Fast preparation of a long chimeric armored RNA as controls for external quality assessment for molecular detection of Zika virus

BACKGROUND

The emergence of Zika virus demands accurate laboratory diagnostics. Nucleic acid testing is currently the definitive method for diagnosis of Zika infection. In 2016, an external quality assurance (EQA) for assessing the quality of molecular testing of Zika virus was carried out in China.

METHODS

A single armored RNA encapsulating a 4942-nucleotides (nt) long specific RNA sequence of Zika virus was prepared and used as positive samples. A pre-tested EQA panel, consisting of 4 negative and 6 positive samples with different concentrations of armored RNA, was distributed to 38 laboratories that perform molecular detection of Zika virus.

RESULTS

A total of 39 data sets (1 laboratory used two test kits in parallel), produced by using commercial (n=38) or laboratory developed (n=1) quantitative reverse-transcriptase PCR (qRT-PCR) kits, were received. Of these, 35 (89.7%) had correct results for all 10 samples, and 4 (10.3%) reported at least 1 error (11 in total). The testing errors were all false-negatives, highlighting the need of improvements in detecting sensitivity.

CONCLUSIONS

The EQA reveals that the majority of participating laboratories are proficient in molecular testing of Zika virus.

Bioengineering of Tobacco Mosaic Virus to Create a Non-Infectious Positive Control for Ebola Diagnostic Assays

The 2014 Ebola epidemic is the largest to date. There is no cure or treatment for this deadly disease; therefore there is an urgent need to develop new diagnostics to accurately detect Ebola. Current RT-PCR assays lack sensitive and reliable positive controls. To address this critical need, we devised a bio-inspired positive control for use in RT-PCR diagnostics: we encapsulated scrambled Ebola RNA sequences inside of tobacco mosaic virus to create a biomimicry that is non-infectious, but stable, and could therefore serve as a positive control in Ebola diagnostic assays. Here, we report the bioengineering and validation of this probe.

Synthetic RNAs Mimicking Structural Domains in the Foot-and-Mouth Disease Virus Genome Elicit a Broad Innate Immune Response in Porcine Cells Triggered by RIG-I and TLR Activation

The innate immune system is the first line of defense against viral infections. Exploiting innate responses for antiviral, therapeutic and vaccine adjuvation strategies is being extensively explored. We have previously described, the ability of small in vitro RNA transcripts, mimicking the sequence and structure of different domains in the non-coding regions of the foot-and-mouth disease virus (FMDV) genome (ncRNAs), to trigger a potent and rapid innate immune response. These synthetic non-infectious molecules have proved to have a broad-range antiviral activity and to enhance the immunogenicity of an FMD inactivated vaccine in mice. Here, we have studied the involvement of pattern-recognition receptors (PRRs) in the ncRNA-induced innate response and analyzed the antiviral and cytokine profiles elicited in swine cultured cells, as well as peripheral blood mononuclear cells (PBMCs).

5'PPP-RNA induced RIG-I activation inhibits drug-resistant avian H5N1 as well as 1918 and 2009 pandemic influenza virus replication

BACKGROUND

Emergence of drug-resistant strains of influenza viruses, including avian H5N1 with pandemic potential, 1918 and 2009 A/H1N1 pandemic viruses to currently used antiviral agents, neuraminidase inhibitors and M2 Ion channel blockers, underscores the importance of developing novel antiviral strategies. Activation of innate immune pathogen sensor Retinoic Acid Inducible Gene-I (RIG-I) has recently been shown to induce antiviral state.

RESULTS

In the present investigation, using real time RT-PCR, immunofluorescence, immunoblot, and plaque assay we show that 5'PPP-containing single stranded RNA (5'PPP-RNA), a ligand for the intracytoplasmic RNA sensor, RIG-I can be used as a prophylactic agent against known drug-resistant avian H5N1 and pandemic influenza viruses. 5'PPP-RNA treatment of human lung epithelial cells inhibited replication of drug-resistant avian H5N1 as well as 1918 and 2009 pandemic influenza viruses in a RIG-I and type 1 interferon dependant manner. Additionally, 5'PPP-RNA treatment also inhibited 2009 H1N1 viral replication in vivo in mice.

CONCLUSIONS

Our findings suggest that 5'PPP-RNA mediated activation of RIG-I can suppress replication of influenza viruses irrespective of their genetic make-up, pathogenicity, and drug-sensitivity status.

RT-PCR for confirmation of echovirus 30 isolated in Belém, Brazil

Echovirus (Echo) 30 or human enterovirus B is the most frequent enterovirus associated with meningitis cases. Epidemics and outbreaks of this disease caused by Echo 30 have occurred in several countries. In Brazil, Echo 30 has been isolated from sporadic cases and outbreaks that occurred mainly in the south and southeast regions. We used RT-PCR to examine Echo 30 isolates from meningitis cases detected from March 2002 to December 2003 in Belém, state of Pará, in northern Brazil. The patients were attended in a Basic Health Unit (State Health Secretary of Pará), where cerebrospinal fluid (CSF) was collected and stored in liquid nitrogen. Weekly visits were made by technicians from Evandro Chagas Institute to the health unit and samples were stored at -70 degrees C in the laboratory until use. HEp-2 and RD cell lines were used for viral isolation and neutralization with specific antisera for viral identification. RNA extraction was made using Trizol reagent. The RT-PCR was made in one step, and the total mixture (50 microL) was composed of: RNA, reaction buffer, dNTP, primers, Rnase inhibitor, reverse transcriptase, Taq polymerase and water. The products were visualized in agarose gel stained with ethidium bromide, visualized under UV light. Among the 279 CSF samples examined, 30 (10.7%) were EV positive, 29 being Echo 30 and one was Cox B. Nineteen Echo 30 were examined with RT-PCR; 18 tested positive (762 and 494 base pairs). The use of this technique permitted viral identification in less time than usual, which benefits the patient and is of importance for public-health interventions.

An improved cell-free system for picornavirus synthesis

Cell-free synthesis of an infectious virus is an ideal tool for elucidating the mechanism of viral replication and for screening anti-viral drugs. In the present study, the synthesis of Encephalomyocarditis virus (EMCV) from its RNA in HeLa and 293-F cell extracts was enhanced by employing a dialysis system in combination with a ribozyme technology. Although translation and processing of the EMCV polyprotein were not accelerated greatly by the dialysis system, de novo synthesis of viral RNA was enhanced considerably by dialysis, leading to a greater than eight-fold increased titer of synthesized EMCV compared with a conventional batch system. Furthermore, a synthetic EMCV RNA with a hammerhead ribozyme sequence at its 5'-end served as an efficient template for viral synthesis in the dialysis system. Therefore, this system provides opportunities for mutational analyses of EMCV in vitro.

