LGP2 binds to PACT to regulate RIG-I- and MDA5-mediated antiviral responses

The retinoic acid-inducible gene I (RIG-I)-like receptors (RLRs) RIG-I, MDA5, and LGP2 stimulate inflammatory and antiviral responses by sensing nonself RNA molecules produced during viral replication. Here, we investigated how LGP2 regulates the RIG-I- and MDA5-dependent induction of type I interferon (IFN) signaling and showed that LGP2 interacted with different components of the RNA-silencing machinery. We identified a direct protein-protein interaction between LGP2 and the IFN-inducible, double-stranded RNA binding protein PACT. The LGP2-PACT interaction was mediated by the regulatory C-terminal domain of LGP2 and was necessary for inhibiting RIG-I-dependent responses and for amplifying MDA5-dependent responses. We described a point mutation within LGP2 that disrupted the LGP2-PACT interaction and led to the loss of LGP2-mediated regulation of RIG-I and MDA5 signaling. These results suggest a model in which the LGP2-PACT interaction regulates the inflammatory responses mediated by RIG-I and MDA5 and enables the cellular RNA-silencing machinery to coordinate with the innate immune response.

The Fate of Mengovirus on Fiberglass Filter of Air Handling Units

One of the most important topics that occupy public health problems is the air quality. That is the reason why mechanical ventilation and air handling units (AHU) were imposed by the different governments in the collective or individual buildings. Many buildings create an artificial climate using heating, ventilation, and air-conditioning systems. Among the existing aerosols in the indoor air, we can distinguish the bioaerosol with biological nature such as bacteria, viruses, and fungi. Respiratory viral infections are a major public health issue because they are usually highly infective. We spend about 90% of our time in closed environments such as homes, workplaces, or transport. Some studies have shown that AHU contribute to the spread and transport of viral particles within buildings. The aim of this work is to study the characterization of viral bioaerosols in indoor environments and to understand the fate of mengovirus eukaryote RNA virus on glass fiber filter F7 used in AHU. In this study, a set-up close to reality of AHU system was used. The mengovirus aerosolized was characterized and measured with the electrical low pressure impact and the scanner mobility particle size and detected with RT-qPCR. The results about quantification and the level of infectivity of mengovirus on the filter and in the biosampler showed that mengovirus can pass through the filter and remain infectious upstream and downstream the system. Regarding the virus infectivity on the filter under a constant air flow, mengovirus was remained infectious during 10 h after aerosolization.

A Novel High-Throughput Method for Molecular Detection of Human Pathogenic Viruses Using a Nanofluidic Real-Time PCR System

Human enteric viruses are recognized as the main causes of food- and waterborne diseases worldwide. Sensitive and quantitative detection of human enteric viruses is typically achieved through quantitative RT-PCR (RT-qPCR). A nanofluidic real-time PCR system was used to develop novel high-throughput methods for qualitative molecular detection (RT-qPCR array) and quantification of human pathogenic viruses by digital RT-PCR (RT-dPCR). The performance of high-throughput PCR methods was investigated for detecting 19 human pathogenic viruses and two main process controls used in food virology. The conventional real-time PCR system was compared to the RT-dPCR and RT-qPCR array. Based on the number of genome copies calculated by spectrophotometry, sensitivity was found to be slightly better with RT-qPCR than with RT-dPCR for 14 viruses by a factor range of from 0.3 to 1.6 log₁₀. Conversely, sensitivity was better with RT-dPCR than with RT-qPCR for seven viruses by a factor range of from 0.10 to 1.40 log₁₀. Interestingly, the number of genome copies determined by RT-dPCR was always from 1 to 2 log₁₀ lower than the expected copy number calculated by RT-qPCR standard curve. The sensitivity of the RT-qPCR and RT-qPCR array assays was found to be similar for two viruses, and better with RT-qPCR than with RT-qPCR array for eighteen viruses by a factor range of from 0.7 to 3.0 log₁₀. Conversely, sensitivity was only 0.30 log₁₀ better with the RT-qPCR array than with conventional RT-qPCR assays for norovirus GIV detection. Finally, the RT-qPCR array and RT-dPCR assays were successfully used together to screen clinical samples and quantify pathogenic viruses. Additionally, this method made it possible to identify co-infection in clinical samples. In conclusion, given the rapidity and potential for large numbers of viral targets, this nanofluidic RT-qPCR assay should have a major impact on human pathogenic virus surveillance and outbreak investigations and is likely to be of benefit to public health.

Lower respiratory tract infection induced by a genetically modified picornavirus in its natural murine host

