cis-acting sequences required for coronavirus infectious bronchitis virus defective-RNA replication and packaging

The parts of the RNA genome of infectious bronchitis virus (IBV) required for replication and packaging of the RNA were investigated using deletion mutagenesis of a defective RNA (D-RNA) CD-61 (6.1 kb) containing a chloramphenicol acetyltransferase reporter gene. A D-RNA with the first 544, but not as few as 338, nucleotides (nt) of the 5' terminus was replicated; the 5' untranslated region (UTR) comprises 528 nt. Region I of the 3' UTR, adjacent to the nucleocapsid protein gene, comprised 212 nt and could be removed without impairment of replication or packaging of D-RNAs. A D-RNA with the final 338 nt, including the 293 nt in the highly conserved region II of the 3' UTR, was replicated. Thus, the 5'-terminal 544 nt and 3'-terminal 338 nt contained the necessary signals for RNA replication. Phylogenetic analysis of 19 strains of IBV and 3 strains of turkey coronavirus predicted a conserved stem-loop structure at the 5' end of region II of the 3' UTR. Removal of the predicted stem-loop structure abolished replication of the D-RNAs. D-RNAs in which replicase gene 1b-derived sequences had been removed or replaced with all the downstream genes were replicated well but were rescued poorly, suggesting inefficient packaging. However, no specific part of the 1b gene was required for efficient packaging.     

A 100-kilodalton polypeptide encoded by open reading frame (ORF) 1b of the coronavirus infectious bronchitis virus is processed by ORF 1a products.

The genome-length mRNA (mRNA 1) of the coronavirus infectious bronchitis virus (IBV) contains two large open reading frames (ORFs), 1a and 1b, with the potential to encode polypeptides of 441 and 300 kDa, respectively. The downstream ORF, ORF 1b, is expressed by a ribosomal frameshifting mechanism. In an effort to detect viral polypeptides encoded by ORF 1b in virus-infected cells, immunoprecipitations were carried out with a panel of region-specific antisera. A polypeptide of approximately 100 kDa was precipitated from IBV-infected, but not mock-infected, Vero cells by one of these antisera (V58). Antiserum V58 was raised against a bacterially expressed fusion protein containing polypeptide sequences encoded by ORF 1b nucleotides 14492 to 15520; it recognizes specifically the corresponding in vitro-synthesized target protein. A polypeptide comigrating with the 100,000-molecular-weight protein (100K protein) identified in infected cells was also detected when the IBV sequence from nucleotides 8693 to 16980 was expressed in Vero cells by using a vaccinia virus-T7 expression system. Deletion analysis revealed that the sequence encoding the C terminus of the 100K polypeptide lies close to nucleotide 15120; it may therefore be generated by proteolysis at a potential QS cleavage site encoded by nucleotides 15129 to 15135. In contrast, expression of IBV sequences from nucleotides 10752 to 16980 generated two polypeptides of approximately 62 and 235 kDa, which represent the ORF 1a stop product and the 1a-1b fused product generated by a frameshifting mechanism, respectively, but no processed products were observed. Since the putative picornavirus 3C-like proteinase domain is located in ORF 1a between nucleotides 8937 and 9357, this observation suggests that deletion of the picornavirus 3C-like proteinase domain and surrounding regions abolishes processing of the 1b polyprotein. In addition, the in vitro translation and in vivo transfection studies also indicate that the ORF 1a region between nucleotides 8763 and 10720 contains elements that down-regulate the expression of ORF 1b.     

Fine mapping of a cis-acting sequence element in yellow fever virus RNA that is required for RNA replication and cyclization

We present fine mapping of a cis-acting nucleotide sequence found in the 5' region of yellow fever virus genomic RNA that is required for RNA replication. There is evidence that this sequence interacts with a complementary sequence in the 3' region of the genome to cyclize the RNA. Replicons were constructed that had various deletions in the 5' region encoding the capsid protein and were tested for their ability to replicate. We found that a sequence of 18 nucleotides (residues 146 to 163 of the yellow fever virus genome, which encode amino acids 9 to 14 of the capsid protein) is essential for replication of the yellow fever virus replicon and that a slightly longer sequence of 21 nucleotides (residues 146 to 166, encoding amino acids 9 to 15) is required for full replication. This region is larger than the core sequence of 8 nucleotides conserved among all mosquito-borne flaviviruses and contains instead the entire sequence previously proposed to be involved in cyclization of yellow fever virus RNA.     