Inhibition of avian metapneumovirus (AMPV) replication by RNA interference targeting nucleoprotein gene (N) in cultured cells

Avian metapneumovirus (AMPV) is the primary causative agent of severe rhinotracheitis in turkeys. It is associated with swollen head syndrome in chickens and is the source of significant economic losses to animal food production. In this study, we designed specific short interfering RNA (siRNA) targeting the AMPV nucleoprotein (N) and fusion (F) genes. Three days post-virus infection, virus titration, real time RT-PCR, and RT-PCR assays were performed to verify the effect of siRNA in AMPV replication. A marked decrease in virus titers from transfected CER cells treated with siRNA/N was observed. Also, the production of N, F, and G mRNAs in AMPV was decreased. Results indicate that N-specific siRNA can inhibit virus replication. In future studies, a combination of siRNAs targeting the RNA polymerase complex may be used as a tool to study AMPV replication and/or antiviral therapy.

Characterization of the E-138 (Glu/Lys) mutation in Japanese encephalitis virus by using a stable, full-length, infectious cDNA clone

A stable plasmid DNA, pMWJEAT, was constructed by using full-length Japanese encephalitis virus (JEV) cDNA isolated from the wild-type strain JEV AT31. Recombinant JEV was obtained by synthetic RNA transfection into Vero cells and designated rAT virus. JEV rAT exhibited similar large-plaque morphology and antigenicity to the parental AT31 strain. Mutant clone pMWJEAT-E138K, containing a single Glu-to-Lys mutation at aa 138 of the envelope (E) protein, was also constructed to analyse the mechanisms of viral attenuation arising from this mutation. Recombinant JEV rAT-E138K was also recovered and displayed a smaller-plaque morphology and lower neurovirulence and neuroinvasiveness than either AT31 virus or rAT virus. JEV rAT-E138K exhibited greater plaque formation than rAT virus in virus-cell interactions under acidic conditions. Heparin or heparinase III treatment inhibited binding to Vero cells more efficiently for JEV rAT-E138K than for rAT virus. Inhibition of virus-cell interactions by using wheatgerm agglutinin was more effective for JEV rAT than for rAT-E138K on Vero cells. About 20 % of macropinoendocytosis of JEV rAT for Vero cells was inhibited by cytochalasin D treatment, but no such inhibition occurred for rAT-E138K virus. Furthermore, JEV rAT was predominantly secreted from infected cells, whereas rAT-E138K was more likely to be retained in infected cells. This study demonstrates clearly that a single Glu-to-Lys mutation at aa 138 of the envelope protein affects multiple steps of the viral life cycle. These multiple changes may induce substantial attenuation of JEV.

Enzymatic synthesis and 19F NMR studies of 2-fluoroadenine-substituted RNA

The production of isotopically labeled RNA remains critical to current NMR structural studies. One approach to obtain simple NMR spectra is to label with a nucleus that is not naturally occurring in RNA. Fluorine-19 can serve as a sensitive site-specific probe upon incorporation into RNA. Here we report the efficient in vitro enzymatic synthesis of 2-fluoroadenosine-5'-triphosphate and its incorporation into the HIV-2 transactivation region (TAR) of RNA by DNA template-directed transcription using phage T7 RNA polymerase. We provide unequivocal evidence for this 19F-substituted base analogue capability to selectively interact with uracil, forming 2F-A-U base pairs in RNA. The introduction of a 2-fluoroadenyl substitution is relatively nonperturbing and provides us with uniquely positioned, sensitive NMR reporter groups to monitor structural changes in the local RNA environment.

A comparative binding study of modified bovine immunodeficiency virus TAR RNA against its TAT peptide

Besides generating novel binding peptides or small molecules to their RNA target, successful design of chemically modified RNA constructs capable of tighter binding with their binding peptides is also of significant importance. Herein, the synthesis and binding studies of a series of both wt and mutant bovine immunodeficiency virus (BIV) TAR RNA constructs against its Tat peptide are reported. Understanding the requirements that enable RNA construct binding properties, especially at the hairpin loop or internal bulge, would afford potential therapeutic approaches to control the BIV life cycle.

Arthritogenic properties of double-stranded (viral) RNA

Viral infections often lead to arthralgias and overt arthritic states. The inflammatogenic compound of the viruses giving rise to such an outcome has to date not been identified. Because expression of dsRNA is a common feature of all viruses, we decided to analyze whether this property leads to the induction of arthritis. Histological signs of arthritis were evident already on day 3 following intra-articular administration of dsRNA. Arthritis was characterized by infiltration of macrophages into synovial tissue. It was not dependent on acquired immune responses because SCID mice also raised joint inflammation. NF-kappa B was activated upon in vitro exposure to dsRNA, indicating its role in the induction/progression of arthritis. Importantly, we found that dsRNA arthritis was triggered through IL-1R signaling because mice being deficient for this molecule were unable to develop joint inflammation. Although dsRNA is typically recognized by Toll-like receptor 3, Toll-like receptor 3 knockout mice developed arthritis, indicating that some other receptors are instrumental in the inducing of inflammation. Our results from in vitro experiments indicate that proinflammatory cytokines and chemokines stimulating monocyte influx were readily triggered in response to stimulation with dsRNA. These findings demonstrate that viral dsRNA is clearly arthritogenic. Importantly, macrophages and their products play an important role in the development of arthritis triggered by dsRNA.

Lysine directed cross-linking of viral DNA-RNA:DNA hybrid substrate to the isolated RNase H domain of HIV-1 reverse transcriptase

An isolated ribonuclease H domain of HIV-1 reverse transcriptase is capable of specifically removing the tRNA primer within an oligonucleotide mimic. The determinants for substrate specificity are located in a region within the terminal octanucleotide of the acceptor stem of the tRNA. Recognition of the substrate by HIV-1 RNase H was analyzed by the introduction of a cross-linking reagent directed toward lysines on the thymine residue complementary to the scissile bond, facing the major groove of the DNA-RNA:DNA substrate. Cross-linking of the modified substrate to RNase H required the presence of Mn(2+). The Mn(2+) titration of cross-linking paralleled the Mn(2+) requirement for activity. Modified substrate quenched with glycine prior to binding of substrate was efficiently cleaved, whereas the RNA within the cross-linked product was intact. Tryptic digestion of the isolated RNase H-nucleic acid covalent complex revealed a main cross-linked peptide whose N-terminal peptide sequence is VVTLTDTTNQ, indicating that the cross-linked lysine corresponds to Lys476. Cross-linking to K476 was confirmed by analysis of K476C RNase H. Mutation of K476C disrupted the chemical cross-linking while maintaining activity. On the basis of the size of the cross-linker arm, the results indicate that K476 is in closer proximity to the tRNA mimic substrate within the isolated RNase H domain than observed for the RNase H-resistant polypurine tract (PPT) substrate within the HIV-1 RT.

