Analysis of synonymous codon usage bias in 09H1N1

A novel subtype of influenza A virus 09H1N1 has rapidly spread across the world. Evolutionary analyses of this virus have revealed that 09H1N1 is a triple reassortant of segments from swine, avian and human influenza viruses. In this study, we investigated factors shaping the codon usage bias of 09H1N1 and carried out cluster analysis of 60 strains of influenza A virus from different subtypes based on their codon usage bias. We discovered that more preferentially used codons of 09H1N1 are A-ended or U-ended, and the intra-genomic codon usage bias of 09H1N1 is quite low. Base composition constraint, dinucleotide biases and translational selection are the main factors influencing the codon usage bias of 09H1N1. At the genome level, we find that the codon usage bias of 09H1N1 is similar to H1N1 (A/swine/Kansas/77778/2007H1N1), H9N2 from Asia, H1N2 from Asia and North America and H3N2 from North America. Our results provide insight for understanding the processes governing evolution, regulation of gene expression, and revealing the evolution of 09H1N1.     

Analysis of synonymous codon usage in H5N1 virus and other influenza A viruses

In this study, we calculated the codon usage bias in H5N1 virus and performed a comparative analysis of synonymous codon usage patterns in H5N1 virus, five other evolutionary related influenza A viruses and a influenza B virus. Codon usage bias in H5N1 genome is a little slight, which is mainly determined by the base compositions on the third codon position. By comparing synonymous codon usage patterns in different viruses, we observed that the codon usage pattern of H5N1 virus is similar with other influenza A viruses, but not influenza B virus, and the synonymous codon usage in influenza A virus genes is phylogenetically conservative, but not strain-specific. Synonymous codon usage in genes encoded by different influenza A viruses is genus conservative. Compositional constraints could explain most of the variation of synonymous codon usage among these virus genes, while gene function is also correlated to synonymous codon usages to a certain extent. However, translational selection and gene length have no effect on the variations of synonymous codon usage in these virus genes.     

A型流感病毒NS1基因密码子去优化改造引起病毒毒力减弱

根据A型流感病毒密码子使用偏嗜性,选取稀有密码子对A/Puerto Rico/8/34(H1N1)病毒NS1基因内部110个氨基酸区域进行密码子同义突变改造,并全基因合成NS基因,利用反向遗传操作技术拯救出含有密码子去优化NS1基因的重组病毒(deoNS)。体外细胞噬斑形成实验和病毒生长曲线证明该病毒在MDCK细胞内的感染和复制能力比野生型病毒低约1000倍;BALB/c小鼠体内致病力实验证明deoNS病毒不能引起小鼠发病和死亡,该病毒在小鼠肺内的复制滴度比野生型病毒低100～1000倍。本研究探索了通过基因组密码子去优化改造途径降低A型流感病毒毒力的可行性,首次证明流感病毒NS1基因密码子去优化同义突变可以降低病毒毒力,为流感减毒活疫苗的研究提供了新的思路。     

H1N1流感病毒聚合酶片段的CpG抑制及其对密码子偏爱性的影响

H1N1流感病毒的聚合酶具有RNA复制、转录等功能,并且对流感病毒片段包装、子代繁殖及宿主适应性等有着重要作用。通过分析人、猪及禽类H1N1流感病毒聚合酶片段的二核苷酸频率及同义密码子的偏爱性,发现不同宿主中,流感病毒聚合酶片段的CpG频率最低,且均被强烈抑制;通过三类宿主间的比较发现,人流感病毒抑制最为强烈,且其CpG频率随年份呈下降趋势,但2009年毒株的CpG频率突然上升。比较同义密码子使用频率发现,含有CpG的同义密码子相对使用频率均小于1,证明CpG抑制作用是影响同义密码子偏爱性的一个重要因素。以上结果暗示,CpG抑制对H1N1流感病毒的进化及跨宿主传播可能有重要影响。     

流感病毒基因的密码子偏好性及聚类分析

流行性感冒病毒是一种造成人类及动物患流行性感冒的RNA病毒,它造成急性上呼吸道感染,并由空气迅速传播,在世界各地常有周期性的大流行。根据该病毒的基因组CDS序列,探讨了基因组序列密码子的使用模式和特性,并进行了病毒间的聚类分析。结果表明:流感病毒的G+C含量均低于A+U含量,偏向使用以A、U结尾的密码子的程度比使用以G、C结尾的较高,CUG、UCA、AGU、AGC、AGA、AGG、GUG、CCA、ACA、GGA、GCA、AUU、UGA、CAU、CAA、AAU、AAA、GAA等18个密码子为流感病毒共有的偏好性密码子,且以A结尾的居多,尤其偏爱AGA、GGA。聚类结果表明首先亚洲流感病毒H2N2和香港流感病毒H2N2聚为一类,亚洲流感病毒H1N1和俄罗斯流感病毒H1N1聚为一类,1997年和2003年~2004年发生的人禽流感聚为一类,说明它们的密码子使用的偏好性相似;而2009年爆发的甲型H1N1流感和任何一个流感的距离都比较远,说明甲型H1N1流感病毒是一种新型的病毒,不同于以往任何一种流感病毒。     

