Seasonal influenza epidemics and occasional pandemics threaten public health worldwide. New alternative strategies for generating recombinant viruses with vaccine potential are needed. Interestingly, influenza viruses circulating in different hosts have been found to have distinct codon usage patterns, which may reflect host adaptation. We therefore hypothesized that it is possible to make a human seasonal influenza virus that is specifically attenuated in human cells but not in eggs by converting its codon usage so that it is similar to that observed from avian influenza viruses. This approach might help to generate human live attenuated viruses without affecting their yield in eggs. To test this hypothesis, over 300 silent mutations were introduced into the genome of a seasonal H1N1 influenza virus. The resultant mutant was significantly attenuated in mammalian cells and mice, yet it grew well in embryonated eggs. A single dose of intranasal vaccination induced potent innate, humoral, and cellular immune responses, and the mutant could protect mice against homologous and heterologous viral challenges. The attenuated mutant could also be used as a vaccine master donor strain by introducing hemagglutinin and neuraminidase genes derived from other strains. Thus, our approach is a successful strategy to generate attenuated viruses for future application as vaccines. IMPORTANCE Vaccination has been one of the best protective measures in combating influenza virus infection. Current licensed influenza vaccines and their production have various limitations. Our virus attenuation strategy makes use of the codon usage biases of human and avian influenza viruses to generate a human-derived influenza virus that is attenuated in mammalian hosts. This method, however, does not affect virus replication in eggs. This makes the resultant mutants highly compatible with existing egg-based vaccine production pipelines. The viral proteins generated from the codon bias mutants are identical to the wild-type viral proteins. In addition, our massive genome-wide mutational approach further minimizes the concern over reverse mutations. The potential use of this kind of codon bias mutant as a master donor strain to generate other live attenuated viruses is also demonstrated. These findings put forward a promising live attenuated influenza vaccine generation strategy to control influenza. Seasonal influenza strikes every year, and the threat of avian influenza outbreaks and worldwide pandemics together make influenza a significant health risk to the general public, particularly young children, pregnant women, the elderly, and patients with underlying medical conditions (1). Vaccination remains one of the best control measures against influenza. However, currently licensed inactivated and live attenuated influenza vaccines have their limitations. Therefore, new options for vaccine development are needed.Vaccination with an updated virus strain is required every year in response to the frequent occurrence of antigenic drift. Even w...
BACKGROUND A novel subtype of influenza A virus (H7N9) was recently identified in humans. The virus is a reassortant of avian viruses, but these human isolates contain mutations [hemagglutinin (HA) Q226L and PB2 E627K] that might make it easier for the virus to adapt to mammalian hosts. Molecular tests for rapid detection of this virus are urgently needed. METHODS We developed a 1-step quantitative real-time reverse-transcription PCR assay to detect the novel human H7N9 virus. The primer set was specific to the hemagglutinin (HA) gene of the H7N9 viruses currently causing the outbreak in China and had mismatches to all previously known avian or mammalian H7 HA sequences. In addition, the assay was evaluated using influenza A viruses of various genetic BACKGROUNDs and other negative controls. RESULTS The detection limit of the assay was approximately 0.04 TCID50 (median tissue culture infective dose) per reaction. The assay specificity was high and all negative control samples, including 8 H7 viruses not closely related to the human H7N9 virus, tested negative. CONCLUSIONS The established assay allows rapid detection of the novel human H7N9 virus, thereby allowing better pandemic preparedness.
The emergence of pandemic (H1N1) 2009 virus highlighted the need for enhanced surveillance of swine influenza viruses. We used real-time reverse–transcription PCR–based genotyping and found that this rapid and simple genotyping method may identify reassortants derived from viruses of Eurasian avian-like, triple reassortant-like, and pandemic (H1N1) 2009 virus lineages.
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