Comparative evaluation of measles virus specific TaqMan PCR and conventional PCR using synthetic and natural RNA templates

Comparative evaluation of TaqMan RT-polymerase chain reaction (PCR) methodology developed during this study with the conventional RT-PCR-nested PCR methodology developed earlier, using measles virus RNA templates derived from synthetic and natural sources against a number of primer sets belonging to various regions of the genome, revealed the existence of similar assay thresholds for both methods. An exception to this finding was, however, noted using primer sets of the N and M genes regions with RNA templates extracted from the wild type measles virus strain where the nested PCR method proved to be 10- to 100-fold more sensitive than the end points established with the N gene specific TaqMan RT-PCR method with synthetic RNA templates. These differences were not evident when the same primer sets were evaluated with RNA templates extracted from a brain sample of SSPE patient. These findings indicate that the genetic make up of measles virus strain in any given clinical specimen, in relation to the amplifying primers/probe sequences, can have impact on the overall sensitivity and specificity of the methodology applied. Both methods are equally suitable for the molecular detection of measles virus sequences in clinical specimens, although the TaqMan RT-PCR method may be preferred due to its advantages of contamination control, automation, and real-time product quantitation.

Formation of dendrimeric RNA assemblies though RNA loop-loop interactions

We describe the construction of nano-scale dendritic assemblies using RNA building blocks based on dimerization initiation site (DIS) RNA of the human immunodeficiency virus type 1 (HIV-1) that forms stable base pairing through loop-loop ("kissing") interactions. RNA building blocks containing three DIS-like hairpins connected by a two nucleotide linker self-assembled in a magnesium-dependent manner to form dendrimeric structures as observed by non-denaturing polyacrylamide gel electrophoresis (PAGE).

Mutations in the ribonuclease H active site of HIV-RT reveal a role for this site in stabilizing enzyme-primer-template binding

The RNase H activity of HIV-RT is coordinated by a catalytic triad (E478, D443, D498) of acidic residues that bind divalent cations. We examined the effect of RNase H deficient E(478)-->Q and D(549)-->N mutations that do not alter polymerase activity on binding of enzyme to various nucleic acid substrates. Binding of the mutant and wild-type enzymes to various nucleic acid substrates was examined by determining dissociation rate constants (k(off)) by titrating both Mg(2+) and salt concentrations. In agreement with the unaltered polymerase activity of the mutant, the k(off) values for the wild-type and mutant enzymes were essentially identical using DNA-DNA templates in the presence of 6 mM Mg(2+). However, with lower concentrations of Mg(2+) and in the absence of Mg(2+), although both enzymes dissociated more rapidly, the mutant enzymes dissociated several-fold more slowly than the wild type. This was also observed on RNA-DNA templates. These results indicate that alterations in residues essential for Mg(2+) binding have a pronounced positive effect on enzyme-template stability and that the negative residues in the RNase H region of the enzyme have a negative influence on binding in the absence of Mg(2+). In this regard RT is similar to other nucleic acid cleaving enzymes that show enhanced binding upon mutation of active site residues.

Chemical synthesis of poliovirus cDNA: generation of infectious virus in the absence of natural template

Full-length poliovirus complementary DNA (cDNA) was synthesized by assembling oligonucleotides of plus and minus strand polarity. The synthetic poliovirus cDNA was transcribed by RNA polymerase into viral RNA, which translated and replicated in a cell-free extract, resulting in the de novo synthesis of infectious poliovirus. Experiments in tissue culture using neutralizing antibodies and CD155 receptor-specific antibodies and neurovirulence tests in CD155 transgenic mice confirmed that the synthetic virus had biochemical and pathogenic characteristics of poliovirus. Our results show that it is possible to synthesize an infectious agent by in vitro chemical-biochemical means solely by following instructions from a written sequence.

Specific HIV-1 TAR RNA loop sequence and functional groups are required for human cyclin T1-Tat-TAR ternary complex formation

Replication of human immunodeficiency virus requires Tat protein which activates elongation of RNA polymerase II transcription at the HIV-1 promoter through interaction with the cyclin T1 (CycT1) subunit of the positive transcription elongation factor complex (P-TEFb). Tat binds directly through its transactivation domain to the CycT1 subunit of the P-TEFb and induces loop sequence specific binding of the P-TEFb onto nascent HIV-1 TAR RNA. By using a gel electrophoresis method and a comprehensive set of TAR loop mutants, we have identified the sequence and structural determinants for high-affinity CycT1-Tat-TAR ternary complex formation. Our results show that CycT1 and Tat binding to TAR RNA is highly cooperative, and a capacity of 85%, a Hill coefficient of 2.7, and a dissociation constant (K(D)) of 2.45 nM were observed. These results indicate that there are three binding sites on TAR RNA. CycT1 does not bind TAR RNA in the absence of Tat, and Tat binding to TAR, while detectable, is very inefficient in the absence of CycT1. It is conceivable that the CycT1-Tat heterodimer directly binds to TAR RNA in the U-rich RNA bulge region and this binding facilitates the interactions of the CycT1-Tat heterodimer at the other two sites in the RNA loop region. On the basis of our results, we suggest a model where CycT1 interacts with Tat protein and positions the protein complex to make contacts with the G34 region of the loop sequence; G34 is critical for CycT1-Tat binding and forms a C30.G34 base pair. Two functional groups, O6 and N7, at nucleotide positions 32 and 34 in the TAR loop are essential for CycT1-Tat interactions with TAR RNA. The identity of two nucleotides, U31 and G33, is not critical, but they contribute to the stabilization of the RNA-protein complex. The presence of a single-nucleotide bulge of A35 or C35 is essential for distortion of the backbone RNA structure as well as the accessibility of functional groups in the major groove of the double-helical region. CycT1-Tat interaction with TAR RNA represents another example of the flexibility and complexity of RNA structure involved in protein recognition.

