Identification of B-cell epitopes located on the surface in the PB2 protein of the H9N2 subtype avian influenza virus.

Avian influenza (AI), caused by H9N2 subtype avian influenza virus (AIV), poses a serious threat to poultry farming and public health due to its transmissibility and pathogenicity. The PB2 protein is a major component of the viral RNA polymerase complex. It is of great importance to identify the antigenic determinants of the PB2 protein to explore the function of the PB2 protein. In this study, the PB2 sequence of H9N2 subtype AIV, from 1090 to 1689 bp, was cloned and expressed. The recombinant PB2 protein with cutting gel was used to immunize BALB/c mice. After cell fusion, the hybridoma cell lines secreting monoclonal antibodies (mAbs) targeting the PB2 protein were screened by indirect ELISA and western blotting, and the antigenic epitopes of mAbs were identified by constructing truncated overlapping fragments in the PB2 protein of H9N2 subtype AIV. The results showed that three hybridoma cell lines (4B7, 4D10, and 5H1) that stably secreted mAbs specific to the PB2 protein were screened; the heavy chain of 4B7 was IgG2α, those of 4D10 and 5H1 were IgG1, and all three mAbs had kappa light chain. Also, the minimum B-cell epitope recognized was 475LRGVRVSK482 and 528TITYSSPMMW537. Homology analysis showed that these two epitopes were conserved among the different subtypes of AIV strains and located on the surface of the PB2 protein. The above findings provide an experimental foundation for further investigation of the function of the PB2 protein and developing monoclonal antibody-based diagnostic kits.

Amino acid sites related to the PB2 subunits of IDV affect polymerase activity.

BACKGROUND: In 2011, a new influenza virus, named Influenza D Virus (IDV), was isolated from pigs, and then cattle, presenting influenza-like symptoms. IDV is one of the causative agents of Bovine Respiratory Disease (BRD), which causes high morbidity and mortality in feedlot cattle worldwide. To date, the molecular mechanisms of IDV pathogenicity are unknown. Recent IDV outbreaks in cattle, along with serological and genetic evidence of IDV infection in humans, have raised concerns regarding the zoonotic potential of this virus. Influenza virus polymerase is a determining factor of viral pathogenicity to mammals. METHODS: Here we take a prospective approach to this question by creating a random mutation library about PB2 subunit of the IDV viral polymerase to test which amino acid point mutations will increase viral polymerase activity, leading to increased pathogenicity of the virus. RESULTS: Our work shows some exact sites that could affect polymerase activities in influenza D viruses. For example, two single-site mutations, PB2-D533S and PB2-G603Y, can independently increase polymerase activity. The PB2-D533S mutation alone can increase the polymerase activity by 9.92 times, while the PB2-G603Y mutation increments the activity by 8.22 times. CONCLUSION: Taken together, our findings provide important insight into IDV replication fitness mediated by the PB2 protein, increasing our understanding of IDV replication and pathogenicity and facilitating future studies.

Phylogenetic Analysis and Functional Characterization of the Influenza A H5N1 PB2 Gene.

