Bioinformatical study on the proteomics and evolution of SARS-CoV

A novel coronavirus has been identified as the causative agent of the severe acute respiratory syndrome (SARS). For all the SARS-CoV associated proteins derivated from the SARS-CoV genome, the physiochemical properties such as the molecular weight, isoelectric point and extinction coefficient of each protein were calculated. The transmembrane segments and subeellular localization (SubLoeation) prediction and conserved protein motifs search against database were employed to analyze the function of SARS-CoV proteins. Also, the homology protein sequence alignment and evolutionary distance matrix calculation between SARS-CoV associated proteins and the corresponding proteins of other coronaviruses were employed to identify the classification and phylogenetic relationship between SARS-CoV and other coronaviruses. The results showed that SARS-CoV is a novel coronavirus which is different from any of the three previously known groups of coronviruses, but it is closer to BoCoV and MHV than to other coronaviruses. This study is in aid of experimental determination of SARS-CoV proteomics and the development of antiviral vaccine.     

传染性非典型肺炎病毒核蛋白的表达与活性检测

用PCR方法，人工合成传染性非典型肺炎病毒(SARS-CoV)核蛋白(N)全编码基因，并构建原核表达载体．在大肠杆菌中进行表达．结果重组N蛋白表达产量占菌体总蛋白的40％以上，主要以可溶形式存在．用SARS患者急性期血清进行蛋白印迹检测，表明可溶形式和包含体形式均有明显活性．包含体形式的重组蛋白经纯化后纯度可达90％以上，活性与纯化前相当，可作为SARS抗体诊断试剂盒的抗原原料．     

Angiotensin-converting enzyme 2 is a functional receptor for the SARS coronavirus

Spike (S) proteins of coronaviruses, including the coronavirus that causes severe acute respiratory syndrome (SARS), associate with cellular receptors to mediate infection of their target cells. Here we identify a metallopeptidase, angiotensin-converting enzyme 2 (ACE2), isolated from SARS coronavirus (SARS-CoV)-permissive Vero E6 cells, that efficiently binds the S1 domain of the SARS-CoV S protein. We found that a soluble form of ACE2, but not of the related enzyme ACE1, blocked association of the S1 domain with Vero E6 cells. 293T cells transfected with ACE2, but not those transfected with human immunodeficiency virus-1 receptors, formed multinucleated syncytia with cells expressing S protein. Furthermore, SARS-CoV replicated efficiently on ACE2-transfected but not mock-transfected 293T cells. Finally, anti-ACE2 but not anti-ACE1 antibody blocked viral replication on Vero E6 cells. Together our data indicate that ACE2 is a functional receptor for SARS-CoV.     

SARS的研究进展

2003年3月,发现SARS病原是一种从未在人类或动物中发现过的新的冠状病毒.其基因组结构与其他的冠状病毒相似,由29727核苷酸组成,有11个开放阅读框.通过多基因分析序列比较说明,SARS冠状病毒与已知的冠状病毒无关.针对SARS冠状病毒的各种特征及研究进展进行了综述.     

SARS-CoVS基因表达及纯化

严重急性呼吸道综合症是由一种新的冠状病毒SARS-CoY引起的．作者通过PCR扩增得到了S蛋白的6个编码片段，并利用表达载体pET28a( )在E．coli BL21中进行了原核表达．通过亲和层析纯化了包含大部分ACE2结合区域的S蛋白片段(S4)．ELISA分析结果表明S4与SARS病人恢复期血清具有良好的反应能力．     

SARS相关冠状病毒刺突糖蛋白的研究(综述)

概述了SARS—CoV的S蛋白的结构及功能相关研究。严重急性呼吸综合症相关的冠状病毒(SARS-CoV)引起2003年我国南方非典型肺炎爆发流行，波及多个国家和地区。目前全球许多学对SARS-CoV进行了广泛的研究，发现S蛋白是病毒表面的主要蛋白，它构成冠状病毒科特征性的冠状样结构，在严重急性呼吸综合症的发病机制起着关键性作用，可介导表达相关受体的宿主细胞感染。现已鉴定出SARS-CoV的S蛋白相关受体，同时它在抗病毒感染中是一个关键靶蛋白。     

SARS冠状病毒核衣壳蛋白基因的表达及其在SARS诊断中的应用

目的为SARS感染后建立一种特异性免疫学诊断方法,为基因疫苗的研制提供备选实验材料.方法利用基因重组的方法,在大肠杆菌中表达了SARS冠状病毒(SARS-CoV)N蛋白全长基因,经包涵体的初步纯化,金属螯合层析进一步纯化N蛋白,SDS-PAGE电泳和ELISA方法进行结果检测.结果N蛋白抗原与30名SARS感染患者血清结合全部为阳性,对照组30名正常人血清为阴性,30名发热但非SARS患者血清为阴性.结论利用基因重组的方法对SARS-CoV N蛋白进行了表达和纯化,证明该重组N蛋白抗原具有良好的反应特异性,是良好的应用于病毒感染早期诊断的抗原.完全可用于组构检测核心抗体的诊断试剂.并建立了免疫学的检测方法,为抗体检测提供了安全、方便的手段,并为基因工程疫苗研究奠定了基础.     

