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Frontiers of Medicine

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Front. Med.    2020, Vol. 14 Issue (1) : 8-20    https://doi.org/10.1007/s11684-020-0739-z
REVIEW
Research progress on human infection with avian influenza H7N9
Xiaoxin Wu, Lanlan Xiao, Lanjuan Li()
State Key Laboratory for Diagnosis and Treatment of Infectious Diseases, Collaborative Innovation Center for Diagnosis and Treatment of Infectious Diseases, The First Affiliated Hospital, School of Medicine, Zhejiang University, Hangzhou 310003, China
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Abstract

Since the first case of novel H7N9 infection was reported, China has experienced five epidemics of H7N9. During the fifth wave, a highly pathogenic H7N9 strain emerged. Meanwhile, the H7N9 virus continues to accumulate mutations, and its affinity for the human respiratory epithelial sialic acid 2-6 receptor has increased. Therefore, a pandemic is still possible. In the past 6 years, we have accumulated rich experience in dealing with H7N9, especially in terms of virus tracing, epidemiological research, key site mutation monitoring, critical disease mechanisms, clinical treatment, and vaccine development. In the research fields above, significant progress has been made to effectively control the spread of the epidemic and reduce the fatality rate. To fully document the research progress concerning H7N9, we reviewed the clinical and epidemiological characteristics of H7N9, the key gene mutations of the virus, and H7N9 vaccine, thus providing a scientific basis for further monitoring and prevention of H7N9 influenza epidemics.
Keywords H7N9      pandemic      epidemiology      mutations      vaccine      influenza     
Corresponding Author(s): Lanjuan Li   
Just Accepted Date: 27 December 2019   Online First Date: 11 February 2020    Issue Date: 02 March 2020
 Cite this article:   
Xiaoxin Wu,Lanlan Xiao,Lanjuan Li. Research progress on human infection with avian influenza H7N9[J]. Front. Med., 2020, 14(1): 8-20.
 URL:  
https://academic.hep.com.cn/fmd/EN/10.1007/s11684-020-0739-z
https://academic.hep.com.cn/fmd/EN/Y2020/V14/I1/8
Fig.1  Schematic of the four-anti and two-balance strategies used in treating severe H7N9. The balance between Yin and Yang in the human body is very important. The four-anti and two-balance strategies are used to maintain this balance. Each strategy (antiviral treatment, anti-shock, anti-hypoxemia and anti-multi-organ failure, anti-secondary infection, maintaining the water–electrolyte acid−base balance, and maintaining the microecological balance) plays an important role in the treatment of severe H7N9.
Gene Function Mutation References
HAa Change of antigenicity A143V [58]
Change of antigenicity R148K [58]
Change of antigenicity L217Q [59]
Increases affinity for sialic acid α2-6 receptor Q226L/I [49, 51–57]
Increases affinity for sialic acid α2-6 receptor G186V [51–55, 57]
Increases affinity for sialic acid α2-6 receptor G228S [50]
Cleavage peptides PEVPKRKRTAR↓G [6, 7]
NAb Reduces drug sensitivity R292K [54, 60, 61]
Reduces drug sensitivity H274Y [61]
Reduces drug sensitivity E119V [62]
Reduces drug sensitivity I222K [63]
PB2 Enhances viral transcription and replication in cells K526R [61]
Enhances viral transcription and replication in cells E627K [51, 64, 65]
Increases virulence in mammalian models D701N [51, 64, 65]
Restores polymerase activity M535L [66–68]
Host signature amino acids (avian to human) T271A [69]
Increases viral replication and virulence Q591K [66–68]
Increases viral replication and virulence A588V [8]
Host signature amino acids (avian to human) K702R [7, 70]
Tab.1  Key genetic variations of the H7N9 virus
Fig.2  Seed strain construction of H7N9 vaccine by reverse genetic method. The HA and NA genes were from the H7N9 strain. All other internal genes (PB1, PB2, NS, M, NP, PA) were derived from A/Puerto Rico/8/34 (PR8). All the genes were constructed into pHW2000 plasmid. Then, all eight plasmids were co-transfected into MDCK or VERO cells. The seed strain of H7N9 vaccine could be collected in culture supernatant.
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