Antigenic epitope peptides of influenza H3N2 virus neuraminidase gene based on experiments

The neuraminidase (NA) in viral surface is one of the main subtype-specific antigen of influenza type A viruses.Neuraminidase is an enzyme to break the bonds between hemagglutinin (HA) and sialic acid to release newly formed viruses from infected cells.In this study,the H3N2 subtype virus NA genes were sequenced and NA proteins were screened for B-cell epitopes and assessed based on immunoinformatics.Based on this results,four peptides DR6,EY7,VG8 and RE8 (covering amino acid residues 151-156,368-374,398-405 and 428-435,respectively) of the NA protein were synthesized artificially.These peptides were used to immunize New Zealand rabbits subcutaneously to raise antisera.Experimental results showed that these four peptides were capable of eliciting antibodies against H3N2 viruses in a specific and sensitive feature,detected in vitro by enzyme-linked immunosorbent assay.Moreover,hemadsorption anti-releasing effects took place in three three-antisera-mixtures at a dilution of 1:40.Alignment using NA gene database showed that amino acid residues in these four epitope peptides were substituted at specific sites in all the NAs sequenced in this study.It was suggested that these NA epitope peptides might be used in combination with HA proteins as vaccine antigens.     

Avian flu: influenza virus receptors in the human airway

Although more than 100 people have been infected by H5N1 influenza A viruses, human-to-human transmission is rare. What are the molecular barriers limiting human-to-human transmission? Here we demonstrate an anatomical difference in the distribution in the human airway of the different binding molecules preferred by the avian and human influenza viruses. The respective molecules are sialic acid linked to galactose by an alpha-2,3 linkage (SAalpha2,3Gal) and by an alpha-2,6 linkage (SAalpha2,6Gal). Our findings may provide a rational explanation for why H5N1 viruses at present rarely infect and spread between humans although they can replicate efficiently in the lungs.     

Evidence for host-cell selection of influenza virus antigenic variants

Extensive antigenic variability and a capricious epidemiology are characteristics of influenza A and B viruses of man. The haemagglutinin (HA) undergoes frequent and progressive antigenic drift as a result of selection, under immunological pressure, of viruses possessing alterations in the amino acid sequences at specific sites in the molecule. Here we present evidence for an additional selection mechanism for antigenic variants of influenza virus that depends on differing host cell tropisms of virus subpopulations. These studies were initiated after earlier observations of the occurrence of a marked degree of antigenic variation during passage of laboratory strains of influenza virus in eggs and cell cultures (J.C.J., in preparation). We have now shown that cultivation of influenza B viruses in eggs selects subpopulations which are antigenically distinct from virus from the same source grown in mammalian cell cultures. As antigenic characterization of influenza virus strains for epidemiological purposes and for the preparation of influenza vaccines conventionally relies on the cultivation of virus in eggs, our findings may have important practical implications for vaccine design and efficacy.     

A common function for polyoma virus large-T and papillomavirus E1 proteins?

Nucleotide sequencing has revealed a common genetic organization for three papillomaviruses: BPV-1 (bovine papillomavirus type 1), HPV-1 (human papillomavirus type 1a) and HPV-6 (human papillomavirus type 6b). Several open reading frames, corresponding to as yet uncharacterized proteins, were observed in these genomes in the region that is required for oncogenic transformation by BPV-1 and for plasmidial maintenance of its genome. The longest of these frames, E1, is also the most conserved between the three viruses; we have compared the amino acid sequence of its putative product ('E1 protein') with those of the large-T proteins of three polyoma viruses and report here significant homologies in their carboxy-terminal halves, extending for over 200 amino acids. Moreover, similar secondary structures were predicted in this region, especially in two blocks of homologous residues, which correspond in the large-T proteins of polyoma and simian virus 40 (SV40) viruses to sites involved in the ATPase and nucleotide-binding activities. These observations suggest that the papillomavirus E1 proteins might have a function in common with the polyoma virus large-T proteins (which are required for the initiation of viral DNA replication). As it was suggested recently that the E1 gene product is involved in maintaining the BPV-1 genome as a plasmid in transformed cells, we speculate that the structural features conserved in these otherwise very different viruses are general characteristics of eukaryotic proteins involved in the control of DNA replication.     