Dissection of SARS Coronavirus Spike Protein into Discrete Folded Fragments

Introduction Severe acute respiratory syndrome coronavirus (SARS-CoV), which is the causative agent of the atypical pneumonia, was first identified in the fall of 2002 to be a previously unknown member of the family of coronaviruses[1]. The rapid transmis…     

HLA-A2 molecules in an antigen-processing mutant cell contain signal sequence-derived peptides.

The mutant human cell line T2 is defective in antigen presentation in the context of class I major histocompatibility complex (MHC) molecules, and also in that transfected T2 cells show poor surface expression of exogenous human class I (HLA) alleles. Both defects are thought to lie in the transport of antigenic peptides derived from cytosolic proteins into the endoplasmic reticulum (ER), as peptide-deficient class I molecules might be expected to be either unstable or retained in the ER. The products of several mouse class I (H-2) genes, and the endogenous gene HLA-A2 do, however, reach the surface of T2 cells at reasonable levels although they are non-functional. We report here that, as expected, poorly surface-expressed HLA molecules do not significantly bind endogenous peptides. Surprisingly, H-2 molecules expressed in T2 also lack associated peptides, arguing that 'empty' complexes of mouse class I glycoproteins with human beta 2-microglobulin are neither retained in the ER nor unstable. HLA-A2 molecules, however, do bind high levels of a limited set of endogenous peptides. We have sequenced three of these peptides and find that two, a 9-mer and an 11-mer, are derived from a putative signal sequence (of IP-30, an interferon-gamma-inducible protein), whereas a third, a 13-mer, is of unknown origin. The unusual length of two of the peptides argues that the 9-mers normally associated with HLA-A2 molecules may be generated before their transport from the cytosol rather than in a pre-Golgi compartment. To our knowledge, this is the first report of the isolation of a fragment of a eukaryotic signal peptide generated in vivo.     

Molecular characterization of H1N1 influenza A viruses from human cases in North America

Subtypes of H1N1 influenza virus can be found in humans in North America, while they are also associated with the infection of swine. Characterization of the genotypes of viral strains in human populations is important to understand the source and distribution of viral strains. Genomic and protein sequences of 10 isolates of the 2009 outbreak of influenza A （H1N1） virus in North America were obtained from GenBank database. To characterize the genotypes of these viruses, phylogenetic trees of genes PB2, PB1, PA, HA, NP, NA, NS and M were constructed by Phylip3.67 program and N-Linked glycosylation sites of HA, NA, PB2, NS1 and M2 proteins were analyzed online by NetNGlyc1.0 program. Phylogenetic analysis indicated that these isolates are virtually identical but may be recombinant viruses because their genomic fragments come from different viruses. The isolates also contain a characteristic lowly pathogenic amino acid motif at their HA cleavage sites （IPSIQSR↓GL）, and an E residue at position 627 of the PB2 protein which shows its high affinity to humans. The homologous model of M proteins showed that the viruses had obtained the ability of anti-amantadine due to the mutation at the drug-sensitive site, while sequence analysis of NA proteins indicated that the viruses are still susceptible to the neuraminidase inhibitor drug （i.e. oseltamivir and zanamivir） because no mutations have been observed. Our results strongly suggested that the viruses responsible for the 2009 outbreaks of influenza A （H1N1） virus have the ability to cross species barriers to infect human and mammalian animals based on molecular analysis. These findings may further facilitate the therapy and prevention of possible transmission from North America to other countries.     

Molecular phylogeny of coronaviruses including human SARS-CoV

The outbreak of SARS sets an urgent task to reveal the origin of human SARS-CoV, i.e. its relation to other known species of coronavirus, and to trace the genetic variation in the spreading process of SARS. Partial answer to the problem may be obtained from phylogenetic analy-sis of available genomes. We call a phylogenetic tree of different species of coronavirus including the human SARS-Cov a CoV Tree and that of different isolates of SARS-CoV a SARS Tree. CoV trees have been c…     

A Coordination Model of Gene Sequences for SARS-CoV and its Receptor

IntroductionFrom the emergence of SARS CoV, manystudies havebeen done on its biological medicine aspects, such aspathogeny characteristics, mechanisms of causing disease,clinic diagnosis and treatment, bacterin development andthe spreading rules. At the level of molecule biology,studies have been done on its genome sequences characteristics, structures and functions of the translatedproteins, and the evolution relationships in sequences[1 5].The caus…     

