Translational efficiency of BVDV IRES and EMCV IRES for T7 RNA polymerase driven cytoplasmic expression in mammalian cell lines

Mammalian T7 polymerase-based cytoplasmic expression systems are common tool for molecular studies. The majority of these systems include the internal ribosome entry site (IRES) of the encephalomyocarditis virus (EMCV). To carry out a cap-independent translation process, this type of IRES might require the expression of an extensive array of host factors, what is a disadvantage. Other IRESes might be less dependent on the host cell factors, but their biology is characterized to a lesser degree. Here, we compare the translational efficiencies of bovine viral diarrhea virus (BVDV) IRES with that of ECMV. Both IRESes were tested in reporter vectors containing the T7 promoter, an IRES of choice and the coding sequence of the enhanced green fluorescent protein (EGFP). To provide for the expression of T7 RNA polymerase, the corresponding gene was isolated from Escherichia coli and inserted into pCDNA3.1-Hygro(+). After co-transfection of the T7 RNA polymerase encoding vector with either of the two IRES-containing reporter vectors into T7 baby hamster kidney (T7-BHK), human embryonic kidney (HEK) 293T, chinese hamster ovary (CHO) and HeLa cells, the translational efficiency of the reporter construct was studied by fluorescence microscopy and flow cytometry. In T7-BHK, HEK 293T and HeLa cells the translational efficiency of BVDV IRES was two to three times higher than that of EMCV IRES. In CHO cells, BVDV IRES and EMCV IRES were equally efficient. An analysis of the secondary structure of respective mRNAs showed that their ΔG values were–544.00 and–469.40 kcal/mol for EMCV IRES and BVDV IRES harboring molecules, respectively. As EMCV IRES-containing mRNA is more stable, it is evident that other, still unidentified factors should be held responsible for the enhanced translational efficiency of BDVD IRES. Taken together, our results indicate the potential of BVDV IRES as a replacement for EMCV IRES, which is now commonly used for T7 polymerase driven cytoplasmic expression of genes of interest or virus cDNA rescue experiments.     

Intron-derived small RNAs for silencing viral RNAs in mosquito cells

Aedes aegypti and Ae. albopictus are the main vectors of mosquito-borne viruses of medical and veterinary significance. Many of these viruses have RNA genomes. Exogenously provided, e.g. transgene encoded, small RNAs could be used to inhibit virus replication, breaking the transmission cycle. We tested, in Ae. aegypti and Ae. albopictus cell lines, reporter-based strategies for assessing the ability of two types of small RNAs to inhibit a chikungunya virus (CHIKV) derived target. Both types of small RNAs use a Drosophila melanogaster pre-miRNA-1 based hairpin for their expression, either with perfect base-pairing in the stem region (shRNA-like) or containing two mismatches (miRNA-like). The pre-miRNA-1 stem loop structure was encoded within an intron; this allows co-expression of one or more proteins, e.g. a fluorescent protein marker tracking the temporal and spatial expression of the small RNAs in vivo. Three reporter-based systems were used to assess the relative silencing efficiency of ten shRNA-like siRNAs and corresponding miRNA-like designs. Two systems used a luciferase reporter RNA with CHIKV RNA inserted either in the coding sequence or within the 3’ UTR. A third reporter used a CHIKV derived split replication system. All three reporters demonstrated that while silencing could be achieved with both miRNA-like and shRNA-like designs, the latter were substantially more effective. Dcr-2 was required for the shRNA-like siRNAs as demonstrated by loss of inhibition of the reporters in Dcr-2 deficient cell lines. These positive results in cell culture are encouraging for the potential use of this pre-miRNA-1-based system in transgenic mosquitoes.     

Identification and functional implications of pseudouridine RNA modification on small noncoding RNAs in the mammalian pathogen Trypanosoma brucei

Trypanosoma brucei, the parasite that causes sleeping sickness, cycles between an insect and a mammalian host. However, the effect of RNA modifications such as pseudouridinylation on its ability to survive in these two different host environments is unclear. Here, two genome-wide approaches were applied for mapping pseudouridinylation sites (Ψs) on small nucleolar RNA (snoRNA), 7SL RNA, vault RNA, and tRNAs from T. brucei. We show using HydraPsiSeq and RiboMeth-seq that the Ψ on C/D snoRNA guiding 2′-O-methylation increased the efficiency of the guided modification on its target, rRNA. We found differential levels of Ψs on these noncoding RNAs in the two life stages (insect host and mammalian host) of the parasite. Furthermore, tRNA isoform abundance and Ψ modifications were characterized in these two life stages demonstrating stage-specific regulation. We conclude that the differential Ψ modifications identified here may contribute to modulating the function of noncoding RNAs involved in rRNA processing, rRNA modification, protein synthesis, and protein translocation during cycling of the parasite between its two hosts.     