传染性支气管炎病毒核衣壳蛋白基因克隆及在E.coli中的表达

核衣壳蛋白基因 (N基因 )是传染性支气管炎病毒的重要结构基因 .根据已报道的序列设计引物 ,利用RT PCR技术从病毒RNA中扩增和克隆到了N基因的cDNA ,并测定了核苷酸序列 .克隆的N基因片段ORF全长 12 30bp ,编码 4 0 9个氨基酸 .将该片段序列与其他IBV病毒株比较 ,核苷酸的同一性为 87 0 %～ 98 6 %,氨基酸的同一性为 91 0 %～ 98 1%.将该cDNA亚克隆到pBV2 2 0表达载体 ,转化大肠杆菌DH5α菌株 ,Western印迹检测 ,获得了分子量约 4 5kD表达蛋白     

Eukaryotic coupled translation of tandem cistrons: identification of the influenza B virus BM2 polypeptide.

Previous nucleotide sequence analysis of RNA segment 7 of influenza B virus indicated that, in addition to the reading frame encoding the 248 amino acid M1 protein, there is a second overlapping reading frame (BM2ORF) of 585 nucleotides that has the coding capacity for 195 amino acids. To search for a polypeptide product derived from BM2ORF, a genetically engineered beta-galactosidase-BM2ORF fusion protein was expressed in Escherichia coli and a polyclonal rabbit antiserum was raised to the purified fusion protein. This antiserum was used to identify a polypeptide, designated BM2 protein (Mr approximately equal to 12,000), that is synthesized in influenza B virus-infected cells. To understand the mechanism by which the BM2 protein is generated from influenza B virus RNA segment 7, a mutational analysis of the cloned DNA was performed and the altered DNAs were expressed in eukaryotic cells. The expression patterns of the M1 and BM2 proteins from the altered DNAs indicate that the BM2 protein initiation codon overlaps with the termination codon of the M1 protein in an overlapping translational stop-start pentanucleotide, TAATG, and that the expression of the BM2 protein requires 5'-adjacent termination of M1 synthesis. Our data suggest that a termination-reinitiation scheme is used in translation of a bicistronic mRNA derived from influenza B virus RNA segment 7, and this strategy has some analogy to prokaryotic coupled stop-start translation of tandem cistrons.     

Trypsin cleavage in the COOH terminus of the bacteriophage T4 gene 41 DNA helicase alters the primase-helicase activities of the T4 replication complex in vitro

The bacteriophage T4 gene 41 protein is a 5' to 3' DNA helicase which unwinds DNA ahead of the growing replication fork and, together with the T4 gene 61 protein, also functions as a primase to initiate DNA synthesis on the lagging strand. Proteolytic cleavage by trypsin approximately 20 amino acids from the COOH terminus of the 41 protein produces 41T, a 51,500-dalton fragment (possibly still associated with small COOH-terminal fragments) which still retains the ssDNA-stimulated GTPase (ATPase) activity, the 61 protein-stimulated DNA helicase activity, and the ability to act with 61 protein to synthesize pentaribonucleotide primers. In the absence of the T4 gene 32 ssDNA binding protein, the primase-helicase composed of the tryptic fragment (41T) and 61 proteins efficiently primes DNA synthesis on circular ssDNA templates by the T4 DNA polymerase and the three T4 polymerase accessory proteins. In contrast, the 41T protein is defective as a helicase or a primase component on 32 protein-covered DNA. Thus, unlike the intact protein, 41T does not support RNA-dependent DNA synthesis on 32 protein-covered ssDNA and does not stimulate strand displacement DNA synthesis on a nicked duplex DNA template. High concentrations of 32 protein strongly inhibit RNA primer synthesis with either 41 T or intact 41 protein. The 44/62 and 45 polymerase accessory proteins (and even the 44/62 proteins to some extent) substantially reverse the 32 protein inhibition of RNA primer synthesis with intact 41 protein but not with 41T protein. We propose that the COOH-terminal region of the 41 protein is required for its interaction with the T4 polymerase accessory proteins, permitting the synthesis and utilization of RNA primers and helicase function within the T4 replication complex. When this region is altered, as in 41T protein, the protein is unable to assemble a functional primase-helicase in the replication complex. An easy and rapid purification of T4 41 protein produced by a plasmid encoding this gene (Hinton, D. M., Silver, L. L., and Nossal, N. G. (1985) J. Biol. Chem. 260, 12851-12857) is also described.     

