In 2013, two episodes of influenza emerged in China and caused worldwide concern. A new H7N9 avian influenza virus (AIV) first appeared in China on February 19, 2013. By August 31, 2013, the virus had spread to ten provinces and two metropolitan cities. Of 134 patients with H7N9 influenza, 45 died. From then on, epidemics emerged sporadically in China and resulted in several victims. On November 30, 2013, a 73-year-old woman presented with an influenza-like illness. She developed multiple organ failure and died 9 d after the onset of disease. A novel reassortant AIV, H10N8, was isolated from a tracheal aspirate specimen that was obtained from the patient 7 d after onset. This case was the first human case of influenza A subtype H10N8. On 4 February, 2014, another death due to H10N8 avian influenza was reported in Jiangxi Province, China.
Aged ; China ; epidemiology ; Female ; Humans ; Influenza A Virus, H10N8 Subtype ; classification ; Influenza A Virus, H7N9 Subtype ; classification ; Influenza A Virus, H9N2 Subtype ; classification ; Influenza, Human ; epidemiology ; virology ; Phylogeny ; Reassortant Viruses ; classification

Novel subtypes of Asian-origin (Goose/Guangdong lineage) H5 highly pathogenic avian influenza (HPAI) viruses belonging to clade 2.3.4, such as H5N2, H5N5, H5N6, and H5N8, have been identified in China since 2008 and have since evolved into four genetically distinct clade 2.3.4.4 groups (A–D). Since 2014, HPAI clade 2.3.4.4 viruses have spread rapidly via migratory wild aquatic birds and have evolved through reassortment with prevailing local low pathogenicity avian influenza viruses. Group A H5N8 viruses and its reassortant viruses caused outbreaks in wide geographic regions (Asia, Europe, and North America) during 2014–2015. Novel reassortant Group B H5N8 viruses caused outbreaks in Asia, Europe, and Africa during 2016–2017. Novel reassortant Group C H5N6 viruses caused outbreaks in Korea and Japan during the 2016–2017 winter season. Group D H5N6 viruses caused outbreaks in China and Vietnam. A wide range of avian species, including wild and domestic waterfowl, domestic poultry, and even zoo birds, seem to be permissive for infection by and/or transmission of clade 2.3.4.4 HPAI viruses. Further, compared to previous H5N1 HPAI viruses, these reassortant viruses show altered pathogenicity in birds. In this review, we discuss the evolution, global spread, and pathogenicity of H5 clade 2.3.4.4 HPAI viruses.
Africa ; Animals ; Asia ; Birds ; China ; Disease Outbreaks ; Epidemiology ; Europe ; Influenza in Birds* ; Japan ; Korea ; Poultry ; Reassortant Viruses ; Seasons ; Vietnam ; Virulence*

Preparation of maternal strain A/PR/8/34 HA antiserum for influenza virus classical reassortment. A/PR/8/34 virus was digested by bromelain after inactivation and purification. 5%-20% sucrose continuous density gradient centrifugation method was used to purify HA protein. SIRD method was used to select the target protein. SDS-PAGE method was used to identified HA protein. High Immunogenic A/PR/8/34 HA protein was successfully prepared and HI titer reached 10240. High purity HA antiserum was identified by SIRD method. The key reagent in the classical reassortment of influenza virus was prepared, and the complete set of technical methods were explored, which laid the foundation for the independent research and development of seasonal influenza vaccine strains of China.
Animals ; Antibodies, Viral ; immunology ; Electrophoresis, Polyacrylamide Gel ; Female ; Hemagglutination Inhibition Tests ; Hemagglutinin Glycoproteins, Influenza Virus ; analysis ; immunology ; Humans ; Influenza A Virus, H1N1 Subtype ; genetics ; immunology ; Influenza, Human ; immunology ; virology ; Rabbits ; Reassortant Viruses ; genetics ; immunology