Visualization by atomic force microscopy of tobacco mosaic virus movement protein-RNA complexes formed in vitro

The structure of complexes formed in vitro by tobacco mosaic virus (TMV)-coded movement protein (MP) with TMV RNA and short (890 nt) synthetic RNA transcripts was visualized by atomic force microscopy on a mica surface. MP molecules were found to be distributed along the chain of RNA and the structure of MP-RNA complexes depended on the molar MP:RNA ratios at which the complexes were formed. A rise in the molar MP:TMV RNA ratio from 20:1 to 60-100:1 resulted in an increase in the density of the MP packaging on TMV RNA and structural conversion of complexes from RNase-sensitive 'beads-on-a-string' into a 'thick string' form that was partly resistant to RNAse. The 'thick string'-type RNase-resistant complexes were also produced by short synthetic RNA transcripts at different MP:RNA ratios. The 'thick string' complexes are suggested to represent clusters of MP molecules cooperatively bound to discrete regions of TMV RNA and separated by protein-free RNA segments.

Probing Tat Peptide−TAR RNA Interactions by Psoralen Photo-Cross-Linking

Replication of human immunodeficiency virus type 1 (HIV-1) requires specific interactions of Tat protein with the trans-activation responsive region (TAR) RNA, a 59-base stem-loop structure located at the 5'-end of all HIV mRNAs. We have used a site-specific cross-linking method based on psoralen photochemistry to determine the effect of core residues from the Tat sequence on the protein orientation in the Tat-TAR complex and on the specificity of Tat-TAR binding. We synthesized two Tat fragments, Tat(42-72) and Tat(37-72), and incorporated a psoralen-modified amino acid at position 41 during solid-phase assembly of the peptides. We used these psoralen-Tat conjugates to form specific complexes with TAR RNA. Upon near-ultraviolet irradiation (360 nm), psoralen-Asp41-Tat(37-72) cross-linked to a single site in the TAR RNA sequence. The RNA-protein complex was purified and the cross-link site on TAR RNA was determined by primer extension analysis, which revealed that Asp41 of Tat is close to U42 of the lower stem region of TAR RNA. Specificity of the RNA-peptide cross-linking reactions was determined by competition experiments. Our results show that the addition of only four residues (Cys37-Thr40) from the Tat core region significantly enhanced the specificity of the Tat peptide-TAR interactions without altering the site or chemical nature of the cross-link. These studies provide new insights into RNA-protein recognition that could be useful in designing peptidomimetics for RNA targeting. Such psoralen-peptide conjugates provide a new class of probes for sequence-specific protein-nucleic acid interactions and could be used to selectively control gene expression or to induce site-directed mutations.

Bacteriophage T7 RNA polymerase transcription elongation is inhibited by site-specific, stereospecific benzo[c]phenanthrene diol epoxide DNA lesions

Benzo[c]phenanthrene diol epoxide (B[c]PhDE), the ultimate carcinogenic metabolite of the environmental pollutant benzo[c]phenanthrene, reacts with DNA primarily at the exocyclic amino groups of purines, forming B[c]PhDE-DNA adducts that differ in their stereochemical configurations and their effect on biological processes such as transcription. To determine the effect of these stereoisomers on RNA synthesis, in vitro T7 RNA polymerase transcription assays were performed using DNA templates modified on the transcribed strand by either a site-specific (+)-trans- or (-)-trans-anti-B[c]PhDE-N(6)-dA lesion located within the sequence 5'-CTCTCACTTCC-3'. The results show that both (-)-trans-anti-B[c]PhDE-N(6)-dA and (+)-trans-anti-B[c]PhDE-N(6)-dA block RNA synthesis. Furthermore, both B[c]PhDE-dA stereoisomeric adducts lead to lower levels of initiation of transcription relative to that observed using an unmodified DNA template. In contrast to these results, placement of the adduct on the nontranscribed strand within the template does not impede transcription elongation. In addition to the assessment of the effect of the lesions on transcription elongation, the resulting transcripts were characterized in terms of their base composition. A high level of base misincorporation is detected at the 3'-ends of truncated transcripts, with guanosine being most frequently incorporated opposite the modified nucleotide rather than the expected uridine. This result supports the notion that translocation past a modified base in a DNA template relies in part on correct base incorporation, and suggests that stalling of RNA polymerases at damaged sites in DNA may well be dependent on both the presence of the lesion and the base which is incorporated opposite the modified nucleotide.

Probing the kinetics of formation of the bacteriophage MS2 translational operator complex: identification of a protein conformer unable to bind RNA

We have investigated the kinetics of complex formation between bacteriophage MS2 coat protein subunits and synthetic RNA fragments encompassing the natural translational operator site, or the consensus sequences of three distinct RNA aptamer families, which are known to bind to the same site on the protein. Reactions were assayed using stopped-flow fluorescence spectroscopy and either the intrinsic tryptophan fluorescence of the protein or the signals from RNA fragments site-specifically substituted with the fluorescent adenosine analogue 2'-deoxy, 2-aminopurine. The kinetics observed were independent of the fluorophore being monitored or its position within the complex, indicating that the data report global events occurring during complex formation. Competition assays show that the complex being formed consists of a single coat protein dimer and one RNA molecule. The binding reaction is at least biphasic. The faster phase, constituting 80-85 % of the amplitude, is a largely diffusion driven RNA-protein interaction (k1 approximately 2x10(9) M(-1) s(-1)). The salt dependence of the forward reaction and the similarities of the on-rates of lower-affinity RNA fragments are consistent with a diffusion-controlled step dominated by electrostatic steering. The slower phase is independent of reactant concentration, and appears to correspond to isomerisation of the coat protein subunit(s) prior to RNA binding (k(iso) approximately 0.23 s(-1)). Measurements with a coat protein mutant (Pro78Asn) show that this phase is not due to cis-trans isomerisation at this residue. The conformational changes in the protein ligand during formation of an RNA-protein complex might play a role in the triggering of capsid self-assembly and a model for this is discussed.

Conserved stem-loop structures in the HIV-1 RNA region containing the A3 3' splice site and its cis-regulatory element: possible involvement in RNA splicing

The HIV-1 transcript is alternatively spliced to over 30 different mRNAs. Whether RNA secondary structure can influence HIV-1 RNA alternative splicing has not previously been examined. Here we have determined the secondary structure of the HIV-1/BRU RNA segment, containing the alternative A3, A4a, A4b, A4c and A5 3' splice sites. Site A3, required for tat mRNA production, is contained in the terminal loop of a stem-loop structure (SLS2), which is highly conserved in HIV-1 and related SIVcpz strains. The exon splicing silencer (ESS2) acting on site A3 is located in a long irregular stem-loop structure (SLS3). Two SLS3 domains were protected by nuclear components under splicing condition assays. One contains the A4c branch points and a putative SR protein binding site. The other one is adjacent to ESS2. Unexpectedly, only the 3' A residue of ESS2 was protected. The suboptimal A3 polypyrimidine tract (PPT) is base paired. Using site-directed mutagenesis and transfection of a mini-HIV-1 cDNA into HeLa cells, we found that, in a wild-type PPT context, a mutation of the A3 downstream sequence that reinforced SLS2 stability decreased site A3 utilization. This was not the case with an optimized PPT. Hence, sequence and secondary structure of the PPT may cooperate in limiting site A3 utilization.