Inhibition of severe acute respiratory syndrome virus replication by small interfering RNAs in mammalian cells

Severe acute respiratory syndrome (SARS) is an acute respiratory infectious disease that spread worldwide in early 2003. The cause was determined as a novel coronavirus (CoV), SARS-associated CoV (SARS-CoV), with a single-stranded, plus-sense RNA. To date, no effective specific treatment has been identified. To exploit the possibility of using RNA interference as a therapeutic approach to fight the disease, plasmid-mediated small interfering RNAs (siRNAs) were generated to target the SARS-CoV genome. The expression of siRNAs from two plasmids, which specifically target the viral RNA polymerase, effectively blocked the cytopathic effects of SARS-CoV on Vero cells. These two plasmids also inhibited viral replication as shown by titer assays and by an examination of viral RNA and protein levels. Thus, our results demonstrated the feasibility of developing siRNAs as effective anti-SARS drugs.     

A preformed compact ribosome-binding domain in the cricket paralysis-like virus IRES RNAs

The internal ribosome site RNA of the cricket paralysis-like viruses (CrPV-like) binds directly to the ribosome, assembling the translation machinery without initiation factors. This mechanism does not require initiator tRNA, and translation starts from a non-AUG codon. A wealth of biochemical data has yielded a working model for this process, but the three-dimensional structure and biophysical characteristics of the unbound CrPV-like IRES RNAs are largely unexplored. Here, we demonstrate that the CrPV-like IRESes prefold into a two-part structure in the presence of magnesium ions. The largest part is a prefolded compact RNA domain that shares folding and structural characteristics with other compactly folded RNAs such as group I intron RNAs and RNase P RNA. Chemical probing reveals that the CrPV-like IRES' compact domain contains RNA helices that are packed tightly enough to exclude solvent, and analytical ultracentrifugation indicates a large change in the shape of the IRES upon folding. Formation of this compact domain is necessary for binding of the 40S subunit, and the structural organization of the unbound IRES RNA is consistent with the hypothesis that the IRES is functionally and structurally preorganized before ribosome binding.     

Small RNAs with imperfect match to endogenous mRNA repress translation. Implications for off-target activity of small inhibitory RNA in mammalian cells

A 21-base pair RNA duplex that perfectly matches an endogenous target mRNA selectively degrades the mRNA and suppresses gene expression in mammalian tissue culture cells. A single base mismatch with the target is believed to protect the mRNA from degradation, making this type of interference highly specific to the targeted gene. A short RNA with mismatches to a target sequence present in multiple copies in the 3'-untranslated region of an exogenously expressed gene can, however, silence it by translational repression. Here we report that a mismatched RNA, targeted to a single site in the coding sequence of an endogenous gene, can efficiently silence gene expression by repressing translation. The antisense strand of such a mismatched RNA requires a 5'-phosphate but not a 3'-hydroxyl group. G.U wobble base pairing is tolerated as a match for both RNA degradation and translation repression. Together, these findings suggest that a small inhibitory RNA duplex can suppress expression of off-target cellular proteins by RNA degradation or translation repression. Proper design of experimental small inhibitory RNAs or a search for targets of endogenous micro-RNAs must therefore take into account that these short RNAs can affect expression of cellular genes with as many as 3-4 base mismatches and additional G.U mismatches.     

