Your search keyword '"Hao, Xiaoli"' showing total 9 results

1. A dominant internal gene cassette of high pathogenicity avian influenza H7N9 virus raised since 2018

Author

He, Dongchang, Gu, Min, Hao, Xiaoli, Zhan, Tiansong, Wang, Xiyue, Wang, Xiaoquan, Hu, Shunlin, and Liu, Xiufan

Published

2022

2. G1-like M and PB2 genes are preferentially incorporated into H7N9 progeny virions during genetic reassortment

Author

Li, Xiuli, Gu, Min, Wang, Xiaoquan, Gao, Ruyi, Bu, Xinxin, Hao, Xiaoli, Ma, Jing, Hu, Jiao, Hu, Shunlin, Liu, Xiaowen, Chen, Sujuan, Peng, Daxin, Jiao, Xinan, and Liu, Xiufan

Published

2021

3. Genome-Wide Reassortment Analysis of Influenza A H7N9 Viruses Circulating in China during 2013–2019.

Author

He, Dongchang, Wang, Xiyue, Wu, Huiguang, Wang, Xiaoquan, Yan, Yayao, Li, Yang, Zhan, Tiansong, Hao, Xiaoli, Hu, Jiao, Hu, Shunlin, Liu, Xiaowen, Ding, Chan, Su, Shuo, Gu, Min, and Liu, Xiufan

Subjects

COVID-19, INFLUENZA A virus, H7N9 subtype, INFLUENZA viruses, INFLUENZA, GENETIC variation, MULTIDIMENSIONAL scaling

Abstract

Reassortment with the H9N2 virus gave rise to the zoonotic H7N9 avian influenza virus (AIV), which caused more than five outbreak waves in humans, with high mortality. The frequent exchange of genomic segments between H7N9 and H9N2 has been well-documented. However, the reassortment patterns have not been described and are not yet fully understood. Here, we used phylogenetic analyses to investigate the patterns of intersubtype and intrasubtype/intralineage reassortment across the eight viral segments. The H7N9 virus and its progeny frequently exchanged internal genes with the H9N2 virus but rarely with the other AIV subtypes. Before beginning the intrasubtype/intralineage reassortment analyses, five Yangtze River Delta (YRD A-E) and two Pearl River Delta (PRD A-B) clusters were divided according to the HA gene phylogeny. The seven reset segment genes were also nomenclatured consistently. As revealed by the tanglegram results, high intralineage reassortment rates were determined in waves 2–3 and 5. Additionally, the clusters of PB2 c05 and M c02 were the most dominant in wave 5, which could have contributed to the onset of the largest H7N9 outbreak in 2016–2017. Meanwhile, a portion of the YRD-C cluster (HP H7N9) inherited their PB2, PA, and M segments from the co-circulating YRD-E (LP H7N9) cluster during wave 5. Untanglegram results revealed that the reassortment rate between HA and NA was lower than HA with any of the other six segments. A multidimensional scaling plot revealed a robust genetic linkage between the PB2 and PA genes, indicating that they may share a co-evolutionary history. Furthermore, we observed relatively more robust positive selection pressure on HA, NA, M2, and NS1 proteins. Our findings demonstrate that frequent reassortment, particular reassorted patterns, and adaptive mutations shaped the H7N9 viral genetic diversity and evolution. Increased surveillance is required immediately to better understand the current state of the HP H7N9 AIV. [ABSTRACT FROM AUTHOR]

Published

2022

4. The PB2 and M genes are critical for the superiority of genotype S H9N2 virus to genotype H in optimizing viral fitness of H5Nx and H7N9 avian influenza viruses in mice.