Central role of double-stranded RNA-activated protein kinase in microbial induction of nitric oxide synthase

NO synthase 2 (NOS2) is induced in airway epithelium by influenza virus infection. NOS2 induction late in the course of viral infection may occur in response to IFN-gamma, but early in infection gene expression may be induced by the viral replicative intermediate dsRNA through the dsRNA-activated protein kinase (PKR). Since PKR activates signaling pathways important in NOS2 gene induction, we determined whether PKR is a component in the signal transduction pathway leading to NOS2 gene expression after viral infection of airway epithelium. We show that NOS2 gene expression in human airway epithelial cells occurs in response to influenza A virus or synthetic dsRNA. Furthermore, dsRNA leads to rapid activation of PKR, followed by activation of signaling components including NF-kappaB and IFN regulatory factor 1. NOS2 expression is markedly diminished and IFN regulatory factor 1 and NF-kappaB activation are substantially impaired in PKR null cells. Strikingly, NOS2 induction in response to LPS is abolished in PKR null cells, confirming a central role for PKR in the general signaling pathway to NOS2.

Selective binding of hepatitis C virus core protein to synthetic oligonucleotides corresponding to the 5' untranslated region of the viral genome

Although it is assumed that hepatitis C virus (HCV) core protein binds with viral RNA to form a nucleocapsid, little is known about the resulting molecular interactions. We utilized surface plasmon resonance technology to study the structural basis of the affinity and the preference of the interaction between HCV core protein and oligonucleotides derived from the viral genome. Among the 10 oligonucleotides corresponding to the 5' untranslated region (5'UTR) of the tested HCV genome, the real-time analysis of sensorgrams indicated that the core protein binds most efficiently and stably to the 31-nucleotide-long sequence of the loop IIId domain, whose secondary structure is highly conserved not only among different HCV genotypes but also among pestiviruses. There also could be some interactions of the core protein with the loop I domain and the region of nt 23-41. The kinetic profiles, together with those obtained in experiments using single- and double-stranded polymeric oligonucleotides, suggest a multimerization of the core protein in solution. These newly characterized properties could provide a basis for understanding the pathway of the viral nucleocapsid assembly.

Sequential folding of the genomic ribozyme of the hepatitis delta virus: structural analysis of RNA transcription intermediates

The structures of the model oligoribonucleotides that mimic the consecutive stages in the transcription of genomic HDV ribozyme have been analyzed by the Pb(2+)-induced cleavage method, partial digestion with specific nucleases and chemical probing. In the transcription intermediates, the P1 and P4 helical segments are found to be present in the final folded forms in which they exist in the full-length transcript. However, the region corresponding to the central hairpin forms another thermodynamically stable hairpin structure. Its correct folding requires the presence of a ribozyme 3'-terminal sequence and the formation of helix P2. This confirms the ribozyme structure of the pseudoknot type and points to the crucial role of helix P2 in its overall folding. Moreover, we show that the J4/2 region can be specifically cleaved in the presence of selected divalent metal ions in the full-length transcript, but not in a shorter one lacking six 3'-terminal nucleotides, which cannot form the pseudoknotted structure. Thus, a particular RNA conformation around that cleavage site is required for specific hydrolysis, and the J4/2 region seems to be involved in the formation of a general metal ion binding site. Recently, it has been proposed that, in the antigenomic ribozyme, a four nucleotide sequence within the J1/2 region may contribute to the folding pathway, being part of a mechanism responsible for controlling ribozyme cleavage activity. Our study shows that in the genomic ribozyme the central hairpin region may contribute to a similar mechanism, providing a barrier to the formation of an active structure in the ribozyme folding pathway.

In vitro-synthesized infectious RNA as an attenuated live vaccine in a flavivirus model

Live virus vaccines have in many cases proven to be an extremely effective tool for the prevention of viral diseases. However, the production of conventional live vaccines in eukaryotic cell cultures has many disadvantages, including the potential for contamination with adventitious agents and genetic alterations during propagation, making it necessary to do extensive testing before distribution. Based on results obtained with a flavivirus (tick-borne encephalitis virus) in an experimental animal system, we propose a novel live attenuated virus vaccination strategy consisting of the application of in vitro-synthesized infectious RNA instead of the live virus itself. When administered using the GeneGun, less than 1 ng of RNA was required to initiate replication of virus that was attenuated by a specifically engineered deletion and this induced a protective immunity in laboratory mice. Because this approach uses RNA, it does not have the potential drawbacks of DNA vaccines and thus combines the advantages of conventional live virus vaccines (for example, mimicking natural infection and inducing long-lasting immunity) with those of nucleic acid-based vaccines (for example, ease of production without a requirement for eukaryotic cell culture, stability and purity).

Rapid detection of enteroviral RNA in cerebrospinal fluid (CSF) from patients with aseptic meningitis by reverse transcription-nested polymerase chain reaction

The aim of this study was to compare conventional enterovirus isolation with rapid detection of enteroviral RNA by a reverse transcription-nested polymerase chain reaction (RT-nPCR) method amplifying the 5' nontranslated region of the enteroviral genome in specimens from patients with aseptic meningitis. Reference enterovirus strains and clinical enterovirus isolates were analyzed to evaluate assay sensitivity and specificity. All known enteroviral serotypes tested, but one (echovirus type 22), were detected by RT-nPCR. A series of unrelated viral isolates as well as CSF samples from patients with meningitis/encephalitis or neurological syndromes unrelated to enterovirus infection were included as controls. A total of 47 specimens (31 CSF, 12 rectal swabs, 4 throat swabs) from 30 patients with aseptic meningitis were available for the study. Of the 31 CSF samples tested from 30 patients, 17 from 17 patients (54.8%) were positive by RT-nPCR, while only 10 from 10 patients (32.2%) were positive by culture. Thus, RT-nPCR allowed diagnosis of enterovirus meningitis in 7 additional patients compared to cell culture. The cytopathic effect was observed 5-15 days after inoculation of CSF specimens onto cell cultures, while direct detection of viral RNA in CSF samples by RT-nPCR permitted diagnosis of enteroviral meningitis within 1-2 days. On the whole, viral isolation was positive in 12/47 (25.5%) specimens, whereas viral RNA was detected by RT-nPCR in 11 additional samples (23/47, 48.9%). Specimens of the control group were consistently negative by both viral isolation and RT-nPCR. Restriction endonuclease analysis of PCR products (RFLP) was applied to differentiate poliovirus (PV) from non-polio enteroviruses (NPEV). All enterovirus strains detected in clinical samples (n = 23) were identified as NPEV by RFLP. Clinical isolates were typed by neutralization as echovirus type 30 (n = 6), while 6 were not typed. In conclusion, detection of enteroviral RNA in CSF by RT-nPCR allows: i) rapid diagnosis of enteroviral meningitis; ii) increased sensitivity with respect to virus isolation; iii) differentiation between PV and NPEV infections of the central nervous system.

