Immunocapture isotope dilution mass spectrometry in response to a pandemic influenza threat.

As a result of recent advances in mass spectrometry-based protein quantitation methods, these techniques are now poised to play a critical role in rapid formulation of pandemic influenza vaccines. Analytical techniques that have been developed and validated on seasonal influenza strains can be used to increase the quality and decrease the time required to deliver protective pandemic vaccines to the global population. The emergence of a potentially pandemic avian influenza A (H7N9) virus in March of 2013, prompted the US public health authorities and the vaccine industry to initiate production of a pre-pandemic vaccine for preparedness purposes. To this end, we evaluated the feasibility of using immunocapture isotope dilution mass spectrometry (IC-IDMS) to evaluate the suitability of the underlying monoclonal and polyclonal antibodies (mAbs and pAbs) for their capacity to isolate the H7 hemagglutinin (HA) in this new vaccine for quantification by IDMS. A broad range of H7 capture efficiencies was observed among mAbs tested by IC-IDMS with FR-545, 46/6, and G3 A533 exhibiting the highest cross-reactivity capabilities to H7 of A/Shanghai/2/2013. MAb FR-545 was selected for continued assessment, evaluated by IC-IDMS for mAb reactivity against H7 in the H7N9 candidate vaccine virus and compared with/to reactivity to the reference polyclonal antiserum in allantoic fluid, purified whole virus, lyophilized whole virus and final detergent-split monovalent vaccine preparations for vaccine development. IC-IDMS assessment of FR-545 alongside IC-IDMS using the reference polyclonal antiserum to A/Shanghai/2/2013 and with the regulatory SRID method showed strong correlation and mAb IC-IDMS could have played an important role in the event a potential surrogate potency test was required to be rapidly implemented.

Rapid strategy for screening by pyrosequencing of influenza virus reassortants--candidates for live attenuated vaccines.

BACKGROUND: Live attenuated influenza vaccine viruses (LAIVs) can be generated by classical reassortment of gene segments between a cold adapted, temperature sensitive and attenuated Master Donor Virus (MDV) and a seasonal wild-type (wt) virus. The vaccine candidates contain hemagglutinin (HA) and neuraminidase (NA) genes derived from the circulating wt viruses and the remaining six genes derived from the MDV strains. Rapid, efficient selection of the viruses with 6∶2 genome compositions from the large number of genetically different viruses generated during reassortment is essential for the biannual production schedule of vaccine viruses. METHODOLOGY/PRINCIPAL FINDINGS: This manuscript describes a new approach for the genotypic analysis of LAIV reassortant virus clones based on pyrosequencing. LAIV candidate viruses were created by classical reassortment of seasonal influenza A (H3N2) (A/Victoria/361/2011, A/Ohio/02/2012, A/Texas/50/2012) or influenza A (H7N9) (A/Anhui/1/2013) wt viruses with the MDV A/Leningrad/134/17/57(H2N2). Using strain-specific pyrosequencing assays, mixed gene variations were detected in the allantoic progenies during the cloning procedure. The pyrosequencing analysis also allowed for estimation of the relative abundance of segment variants in mixed populations. This semi-quantitative approach was used for selecting specific clones for the subsequent cloning procedures. CONCLUSIONS/SIGNIFICANCE: The present study demonstrates that pyrosequencing analysis is a useful technique for rapid and reliable genotyping of reassortants and intermediate clones during the preparation of LAIV candidates, and can expedite the selection of vaccine virus candidates.

The effect of the MDCK cell selected neuraminidase D151G mutation on the drug susceptibility assessment of influenza A(H3N2) viruses.

Propagation of influenza A(H3N2) viruses in MDCK cells has been associated with the emergence of neuraminidase (NA) variants carrying a change at residue 151. In this study, the pyrosequencing assay revealed that ∼90% of A(H3N2) virus isolates analyzed (n=150) contained more than one amino acid variant (D/G/N) at position 151. Susceptibilities of the virus isolates to zanamivir and oseltamivir were assessed using the chemiluminescent and fluorescent NA inhibition (NI) assays. In the chemiluminescent assay, which utilizes NA-Star® substrate, up to 13-fold increase in zanamivir-IC50 was detected for isolates containing a high proportion (>50%) of the G151 NA variant. However, an increase in zanamivir-IC50s was not seen in the fluorescent assay, which uses MUNANA as substrate. To investigate this discrepancy, recombinant NAs (rNAs) were prepared and tested in both NI assays. Regardless of the assay used, the zanamivir-IC50 for the rNA G151 was much greater (>1500-fold) than that for rNA D151 wild-type. However, zanamivir resistance conferred by the G151 substitution was masked in preparations containing the D151 NA which had much greater activity, especially against MUNANA. In conclusion, the presence of NA D151G variants in cell culture-grown viruses interferes with drug susceptibility assessment and therefore measures need to be implemented to prevent their emergence.

Cell culture-selected substitutions in influenza A(H3N2) neuraminidase affect drug susceptibility assessment.

