting these compounds as a first line of defence against the recently declared S-OIV pandemic.

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Allele-Specific Targeting of microRNAs to HLA-G and Risk of Asthma

Tan

Randall

Fan

et al. 2007

The American Journal of Human Genetics

347

270

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HLA-G is a nonclassic, class I HLA molecule that has important immunomodulatory properties. Previously, we identified HLA-G as an asthma-susceptibility gene and discovered that the risk of asthma in a child was determined by both the child's HLA-G genotype and the mother's affection status. Here we report a SNP in the 3' untranslated region of HLA-G that influences the targeting of three microRNAs (miRNAs) to this gene, and we suggest that allele-specific targeting of these miRNAs accounts, at least in part, for our earlier observations on HLA-G and the risk of asthma.

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Similar Frequency of Rhinovirus‐Infectible Cells in Upper and Lower Airway Epithelium

et al. 2002

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Rhinovirus (RV) infections can alter lower airway physiology and inflammation, yet the characteristics of RV replication in lower airway cells are incompletely understood. An RV serotype 16 (RV16)-specific monoclonal antibody was identified. Immunohistochemistry and an infectious center assay were used to quantitate the infectivity of RV16 in primary bronchial and adenoidal epithelial cells. The proportion of infectible epithelial cells increased with the inoculum but did not exceed 10%. Analysis of bronchial tissue samples infected ex vivo demonstrated a small subset of RV-infected cells in the epithelial layer. These data confirm previous reports that RV infects only a small subset of epithelial cells in upper airway tissues and indicate that lower airway epithelial cells have a similar susceptibility to RV infection. In confirming that RV can infect cells in the lower airway, these results suggest that lower airway dysfunction occurs through this mechanism in susceptible persons.

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Basal Cells of Differentiated Bronchial Epithelium Are More Susceptible to Rhinovirus Infection

Jakieła

Brockman-Schneider²,

Amineva³

et al. 2008

Am J Respir Cell Mol Biol

153

131

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We used an in vitro model of differentiated tracheobronchial epithelium to analyze the susceptibility of different cell types to infection with rhinoviruses (RVs). Primary cells from control subjects were cultured in an air-liquid interface to form differentiated epithelia. Suprabasal and basal fractions were separated after trypsin digestion, and cell suspensions were infected with serotypes RV16 and RV1A. These cell fractions were analyzed for expression of viral capsid protein VP2 (flow cytometry), viral replication (real-time PCR), cytokeratin-14, and intercellular adhesion molecule-1 (ICAM-1). Compared with suprabasal fraction, basal cells had increased percentages of cells staining positive for VP2 (RV1A: 37.8% versus 9.1%, P < 0.01; RV16: 12.0 versus 3.0%, P < 0.05). The average number of viral RNA copies per cell was also higher in basal cells (2.2- and 2.4-fold increase in RV1A- and RV16-infected cells, respectively) compared with suprabasal cells. Furthermore, ICAM-1 was expressed by 33.3% of basal cells, compared with 8.1% of suprabasal cells (P < 0.05). Finally, in culture models of epithelial injury (detached suprabasal cells or scratched surface), there was significantly greater replication of RV1A compared with intact cell layer. These findings demonstrate that basal cells are more susceptible to RV infection than suprabasal cells. For major group RV, this may be in part due to increased expression of ICAM-1; however, minor group RV also replicated more effectively in basal cells. These results suggest the possibility that epithelial cell differentiation is associated with the maturation of antiviral defense mechanisms.

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Double-Stranded RNA Induces the Synthesis of Specific Chemokines by Bronchial Epithelial Cells

Gern

French

Grindle

et al. 2003

Am J Respir Cell Mol Biol

129

101

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Virus-induced secretion of proinflammatory chemokines (e.g., regulated on activation, normal T cells expressed and secreted [RANTES], interleukin [IL]-8) by airway epithelial cells helps to initiate antiviral responses and airway inflammation by enhancing inflammatory cell recruitment. To define mechanisms for virus-induced chemokine secretion, monolayers of nontransformed bronchial epithelial cells were transfected or incubated with polydeoxyinosinic-deoxycytidylic acid (synthetic double-stranded [ds] RNA), rhinovirus dsRNA, or single-stranded RNA (ssRNA), and the secretion of selected chemokines was determined. Transfection or incubation with dsRNA, but not ssRNA, significantly enhanced secretion of RANTES and IL-8, but not eotaxin or macrophage inflammatory protein-1alpha. Mechanistically, dsRNA induced and activated dsRNA-dependent protein kinase (PKR), and activated nuclear factor-kappaB and p38 mitogen-activated protein kinase. Furthermore, the PKR inhibitor 2-aminopurine significantly blocked dsRNA-induced RANTES and IL-8 secretion, whereas the p38 mitogen-activated protein kinase inhibitor SB203580 suppressed dsRNA-induced IL-8, but not RANTES. These findings indicate that dsRNA selectively induce the secretion of chemokines such as IL-8 and RANTES, and implicate dsRNA-sensitive signaling proteins in this process. Moreover, these data suggest that this may be an important mechanism for the selective secretion of chemokines by viruses (e.g., rhinovirus, respiratory syncytial virus, influenza) that synthesize dsRNA during replication.

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