Novel functional small RNAs are selectively loaded onto mammalian Ago1

Argonaute (Ago) proteins function in RNA silencing as components of the RNA-induced silencing complex (RISC). In lower organisms, the small interfering RNA and miRNA pathways diverge due in part to sorting mechanisms that direct distinct small RNA (sRNA) duplexes onto specific Ago-RISCs. However, such sorting mechanisms appear to be lost in mammals. miRNAs appear not to distinguish among Ago1–4. To determine the effect of viral infection on the sorting system, we compared the content of deep-sequenced RNA extracted from immunoprecipitation experiments with the Ago1 and Ago2 proteins using Epstein–Barr virus (EBV)-infected cells. Consistent with previous observations, sequence tags derived from miRNA loci in EBV and humans globally associate in approximately equivalent amounts with Ago1 and Ago2. Interestingly, additional sRNAs, which have not been registered as miRNAs, were associated with Ago1. Among them, some unique sequence tags derived from tandem loci in the human genome associate exclusively with Ago1 but not, or rarely, with Ago2. This is supported by the observation that the expression of the unique sRNAs in the cells is highly dependent on Ago1 proteins. When we knocked down Ago1, the expression of the Ago1-specific sRNAs decreased dramatically. Most importantly, the Ago1-specific sRNAs bound to mRNAs and regulated target genes and were dramatically upregulated, depending on the EBV life cycle. Therefore, even in mammals, the sorting mechanism in the Ago1–4 family is functional. Moreover, the existence of Ago1-specific sRNAs implies vital roles in some aspects of mammalian biology.     

Replication of nodamura virus after transfection of viral RNA into mammalian cells in culture.

Nodamura virus (NOV) was purified from the hind limbs of infected suckling mice and used as a source of the two genomic RNAs of the virus, RNA 1 and RNA 2. Upon transfection of the viral RNAs into baby hamster kidney (BHK21) cells in culture, vigorous RNA replication ensued and single-stranded RNAs 1 and 2 accumulated to reach an abundance which approximated that of the cellular rRNAs. Transient synthesis of a small subgenomic RNA (RNA 3) was also observed, and double-stranded versions of RNAs 1, 2, and 3 were detected. Three major viral proteins were synthesized in transfected cells. Protein A (about 115 kDa) and protein B (about 15 kDa) were made transiently at early times after transfection, whereas a large amount of protein alpha (43 kDa), the precursor to the two viral coat proteins, was made continuously starting later in the infectious cycle. When very low concentrations of viral RNAs were used for transfection, preferential replication of RNA 1 occurred. This result was attributed to segregation of the transfected viral RNAs to separate cells in culture and the subsequent replication and amplification of RNA 1 in cells that had received no RNA 2. Accordingly, multiple passages of the viral RNAs by transfection at the limit dilution resulted in the purification of RNA 1 free of RNA 2 and demonstrated that RNA 1 was capable of prolonged autonomous replication which was also accompanied by the continuous synthesis of RNA 3. In cells transfected with RNA 1 alone, protein alpha was not synthesized and proteins A and B were made continuously. Electron microscopic analysis of BHK21 cells 24 h after transfection with NOV RNAs 1 and 2 showed that large numbers of virus particles accumulated in the cytoplasm and formed paracrystalline arrays in some regions. Whole NOV purified from transfected BHK21 cells was infectious for suckling mice and had an electrophoretic mobility that was similar but not identical to that of NOV purified from infected mouse muscle. The high yield of NOV, its simple genetic composition, and its unusual genome strategy make this virus an attractive system for the study of viral RNA replication in animal cells.     

Mammalian RNA virus-derived small RNA: biogenesis and functional activity

The role of virus-derived small RNAs (vsRNAs) has been identified as an antiviral mechanism in plants, arthropods, and nematodes. Although mammalian DNA viruses have been observed to encode functional miRNAs, whether RNA virus infection generates functional vsRNAs remains under discussion. This article reviews the most recent reports regarding pathways for generating vsRNAs and the identified vsRNA activity in mammalian cells infected with RNA viruses. We also discuss several hypotheses regarding the roles of mammalian vsRNAs and comment on the potential directions for this research field.     

A Rab11- and microtubule-dependent mechanism for cytoplasmic transport of influenza A virus viral RNA

The viral RNA (vRNA) genome of influenza A virus is replicated in the nucleus, exported to the cytoplasm as ribonucleoproteins (RNPs), and trafficked to the plasma membrane through uncertain means. Using fluorescent in situ hybridization to detect vRNA as well as the live cell imaging of fluorescently labeled RNPs, we show that an early event in vRNA cytoplasmic trafficking involves accumulation near the microtubule organizing center in multiple cell types and viral strains. Here, RNPs colocalized with Rab11, a pericentriolar recycling endosome marker. Cytoplasmic RNP localization was perturbed by inhibitors of vesicular trafficking, microtubules, or the short interfering RNA-mediated depletion of Rab11. Green fluorescent protein (GFP)-tagged RNPs in living cells demonstrated rapid, bidirectional, and saltatory movement, which is characteristic of microtubule-based transport, and also cotrafficked with fluorescent Rab11. Coprecipitation experiments showed an interaction between RNPs and the GTP-bound form of Rab11, potentially mediated via the PB2 subunit of the polymerase. We propose that influenza virus RNPs are routed from the nucleus to the pericentriolar recycling endosome (RE), where they access a Rab11-dependent vesicular transport pathway to the cell periphery.     

