Construction and verification of an infectious cDNA clone of coxsackievirus B5

Highlights:
· An infectious cDNA clone of CV-B5 was constructed.
· The rescued and parental virus possessed similar biological characteristics.
· The virulence of the rescued virus was similiar to that of the parental virus.
· Viral distribution and tissue tropism of those two viruses were in agreement.     

一株A型口蹄疫流行毒株全序列的测定及其全长感染性克隆的构建

【目的】测定一株A型口蹄疫流行毒株的全基因组序列,并构建其全长感染性克隆。【方法】参照已公布的A型口蹄疫病毒序列设计引物,将分离的口蹄疫病毒株A/Sea-97/CHA/2014全基因组分为4个重叠的片段进行RT-PCR扩增,并对其进行序列测定与分析。利用酶切连接法将4个基因片段依次克隆至p Blue Script SKhdv载体中,构建该流行毒株的全长c DNA克隆p QAHN。pQAHN经NotⅠ线性化后转染表达T7 RNA聚合酶的BSR/T7细胞,拯救病毒。【结果】口蹄疫病毒全基因组序列测定结果表明该毒株基因组全长8 171 bp[不包括poly(C)区段和poly(A)尾巴],开放阅读框为6 996 bp,编码2 332个氨基酸,5′和3′非编码区分别为1 091 bp和95 bp。VP1系统发生树分析表明该毒株与A/GDMM/CHA/2013毒株亲缘关系最近,相似性为99.1%。线化全长质粒转染BSR/T7细胞68 h后可观察到典型的细胞病变。拯救病毒的间接免疫荧光、RT-PCR和序列测定结果表明成功拯救出了具有感染性的FMDV。拯救病毒与亲本病毒的噬斑表型及生长曲线试验表明二者具有相似的生长表型和增殖能力。【结论】该研究为我国口蹄疫病原生态分布、分子流行病学调查以及A型FMD新型疫苗的研究提供了有益的材料。     

Construction of an infectious cDNA clone of Tembusu virus isolated from breeder Peking ducks

正Dear Editor,Since April 2010,an outbreak of a new disease has elicited symptoms of high fever,loss of appetite,and reduction in egg production in layer ducks in eastern China;this phenomenon has now spread throughout China(Cao et al.,2011;Su et al.,2011).The causative agent of the disease was identified as Tembusu virus(TMUV),which was classified into the genus Flavivirus,     

型内嵌合口蹄疫病毒全长感染性cDNA克隆的构建

【目的】近年来,O型口蹄疫的不断暴发严重危害了我国畜牧业的发展,其病原——O型口蹄疫病毒已演化出3种谱系:中国型猪毒系、泛亚系和缅甸98系。其中中国型猪毒系病毒高度嗜猪,对养猪业危害最大。目前应用的疫苗已不能有效保护中国型猪毒系变异株的流行,这给我国猪口蹄疫的防控带来了极大的困难。为了进一步发展免疫原性好、抗原谱广的猪O型口蹄疫疫苗候选株,本研究以O/HN/93现用疫苗毒株的感染性克隆为骨架,用流行的新猪毒系病毒的部分VP3和VP1基因(主要是替换VP1蛋白上的B-C环和G-H环)替换疫苗毒株的相应部分,构建了嵌合的FMDV全长cDNA克隆。【方法】线化的嵌合全长质粒和表达T7 RNA聚合酶的真核质粒pcDNAT7P共转染BHK-21细胞,体内转录拯救嵌合病毒。【结果】嵌合全长质粒转染BHK-21细胞36h后,出现明显的FMDV致细胞病变效应。对收获的病毒分别用RT-PCR、间接免疫荧光、电子显微镜观察结果证实成功拯救到嵌合的FMDV。拯救的病毒乳鼠致病性试验结果表明该拯救病毒对乳鼠的致病力减弱。该嵌合病毒的成功拯救为研制口蹄疫新型疫苗等奠定了基础。     

Sesbania mosaic virus (SeMV) infectious clone: possible mechanism of 3' and 5' end repair and role of polyprotein processing in viral replication

Sesbania mosaic virus (SeMV) is a positive stranded RNA virus belonging to the genus Sobemovirus. Construction of an infectious clone is an essential step for deciphering the virus gene functions in vivo. Using Agrobacterium based transient expression system we show that SeMV icDNA is infectious on Sesbania grandiflora and Cyamopsis tetragonoloba plants. The efficiency of icDNA infection was found to be significantly high on Cyamopsis plants when compared to that on Sesbania grandiflora. The coat protein could be detected within 6 days post infiltration in the infiltrated leaves. Different species of viral RNA (double stranded and single stranded genomic and subgenomic RNA) could be detected upon northern analysis, suggesting that complete replication had taken place. Based on the analysis of the sequences at the genomic termini of progeny RNA from SeMV icDNA infiltrated leaves and those of its 3' and 5' terminal deletion mutants, we propose a possible mechanism for 3' and 5' end repair in vivo. Mutation of the cleavage sites in the polyproteins encoded by ORF 2 resulted in complete loss of infection by the icDNA, suggesting the importance of correct polyprotein processing at all the four cleavage sites for viral replication. Complementation analysis suggested that ORF 2 gene products can act in trans. However, the trans acting ability of ORF 2 gene products was abolished upon deletion of the N-terminal hydrophobic domain of polyprotein 2a and 2ab, suggesting that these products necessarily function at the replication site, where they are anchored to membranes.     