Author

Hao, Xiaoli, Hu, Jiao, Wang, Xiaoquan, Gu, Min, Wang, Jiongjiong, Liu, Dong, Gao, Zhao, Chen, Yu, Gao, Ruyi, Li, Xiuli, Hu, Zenglei, Hu, Shunlin, Liu, Xiaowen, Peng, Daxin, Jiao, Xinan, and Liu, Xiufan

Subjects

*INFLUENZA A virus, H7N9 subtype, *AVIAN influenza A virus, *AVIAN influenza, *GENOTYPES, *GENES, *INFLUENZA viruses

Abstract

Genotype S H9N2 avian influenza virus, which has been predominant in China since 2010, contributed its entire internal gene cassette to the genesis of novel reassortant influenza viruses, including H5Nx, H7N9 and H10N8 viruses that pose great threat to poultry and humans. A key feature of the genotype S H9N2 virus is the substitution of G1‐like M and PB2 genes for the earlier F/98‐like M and PB2 of genotype H virus. However, how this gene substitution has influenced viral adaptability of emerging influenza viruses in mammals remains unclear. We report here that reassortant H5Nx and H7N9 viruses with the genotype S internal gene cassette displayed enhanced replication and virulence over those with genotype H internal gene cassette in cell cultures as well as in the mouse models. We showed that the G1‐like PB2 gene was associated with increased polymerase activity and improved nuclear accumulation compared with the F/98‐like counterpart, while the G1‐like M gene facilitated effective translocation of RNP to cytoplasm. Our findings suggest that the genotype S H9N2 internal gene cassette, which possesses G1‐like M and PB2 genes, is superior to that of genotype H, in optimizing viral fitness, and thus have implications for assessing the potential risk of these gene introductions to generate emerging influenza viruses. [ABSTRACT FROM AUTHOR]

Published

2020

5. The PB2 and M genes of genotype S H9N2 virus contribute to the enhanced fitness of H5Nx and H7N9 avian influenza viruses in chickens.

Author

Hao, Xiaoli, Wang, Xiaoquan, Hu, Jiao, Gu, Min, Wang, Jiongjiong, Deng, Yonghuan, Jiang, Daxiu, He, Dongchang, Xu, Haixu, Yang, Yi, Hu, Zenglei, Chen, Sujuan, Hu, Shunlin, Liu, Xiaowen, Shang, Shaobin, Peng, Daxin, Jiao, Xinan, and Liu, Xiufan

Subjects

*INFLUENZA A virus, H7N9 subtype, *CHICKEN diseases, *GENOTYPES, *AVIAN influenza, *GENES, *CHICKENS, *INFLUENZA viruses

Abstract

Genotype S H9N2 viruses frequently donate their internal genes to facilitate the generation of novel influenza viruses, e.g., H5N6, H7N9, and H10N8, which have caused human infection. Genotype S was originated from the replacement of F/98-like M and PB2 genes of the genotype H with those from G1-like lineage. However, whether this gene substitution will influence the viral fitness of emerging influenza viruses remains unclear. We found that H5Nx and H7N9 viruses with G1-like PB2 or M gene exhibited higher virulence and replication than those with F/98-like PB2 or M in chickens. We also determined the functional significance of G1-like PB2 in conferring increased polymerase activity and improved nucleus transportation efficiency, and facilitated RNP nuclear export by G1-like M. Our results suggest that G1-like PB2 and M genes optimize viral fitness, and thus play a crucial role in the genesis of emerging influenza viruses that cause rising prevalence in chickens. • Genotype S H9N2 AIV donate their internal gene cassette to facilitate the generation of H5N6, H7N9, etc. • Genotype S H9N2 is the substitution of G1-like PB2 and M genes for the earlier F/98-like M and PB2 of genotype H. • G1-like H9N2 PB2 and M genes enhance virulence of reassortant H5Nx and H7N9 viruses in chickens. • Genotype S H9N2 internal gene cassette is superior to that of genotype H in optimizing viral fitness in chickens. [ABSTRACT FROM AUTHOR]

Published

2019

6. Spatiotemporal Associations and Molecular Evolution of Highly Pathogenic Avian Influenza A H7N9 Virus in China from 2017 to 2021.