Pre-steady-state kinetic characterization of RNA-primed initiation of transcription by HIV-1 reverse transcriptase and analysis of the transition to a processive DNA-primed polymerization mode

Single-turnover and equilibrium measurements were carried out to determine the basis of the apparently slow, nonprocessive polymerization reaction catalyzed by HIV-1 reverse transcriptase (RT) during transcription initiation, when both the primer and template are composed of RNA. Comparison of the binding and kinetic parameters of a 20-mer, all-RNA primer/35-mer template substrate to one identical in sequence but composed of a 20-mer, all-DNA primer/35-mer RNA template reveals striking differences. Equilibrium titrations yielded a dissociation constant (Kd) >200 nM for the RNA/RNA-RT complex which is at least 200-fold higher than that of the DNA/RNA-substrate (Kd approximately 1 nM). The affinity of the RT-RNA/RNA complex for dTTP was found to be at least 500 times lower (Kd approximately 3.4 mM) than that of the RT-DNA/RNA complex (Kd approximately 6.6 microM). The single-turnover dNTP incorporation time course using the RNA-primer substrate, the DNA-primer substrate, or a series of RNA-primer substrates preextended with one to eight deoxynucleotides showed that dNTP incorporation occurs with a biphasic exponential burst of +1 extension product, followed by a linear phase. At least three different RT-bound forms of the p/ts exist: a fast, kinetically competent form (single-turnover rate approximately 10-50 s-1); a slow form (rate approximately 0.3-1 s-1); and a form that is dead-end (no turnover). The studies further revealed that a switch to a fast, kinetically competent p/t occurs after six dNTPs are incorporated into the RNA primer, with the switch being defined as the transition from a minority to a majority of the p/t bound in the optimal manner.

Synthesis of full-length potyvirus cDNA copies suitable for the analysis of genome polymorphism

New methods facilitating the synthesis and amplification of full-length cDNA copies of single-stranded viral RNA genomes have been developed. A method is described for the efficient purification of potyviral RNA and total RNA from infected plants and it is shown that they can serve as templates for the efficient synthesis of a full-length, 10 kb long, genomic cDNA. Two different reverse transcriptases were used (AMV-RT and MMLV-RT); only the first reverse transcriptase produced a good quality, full-length cDNA using viral RNA as a template. Surprisingly, MMLV-RT allowed for the full-length cDNA synthesis on virions rather than viral RNA. The PVY cDNA, synthesized using either RNA or virions, can be amplified successfully by PCR with high yields of full-length products. Such products are good substrates for the study by RFLP of the total genome polymorphism of virus isolates.

Synthesis and purification of single-stranded RNA for use in experiments with PKR and in cell-free translation systems

The biosynthesis of RNA in vitro using bacteriophage RNA polymerases has opened up many avenues of research. Large amounts of specific RNA species can be readily produced but small amounts of contaminants that are simultaneously generated can interfere with biological assays, PKR, a ribosome-associated and double-stranded (ds) RNA-dependent protein kinase, is an important regulator of the initiation of protein synthesis. It can be activated by very low concentrations of dsRNA and inhibited by small structured RNAs or high concentrations of dsRNA. The best-studied inhibitor of PKR activation is adenovirus VA RNA1. Its gene was cloned into a plasmid under the control of the T7 RNA polymerase promoter, and the optimization of VA RNA transcription is described. A dsRNA by-product of the transcription reaction activates PKR in kinase autophosphorylation assays, and hence a purification protocol that allows the separation and removal of dsRNA contaminants was developed. A scheme to analyze the RNA product with specific nucleases is discussed. In a reticulocyte cell-free translation system the activation of PKR by dsRNA contaminating a synthetic mRNA preparation is likely to lead to shut-off of translation. An assay to directly visualize and measure the level of PKR phosphorylation in the lysate is detailed.

Characterization of synthetic foot-and-mouth disease virus provirions separates acid-mediated disassembly from infectivity

One of the final steps in the maturation of foot-and-mouth disease virus (FMDV) is cleavage of the VP0 protein to produce VP4 and VP2. The mechanism of this cleavage is unknown, but it is thought to function in stabilizing the virus particle and priming it for infecting cells. To investigate the cleavage process and to understand its role in virion maturation, we engineered synthetic FMDV RNAs with mutations at Ala-85 (A85) and Asp-86 (D86) of VP0, which border the cleavage site. BHK cells transfected with synthetic RNAs containing substitutions at position 85 (A85N or A85H) or at position 86 (D86N) yielded particles indistinguishable from wild-type (WT) virus in sedimentation and electrophoretic profiles. Viruses derived from these transfected cells were infectious and maintained their mutant sequences upon passage. However, BHK cells transfected with synthetic RNAs encoding Phe and Lys at these positions (A85F/D86K) or a Cys at position 86 (D86C) produced noninfectious provirions with uncleaved VP0 molecules. Despite their lack of infectivity, the A85F/D86K provirions displayed cell binding and acid sensitivity similar to those of WT virus. However, acid breakdown products of the A85F/D86K provirions differed in hydrophobicity from the comparable WT virion products, which lack VP4. Taken together, these studies are consistent with a role for soluble VP4 molecules in release of the viral genome from the endosomal compartment of susceptible cells.