Increased pathogenicity of a reassortant 2009 pandemic H1N1 influenza virus containing an H5N1 hemagglutinin

A novel H1N1 influenza virus emerged in 2009 (pH1N1) to become the first influenza pandemic of the 21st century. This virus is now cocirculating with highly pathogenic H5N1 avian influenza viruses in many parts of the world, raising concerns that a reassortment event may lead to highly pathogenic influenza strains with the capacity to infect humans more readily and cause severe disease. To investigate the virulence of pH1N1-H5N1 reassortant viruses, we created pH1N1 (A/California/04/2009) viruses expressing individual genes from an avian H5N1 influenza strain (A/Hong Kong/483/1997). Using several in vitro models of virus replication, we observed increased replication for a reassortant CA/09 virus expressing the hemagglutinin (HA) gene of HK/483 (CA/09-483HA) relative to that of either parental CA/09 virus or reassortant CA/09 expressing other HK/483 genes. This increased replication correlated with enhanced pathogenicity in infected mice similar to that of the parental HK/483 strain. The serial passage of the CA/09 parental virus and the CA/09-483HA virus through primary human lung epithelial cells resulted in increased pathogenicity, suggesting that these viruses easily adapt to humans and become more virulent. In contrast, serial passage attenuated the parental HK/483 virus in vitro and resulted in slightly reduced morbidity in vivo, suggesting that sustained replication in humans attenuates H5N1 avian influenza viruses. Taken together, these data suggest that reassortment between cocirculating human pH1N1 and avian H5N1 influenza strains will result in a virus with the potential for increased pathogenicity in mammals.     

Prediction of Directional Changes of Influenza A Virus Genome Sequences with Emphasis on Pandemic H1N1/09 as a Model Case

Influenza virus poses a significant threat to public health, as exemplified by the recent introduction of the new pandemic strain H1N1/09 into human populations. Pandemics have been initiated by the occurrence of novel changes in animal sources that eventually adapt to human. One important issue in studies of viral genomes, particularly those of influenza virus, is to predict possible changes in genomic sequence that will become hazardous. We previously established a clustering method termed ‘BLSOM’ (batch-learning self-organizing map) that does not depend on sequence alignment and can characterize and compare even 1 million genomic sequences in one run. Strategies for comparing a vast number of genomic sequences simultaneously become increasingly important in genome studies because of remarkable progresses in nucleotide sequencing. In this study, we have constructed BLSOMs based on the oligonucleotide and codon composition of all influenza A viral strains available. Without prior information with regard to their hosts, sequences derived from strains isolated from avian or human sources were successfully clustered according to the hosts. Notably, the pandemic H1N1/09 strains have oligonucleotide and codon compositions that are clearly different from those of human seasonal influenza A strains. This enables us to infer future directional changes in the influenza A viral genome.     

Evolution of the Hemagglutinin Gene of the Influenza A(H1N1)pdm09 Virus in Morocco During Two Influenza Seasons 2009–2011

To study genetic evolution of Moroccan influenza A(H1N1)pdm09 virus strains, we conducted a molecular characterization of the hemagglutinin gene subunit 1 (HA1) of 36 influenza A(H1N1)pdm09 virus strains. The stains were collected from patients in Rabat and Casablanca during two influenza seasons 2009–2010 and 2010–2011. Nucleotide and amino acid sequences of 14 influenza A(H1N1)pdm09 virus strains from 2009 to 2010 were ~97 and 99 %, respectively, similar to the reference strain A/California/07/2009 (H1N1). Phylogenetic analysis of 22 influenza A(H1N1)pdm09 virus strains from 2010 to 2011 revealed a co-circulation of three well-described different genetic groups. Most important, none of the identified groups showed significant changes at the antigenic site of the virus HA1 subunit which may alter the efficacy of California/07/2009 (H1N1) vaccine.     