Structure of the influenza virus haemagglutinin complexed with its receptor, sialic acid

The three-dimensional structures of influenza virus haemagglutinins complexed with cell receptor analogues show sialic acids bound to a pocket of conserved amino acids surrounded by antibody-binding sites. Sialic acid fills the conserved pocket, demonstrating that it is the influenza virus receptor. The proximity of the antibody-binding sites suggests that antibodies neutralize virus infectivity by preventing virus-to-cell binding. The structures suggest approaches to the design of anti-viral drugs that could block attachment of viruses to cells.     

Characterization of the 1918 influenza virus polymerase genes

The influenza A viral heterotrimeric polymerase complex (PA, PB1, PB2) is known to be involved in many aspects of viral replication and to interact with host factors, thereby having a role in host specificity. The polymerase protein sequences from the 1918 human influenza virus differ from avian consensus sequences at only a small number of amino acids, consistent with the hypothesis that they were derived from an avian source shortly before the pandemic. However, when compared to avian sequences, the nucleotide sequences of the 1918 polymerase genes have more synonymous differences than expected, suggesting evolutionary distance from known avian strains. Here we present sequence and phylogenetic analyses of the complete genome of the 1918 influenza virus, and propose that the 1918 virus was not a reassortant virus (like those of the 1957 and 1968 pandemics), but more likely an entirely avian-like virus that adapted to humans. These data support prior phylogenetic studies suggesting that the 1918 virus was derived from an avian source. A total of ten amino acid changes in the polymerase proteins consistently differentiate the 1918 and subsequent human influenza virus sequences from avian virus sequences. Notably, a number of the same changes have been found in recently circulating, highly pathogenic H5N1 viruses that have caused illness and death in humans and are feared to be the precursors of a new influenza pandemic. The sequence changes identified here may be important in the adaptation of influenza viruses to humans.     

Genetic recombination between RNA components of a multipartite plant virus

Genetic recombination of DNA is one of the fundamental mechanisms underlying the evolution of DNA-based organisms and results in their diversity and adaptability. The importance of the role of recombination is far less evident for the RNA-based genomes that occur in most plant viruses and in many animal viruses. RNA recombination has been shown to promote the evolutionary variation of picornaviruses, it is involved in the creation of defective interfering (DI) RNAs of positive- and negative-strand viruses and is implicated in the synthesis of the messenger RNAs of influenza virus and coronavirus. However, RNA recombination has not been found to date in viruses that infect plants. In fact, the lack of DI RNAs and the inability to demonstrate recombination in mixedly infected plants has been regarded as evidence that plants do not support recombination of viral RNAs. Here we provide the first molecular evidence for recombination of plant viral RNA. For brome mosaic virus (BMV), a plus-stranded, tripartite-genome virus of monocots, we show that a deletion in the 3' end region of a single BMV RNA genomic component can be repaired during the development of infection by recombination with the homologous region of either of the two remaining wild-type BMV RNA components. This result clearly shows that plant viruses have available powerful recombinatory mechanisms that previously were thought to exist only in animal hosts, thus they are able to adapt and diversify in a manner comparable to animal viruses. Moreover, our observation suggests an increased versatility of viruses for use as vectors in introducing new genes into plants.     

A New Definition of Virus

Security experts have not formally defined the distinction between viruses and normal programs. The paper takes user＇s intension as the criteria for malice, gives a formal definition of viruses that aim at stealing or destroying files, and proposes an algorithm to detect virus correctly. Compared with traditional definitions, this new definition is easy to understand, covers more malwares, adapts development of virus technology, and defines virus on the spot. The paper has also analyzed more than 250 real viruses and finds that they are all in the domain of the new definition, this implies that the new definition has great practical significance.     