One unusual human G3P[3] group A rotavirus (RVA) strain M2-102 was identified in stool sample collected from a child with diarrhea in Guangxi Province, China in 2014. It is well known that G3P[3] is a genotype commonly identified in feline and canine RVAs. However, the preliminary phylogenetic analyses of the VP7 and VP4 genes of strain M2-102 indicated that these two genes were closely related to bat RVA strain MYAS33 and simian strain RRV, respectively, whereas both clustered distantly to feline/canine-like RVA strains. In this study, full genome sequencing and molecular analyses were conducted to obtain the true origin of strain M2-102. It was revealed that strain RVA/Human-wt/CHN/M2-102/2014/G3P[3] exhibited a G3-P[3]-I3-R3-C3-M3-A9-N3-T3-E3-H6 genotype constellation for VP7-VP4-VP6-VP1-VP2-VP3-NSP1-NSP2-NSP3-NSP4-NSP5 genes. Phylogenetic analyses revealed that 5 genes (VP7, VP1, VP2, NSP2 and NSP3) from strain M2-102 were closely related to those of bat strain MYAS33 from Yunnan Province which was thought a true bat RVA strain rather than a virus transmitted between species, while another 5 genes (VP4, VP3, NSP1, NSP4 and NSP5) clustered closely with those of simian strain RRV, yet the VP6 gene was closely related to that of human G3P[9] strain AU-1 and AU-1-like RVAs. The epidemiological data indicated that the child infected with M2-102 came from a countryside village, located in Dong Autonomous County of Sanjiang (subtropical hilly wooded area), Liuzhou city in Guangxi Province which might provide natural environment for reassortment events occurring among animal and human RVAs. Therefore, the data suggest that human strain M2-102 might originate from multiple reassortment events among bat, simian and human AU-1-like RVAs, yet it is not clear whether the genomic backbone based on bat MYAS33 (5 genes) and simian RRV (5 genes) like rotaviruses had been obtained through reassortment before being transmitted to the human. This is the first report on whole genome analysis of human G3P[3] RVA from China.
Child, Preschool ; China ; Genome, Viral ; Genomics ; Humans ; Male ; Molecular Sequence Data ; Phylogeny ; Reassortant Viruses ; classification ; genetics ; isolation & purification ; Rotavirus ; classification ; genetics ; isolation & purification ; Rotavirus Infections ; virology ; Viral Proteins ; genetics

Novel reassortant H3N2 swine influenza viruses (SwIV) with the matrix gene from the 2009 H1N1 pandemic virus have been isolated in many countries as well as during outbreaks in multiple states in the United States, indicating that H3N2 SwIV might be a potential threat to public health. Since southern China is the world's largest producer of pigs, efficient vaccines should be developed to prevent pigs from acquiring H3N2 subtype SwIV infections, and thus limit the possibility of SwIV infection at agricultural fairs. In this study, a high-growth reassortant virus (GD/PR8) was generated by plasmid-based reverse genetics and tested as a candidate inactivated vaccine. The protective efficacy of this vaccine was evaluated in mice by challenging them with another H3N2 SwIV isolate [A/Swine/Heilongjiang/1/05 (H3N2) (HLJ/05)]. Prime and booster inoculation with GD/PR8 vaccine yielded high-titer serum hemagglutination inhibiting antibodies and IgG antibodies. Complete protection of mice against H3N2 SwIV was observed, with significantly reduced lung lesion and viral loads in vaccine-inoculated mice relative to mock-vaccinated controls. These results suggest that the GD/PR8 vaccine may serve as a promising candidate for rapid intervention of H3N2 SwIV outbreaks in China.
Animals ; Female ; Influenza A Virus, H3N2 Subtype/*genetics/immunology ; Influenza Vaccines/genetics/immunology/*therapeutic use ; Mice ; Mice, Inbred BALB C ; Orthomyxoviridae Infections/immunology/*prevention & control/virology ; Reassortant Viruses/genetics/immunology ; Reverse Genetics/methods/*veterinary ; Swine ; Swine Diseases/immunology/*prevention & control/virology ; Vaccines, Inactivated ; Virus Replication