Construction of an infectious clone of canine herpesvirus genome as a bacterial artificial chromosome

Canine herpesvirus (CHV) is an attractive candidate not only for use as a recombinant vaccine to protect dogs from a variety of canine pathogens but also as a viral vector for gene therapy in domestic animals. However, developments in this area have been impeded by the complicated techniques used for eukaryotic homologous recombination. To overcome these problems, we used bacterial artificial chromosomes (BACs) to generate infectious BACs. Our findings may be summarized as follows: (i) the CHV genome (pCHV/BAC), in which a BAC flanked by loxP sites was inserted into the thymidine kinase gene, was maintained in Escherichia coli; (ii) transfection of pCHV/BAC into A-72 cells resulted in the production of infectious virus; (iii) the BAC vector sequence was almost perfectly excisable from the genome of the reconstituted virus CHV/BAC by co-infection with CHV/BAC and a recombinant adenovirus that expressed the Cre recombinase; and (iv) a recombinant virus in which the glycoprotein C gene was deleted was generated by lambda recombination followed by Flp recombination, which resulted in a reduction in viral titer compared with that of the wild-type virus. The infectious clone pCHV/BAC is useful for the modification of the CHV genome using bacterial genetics, and CHV/BAC should have multiple applications in the rapid generation of genetically engineered CHV recombinants and the development of CHV vectors for vaccination and gene therapy in domestic animals.     

狂犬病病毒CVS-11株全序列测定及其感染性克隆的构建

[目的]测定狂犬病病毒标准攻击毒CVS-11株全基因组序列,构建CVS-11株全长cDNA感染性克隆.[方法]RT-PCR扩增CVS-11株全基因组得到有重叠的12个片段,分别克隆至平端载体pEASY-Blunt,测定CVS-11株全基因组核苷酸序列.用软件DNAMAN分析CVS-11全序列单一性酶切位点,设计引物,分4段扩增CVS-11全基因组,扩增产物经多步酶切、连接逐步插入至真核表达载体pcDNA3.1,获得全长质粒pcDNA3.1-CVS-11.pcDNA3.1-CVS-11与其辅助质粒pcDNA3.1-N、P、L、G共转染NA细胞,经免疫荧光染色、RT-PCR鉴定,拯救得到重组病毒rCVS-11.[结果]CVS-11全基因组序列由11 927个核苷酸组成,编码5个结构蛋白,结构基因排列同已知的其他狂犬病病毒一致.成功构建了CVS-11全长cDNA重组质粒pcDNA3.1-CVS-11和其辅助质粒pcDNA3.1-N、P、L和G.经共转染,成功拯救了重组病毒rCVS-11.[结论]CVS-11株感染性克隆的构建为从分子水平上进一步研究狂犬病病毒奠定了基础.     

Characterization of a cDNA clone encoding a new species of the nonspecific cross-reacting antigen (NCA), a member of the CEA gene family

To clarify the molecular structures of the nonspecific cross-reacting antigens (NCAs) produced by human granulocytes, we cloned cDNAs from libraries of normal white blood cells. A clone, NCA-W272, was found to code a protein similar to NCA of tumor cells. The protein consisted of a signal peptide (34 aa), domain-N (108 aa), -A1 (92 aa), -B1 (86 aa) and -M (29 aa). Similarity of the amino acid sequence of each domain to that of the tumor NCA was 72, 92, 76 and 79%, respectively. COS-1 cells transfected with an expression vector carrying the cDNA synthesized a 70 kDa glycoprotein, which was reactive with anti-NCA antibody and released from cell surface by phosphatidylinositol-specific phospholipase C. Thus the clone NCA-W272 was indicated to encode a new species of NCA distinct from the tumor NCA.     

Identification of a novel sequence at the 3' end of the GB virus B genome

GB virus B (GBV-B) is a virus of the family Flaviviridae that infects small primates (Saguinus sp. [tamarins]) and shows similarities to hepatitis C virus (HCV) in genome organization, protein function, tissue tropism, and pathogenicity. This suggests the possibility of using tamarins infected by GBV-B or GBV-B/HCV chimeric viruses as a surrogate animal model of HCV infection. To achieve the construction of such chimeric viruses, it is essential to produce a complete and infectious GBV-B genomic RNA. We have identified a novel sequence at the 3' end of the GBV-B genome and show that it can be arranged in a secondary structure resembling that of the 3' end of the HCV genome, which is known to be essential for infectivity.     