Assessment of drug susceptibility has become an integral part of influenza virus surveillance. In this study, we describe the drug resistance profile of influenza A(H3N2) virus, A/Mississippi/05/2011, collected from a patient treated with oseltamivir and detected via surveillance. An MDCK cell-grown isolate of this virus exhibited highly reduced inhibition by the neuraminidase (NA) inhibitors (NAIs) oseltamivir (8,005-fold), zanamivir (813-fold), peramivir (116-fold), and laninamivir (257-fold) in the NA inhibition assay. Sequence analysis of its NA gene revealed a known oseltamivir-resistance marker, the glutamic acid-to-valine substitution at position 119 (E119V), and an additional change, threonine to isoleucine at position 148 (T148I). Unlike E119V, T148I was not detected in the clinical sample but acquired during viral propagation in MDCK cells. Using recombinant proteins, T148I by itself was shown to cause only a 6-fold increase in the zanamivir 50% inhibitory concentration (IC50) and had no effect on inhibition by other drugs. The T148I substitution reduced NA activity by 50%, most likely by affecting the positioning of the 150 loop at the NA catalytic site. Using pyrosequencing, changes at T148 were detected in 35 (23%) of 150 MDCK cell-grown A(H3N2) viruses tested, which was lower than the frequency of changes at D151 (85%), an NA residue previously implicated in cell selection. We demonstrate that culturing of the A(H3N2) viruses (n = 11) at a low multiplicity of infection delayed the emergence of the NA variants with changes at position 148 and/or 151, especially when conducted in MDCK-SIAT1 cells. Our findings highlight the current challenges in monitoring susceptibility of influenza A(H3N2) viruses to the NAI class of antiviral drugs.

Neuraminidase inhibitor susceptibility testing of influenza type B viruses in China during 2010 and 2011 identifies viruses with reduced susceptibility to oseltamivir and zanamivir.

Influenza type B viruses are responsible for substantial morbidity and mortality in humans. Antiviral drugs are an important supplement to vaccination for reducing the public health impact of influenza virus infections. Influenza B viruses are not sensitive to M2 inhibitors which limit the current therapeutic options to two neuraminidase inhibitors (NAIs), oseltamivir and zanamivir, which are licensed in many countries. Drug resistance is a public health concern which has necessitated monitoring of influenza virus drug susceptibilities through active global surveillance. Here, we report the results of drug susceptibility surveillance of influenza type B viruses (n=680) collected in mainland China during two calendar years, 2010 and 2011, assessed using functional neuraminidase (NA) inhibition (NI) assays. Four influenza B viruses exhibited reduced susceptibilities to oseltamivir, but not zanamivir, and shared the amino acid substitution I221T (ATC→ACC), at this conserved residue in the NA active site (I222T in N2 numbering). Additionally, a single virus with reduced susceptibility to both oseltamivir and zanamivir was identified and contained an amino acid substitution D197N (GAC→AAC) at another conserved residue in the NA active site (D198N in N2 numbering). This report underlies the importance of continued influenza antiviral susceptibility surveillance globally, even in countries where the use of NAIs has been low or non-existing.

Analysis of influenza viruses from patients clinically suspected of infection with an oseltamivir resistant virus during the 2009 pandemic in the United States.

During the 2009 influenza pandemic, the Centers for Disease Control and Prevention provided antiviral susceptibility testing for patients infected with suspected drug-resistant viruses. Specimens from 72 patients admitted to an intensive care unit or with a severe immunocompromising condition, who failed to clinically improve after oseltamivir treatment, were accepted for testing. Respiratory specimens were tested for the presence of the oseltamivir resistance-conferring H275Y substitution in the neuraminidase (NA) by pyrosequencing. Virus isolates propagated in MDCK cells were tested in phenotypic NA inhibition (NI) assays using licensed NA inhibitors (NAIs), zanamivir and oseltamivir, and investigational NAIs, peramivir and laninamivir. Conventional sequencing and plaque purification were conducted on a subset of viruses. Pyrosequencing data were obtained for 87 specimens collected from 58 of the 72 (81%) patients. Of all patients, 27 (38%) had at least one specimen in which H275Y was detected. Analysis of sequential samples from nine patients revealed intra-treatment emergence of H275Y variant and a shift from wildtype-to-H275Y in quasispecies during oseltamivir therapy. A shift in the H275Y proportion was observed as a result of virus propagation in MDCK cells. Overall, the NI method was less sensitive than pyrosequencing in detecting the presence of H275Y variants in virus isolates. Using the NI method, isolates containing H275Y variant at⩾50% exhibited resistance to oseltamivir and peramivir, but retained full susceptibility to zanamivir. H275Y viruses recovered from two patients had an additional substitution I223K or I223R that conferred a 38-52- and 33-97-fold enhancement in oseltamivir- and peramivir-resistance, respectively. These viruses also showed decreased susceptibility to zanamivir and laninamivir. These data suggest that pyrosequencing is a powerful tool for timely detection of NAI resistant viruses and that NI assays are needed for comprehensive testing to detect novel resistance substitutions.

Detection of hemagglutinin variants of the pandemic influenza A (H1N1) 2009 virus by pyrosequencing.

For influenza viruses, pyrosequencing has been successfully applied to the high-throughput detection of resistance markers in genes encoding the drug-targeted M2 protein and neuraminidase. In this study, we expanded the utility of this assay to the detection of multiple receptor binding variants of the hemagglutinin protein of influenza viruses directly in clinical specimens. Specifically, a customized pyrosequencing protocol that permits detection of virus variants with the D, G, N, or E amino acid at position 222 in the hemagglutinin of the 2009 pandemic influenza A (H1N1) virus was developed. This customized pyrosequencing protocol was applied to the analysis of 241 clinical specimens. The use of the optimized nucleotide dispensation order allowed detection of mixtures of variants in 10 samples (4.1%) which the standard cyclic nucleotide dispensation protocol failed to detect. The optimized pyrosequencing protocol is expected to provide a more accurate tool in the analysis of virus variant composition.