Understanding inter-species transmission of influenza viruses is an important research topic. Scientists try to identify and evaluate the functional factors determining the host range of influenza viruses by generating the recombinant viruses through reverse genetics in laboratories, which reveals the viruses' molecular mechanisms of infection and transmission in different species. Therefore, the reverse genetic method is a very important tool for further understanding the biology of influenza viruses and will provide the insight for the prevention and treatment of infections and transmission. However, these recombinant influenza viruses generated in laboratories will become the potential threat to the public health and the environment. In this paper, we discussed the biological safety issues of recombinant influenza viruses and suggested we should set up protocols for risk management on research activities related to recombinant highly pathogenic influenza viruses.
Influenza A Virus, H5N1 Subtype ; genetics ; Laboratories ; Microbiology ; Orthomyxoviridae ; genetics ; Public Health ; Reassortant Viruses ; genetics ; Recombination, Genetic ; Safety

OBJECTIVETo explore the characteristics of the genetic variation of hemagglutinin( HA) and three internal genes coding for the nucleoprotein ( NP) , matrix protein ( M) and nonstructural protein ( NS) of influenza B virus.

METHODSA total of 31 strains of influenza B virus were isolated in Zhejiang province from 1999 to 2012, and then were amplified and sequenced the genes of HAl , NP, M and NS. The phylogenetic tree was constructed, the nucleotide substitution rate of the above individual gene was estimated and the variation sites of amino acids were analyzed.

RESULTSThe 31 isolated strains of influenza B virus were divided into two distinct lineages Victoria and Yamagata in the phylogenetic tree of HAl gene,represented by B/Victoria/2/87 and B/Yamagata/16/88. Phylogenetic analysis of the NP gene showed that the NP gene of Victoria-like influenza B strains which were isolated after 2010 was highly homologous with Yamagata-like isolates, and thereby they were found to be on the same branch of the phylogenetic tree of the NP gene. Nucleotide substitution rates of HAl , NP, M and NS genes were estimated to be 2. 29 x 10 -3 ,1. 39 X 10-3 ,1. 78 X 10-3 ,1. 30 X 10-3 /site per year, respectively. Variations of amino acid of HAl domain of Victoria-like isolates mainly included K48E ,L58P ,N75K,K80R,K129N/S,N165K,S172P ,Sl97N/D and A202V; while those in Yamagata-like isolates were R48K, S1501, N166Y, N203S, G230D and D233N. Determined amino acid sequences of NP of Victoria-like influenza B isolates were similar to Yamagata-like isolates after 2010 and variations happened on four characteristic amino acid sites, naming A60D, I233V, N513S and V5341, compared with previous Victoria-like influenza B isolates.

CONCLUSIONSignificant variation was found among influenza B strains isolated in Zhejiang province from 1999 to 2012. The surface HAl gene evolved more rapidly than internal genes. Gene reassortment and gene mutation were the main evolutionary mechanism of influenza B virus.

China ; epidemiology ; Evolution, Molecular ; Genes, Viral ; Genetic Variation ; Hemagglutinin Glycoproteins, Influenza Virus ; genetics ; Humans ; Influenza B virus ; genetics ; Influenza, Human ; epidemiology ; virology ; Phylogeny ; Reassortant Viruses ; genetics ; Viral Core Proteins ; genetics ; Viral Matrix Proteins ; genetics ; Viral Nonstructural Proteins ; genetics

OBJECTIVETo investigate the evolution features of whole-genome of influenza virus H3N2 prevalent in Qingdao from year 2007 to 2011.

METHODSThe RNA of 58 strains of influenza virus H3N2 prevalent in Qingdao between 2007 and 2011 was extracted and all segments amplified by RT-PCR. The sequence was then detected and assembled by software Sequencer. A total of 589 strains of influenza virus H3N2 with more than 300 amino acid recorded by GenBank were selected. The phylogeny and molecular features of all gene segments were analyzed by software Mega 5.0, referred by the heavy chain of hemagglutinin (HA1).