Proteolytic processing of the coronavirus infectious bronchitis virus 1a polyprotein: identification of a 10-kilodalton polypeptide and determination of its cleavage sites.

Proteolytic processing of the polyprotein encoded by mRNA 1 is an essential step in coronavirus RNA replication and gene expression. We have previously reported that an open reading frame (ORF) 1a-specific proteinase of the picornavirus 3C proteinase group is involved in processing of the coronavirus infectious bronchitis virus (IBV) 1a/1b polyprotein, leading to the formation of a mature viral protein of 100 kDa. We report here the identification of a novel 10-kDa polypeptide and the involvement of the 3C-like proteinase in processing of the ORF 1a polyprotein to produce the 10-kDa protein species. By using a region-specific antiserum, V47, raised against a bacterial-viral fusion protein containing IBV sequence encoded between nucleotides 11488 and 12600, the 10-kDa polypeptide was detected in lysates from both IBV-infected and plasmid DNA-transfected Vero cells. Coexpression, deletion, and mutagenesis studies showed that this novel polypeptide was encoded by ORF 1a from nucleotide 11545 to 11878 and was cleaved from the 1a polyprotein by the 3C-like proteinase domain. Evidence presented suggested that a previously predicted Q-S (Q3783 S3784) dipeptide bond encoded by ORF 1a between nucleotides 11875 and 11880 was responsible for the release of the C terminus of the 10-kDa polypeptide and that a novel Q-N (Q3672 N3673) dipeptide bond encoded between nucleotides 11542 and 11547 was responsible for the release of the N terminus of the 10-kDa polypeptide.     

Cloning and sequencing of a cluster of genes encoding branched-chain alpha-keto acid dehydrogenase from Streptomyces avermitilis and the production of a functional E1 [alpha beta] component in Escherichia coli.

A cluster of genes encoding the E1 alpha, E1 beta, and E2 subunits of branched-chain alpha-keto acid dehydrogenase (BCDH) of Streptomyces avermitilis has been cloned and sequenced. Open reading frame 1 (ORF1) (E1 alpha), 1,146 nucleotides long, would encode a polypeptide of 40,969 Da (381 amino acids). ORF2 (E1 beta), 1,005 nucleotides long, would encode a polypeptide of 35,577 Da (334 amino acids). The intergenic distance between ORF1 and ORF2 is 73 bp. The putative ATG start codon of the incomplete ORF3 (E2) overlaps the stop codon of ORF2. Computer-aided searches showed that the deduced products of ORF1 and ORF2 resembled the corresponding E1 subunit (alpha or beta) of several prokaryotic and eukaryotic BCDH complexes. When these ORFs were overexpressed in Escherichia coli, proteins of about 41 and 34 kDa, which are the approximate masses of the predicted S. avermitilis ORF1 and ORF2 products, respectively, were detected. In addition, specific E1 [alpha beta] BCDH activity was detected in E. coli cells carrying the S. avermitilis ORF1 (E1 alpha) and ORF2 (E1 beta) coexpressed under the control of the T7 promoter.     