Highly pathogenic avian influenza (HPAI) H5N1 viruses are endemic in poultry and cause continued inter-species transmission to human in Asia, such as China and Vietnam, leading to pandemic concerns and socio-economic challenges. Phylogenetic analysis of H5N1 viruses isolated from China and Vietnam during 2001-2012 showed that several geographically distinct sublineages have become established in these two countries. Subsequently, we reassigned HPAI H5N1 viruses into three distinct groups to reveal the intrasubtype reassortment. Apart from six reassortants detected here, we found that several viral strains showed signals for homologous recombination within PB2 and PB1 genes, suggestive of the fluidity of the H5N1 virus gene pool. Furthermore, sequenced-based analyses revealed that the viral polymerase displayed a higher level of genetic polymorphism but associated with lower substitution rate when compared with those of other gene segments. In addition, the selection pressure analysis indicated that purifying selection was predominant in eight genomic segments especially in the polymerase complex. However, the site-by-site analysis helped to detect 14 positively selected sites in the PB1, PA, HA, NA, MP and NS proteins. Despite the fact that PB2 protein of H5N1 viruses was highly conserved at the amino acid level, eleven adaptive mutations were still observed in the protein. Further comparative structural analysis of the K627E mutation indicated that there were no structural differences between the variants, which possessed either PB2-627E or PB2-627K. Transcriptomic analysis suggested the non-mitochondrial PB2 protein of H5N1 virus that forms a stable complex with the mitochondrial antiviral signalling protein (MAVS, also known as IPS-1, VISA or Cardif) can induce interferon-beta (IFN-ß) expression, but the substitution (PB2-K627E) is not the sole determinant of the RIG-I-like receptors (RLR) signalling components induction in Calu-3 cells.

Resistance to influenza A virus infection in transformed cell lines expressing an anti-PB2 monoclonal antibody.

The polymerase basic 2 (PB2) protein is one of four proteins that make up the influenza A virus replication complex, which is responsible for viral gene transcription and replication. To assess the antiviral potential of an anti-PB2 monoclonal antibody that inhibits RNA transcription of influenza A viruses, Mardin-Darby canine kidney (MDCK) cells were transformed with two transgenes that encode the light and heavy chains of the monoclonal antibody. The transformed cell lines expressing this monoclonal antibody displayed resistance to several subtypes of influenza A virus infection. In the transformed cell lines infected with influenza A virus, the level of viral RNA transcription was decreased and the effective nuclear transportation of the PB2 protein was also inhibited. These results demonstrate that the anti-PB2 intrabody is potentially able to interfere with the effective nuclear transportation of PB2 protein, resulting in the observed resistance to influenza A virus infection in vitro.

Human H7N9 avian influenza virus infection: a review and pandemic risk assessment.

China is undergoing a recent outbreak of a novel H7N9 avian influenza virus (nH7N9) infection that has thus far involved 132 human patients, including 37 deaths. The nH7N9 virus is a reassortant virus originating from the H7N3, H7N9 and H9N2 avian influenza viruses. nH7N9 isolated from humans contains features related to adaptation to humans, including a Q226L mutation in the hemagglutinin cleavage site and E627K and D701N mutations in the PB2 protein. Live poultry markets provide an environment for the emergence, spread and maintenance of nH7N9 as well as for the selection of mutants that facilitate nH7N9 binding to and replication in the human upper respiratory tract. Innate immune suppression conferred by the internal genes of H9N2 may contribute to the virulence of nH7N9. The quail may serve as the intermediate host during the adaptation of avian influenza viruses from domestic waterfowl to gallinaceous poultry, such as chickens and related terrestrial-based species, due to the selection of viral mutants with a short neuraminidase stalk. Infections in chickens, common quails, red-legged partridges and turkeys may select for mutants with human receptor specificity. Infection in Ratitae species may lead to the selection of PB2-E627K and PB2-D701N mutants and the conversion of nH7N9 to a highly pathogenic avian influenza virus.

Analysis of PB2 protein from H9N2 and H5N1 avian flu virus.

Influenza A viruses of subtype H9N2 are wide spread among poultry and other mammalian species. Crossing the species barrier from poultry to human occurred in recent years creating a pandemic of H9N2 virus. It is known that the pathogenicity of H9N2 is lower than H5N1. Nonetheless, it is important to establish the molecular functions of H9N2 viral proteins. We studied mutations in the polymerase protein PB2 of H9N2 from different strains and compared it with the highly pathogenic H5N1. The mutation M294T was found to be important in the N-myristoylation domain of Ck/UP/2573/India/04(H9N2) isolate. Prediction of secondary structures and PROSITE motif assignments were performed for PB2 to gain functional insight. Subsequently, the effect of mutations in secondary structures among strains is discussed.