Genome evolution of novel influenza A （H1N1 ） viruses in humans

The epidemic situation of A H1N1 flu arose in North America in April 2009, which rapidly expanded to three continents of Europe, Asia and Africa, with the risk ranking up to 5. Until May 13th, the flu virus of A H1N1 had spread into 33 countries and regions, with a laboratory confirmed case number of 5728, including 61 deaths. Based on IRV and EpiFluDB database, 425 parts of A H1N1 flu virus sequence were achieved, followed by sequenced comparison and evolution analysis. The results showed that the current predominant A H1N1 flu virus was a kind of triple reassortment A flu virus： （i） HA, NA, MP, NP and NS originated from swine influenza virus; PB2 and PA originated from bird influenza virus; PB1 originated from human influenza virus. （ii） The origin of swine influenza virus could be subdivided as follows： HA, NP and NS originated from classic swine influenza virus of H1N1 subtype; NA and MP originated from bird origin swine influenza virus of H1N1 subtype. （iii） A H1N1 flu virus experienced no significant mutation during the epidemic spread, accompanied with no reassortment of the virus genome. In the paper, the region of the representative strains for sequence analysis （A/California/04/2009 （H1N1） and A/Mexico/4486/2009 （H1N1）） included USA and Mexico and was relatively wide, which suggested that the analysis results were convincing.     

Protein Subcellular Localization Prediction and Genomic Polymorphism Analysis of the SARS Coronavirus

Introduction In March 2003, a novel coronavirus (CoV) was dis-covered in association with the outbreak of severe acute respiratory syndrome (SARS)[1-3]. The complete genome sequence of several SARS-CoV isolates was soon determined and characterized[4,5]. Comparison of variant SARS-CoV genome sequences has identified certain genetic signatures that can be used to trace sources of infection[6]. Vaccines are now being devel-oped and molecular modeling has suggested that modi-fied rhinovir…     

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).     

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…     

基于位点特异性打分矩阵的卷积神经网络预测SARS-CoV-2核衣壳蛋白的蛋白质二级结构

新型冠状病毒(SARS-CoV-2)有4种关键的结构蛋白,而核衣壳蛋白就是其中的1种.本实验从公开数据库NCBI上选取的SARS-CoV-2核衣壳蛋白质序列数据,分析SARS-CoV-2核衣壳蛋白与SARS-CoV核衣壳蛋白的序列相似性,对SARS-CoV-2核衣壳蛋白的理化性质和疏水性进行分析;在此基础上提出基于位点...     

Prediction of a common neutralizing epitope of H5N1 avian influenza virus by in silico molecular docking

The H5N1 avian influenza virus （AIV） has widely spread in Asia, Europe and Africa, making a large amount of economic loss. Recently, our research group has screened a common neutralizing mono-clonal antibody named 8H5, which can neutralize almost all H5 subtype AIV ever isolated so far. Obviously, this monoclonal antibody would benefit for research and development of the universal AIV vac-cine and design of the drug against H5N1 AIV in high mutation rate. In this study, the homology modeling was applied to generate the 3D structure of 8H5 Fab fragment, and ＂canonical structure＂ method was used to define the specified loop conformation of CDR regions. The model was subjected to energy minimization in cvff force field with Discovery module in Insight II program. The resulting model has correct stereochemistry as gauged from the Ramachandran plot calculation and good 3D-structure compatibility as assessed by interaction energy analysis, solvent accessible surface （SAS） analysis, and Profiles-3D approach. Furthermore, the 8H5 Fab model was subjected to docking with three H5 subtype hemagglutinin （HA） structures deposited in PDB （ID No： ljsm, 2ibx and 2fk0） respectively. The result indicates that the three docked complexes share a common binding interface, but differ in binding angle related with HA structure similarity between viral subtypes. In the light of the three HA inter-faces with structural homology analysis, the common neutralizing epitope on HA recognized by 8H5 consists of 9 incontinuous amino acid residues： Asp^58, Asn^72, Glu^112, Lys^113, lie^114, Pro^118, Ser^120, Tyr^137, Tyr^252 （numbered as for ljsm sequence）. The primary purpose of the present work is to provide some insight into structure and binding details of a common neutralizing epitope of H5N1 AIV, thereby aiding in the structure-based design of universal AIV vaccines and anti-virus therapeutic drugs.     

SARS冠状病毒的诊断性实验研究

严重急性呼吸综合征(SARS)是一种新的人类感染性疾病，其致病菌为SARS冠状病毒(SARS-CoV)。本文就SARS-CoV发现过程、病毒特点及检测方法的研究进展和应用情况加以概述。     

Stability study of saturated red polymer light-emitting diodes

Saturated red polymer light-emitting diodes have been fabricated with a single emitting polymer blend layer of poly[2-(2-ethylhexyloxy)-5-methoxy-1,4-phenylenevinylene] (MEH-PPV) and poly[9,9-dioc- tylfluorene-co-4,7-di-2-thienyl-2,1,3-benzothiadiazole] (PFO-DBT15). Saturated red emission with the Commission Internationale de l’Eclairage (CIE) coordinates of (0.67, 0.33) was obtained. The device stability was investigated. The results showed that energy transfer occurred from MEH-PPV to PFO-DBT15, and MEH-PPV improved the hole injection and transportation.