The ORF7b protein of severe acute respiratory syndrome coronavirus (SARS-CoV) is expressed in virus-infected cells and incorporated into SARS-CoV particles

Coronavirus replication is facilitated by a number of highly conserved viral proteins. The viruses also encode accessory genes, which are virus group specific and believed to play roles in virus replication and pathogenesis in vivo. Of the eight putative accessory proteins encoded by the severe acute respiratory distress syndrome associated coronavirus (SARS-CoV), only two-open reading frame 3a (ORF3a) and ORF7a-have been identified in virus-infected cells to date. The ORF7b protein is a putative viral accessory protein encoded on subgenomic (sg) RNA 7. The ORF7b initiation codon overlaps the ORF7a stop codon in a -1 shifted ORF. We demonstrate that the ORF7b protein is expressed in virus-infected cell lysates and from a cDNA encoding the gene 7 coding region, indicating that the sgRNA7 is bicistronic. The translation of ORF7b appears to be mediated by ribosome leaky scanning, and the protein has biochemical properties consistent with that of an integral membrane protein. ORF7b localizes to the Golgi compartment and is incorporated into SARS-CoV particles. We therefore conclude that the ORF7b protein is not only an accessory protein but a structural component of the SARS-CoV virion.     

中国西藏小反刍兽疫病毒野生株China/Tib/Gej/07-30基质蛋白基因和融合蛋白基因的分子特征分析

对我国西藏小反刍兽疫病毒野生株China/Tib/Gej/07-30进行基质蛋白(M)和融合蛋白(F)基因序列测定,并进行分子生物学特征分析。首先应用逆转录聚合酶链式反应扩增出M和F基因片段,对聚合酶链式反应产物进行直接测序,然后对测定的核苷酸和推测的氨基酸序列进行比较分析。China/Tib/Gej/07-30的M基因由1483个核苷酸组成,编码335个氨基酸,与其他分离株核苷酸和氨基酸序列同源性分别为92.4%～97.7%和97.0%～98.2%。F基因由2411个核苷酸组成,编码546个氨基酸,与其他分离株核苷酸和氨基酸序列同源性分别为85.5%～96.1%和94.3%～98.2%。China/Tib/Gej/07-30的F蛋白含有信号肽序列和跨膜结构域,序列高度变异。F蛋白第104～108位和第109～133位氨基酸位点分别是高度保守的裂解位点和融合肽结构域。F蛋白还含有序列高度保守的三个七肽重复区。China/Tib/Gej/07-30的M基因3′端的非编码区(UTR)长度为443个核苷酸,GC含量高达68.4%,与其他PPRV毒株的同源性为82.4%～93.5%。China/Tib/Gej/07-30的F基因5′UTR区长度为634个核苷酸,GC含量高达70.0%,与其他PPRV毒株序列相似性为76.2%～91.7%。     

The primary structure and expression of the second open reading frame of the polymerase gene of the coronavirus MHV-A59; a highly conserved polymerase is expressed by an efficient ribosomal frameshifting mechanism.

Sequence analysis of a substantial part of the polymerase gene of the murine coronavirus MHV-A59 revealed the 3' end of an open reading frame (ORF1a) overlapping with a large ORF (ORF1b; 2733 amino acids) which covers the 3' half of the polymerase gene. The expression of ORF1b occurs by a ribosomal frameshifting mechanism since the ORF1a/ORF1b overlapping nucleotide sequence is capable of inducing ribosomal frameshifting in vitro as well as in vivo. A stem-loop structure and a pseudoknot are predicted in the nucleotide sequence involved in ribosomal frameshifting. Comparison of the predicted amino acid sequence of MHV ORF1b with the amino acid sequence deduced from the corresponding gene of the avian coronavirus IBV demonstrated that in contrast to the other viral genes this ORF is extremely conserved. Detailed analysis of the predicted amino acid sequence revealed sequence elements which are conserved in many DNA and RNA polymerases.     