Thermodynamics of folding of the RNA pseudoknot of the T4 gene 32 autoregulatory messenger RNA

Nucleotides U(-67) to C(-40) at the extreme 5' end of the gene 32 mRNA in bacteriophage T4 have been shown to fold into an RNA pseudoknot proposed to be important for translational autoregulation. The thermal denaturation of three in vitro transcribed RNAs corresponding to the pseudoknot region has been investigated as a function of Mg2+ concentration to begin to elucidate the determinants of the structure and stability of this conformation. T4-35 is a 35-nucleotide RNA containing a 5' G followed by the natural T4 sequence starting with the mature 5' end of the mRNA, nucleotides A(-71) to C(-38). A 32-nucleotide RNA, termed T4-32, contains the native sequence form U(-67) to C(40) with 5'GC and 5'CA single-stranded regions appended to the 5' and 3' ends of the core sequence, respectively. T4-28 contains only the 28 core nucleotides, and the predicted closing U(-67)-A(-52) base pair in stem 1 has been replaced with a phylogenetically allowed G(-67)-C(-52) base pair. Ribonuclease mapping of T4-32 and imino proton NMR experiments of T4-35 show that both sequences adopt a pseudoknotted conformation. At pH 6.9 and 50 mM NaCl, T4-35 and T4-32 RNAs are characterized by a single major melting transition over a wide range of [Mg2+] (0-6 mM). The delta H degree of unfolding for T4-35 and T4-32 shows a large dependence on Mg2+ concentration; the maximum delta H degree occurs at about 2.0 mM Mg2+ with further addition of Mg2+ simply increasing the tm. Investigation of the [Mg2+] dependence of the tm suggests that a net of one Mg2+ ion is released upon denaturation of T4-35 and T4-32 RNAs. Over the entire [Mg2+] range, the delta G degree (37 degrees C) for the folding of T4-35 is consistently 1-1.5 kcal mol(-1) more negative than T4-32 due to a higher stabilization enthalpy for the natural sequence molecule. In contrast to this behavior, T4-28 gives consistently higher tm's but less negative enthalpies and is destabilized (at 37 degrees C) by about 0.5-1.5 kcal mol(-1) relative to T4-32 and by about 2-3 kcal mol(-1) relative to T4-35, depending upon cation concentration. (1)H NMR experiments suggest that, even in the presence of 4.0 mM Mg2+, T4-28 RNA does not adopt a stable pseudoknotted conformation. These data show that the stability of the pseudoknot in the gene 32 mRNA encoded by the 28-nucleotide core sequence is significantly influenced by the number and nature of the immediately adjacent "single-stranded" 5' and/or 3' nucleotides appended to the core structure. These findings are discussed within the context of the structural model for the evolutionarily related phage T2 and T6 gene 32 mRNA pseudoknots presented in the following paper [Du, Z., Giedroc, D. P., & Hoffman, D. W. (1996) Biochemistry 35, 4187-4198].

Ionic interactions and the global conformations of the hammerhead ribozyme

Here we investigate the global conformation of the hammerhead ribozyme. Electrophoretic studies demonstrate that the structure is folded in response to the concentration and type of ions present. Folding based on colinear alignment of arms II and III is suggested, with a variable angle subtended by the remaining helix I. In the probable active conformation, a small angle is subtended between helices I and II. Using uranyl photocleavage, an ion binding site has been detected in the long single-stranded region. The folded conformation could generate a preactivation of the scissile bond to permit in-line attack of the 2'-hydroxyl group, with a bound metal ion playing an integral role in the chemistry.

In vivo transfection by hepatitis A virus synthetic RNA

Marmosets injected intrahepatically with nucleic acids (cDNA and RNA transcripts) representing the full-length genome of the wild-type HM-175 strain of hepatitis A virus experienced acute hepatitis and seroconversion to hepatitis A virus capsid proteins. The hepatitis was comparable in severity to that caused by infection with the wild-type virus. The viral cDNA and the hepatitis A virus recovered from the feces of an injected animal contained the same marker mutation. Therefore, intermediate cell culture steps can be omitted and the virulence of a hepatitis A virus encoded by a cDNA clone can be evaluated by direct transfection of marmosets.

Homologous RNA recombination allows efficient introduction of site-specific mutations into the genome of coronavirus MHV-A59 via synthetic co-replicating RNAs

We describe a novel strategy to site-specifically mutagenize the genome of an RNA virus by exploiting homologous RNA recombination between synthetic defective interfering (DI) RNA and viral RNA. Marker mutations introduced in the DI RNA were replaced by the wild-type residues during replication. More importantly, however, these genetic markers were introduced into the viral genome; even in the absence of positive selection, MHV recombinants were isolated. This finding provides new prospects for the study of coronavirus replication using recombinant DNA techniques. As a first application, we describe the rescue of the temperature sensitive mutant MHV Albany-4 using DI-directed mutagenesis. Possibilities and limitations of this strategy are discussed.

An 'elaborated' pseudoknot is required for high frequency frameshifting during translation of HCV 229E polymerase mRNA

The RNA polymerase gene (gene 1) of the human coronavirus 229E is approximately 20 kb in length and is located at the 5' end of the positive-strand genomic RNA. The coding sequence of gene 1 is divided into two large open reading frames, ORF1a and ORF1b, that overlap by 43 nucleotides. In the region of the ORF1a/ORF1b overlap, the genomic RNA displays two elements that are known to mediate (-1) ribosomal frameshifting. These are the slippery sequence, UUUAAAC, and a 3' pseudoknot structure. By introducing site-specific mutations into synthetic mRNAs, we have analysed the predicted structure of the HCV 229E pseudoknot and shown that besides the well-known stem structures, S1 and S2, a third stem structure, S3, is required for a high frequency of frameshifting. The requirement for an S3 stem is independent of the length of loop 2.

Rescue of synthetic analogs of genome RNA of human parainfluenza virus type 3

A simple system that allows expression and packaging of a foreign gene by human parainfluenza virus type 3 (HPIV-3) has been described. First, a cDNA was constructed to encode an internally deleted version of HPIV-3 genome RNA. The viral genes were replaced with a negative sense copy of the bacterial chloramphenicol acetyl transferase (CAT) reporter gene. In vitro run-off transcription with T7 RNA polymerase synthesized an 870 nucleotide RNA that contained the antisense coding region of the CAT gene flanked by the transcription regulatory sequences and the 3' and 5' end extracistronic sequences of the HPIV-3 genome. When introduced into cells that are infected with HPIV-3, this RNA was amplified and the reporter gene was expressed, as measured by the CAT activity in the cell extract. Furthermore, the synthetic RNA was packaged into infectious virions. The addition of two extra nucleotides at the 5' end of the parental trailer region decreased the CAT activity by more than 90%, suggesting a requirement for the intact 5'-regulatory domain in the viral replicative cycle. Interestingly, the addition of one extra nucleotide to the 3' end totally abolished the CAT activity indicating that an exact 3' terminus is critical in this process.