Expression of recombinant HA1 protein for specific detection of influenza A/H1N1/2009 antibodies in human serum

The hemagglutinin genes (HA1 subunit) from human and animal 2009 pandemic H1N1 virus isolates were expressed with a baculovirus vector. Recombinant HA1 (rHA1) protein‐based ELISA was evaluated for detection of specific influenza A(H1N1)pdm09 antibodies in serum samples from vaccinated humans. It was found that rHA1 ELISA consistently differentiated between antibodies recognizing the seasonal influenza H1N1 and pdm09 viruses, with a concordance of 94% as compared to the hemagglutination inhibition test. This study suggests the utility of rHA1 ELISA in serosurveillance.     

Revelation of Influencing Factors in Overall Codon Usage Bias of Equine Influenza Viruses

Equine influenza viruses (EIVs) of H3N8 subtype are culprits of severe acute respiratory infections in horses, and are still responsible for significant outbreaks worldwide. Adaptability of influenza viruses to a particular host is significantly influenced by their codon usage preference, due to an absolute dependence on the host cellular machinery for their replication. In the present study, we analyzed genome-wide codon usage patterns in 92 EIV strains, including both H3N8 and H7N7 subtypes by computing several codon usage indices and applying multivariate statistical methods. Relative synonymous codon usage (RSCU) analysis disclosed bias of preferred synonymous codons towards A/U-ended codons. The overall codon usage bias in EIVs was slightly lower, and mainly affected by the nucleotide compositional constraints as inferred from the RSCU and effective number of codon (ENc) analysis. Our data suggested that codon usage pattern in EIVs is governed by the interplay of mutation pressure, natural selection from its hosts and undefined factors. The H7N7 subtype was found less fit to its host (horse) in comparison to H3N8, by possessing higher codon bias, lower mutation pressure and much less adaptation to tRNA pool of equine cells. To the best of our knowledge, this is the first report describing the codon usage analysis of the complete genomes of EIVs. The outcome of our study is likely to enhance our understanding of factors involved in viral adaptation, evolution, and fitness towards their hosts.     

Antigenic Drift of the Hemagglutinin from an Influenza A (H1N1) pdm09 Clinical Isolate Increases its Pathogenicity In Vitro

Virologica Sinica - The influenza A (H1N1) pdm09 virus emerged in 2009 and has been continuously circulating in humans for over ten years. Here, we analyzed a clinical influenza A (H1N1)...     

A/H1N1流感—世界关注的焦点

2009年4月,A/H1N1流感在墨西哥和美国暴发。随后,疫情迅速蔓延到美洲、欧洲、亚洲多个国家。A/H1N1流感病毒是一种以前在人或动物身上从未观测到的新病毒。遗传进化和抗原特性分析表明该病毒和猪流感病毒密切相关,与人类的季节性流感病毒有明显区别。但是流行病学信息表明A/H1N1流感病毒只攻击人类,并在人与人之间传播,尚未发现动物向人类传播的情况。本文从A/H1N1流感病毒的生物学特性、临床特征、公共卫生意义等方面全面阐述了A/H1N1流感的最新研究进展,为正确认识和科学防控A/H1N1流感提供参考。     

Epidemiology and Genotypic Diversity of Eurasian Avian-Like H1N1 Swine Influenza Viruses in China

Eurasian avian-like H1 N1(EA H1 N1) swine influenza virus(SIV) outside European countries was first detected in Hong Kong Special Administrative Region(Hong Kong, SAR) of China in 2001. Afterwards, EA H1 N1 SIVs have become predominant in pig population in this country. However, the epidemiology and genotypic diversity of EA H1 N1 SIVs in China are still unknown. Here, we collected the EA H1 N1 SIVs sequences from China between 2001 and 2018 and analyzed the epidemic and phylogenic features, and key molecular markers of these EA H1 N1 SIVs. Our results showed that EA H1 N1 SIVs distributed in nineteen provinces/municipalities of China. After a long-time evolution and transmission, EA H1 N1 SIVs were continuously reassorted with other co-circulated influenza viruses, including 2009 pandemic H1 N1(A(H1 N1)pdm09), and triple reassortment H1 N2(TR H1 N2) influenza viruses, generated 11 genotypes. Genotype 3 and 5, both of which were the reassortments among EA H1 N1, A(H1 N1)pdm09 and TR H1 N2 viruses with different origins of M genes, have become predominant in pig population. Furthermore, key molecular signatures were identified in EA H1 N1 SIVs. Our study has drawn a genotypic diversity image of EA H1 N1 viruses, and could help to evaluate the potential risk of EA H1 N1 for pandemic preparedness and response.     