绵羊FGF5基因的克隆、表达及RNA干扰

根据牛的成纤维细胞内生长因子5(Fibroblast growth factor 5,FGF5)基因cDNA序列设计引物,PCR扩增得到绵羊FGF5基因cDNA的开放阅读框序列,并比较和其他6种高等哺乳动物的序列同源性;同时研究该基因在绵羊多种组织的表达情况,以及研究以细胞模型RNA干扰下的表达情况。结果表明,绵羊FGF5基因ORF全长为813 bp,编码270个氨基酸,分子量约为29.58 kDa,理论等电点10.59。绵羊FGF5基因cDNA序列与牛、人、小鼠、大鼠、犬和猫的对应序列同源性高度保守,预测氨基酸序列同源性同样具有高度保守性。RT-PCR分析表明FGF5在绵羊皮肤、小肠、肾脏、心脏、肝脏、脾脏、胰脏和肺中均有表达,皮肤中表达量最高。构建该基因的原核表达载体和RNAi载体,IPTG诱导在大肠杆菌中融合表达获得55 kDa的蛋白条带,设计的RNA干扰片段能显著抑制FGF5基因的表达。文章为进一步阐明绵羊FGF5的功能尤其是在羊毛生长发育中的作用提供了理论和实验基础。     

Complete genome sequence of a novel picobirnavirus, otarine picobirnavirus, discovered in California sea lions

We discovered a novel otarine picobirnavirus in fecal samples of California sea lions. Its genome contains a large segment with two open reading frames (ORFs), ORF1 encoding a putative protein of 163 amino acids with unknown function and ORF2 encoding capsid protein, and a small segment with one ORF encoding RNA-dependent RNA polymerase.     

番茄LeNHX1基因植物过量表达载体的构建及表达分析

从番茄幼苗中提取RNA,根据NCBI中番茄LeNHX1基因序列设计引物,通过RT-PCR获得了番茄LeNHX1基因的cDNA序列,包含一个1 605 bp的开放阅读框,编码534个氨基酸。将cDNA序列连接到植物过量表达载体PBI121上,对所获得的重组质粒进行双酶切鉴定,结果表明,植物过量表达载体PBI121-LeNHX1已构建成功。半定量RT-PCR结果表明LeNHX1基因在根、茎和叶中均表达,盐、低温和脱落酸的诱导能提高LeNHX1基因的表达量,推测番茄LeNHX1基因在逆境应答中可能起着重要作用。     

Bacteriophage T4 gene 44 DNA polymerase accessory protein. Sequences of gene 44 and its protein product

Bacteriophage T4 gene 44 protein is a DNA polymerase accessory protein which is required for T4 DNA replication. We have isolated the gene for 44 protein from a previously constructed lambda-T4 hybrid phage (Wilson, G. G., Tanyashin, V. I., and Murray, N. E. (1977) Mol. Gen. Genet. 156, 203-214). We report here the nucleotide sequence of gene 44 and about 60 nucleotides 5' upstream from its coding region, which is immediately adjacent to gene 45. We have also purified 44 protein from T4-infected cells and submitted it to extensive protein chemistry characterization. Thus, considerable portions of the protein sequence predicted from the DNA sequence were confirmed by direct protein sequencing of peptides or by matching amino acid compositions of purified peptides. A total of 84% of the predicted amino acids was confirmed by the protein data. These studies indicate that gene 44 codes for a polypeptide containing 319 amino acids, with a calculated Mr = 35,371. The coding region of gene 44 is preceded by a potential regulatory region containing sequences homologous to the Escherichia coli (-10) RNA polymerase binding region and to a conserved sequence at -25 to -30 found in other T4 middle genes. In addition, there are sequence similarities in the translation initiation regions of genes 44, 45, and rIIB, all of which are subject to regulation by regA protein.     

鸡传染性支气管炎病毒变异株（793／B）核蛋白基因的克隆与序列分析

根据GenBank已经发表的传染性支气管炎病毒(IBV)N全基因组序列设计引物,对IBV793/B分离毒株N基因进行克隆与序列分析。结果表明,IBV793/B的N基因由1229bp组成,与GenBank已发表的11株IBV的N基因相比较,IBV793/B的N基因共有88处点突变,在第991位发生了一个核苷酸的缺失。N基因的核苷酸同源性为86.9%～91.4%,氨基酸同源性为75.8%～77.5%。表明IBV93/B的N基因存在着较大的变异性。