Design and synthesis of RNA miniduplexes via a synthetic linker approach. 2. Generation of covalently closed, double-stranded cyclic HIV-1 TAR RNA analogs with high Tat-binding affinity

We recently developed an approach which allows rapid generation of short, double-stranded oligonucleotides whereby one end of the duplex was joined and stabilized by a synthetic linker of specific design (miniduplexes)(6). Model miniduplexes based on the HIV-1 TAR RNA hairpin were shown to be thermodynamically stable and good substrates for binding by the HIV-1 Tat protein which normally bind to natural TAR (6). In this study, we have extended our studies to the design, synthesis and analysis of the binding properties of covalently closed, double-stranded, cyclic RNA miniduplexes. A strategy using automated chemical synthesis and T4 RNA ligase-catalyzed cyclization was employed to generate cyclic oligoribonucleotides. When both ends of a shortened, wild-type TAR RNA stem (9 bp) were covalently linked through either nucleotidic loops (4-6 nt) or synthetic linkers (derivatized from hexaethylene glycol), the resulting cyclic TAR RNA analogs were good substrates for binding by both Tat-derived peptide or full-length Tat protein. Interestingly, the cyclic TAR analogs failed to show any binding if the synthetic linker was reduced in length (e.g. derivatized from triethylene glycol), although such linkers are acceptable in the hairpin-shaped miniduplexes series (6). This implies that RNA conformational changes are required for Tat binding and that these changes are restricted in certain cyclic variants. Our findings suggest that covalently-closed nucleic acid miniduplexes may be useful both to study nucleic acid-protein interactions as well as to provide a basis for therapeutic intervention as transcription decoys.

Selective isotopic enrichment of synthetic RNA: application to the HIV-1 TAR element

The introduction of isotopically enriched nucleotides into NMR quantities of a synthetic 29-mer RNA derived from the HIV-1 TAR element is described. RNA enriched in 13C and/or 15N is produced by a procedure which involves isolation of whole cellular RNA from Escherichia coli, nucleolysis, separation of mononucleotides, chemical or enzymatic pyrophosphorylation, and in vitro transcription by T7 RNA polymerase. Spectral characteristics of each residue type are examined in isolation. 13C chemical shifts provide an alternative method to determine ribose puckers for larger RNAs. Nonprotonated sites such as purine N7 groups can now be monitored through the use of multiple-bond 1H-15N coupling. When applied conservatively, coordinate analysis of chemical shift values should prove valuable for NMR studies of RNA structure and recognition. 1H, 13C, and 15N chemical shift data suggest that TAR residue A35 has an unusual local environment, consistent with extrusion of its base from the terminal loop.

Assembly and transcription of synthetic vesicular stomatitis virus nucleocapsids

The functional template for transcription of vesicular stomatitis virus (VSV) RNA is a ribonucleoprotein particle (nucleocapsid) consisting of the negative-strand sense genomic RNA completely encapsidated by the viral nucleocapsid (N) protein. As an approach to create nucleocapsids in vitro, we demonstrate here the specific encapsidation by purified N protein of in vitro-synthesized RNA sequences representing the 5' end of both the negative- and positive-strand VSV genome-length RNAs. As few as 19 nucleotides from the 5'-end of positive-strand RNA allowed maximal encapsidation, although the 5' terminal 10 nucleotides would allow partial (50%) encapsidation. Sequences downstream of the binding site can be of any origin. Specific encapsidation of VSV sequences was dependent on the presence of uninfected cell cytoplasmic extracts or poly(A). The synthetic nucleocapsids have the properties of RNase resistance and a buoyant density typical of wild-type VSV nucleocapsids. We have encapsidated a synthetic virionlike RNA species which contained just the terminal sequences of the virion RNA: the N encapsidation signal from the 5' end and the leader gene from the 3' end. This assembled nucleocapsid could function in vitro as a transcription template for the VSV RNA polymerase.

In vitro-synthesized hepatitis delta virus RNA initiates genome replication in cultured cells

Monomers of the genomic strand of hepatitis delta virus RNA were transcribed in vitro and then delivered to NIH 3T3 fibroblasts by using a liposome fusion technique. After 7 days, genome replication was detected, but only in fibroblasts that stably expressed the delta antigen. Sequence analysis of the replicated products identified them as faithful copies of the hepatitis delta virus genome found in virions.

Chemical synthesis of the 24 RNA fragments corresponding to hop stunt viroid

A general and practical synthetic method of oligoribonucleotides (10-20 mers) by using the cyanoethyl phosphoramidite approach was described. In this experiment 9-phenylxanthen-9-yl (Pix) and 9-(4-methoxy)phenylxanthen-9-yl (Mox) groups were employed for the 5'-hydroxyls and tetrahydropyranyl (Thp) group was used for the 2'-hydroxyl protecting groups. In addition, suitable acyl groups were introduced for the protection of the lactam functions of guanine and uracil moieties.

Mutational analysis of the genome-linked protein VPg of poliovirus

Using a mutagenesis cartridge (R. J. Kuhn, H. Tada, M. F. Ypma-Wong, J. J. Dunn, B. L. Semler, and E. Wimmer, Proc. Natl. Acad. Sci. USA 85:519-523, 1988), we have generated single and multiple amino acid replacement mutants, as well as a single amino acid insertion mutant in the genome-linked protein VPg of poliovirus. Moreover, we constructed three different 5-amino-acid insertion mutants that map close to the C terminus of 3A, a viral polypeptide whose coding sequence is adjacent to VPg. Transfection of HeLa cells with RNA synthesized in vitro was used to test the effect of the mutation on viral proliferation. Mutations were either lethal or nonlethal. A temperature-sensitive phenotype was not observed. The arginine at position 17 of VPg could not be exchanged with any other amino acid without loss of viability, whereas the lysine at position 20, an amino acid conserved among all known polioviruses, coxsackieviruses, and echoviruses, was replaceable with several neutral amino acids and even with glutamic acid. Replacement of poliovirus VPg with echovirus 9 VPg yielded viable virus with impaired growth properties. Our results suggest considerable flexibility in the amino acid sequence of a functional VPg. All insertions in polypeptide 3A proved to be lethal. In vitro translation of mutated viral RNAs gave patterns of proteolytic processing that in some cases was aberrant, even though the mutation was nonlethal.

Interaction of R17 coat protein with synthetic variants of its ribonucleic acid binding site

The specificity of the interaction between R17 coat protein and its site of translational repression on R17 RNA was studied by enzymatically synthesizing 23 sequence variants of the RNA binding site and measuring their affinity to the coat protein by a nitrocellulose filter binding assay. Experiments using oligomers truncated on the 3' and 5' termini allowed precise determination of the edges of the binding domain. Several oligomers which disrupted one or more of the base pairs in the binding site failed to bind coat protein, establishing the importance of RNA secondary structure for the interaction. Substitution at two single-stranded positions with each of the common bases affected Ka very differently. In one case, Ka was reduced substantially no matter which base was substituted for an adenine. At the other position, when a uracil was substituted with a purine, Ka decreased 10-100-fold, whereas when it was substituted by a cytosine, Ka increased about 5-fold. These studies indicate that the protein and the RNA hairpin loop interact over an extensive area and that several different types of contacts form to stabilize the complex.