Origin of the 1918 pandemic H1N1 influenza A virus as studied by codon usage patterns and phylogenetic analysis

The pandemic of 1918 was caused by an H1N1 influenza A virus, which is a negative strand RNA virus; however, little is known about the nature of its direct ancestral strains. Here we applied a broad genetic and phylogenetic analysis of a wide range of influenza virus genes, in particular the PB1 gene, to gain information about the phylogenetic relatedness of the 1918 H1N1 virus. We compared the RNA genome of the 1918 strain to many other influenza strains of different origin by several means, including relative synonymous codon usage (RSCU), effective number of codons (ENC), and phylogenetic relationship. We found that the PB1 gene of the 1918 pandemic virus had ENC values similar to the H1N1 classical swine and human viruses, but different ENC values from avian as well as H2N2 and H3N2 human viruses. Also, according to the RSCU of the PB1 gene, the 1918 virus grouped with all human isolates and "classical" swine H1N1 viruses. The phylogenetic studies of all eight RNA gene segments of influenza A viruses may indicate that the 1918 pandemic strain originated from a H1N1 swine virus, which itself might be derived from a H1N1 avian precursor, which was separated from the bulk of other avian viruses in toto a long time ago. The high stability of the RSCU pattern of the PB1 gene indicated that the integrity of RNA structure is more important for influenza virus evolution than previously thought.     

The PDZ-binding motif of the avian NS1 protein affects transmission of the 2009 influenza A(H1N1) virus

By nature of their segmented RNA genome, influenza A viruses (IAVs) have the potential to generate variants through a reassortment process. The influenza nonstructural (NS) gene is critical for a virus to counteract the antiviral responses of the host. Therefore, a newly acquired NS segment potentially determines the replication efficiency of the reassortant virus in a range of different hosts. In addition, the C-terminal PDZ-binding motif (PBM) has been suggested as a pathogenic determinant of IAVs. To gauge the pandemic potential from human and avian IAV reassortment, we assessed the replication properties of NS-reassorted viruses in cultured cells and in the lungs of mice and determined their transmissibility in guinea pigs. Compared with the recombinant A/Korea/01/2009 virus (rK09; 2009 pandemic H1N1 strain), the rK09/VN:NS virus, in which the NS gene was adopted from the A/Vietnam/1203/2004 virus (a human isolate of the highly pathogenic avian influenza H5N1 virus strains), exhibited attenuated virulence and reduced transmissibility. However, the rK09/VN:NS-PBM virus, harboring the PBM in the C-terminus of the NS1 protein, recovered the attenuated virulence of the rK09/VN:NS virus. In a guinea pig model, the rK09/VN:NS-PBM virus showed even greater transmission efficiency than the rK/09 virus. These results suggest that the PBM in the NS1 protein may determine viral persistence in the human and avian IAV interface.     

T cell-mediated protection against lethal 2009 pandemic H1N1 influenza virus infection in a mouse model

Genetic mutation and reassortment of influenza virus gene segments, in particular those of hemagglutinin (HA) and neuraminidase (NA), that lead to antigenic drift and shift are the major strategies for influenza virus to escape preexisting immunity. The most recent example of such phenomena is the first pandemic of H1N1 influenza of the 21st century, which started in 2009. Cross-reactive antibodies raised against H1N1 viruses circulating before 1930 show protective activity against the 2009 pandemic virus. Cross-reactive T-cell responses can also contribute to protection, but in vivo support of this view is lacking. To explore the protection mechanisms in vivo, we primed mice with H1 and H3 influenza virus isolates and rechallenged them with a virus derived from the 2009 H1N1 A/CA/04/09 virus, named CA/E3/09. We found that priming with influenza viruses of both H1 and H3 homo- and heterosubtypes protected against lethal CA/E3/09 virus challenge. Convalescent-phase sera from these primed mice conferred no neutralization activity in vitro and no protection in vivo. However, T-cell depletion studies suggested that both CD4 and CD8 T cells contributed to the protection. Taken together, these results indicate that cross-reactive T cells established after initial priming with distally related viruses can be a vital component for prevention of disease and control of pandemic H1N1 influenza virus infection. Our results highlight the importance of establishing cross-reactive T-cell responses for protecting against existing or newly emerging pandemic influenza viruses.     

Phylogenetic analyses of pandemic influenza A (H1N1) virus in university students at Tobetsu, Hokkaido, Japan

Pandemic influenza H1N1 virus (A[H1N1]pdm09) emerged in 2009. To determine the phylogeography of A(H1N1)pdm09 in a single population, 70 strains of the virus were isolated from university students or trainee doctors at Tobetsu, Hokkaido, Japan, between September and December 2009. The nucleotide sequences of the HA1 region of the HA genes and described phylogenetic relationships of the strains circulating among them were analyzed. It was found that the 70 isolates could be phylogenetically separated into three groups and that two epidemics were caused by different groups of the virus. The three groups were also distinguishable from each other by three amino acid changes: A197T, S203T and Q293H. The substitution of S203T, which is located in the antigenic site, suggests antigenic drift of the virus.     