RNA helicase p68 (DDX5) regulates tau exon 10 splicing by modulating a stem-loop structure at the 5' splice site

Regulation of tau exon 10 splicing plays an important role in tauopathy. One of the cis elements regulating tau alternative splicing is a stem-loop structure at the 5' splice site of tau exon 10. The RNA helicase(s) modulating this stem-loop structure was unknown. We searched for splicing regulators interacting with this stem-loop region using an RNA affinity pulldown-coupled mass spectrometry approach and identified DDX5/RNA helicase p68 as an activator of tau exon 10 splicing. The activity of p68 in stimulating tau exon 10 inclusion is dependent on RBM4, an intronic splicing activator. RNase H cleavage and U1 protection assays suggest that p68 promotes conformational change of the stem-loop structure, thereby increasing the access of U1snRNP to the 5' splice site of tau exon 10. This study reports the first RNA helicase interacting with a stem-loop structure at the splice site and regulating alternative splicing in a helicase-dependent manner. Our work uncovers a previously unknown function of p68 in regulating tau exon 10 splicing. Furthermore, our experiments reveal functional interaction between two splicing activators for tau exon 10, p68 binding at the stem-loop region and RBM4 interacting with the intronic splicing enhancer region.     

The secondary structure of the 5' end of the FIV genome reveals a long-range interaction between R/U5 and gag sequences, and a large, stable stem-loop

Feline immunodeficiency virus (FIV) is a lentivirus that infects cats and is related to human immunodeficiency virus (HIV). Although it is a common worldwide infection, and has potential uses as a human gene therapy vector and as a nonprimate model for HIV infection, little detail is known of the viral life cycle. Previous experiments have shown that its packaging signal includes two or more regions within the first 511 nucleotides of the genomic RNA. We have undertaken a secondary structural analysis of this RNA by minimal free-energy structural prediction, biochemical mapping, and phylogenetic analysis, and show that it contains five conserved stem–loops and a conserved long-range interaction between heptanucleotide sequences 5′-CCCUGUC-3′ in R/U5 and 5′-GACAGGG-3′ in gag. This long-range interaction is similar to that seen in primate lentiviruses where it is thought to be functionally important. Along with strains that infect domestic cats, this heptanucleotide interaction can also occur in species-specific FIV strains that infect pumas, lions, and Pallas' cats where the heptanucleotide sequences involved vary. We have analyzed spliced and genomic FIV RNAs and see little structural change or sequence conservation within single-stranded regions of the 5′ UTR that are important for viral packaging, suggesting that FIV may employ a cotranslational packaging mechanism.     

Sequence analysis of a KpnI family member near the 3' end of human beta-globin gene.

We determined the complete nucleotide sequence (6125 bp) of a full-length member of human KpnI family, designated T beta G41, which is located about 3 kb downstream from the beta-globin gene. Comparison of the sequence with the KpnI family sequence compiled by Singer revealed that a new 131 bp sequence is present in the T beta G41. Hybridization analyses showed that a few thousand of human KpnI family members are carrying this additional sequence. Computer search of DNA databases for T beta G41-homologous sequence showed that some T beta G41-homologous sequences were closely associated with pseudogenes. The T beta G41 sequence also showed significant sequence homology with ChBlym-1, a transferrin-like transforming gene of chicken. Furthermore, an amino acid sequence deduced from the T beta G41 nucleotide sequence revealed a relatively-high homology to those of human transferrin and lactotransferrin.     

In vitro synthesis of minus-strand RNA by an isolated cereal yellow dwarf virus RNA-dependent RNA polymerase requires VPg and a stem-loop structure at the 3' end of the virus RNA

Cereal yellow dwarf virus (CYDV) RNA has a 5'-terminal genome-linked protein (VPg). We have expressed the VPg region of the CYDV genome in bacteria and used the purified protein (bVPg) to raise an antiserum which was able to detect free VPg in extracts of CYDV-infected oat plants. A template-dependent RNA-dependent RNA polymerase (RdRp) has been produced from a CYDV membrane-bound RNA polymerase by treatment with BAL 31 nuclease. The RdRp was template specific, being able to utilize templates from CYDV plus- and minus-strand RNAs but not those of three unrelated viruses, Red clover necrotic mosaic virus, Cucumber mosaic virus, and Tobacco mosaic virus. RNA synthesis catalyzed by the RdRp required a 3'-terminal GU sequence and the presence of bVPg. Additionally, synthesis of minus-strand RNA on a plus-strand RNA template required the presence of a putative stem-loop structure near the 3' terminus of CYDV RNA. The base-paired stem, a single-nucleotide (A) bulge in the stem, and the sequence of a tetraloop were all required for the template activity. Evidence was produced showing that minus-strand synthesis in vitro was initiated by priming by bVPg at the 3' end of the template. The data are consistent with a model in which the RdRp binds to the stem-loop structure which positions the active site to recognize the 3'-terminal GU sequence for initiation of RNA synthesis by the addition of an A residue to VPg.     