RESULTSHemagglutinin (HA) genes of influenza virus H3N2 prevalent in Qingdao between year 2007 and 2011 formed a single trunk of phylogenetic tree. Every prevalent strain originated in last season. The analysis of the evolution of whole genome found that reassortment virus strains were prevalent between year 2009 and 2010, but between 2010 and 2011 there were two series of prevalent strains, which showed complicated reassortment. Compared with the vaccine strains, the variant amino acids of protein of virus HA1 between year 2007 and 2011 were 8, 6, 6, 8 and 11, involving 13 antigenic sites. The sequence analysis of M2 protein showed that the isolated influenza virus H3N2 mutated in amino acid site 31, from serine to asparagine (S31N). HA1 gene of influenza virus H3N2 isolated in Qingdao between 2007 and 2011 shared the similar phylogenetic tree with the globally prevalent strain. The comparison of the sequence and the analysis of the antigenicity found co-infection between H3N2 and A/H1N1 in the strain A/Qingdao/F521/2011.

CONCLUSIONThe evolution features of all segments of influenza virus H3N2 prevalent in Qingdao between year 2007 and 2011 were complicated.

China ; Evolution, Molecular ; Genome, Viral ; Hemagglutinin Glycoproteins, Influenza Virus ; genetics ; Humans ; Influenza A Virus, H3N2 Subtype ; genetics ; Phylogeny ; RNA, Viral ; Reassortant Viruses ; genetics ; Sequence Analysis ; Viral Matrix Proteins ; genetics

OBJECTIVETo investigate the origin and the recombinant model of H7N9 virus prevailing in China by sequence analysis.

METHODSThe sequences of H7N9 virus were collected and analyzed with the software BLAST and MEGA 5.0. The phylogenetic trees were constructed after multiple sequences alignment. The homologous sequences of H7N9 segments were determined and the model was inferred according to the origin of H7N9 segments.

RESULTSThe most relevant sequences of HA, NA, NS and PB2 segments were located at one branch of the phylogenetic tree, while the closest relevant sequences of PB1, PA, NP and MP contained two H9N2 virus origins. According to the analysis of sequence origin, H7N9 viruses might be divided into 5 genotypes: namely A, B, A/Shanghai/1/2013-H7N9, A/Pigeon/Shanghai/S1069-H7N9 and A/Zhejiang/HZ1/2013-H7N9, and the genotype A consisted of A1 and A2 subtypes.

CONCLUSIONThe prevailing H7N9 virus might be derived from 5 different viruses after 4 times of recombination, which resulted in the two major types of A and B. The subtypes of A1 and A2 were two different derivatives from one reassortant. The A/Pigeon/Shanghai/S1069-H7N9 strain might be the recombinant of type A H7N9 virus with a local H9N2 virus during the H7N9 epidemics. The A/Zhejiang/HZ1/2013-H7N9 strain could be the re-arrangement of subtype A2 with type B H7N9 virus.

China ; Genome, Viral ; Genotype ; Humans ; Influenza A Virus, H7N9 Subtype ; classification ; genetics ; isolation & purification ; Influenza, Human ; virology ; Phylogeny ; Reassortant Viruses ; classification ; genetics ; isolation & purification ; Sequence Analysis, RNA ; Viral Proteins ; genetics

From April 2009 onward, a new strain of human H1N1 influenza virus has swept over the world. The genome of influenza virus consists of 8 segments, encoding 10 proteins, respectively. The reassortments among the 8 segments cause the variation of influenza virus. Therefore, phylogenetic analysis of the 8 genes is very important. In this paper, we choose neighboring word frequency as the genomic features, using VC++ programming to analyze evolution of the 8 segments of H1N1 virus. As a result, we found that PB2 genes and PA genes of these three isolated virus were originated from North American avian influenza virus, that PB1 genes were originated from the seasonal influenza virus of human, and that HA genes, NS genes and NP genes came from the North American classical swine influenza A virus. The NA segments and M segments were originated from the European swine influenza virus.
Cloning, Molecular ; Genes, Viral ; Genome, Viral ; Humans ; Influenza A Virus, H1N1 Subtype ; genetics ; Influenza, Human ; epidemiology ; virology ; Mexico ; epidemiology ; Phylogeny ; Reassortant Viruses ; genetics ; United States ; epidemiology