The M segment of the 2009 new pandemic H1N1 influenza virus is critical for its high transmission efficiency in the guinea pig model

A remarkable feature of the 2009 pandemic H1N1 influenza virus is its efficient transmissibility in humans compared to that of precursor strains from the triple-reassortant swine influenza virus lineage, which cause only sporadic infections in humans. The viral components essential for this phenotype have not been fully elucidated. In this study, we aimed to determine the viral factors critical for aerosol transmission of the 2009 pandemic virus. Single or multiple segment reassortments were made between the pandemic A/California/04/09 (H1N1) (Cal/09) virus and another H1N1 strain, A/Puerto Rico/8/34 (H1N1) (PR8). These viruses were then tested in the guinea pig model to understand which segment of Cal/09 virus conferred transmissibility to the poorly transmissible PR8 virus. We confirmed our findings by generating recombinant A/swine/Texas/1998 (H3N2) (sw/Tx/98) virus, a representative triple-reassortant swine virus, containing segments of the Cal/09 virus. The data showed that the M segment of the Cal/09 virus promoted aerosol transmissibility to recombinant viruses with PR8 and sw/Tx/98 virus backgrounds, suggesting that the M segment is a critical factor supporting the transmission of the 2009 pandemic virus.     

海南省2016-2018年A(H1N1)pdm09亚型流感病毒基因特性分析

2009年A(H1N1)pdm09亚型流感病毒在墨西哥暴发,之后在全世界流行。为了解海南省2016-2018年A(H1N1)pdm09亚型流感病毒流行态势,分析血凝素(HA)与神经氨酸酶(NA)基因遗传进化特征与变异情况,本研究从中国流感监测信息系统获取海南省2016-2018年流感病毒病原学监测数据,选取5家流感监测网络实验室分离鉴定的37株A(H1N1)pdm09亚型流感毒株进行HA与NA基因测序,利用MEGA 10.1.8构建HA与NA基因种系进化树,并分析其氨基酸变异情况。结果显示,2016-2018年共出现3次A(H1N1)pdm09亚型流感病毒活动高峰。2017年10月份以后的分离株(4/8)与2018年大部分分离株(21/22)独立于疫苗株A/Michigan/45/2015聚为一个小支,发生20余处HA与NA氨基酸位点变异。与疫苗株A/California/7/2009(2010-2016)相比,2016-2018年流感病毒分离株在HA基因抗原决定簇上发生7处氨基酸变异并有一个潜在糖基化位点,未发现HA基因受体结合位点变异与NA基因耐药性变异。本研究提示,2016-2018年,A(H1N1)pdm09亚型流感病毒逐步发生规律性进化,氨基酸变异频率有增加趋势,今后应持续加强流感病毒病原学监测,密切追踪A(H1N1)pdm09亚型流感病毒基因变异情况,为科学防控提供理论依据。     

2009−2015年中国甲型H1N1流感病毒血凝素基因进化分析

【目的】为了解中国地区2009?2015年甲型H1N1流感病毒流行态势,分析血凝素(Hemagglutinin,HA)基因的变异情况及其遗传进化特征。【方法】汇集国家流感中心2009?2015年流感周报的流感流行数据,分析甲型H1N1流感的流行病学特征;从全球共享禽流感数据倡议组织数据库及美国国家生物技术中心数据库下载甲型H1N1流感病毒HA基因序列,采用生物学软件进行系统进化和遗传特性的分析。【结果】2009?2015年全国共发生4次甲型H1N1流感的流行高峰。2009?2015年毒株与参考毒株A/California/07/2009(H1N1)的HA基因同源性逐年降低。遗传进化分析显示同一年份的毒株在系统进化树上基本呈现集中分布,2011年的毒株独立形成2个分支。分子特征表现为HA基因的4个抗原决定簇氨基酸位点均有变异,其中Ca区的203位、Sa区的163位和Sb区的185位氨基酸位点逐渐替换为新的氨基酸。除2010年与2012年,其他年份的毒株通过不同模型均得到正向压力选择HA氨基酸位点240。【结论】甲型H1N1流感在中国地区成为主要流行的亚型之一。HA基因与其编码的氨基酸逐年变异,未来进一步的流感监测能力还需加强。