Author

He, Dongchang, Gu, Min, Wang, Xiyue, Wang, Xiaoquan, Li, Gairu, Yan, Yayao, Gu, Jinyuan, Zhan, Tiansong, Wu, Huiguang, Hao, Xiaoli, Wang, Guoqing, Hu, Jiao, Hu, Shunlin, Liu, Xiaowen, Su, Shuo, Ding, Chan, and Liu, Xiufan

Subjects

AVIAN influenza A virus, AVIAN influenza, INFLUENZA A virus, H7N9 subtype, MOLECULAR evolution, MOLECULAR association, POULTRY farms

Abstract

Highly pathogenic (HP) H7N9 avian influenza virus (AIV) emerged in China in 2016. HP H7N9 AIV caused at least 33 human infections and has been circulating in poultry farms continuously since wave 5. The genetic divergence, geographic patterns, and hemagglutinin adaptive and parallel molecular evolution of HP H7N9 AIV in China since 2017 are still unclear. Here, 10 new strains of HP H7N9 AIVs from October 2019 to April 2021 were sequenced. We found that HP H7N9 was primarily circulating in Northern China, particularly in the provinces surrounding the Bohai Sea (Liaoning, Hebei, and Shandong) since wave 6. Of note, HP H7N9 AIV phylogenies exhibit a geographical structure compatible with high levels of local transmission after unidirectional rapid geographical expansion towards the north of China in 2017. In addition, we showed that two major subclades were continually expanding with the viral population size undergoing a sharp increase after 2018 with an obvious seasonal tendency. Notably, the hemagglutinin gene showed signs of parallel evolution and positive selection. Our research sheds light on the current epidemiology, evolution, and diversity of HP H7N9 AIV that can help prevent and control the spreading of HP H7N9 AIV. [ABSTRACT FROM AUTHOR]

Published

2021

7. Establishing a Multicolor Flow Cytometry to Characterize Cellular Immune Response in Chickens Following H7N9 Avian Influenza Virus Infection.

Author

Hao, Xiaoli, Li, Shuai, Chen, Lina, Dong, Maoli, Wang, Jiongjiong, Hu, Jiao, Gu, Min, Wang, Xiaoquan, Hu, Shunlin, Peng, Daxin, Liu, Xiufan, Shang, Shaobin, Koutsakos, Marios, and Valkenburg, Sophie

Subjects

*INFLUENZA A virus, H7N9 subtype, *IMMUNE response, *VIRUS diseases, *FLOW cytometry, *CELL analysis, *POULTRY breeding, *CYTOPROTECTION

Abstract

Avian influenza virus (AIV) emerged and has continued to re-emerge, continuously posing great threats to animal and human health. The detection of hemagglutination inhibition (HI) or virus neutralization antibodies (NA) is essential for assessing immune protection against AIV. However, the HI/NA-independent immune protection is constantly observed in vaccines' development against H7N9 subtype AIV and other subtypes in chickens and mammals, necessitating the analysis of the cellular immune response. Here, we established a multi-parameter flow cytometry to examine the innate and adaptive cellular immune responses in chickens after intranasal infection with low pathogenicity H7N9 AIV. This assay allowed us to comprehensively define chicken macrophages, dendritic cells, and their MHC-II expression, NK cells, γδ T cells, B cells, and distinct T cell subsets in steady state and during infection. We found that NK cells and KUL01+ cells significantly increased after H7N9 infection, especially in the lung, and the KUL01+ cells upregulated MHC-II and CD11c expression. Additionally, the percentages and numbers of γδ T cells and CD8 T cells significantly increased and exhibited an activated phenotype with significant upregulation of CD25 expression in the lung but not in the spleen and blood. Furthermore, B cells showed increased in the lung but decreased in the blood and spleen in terms of the percentages or/and numbers, suggesting these cells may be recruited from the periphery after H7N9 infection. Our study firstly disclosed that H7N9 infection induced local and systemic cellular immune responses in chickens, the natural host of AIV, and that the flow cytometric assay developed in this study is useful for analyzing the cellular immune responses to AIVs and other avian infectious diseases and defining the correlates of immune protection. [ABSTRACT FROM AUTHOR]

Published

2020

8. Adaptive mutations in PB2 gene contribute to the high virulence of a natural reassortant H5N2 avian influenza virus in mice.