Comparison of dengue virus type 2-specific small RNAs from RNA interference-competent and -incompetent mosquito cells

The exogenous RNA interference (RNAi) pathway is an important antiviral defense against arboviruses in mosquitoes, and virus-specific small interfering (si)RNAs are key components of this pathway. Understanding the biogenesis of siRNAs in mosquitoes could have important ramifications in using RNAi to control arbovirus transmission. Using deep sequencing technology, we characterized dengue virus type 2 (DENV2)-specific small RNAs produced during infection of Aedes aegypti mosquitoes and A. aegypti Aag2 cell cultures and compared them to those produced in the C6/36 Aedes albopictus cell line. We show that the size and mixed polarity of virus-specific small RNAs from DENV-infected A. aegypti cells indicate that they are products of Dicer-2 (Dcr2) cleavage of long dsRNA, whereas C6/36 cells generate DENV2-specific small RNAs that are longer and predominantly positive polarity, suggesting that they originate from a different small RNA pathway. Examination of virus-specific small RNAs after infection of the two mosquito cell lines with the insect-only flavivirus cell fusing agent virus (CFAV) corroborated these findings. An in vitro assay also showed that Aag2 A. aegypti cells are capable of siRNA production, while C6/36 A. albopictus cells exhibit inefficient Dcr2 cleavage of long dsRNA. Defective expression or function of Dcr2, the key initiator of the RNAi pathway, might explain the comparatively robust growth of arthropod-borne viruses in the C6/36 cell line, which has been used frequently as a surrogate for studying molecular interactions between arboviruses and cells of their mosquito hosts.     