A complete sequence and comparative analysis of a SARS-associated virus(Isolate BJ01)

Severe Acute Respiratory Syndrome (SARS) is a newly identified infectious disease[1—5]. The global outbreak of SARS has been threatening the health of people worldwide and has killed 353 people and infected more than 5462 in 27 countries, as reported by WHO on April 29, 2003 (http://www.who.int/csr/sarscountry/en). Although it has been recognized that a variant of virus from the family of coronavirus might be the candidate pathogen of SARS[1—5], its identity as the unique pathogen sti…     

A complete sequence and comparative analysis of a SARS-associated virus （Isolate BJO1）

The genome sequence of the Severe Acute Respiratory Syndrome (SARS)-assoclated virus provides essential information for the identification of pathogen(s), exploration of etiology and evolution, interpretation of transmission and pathogenesis, development of diagnostics, prevention by future vaccination, and treatment by developing new drugs.We report the complete genome sequence and comparative analysis of an isolate (B J01) of the coronavirus that has been recognized as a pathogen for SARS. The genome is 29725 nt in size and has 11 ORFs (Open Reading Frames). It is composed of a stable region encoding an RNA-dependent RNA polymerase (composed of 20RFs) and a variable region representing 4 CDSs (coding sequences) for viral structural genes (the S, E, M, N proteins) and 5 PUPs (putative uncharacterized proteins). Its gene order is identical to that of other known coronaviruses. The sequence alignment with all known RNA viruses places this virus as a member in the family of Coronaviridae. Thirty putative substitutions have been identified by comparative analysis of the 5 SARS-associated virus genome sequences in GenBank. Fifteen of them lead to possible amino acid changes (non-synonymous mutations) in the proteins. Three amino acid changes, with predicted alteration of physical and chemical features, have been detected in the S protein that is postulated to be involved in the immunoreactions between the virus and its host.Two amino acid changes have been detected in the M protein,which could be related to viral envelope formation. Phylogenetic analysis suggests the possibility of non-human origin of the SARS-associated viruses but provides no evidence that they are man-made. Further efforts should focus on identifying the etiology of the SARS-associated virus and ruling out conclusively the existence of other possible SARS-related pathogen(s).     

Myristic acid is coupled to a structural protein of polyoma virus and SV40

In the lytic cycle of papova viruses, both uncoating of the viral genome after infection and assembly of functional virions take place in the cell nucleus. The mechanisms by which newly internalized virions are targeted to the nucleus and viral DNA encapsidated into particles are poorly understood. Although the major capsid protein VP1 is involved in endocytosis, and largely defines virion structure, the functions of the minor proteins VP2 and VP3 have remained obscure. Here we show that VP2 from both polyoma virus and simian virus 40 (SV40) is covalently linked to myristic acid; this is the first report of a myristylated protein in the nucleus and of a fatty acid being important in the structure of a nonenveloped virus. We consider the implications of this unusual modification on encapsidation and suggest that VP2 may be a scaffolding protein for virion assembly.     

Enhanced virulence of influenza A viruses with the haemagglutinin of the 1918 pandemic virus

The 'Spanish' influenza pandemic of 1918-19 was the most devastating outbreak of infectious disease in recorded history. At least 20 million people died from their illness, which was characterized by an unusually severe and rapid clinical course. The complete sequencing of several genes of the 1918 influenza virus has made it possible to study the functions of the proteins encoded by these genes in viruses generated by reverse genetics, a technique that permits the generation of infectious viruses entirely from cloned complementary DNA. Thus, to identify properties of the 1918 pandemic influenza A strain that might be related to its extraordinary virulence, viruses were produced containing the viral haemagglutinin (HA) and neuraminidase (NA) genes of the 1918 strain. The HA of this strain supports the pathogenicity of a mouse-adapted virus in this animal. Here we demonstrate that the HA of the 1918 virus confers enhanced pathogenicity in mice to recent human viruses that are otherwise non-pathogenic in this host. Moreover, these highly virulent recombinant viruses expressing the 1918 viral HA could infect the entire lung and induce high levels of macrophage-derived chemokines and cytokines, which resulted in infiltration of inflammatory cells and severe haemorrhage, hallmarks of the illness produced during the original pandemic.     