Alphavirus RNA genome repair and evolution: molecular characterization of infectious sindbis virus isolates lacking a known conserved motif at the 3' end of the genome

The 3' nontranslated region of the genomes of Sindbis virus (SIN) and other alphaviruses carries several repeat sequence elements (RSEs) as well as a 19-nucleotide (nt) conserved sequence element (3'CSE). The 3'CSE and the adjoining poly(A) tail of the SIN genome are thought to act as viral promoters for negative-sense RNA synthesis and genome replication. Eight different SIN isolates that carry altered 3'CSEs were studied in detail to evaluate the role of the 3'CSE in genome replication. The salient findings of this study as it applies to SIN infection of BHK cells are as follows: i) the classical 19-nt 3'CSE of the SIN genome is not essential for genome replication, long-term stability, or packaging; ii) compensatory amino acid or nucleotide changes within the SIN genomes are not required to counteract base changes in the 3' terminal motifs of the SIN genome; iii) the 5' 1-kb regions of all SIN genomes, regardless of the differences in 3' terminal motifs, do not undergo any base changes even after 18 passages; iv) although extensive addition of AU-rich motifs occurs in the SIN genomes carrying defective 3'CSE, these are not essential for genome viability or function; and v) the newly added AU-rich motifs are composed predominantly of RSEs. These findings are consistent with the idea that the 3' terminal AU-rich motifs of the SIN genomes do not bind directly to the viral polymerase and that cellular proteins with broad AU-rich binding specificity may mediate this interaction. In addition to the classical 3'CSE, other RNA motifs located elsewhere in the SIN genome must play a major role in template selection by the SIN RNA polymerase.     

口蹄疫病毒O/QYYS/s/06株感染性克隆的构建

本研究在完成FMDVO/QYYS/s/06株全基因组序列测定的基础上,分3段对全基因组进行克隆,其后将各片段克隆到载体P43中,从而获得携带O/QYYS/s/06株基因组全长cDNA的重组质粒P43C。将重组质粒P43C与表达RNA聚合酶的质粒T7共转染BHK-21细胞,48h后收获培养液接种2~3d乳鼠,取经乳鼠传代后的第4代病毒液,经反向间接血凝、中和试验和测序等方法证明拯救的病毒为O型FMDV。以上结果表明,O/QYYS/s/06株全长cDNA分子克隆的构建成功。     

BHK cell proteins that bind to the 3' stem-loop structure of the West Nile virus genome RNA.

The first 83 3' nucleotides of the genome RNA of the flavivirus West Nile encephalitis virus (WNV) form a stable stem-loop (SL) structure which is followed in the genome by a smaller SL. These 3' structures are highly conserved among divergent flaviviruses, suggesting that they may function as cis-acting signals for RNA replication and as such might specifically bind to cellular or viral proteins. Cellular proteins from uninfected and WNV-infected BHK-21 S100 cytoplasmic extracts formed three distinct complexes with the WNV plus-strand 3' SL [(+)3'SL] RNA in a gel mobility shift assay. Subsequent competitor gel shift analyses showed that two of these RNA-protein complexes, complexes 1 and 2, contained cell proteins that specifically bound to the WNV (+)3'SL RNA. UV-induced cross-linking and Northwestern blotting analyses detected WNV (+)3'SL RNA-binding proteins of 56, 84, and 105 kDa. When the S100 cytoplasmic extracts were partially purified by ion-exchange chromatography, a complex that comigrated with complex 1 was detected in fraction 19, while a complex that comigrated with complex 2 was detected in fraction 17. UV-induced cross-linking experiments indicated that an 84-kDa cell protein in fraction 17 and a 105-kDa protein in fraction 19 bound specifically to the WNV (+)3'SL RNA. In addition to binding to the (+)3'SL RNA, the 105-kDa protein bound to the SL structure located at the 3' end of the WNV minus-strand RNA. Initial mapping studies indicated that the 84- and 105-kDa proteins bind to different regions of the (+)3'SL RNA. The 3'-terminal SL RNA of another flavivirus, dengue virus type 3, specifically competed with the WNV (+)3'SL RNA in gel shift assays, suggesting that the host proteins identified in this study are flavivirus specific.