Norwalk virus RNA is infectious in mammalian cells

Human noroviruses are positive-sense RNA viruses and are the leading cause of epidemic acute viral gastroenteritis in developed countries. The absence of an in vitro cell culture model for human norovirus infection has limited the development of effective antivirals and vaccines. Human histo-blood group antigens have been regarded as receptors for norovirus infection, and expression of the α(1,2) fucosyltransferase gene (FUT2) responsible for the secretor phenotype is required for susceptibility to Norwalk virus (NV) infection. We report for the first time that transfection of NV RNA, isolated from stool samples from human volunteers, into human hepatoma Huh-7 cells leads to viral replication, with expression of viral antigens, RNA replication, and release of viral particles into the medium. Prior treatment of the RNA with proteinase K completely abolishes RNA infectivity, suggesting a key role of an RNA-protein complex. Although overexpression of the human FUT2 gene enhances virus binding to cells, it is not sufficient to allow a complete viral infection, and viral spread from NV-transfected cells to naïve cells does not occur. Finally, no differences in NV RNA replication are observed between Huh-7 and Huh-7.5.1 cells, which contain an inactivating mutation in retinoic acid-inducible gene I (RIG-I), suggesting that the RIG-I pathway does not play a role in limiting NV replication. Our results strongly suggest that the block(s) to NV replication in vitro is at the stage of receptor and/or coreceptor binding and/or uncoating, either because cells lack some specific factor or activation of cellular antiviral responses independent of RIG-I inhibits virus replication.The human pathogen Norwalk virus (NV) is the prototype strain of the Norovirus genus in the family Caliciviridae. Noroviruses are responsible for the majority of outbreaks of nonbacterial gastroenteritis in developed countries, and it is estimated that they have a significant impact in developing countries as well. Although human noroviruses were originally identified more than 30 years ago, our understanding of their replication cycle and mechanisms of pathogenicity has been limited because these viruses are noncultivatable in established cell lines and a small animal model to study viral infection is not available. Only recently, it has been reported that both genogroup I (GI) and GII strains of human noroviruses can be passaged several times with limited replication in a differentiated three-dimensional cell culture system derived from a human small intestinal cell line (40). In addition, gnotobiotic pigs can support replication of a human norovirus GII strain, with occurrence of mild diarrhea and virus shedding and immunofluorescent detection of both structural and nonstructural proteins in enterocytes (10). Although these results are promising, it remains unclear whether these systems are robust enough to be widely used to efficiently propagate human noroviruses in vitro, and the factors responsible for the block(s) of viral replication using standard cell culture systems remain unknown.The NV genome is a positive-sense, polyadenylated, single-stranded RNA molecule of 7.7 kb and contains three open reading frames (ORFs): ORF1 encodes a nonstructural polyprotein, and ORF2 and ORF3 encode the major and minor capsid proteins, VP1 and VP2, respectively (14, 24). Due to the lack of an in vitro system to propagate human noroviruses, features of their life cycle have been inferred from studies using other animal caliciviruses that can grow in mammalian cell cultures. A 3′ coterminal polyadenylated subgenomic RNA is produced within infected cells, and it is believed that both genomic and subgenomic RNAs are covalently linked to the nonstructural protein VPg at their 5′ ends. Upon infection of cells, nonstructural proteins are expressed from genomic RNA and form an RNA replication complex, which generates new genomic RNA molecules as well as subgenomic RNAs encoding VP1 and VP2. After expression of the structural proteins from subgenomic RNA molecules, the capsid is assembled and viral RNA encapsidated prior to progeny release. Some of these features have been confirmed using recombinant systems to express the native NV genome in mammalian cells by using vaccinia virus expression systems (2, 25).Studies with human volunteers have shown that some individuals are either repeatedly susceptible or resistant to NV infection (36) and led to the identification of a genetically determined factor that predicts a person''s susceptibility to infection and disease (19, 30). Binding experiments using recombinant NV virus-like particles (VLPs) demonstrated attachment of VLPs to surface epithelial cells of the gastroduodenal junction on biopsies from secretors but not to cells from nonsecretors, showing that the expression pattern of ABH histo-blood group antigens may influence susceptibility to NV (32). The gene responsible for the secretor phenotype encodes an α(1,2)fucosyltransferase (FUT2) that produces H antigens on the surface of epithelial cells and in mucosal secretions (27). Since it was observed that transfection of the FUT2 gene into nonpermissive cells enhances NV binding (31), it has been hypothesized that H antigens or related blood group antigens may function as a receptor for NV.The main goal of our study was to understand the molecular basis of the restricted growth of NV in cultured cells by transfecting wild-type NV RNA into human cells. Our studies show for the first time that transfection of wild-type NV RNA isolated from human stool samples can lead to the production of viral particles, indicating that wild-type NV RNA is infectious and replicates. However, a block to NV spread to other cells in the culture remains, indicating that the block(s) exists at the cell entry and/or uncoating steps.     

Nodamura virus nonstructural protein B2 can enhance viral RNA accumulation in both mammalian and insect cells

During infection of both vertebrate and invertebrate cell lines, the alphanodavirus Nodamura virus (NoV) expresses two nonstructural proteins of different lengths from the B2 open reading frame. The functions of these proteins have yet to be determined, but B2 of the related Flock House virus suppresses RNA interference both in Drosophila cells and in transgenic plants. To examine whether the NoV B2 proteins had similar functions, we compared the replication of wild-type NoV RNA with that of mutants unable to make the B2 proteins. We observed a defect in the accumulation of mutant viral RNA that varied in extent from negligible in some cell lines (e.g., baby hamster kidney cells) to severe in others (e.g., human HeLa and Drosophila DL-1 cells). These results are consistent with the notion that the NoV B2 proteins act to circumvent an innate antiviral response such as RNA interference that differs in efficacy among different host cells.     

从少量转染细胞中同时快速提取总RNA和基因组DNA

采用4mol / L LiCl将DNA和RNA分相,建立了同时从少量转染细胞中快速提取细胞总RNA和大分子基因组DNA的方法.与以前的方法相比,本法快速、简便、经济,尤其适合应用在哺乳动物细胞基因表达与调控的研究中．     

A fast and sensitive method for detecting specific viral RNA in mammalian cells.

A quick and sensitive method to quantitate viral RNA synthesis has been developed. Utilizing glutaraldehyde to fix infected cells onto nitrocellulose paper, viral RNA can be probed directly in situ. Viral message can be detected from as few as 10(4) infected cells. This technique can be used to study viral gene expression and can be adapted to screen the activity of antiviral agents such as interferon.