Expression of AIDS virus envelope gene in recombinant vaccinia viruses

Acquired immune deficiency syndrome (AIDS) is an infectious disease characterized by severe impairment of the patient's cell-mediated immune system. Several lines of evidence have indicated that the aetiological agent of AIDS is a group of T-lymphotropic retroviruses, variously known as lymphadenopathy-associated virus (LAV), human T-lymphotropic virus type III (HTLV-III) and AIDS-associated retrovirus (ARV). Serological surveys have indicated that as many as one million people in the United States may have been infected by LAV/HTLV-III, and the spread of AIDS has become a global concern. The need for a better understanding of the viral immunology and for a vaccine against AIDS is self-evident. To this end, we have constructed recombinant vaccinia viruses containing the envelope (env) gene of LAV, and demonstrate here that cells infected with these viruses express immunoreactive proteins similar to those present on LAV virions. Experimental animals infected with these recombinant viruses elicited antibodies that specifically recognized LAV envelope proteins.     

Prisoner's dilemma in an RNA virus

The evolution of competitive interactions among viruses was studied in the RNA phage phi6 at high and low multiplicities of infection (that is, at high and low ratios of infecting phage to host cells). At high multiplicities, many phage infect and reproduce in the same host cell, whereas at low multiplicities the viruses reproduce mainly as clones. An unexpected result of this study was that phage grown at high rates of co-infection increased in fitness initially, but then evolved lowered fitness. Here we show that the fitness of the high-multiplicity phage relative to their ancestors generates a pay-off matrix conforming to the prisoner's dilemma strategy of game theory. In this strategy, defection (selfishness) evolves, despite the greater fitness pay-off that would result if all players were to cooperate. Viral cooperation and defection can be defined as, respectively, the manufacturing and sequestering of diffusible (shared) intracellular products. Because the low-multiplicity phage did not evolve lowered fitness, we attribute the evolution of selfishness to the lack of clonal structure and the mixing of unrelated genotypes at high multiplicity.     

病毒基因组中的对称性

病毒基因组中的重复序列比率很低,因为其核酸序列大都是编码区域.如果出现一段同向对称或者是反向对称序列在病毒基因组中,它往往代表一个调控元件,或者是一个信号因子.我们总结了病毒中的一些对称序列,并阐明它的特点,分布及功能.     

对虾白斑症病毒的初步研究

对虾白斑症病毒可通过人工投喂感染克氏螯虾,病和发展迅速,死亡率高。该病毒既可见在胞核中复制,也常见于胞质中装配。通过差速离心,蔗糖垫层离心或密度梯度离心后,再将分离物中细胞源核酸消化掉,可提取出较纯的病毒ＤＮＡ。     

现有病毒疫苗用于防治新冠肺炎的可行性分析

新冠肺炎的爆发严重危害人类健康和公共卫生安全,已引起全球范围内的高度关注。预防病毒性疾病最有效的措施是接种疫苗,但是目前还没有专门针对新型冠状病毒的疫苗。考虑到疫情的严重性,对同为RNA病毒的流感病毒、其他冠状病毒相关疫苗的研究进行了综述,并通过对这些病毒氨基酸水平的序列比对发现,新冠病毒的棘突糖蛋白与H1N1、H3N2、B型Victoria系和B型Yamagata系流感病毒的血凝素糖蛋白之间具有一定的相似性。由于血凝素糖蛋白是目前商用流感疫苗的主要作用靶点,因此推测,现有季节性商用流感疫苗在新冠肺炎的防控方面可能也具有一定的应用潜能。除此之外,由于新冠病毒与SARS冠状病毒的棘突糖蛋白和核蛋白之间均具有高度的相似性,而SARS冠状病毒疫苗又主要从上述两种蛋白研制而来,因此建议在短期内,可以将目前正在研制的SARS冠状病毒疫苗作为新冠病毒特效疫苗的替代物来使用。     

基于贝叶斯理论的未知病毒检测算法的实现

计算机病毒严重地危害了计算机世界的安全,如何有效地利用已知病毒的特征对未知病毒进行检测是一个非常重要的研究课题。对基于贝叶斯分类理论的未知病毒检测算法给予了系统设计和实现。实验结果表明,这种新的算法对未知病毒具有较高的分辨率。     

基于贝叶斯算法的未知病毒检测的研究

随着计算机技术的发展 ,计算机病毒也层出不穷 ,严重地危害了计算机世界的安全。当前的病毒检测技术对未知病毒还做不到事先检测。基于贝叶斯算法的未知病毒检测技术 ,对代码的特征提取、机器学习方法进行了研究和探讨 ,给出了未知病毒检测系统的基本框架 ,并给出了评估方法和实验结果。