Author

Li, Qunhui, Wang, Xuan, Sun, Zhongtao, Hu, Jiao, Gao, Zhao, Hao, Xiaoli, Li, Juan, Liu, Huimou, Wang, Xiaoquan, Gu, Min, Xu, Xiulong, Liu, Xiaowen, and Liu, Xiufan

Subjects

*AVIAN influenza A virus, *MOUSE diseases, *NUCLEOTIDE sequencing, *MICROBIAL virulence, *INFECTIOUS disease transmission

Abstract

The highly pathogenic A/chicken/Hebei/1102/2010 (HB10) H5N2 virus is a natural reassortant derived from circulating H5N1 and endemic H9N2 avian influenza viruses (AIV). To evaluate the potential of its interspecies transmission, we previously serially passaged the non-virulent HB10 virus in the mouse lung and obtained a high virulence variant (HB10-MA). Genomic sequencing revealed five mutations (HA-S227N, PB2-Q591K, PB2-D701N, PA-I554V and NP-R351K) that distinguished HB10-MA virus from its parental HB10 virus. In this study, we further investigated the molecular basis for the enhanced virulence of HB10-MA in mice. By generating a series of reassortants between the two viruses and evaluating their virulence in mice, we found that both PB2 and PA genes contribute to the high virulence of HB10-MA in mice, whereas PB2 gene carrying the 591K and/or 701N had a dominant function. In addition, the two amino acids showed a cumulative effect on the virulence, virus replication, and polymerase activity of HB10 or HB10-MA. Therefore, our results collectively emphasized the crucial role of PB2 gene, particularly the paired mutations of Q591K and D701N in the host adaptation of the novel reassortant H5N2 AIV in mammals, which may provide helpful insights into the pathogenic potential of emerging AIV in human beings. [ABSTRACT FROM AUTHOR]

Published

2015

9. Genetic and antigenic diversity of H7N9 highly pathogenic avian influenza virus in China.

Author

He, Dongchang, Gu, Jinyuan, Gu, Min, Wu, Huiguang, Li, Juan, Zhan, Tiansong, Chen, Yu, Xu, Naiqing, Ge, Zhichuang, Wang, Guoqing, Hao, Xiaoli, Wang, Xiaoquan, Hu, Jiao, Hu, Zenglei, Hu, Shunlin, Liu, Xiaowen, and Liu, Xiufan

Subjects

*AVIAN influenza A virus, *GENETIC variation, *INFLUENZA A virus, H7N9 subtype, *NATURAL selection, *BINDING sites, *COVID-19, *ZOONOSES

Abstract

Avian influenza virus (AIV) H7N9 that emerged in 2013 in eastern China is a novel zoonotic agent mainly circulating in poultry without clinical signs but causing severe disease with high fatality in humans in more than 5 waves. Since the emergence of highly pathogenic (HP) H7N9 variants in 2016, it has induced heavy losses in the poultry industry leading to the implementation of an intensive nationwide vaccination program at the end of wave 5 (September 2017). To characterize the ongoing evolution of H7N9 AIV, we conducted analyses of H7N9 glycoprotein genes obtained from 2013 to 2019. Bayesian analyses revealed a decreasing population size of HP H7N9 variants post wave 5. Phylogenetic topologies revealed that two novel small subclades were formed and carried several fixed amino acid mutations that were along HA and NA phylogenetic trees since wave 5. Some of the mutations were located at antigenic sites or receptor binding sites. The antigenic analysis may reveal a significant antigenic drift evaluated by hemagglutinin inhibition (HI) assay and the antigenicity of H7N9 AIV might evolute in large leaps in wave 7. Molecular simulations found that the mutations (V135T, S145P, and L226Q) around the HA receptor pocket increased the affinity to α2,3-linked sialic acid (SIA) while decreased to α2,6-linked SIA. Altered affinity may suggest that HP H7N9 variations aggravate the pathogenicity to poultry but lessen the threat to public health. Selection analyses showed that the HP H7N9 AIV experienced an increasing selection pressure since wave 5, and the national implementation of vaccination might intensify the role of natural selection during the evolution waves 6 and 7. In summary, our data provide important insights about the genetic and antigenic diversity of circulating HP H7N9 viruses from 2017 to 2019. Enhanced surveillance is urgently warranted to understand the current situation of HP H7N9 AIV. • Antigenicity of H7N9 AIV might evolute in large leaps in wave 7. • Vaccination might intensify the role of natural selection. • HP H7N9 virus increased its binding affinity to α2,3-linked sialic acid. [ABSTRACT FROM AUTHOR]

Published

2021