Infections with the picornavirus, human rhinovirus (HRV), are a major cause of wheezing illnesses and asthma exacerbations. In developing a murine model of picornaviral airway infection, we noted the absence of murine rhinoviruses and that mice are not natural hosts for HRV. The picornavirus, mengovirus, induces lethal systemic infections in its natural murine hosts, but small genetic differences can profoundly affect picornaviral tropism and virulence. We demonstrate that inhalation of a genetically attenuated mengovirus, vMC₀, induces lower respiratory tract infections in mice. After intranasal vMC₀ inoculation, lung viral titers increased, peaking at 24 h postinoculation with viral shedding persisting for 5 days, whereas HRV-A01a lung viral titers decreased and were undetectable 24 h after intranasal inoculation. Inhalation of vMC₀, but not vehicle or UV-inactivated vMC₀, induced an acute respiratory illness, with body weight loss and lower airway inflammation, characterized by increased numbers of airway neutrophils and lymphocytes and elevated pulmonary expression of neutrophil chemoattractant CXCR2 ligands (CXCL1, CXCL2, CXCL5) and interleukin-17A. Mice inoculated with vMC₀, compared with those inoculated with vehicle or UV-inactivated vMC₀, exhibited increased pulmonary expression of interferon (IFN-α, IFN-β, IFN-λ), viral RNA sensors [toll-like receptor (TLR)3, TLR7, nucleotide-binding oligomerization domain containing 2 (NOD2)], and chemokines associated with HRV infection in humans (CXCL10, CCL2). Inhalation of vMC₀, but not vehicle or UV-inactivated vMC₀, was accompanied by increased airway fluid myeloperoxidase levels, an indicator of neutrophil activation, increased MUC5B gene expression, and lung edema, a sign of infection-related lung injury. Consistent with experimental HRV inoculations of nonallergic, nonasthmatic human subjects, there were no effects on airway hyperresponsiveness after inhalation of vMC₀ by healthy mice. This novel murine model of picornaviral airway infection and inflammation should be useful for defining mechanisms of HRV pathogenesis in humans.

Synthesis of the allergen ovomucoid by a replicating Mengo virus

Interferons induced by viral infections can have powerful immuno- modulatory effects, and several epidemiologic studies have found an association between certain viral infections and reduced prevalence of allergy. We hypothesized that allergenic proteins could be synthesized by a replicating virus, and this construct could be useful as an immunomodulator. To test this hypothesis, we cloned an allergenic protein (ovomucoid [OVM]) into a murine picornavirus (Mengo virus) vector. This plasmid has a multicloning site surrounded by auto-catalytic sequences so that a foreign protein will be cleaved from viral proteins during replication. OVM sequences were cloned in the context of full-length viral genome cDNA, T7 RNA transcripts of this plasmid were transfected into HeLa cells, and recombinant virus plaques appeared on the second passage. Sequence analysis of recombinant viruses derived from individual plaques demonstrated that three viral isolates contained up to 2/3 of the OVM coding sequence, which was retained by the viruses after 5 additional passages in HeLa cells. The experiments verify the stable expression of immunoreactive OVM subunits by replicating viruses. These virus/allergen constructs could provide a tool to evaluate whether intracellular presentation of allergenic proteins in the context of a viral infection could prevent allergic sensitization upon re-challenge.

Dipyridamole reversibly inhibits mengovirus RNA replication

Dipyridamole is an effective inhibitor of cardiovirus growth in cell culture. The effects of dipyridamole on mengovirus replication in vivo and in vitro were examined in the hope the drug could be used as an experimental analog of the poliovirus inhibitor guanidine. Guanidine selectively inhibits poliovirus RNA synthesis but not RNA translation, and as such, has been a valuable research tool. Although guanidine does not inhibit cardiovirus infection, a compound with similar discriminatory characteristics would be experimentally useful for parallel work with these viruses. We found that mengovirus plaque formation in HeLa or L cells was inhibited nearly 100% by the presence of 80 muM dipyridamole. The inhibitory effect was reversible and targeted an early step in the replication cycle. Studies with luciferase-expressing mengovirus replicons showed that viral protein synthesis was unaffected by dipyridamole, and rather, RNA synthesis was the step targeted by the drug. This assessment was confirmed by direct analyses of viral translation and RNA synthesis activities in a Krebs-2-derived in vitro system that supported complete, infectious cardiovirus replication. In Krebs extracts, dipyridamole specifically inhibited viral RNA synthesis to more than 95%, with no concomitant effect on viral protein translation or polyprotein processing. The observed inhibition reversibly affected an early step in both minus-strand and plus-strand RNA synthesis, although inhibition of plus-strand synthesis was more profound than that of minus-strand synthesis. We conclude that dipyridamole is a potent experimental tool that readily distinguishes between cardiovirus translation and RNA replication functions.

Effects of some antiviral isatinisothiosemicarbazones on cellular and viral ribonucleic acid synthesis in Mengovirus-infected FL cells

Three antiviral isatinisothiosemicarbazones strongly inhibited the incorporation of [(3)H]uridine into the ribonucleic acid (RNA) of FL cells as a consequence of the inhibition of uridine transport. After prelabeling of cells at a low temperature (1 h at 16 C) with uptake of [(3)H]uridine into the acid-soluble nucleotide pool, the later addition of the test compounds revealed only a small or negligible influence on host-directed RNA synthesis. The pulse-labeled soluble nucleotide pool of FL cells was sufficient to give a gradual increase in incorporation into RNA over a period of 7 h. With the same method of prelabeling at the beginning of the experiment, it was also possible to detect virus-induced RNA synthesis in the presence of actinomycin D. In this way the specific inhibitory action of the three isatinisothiosemicarbazones on viral RNA synthesis could be demonstrated.

A wild-type porcine encephalomyocarditis virus containing a short poly(C) tract is pathogenic to mice, pigs, and cynomolgus macaques

Previous studies using wild-type Encephalomyocarditis virus (EMCV) and Mengo virus, which have long poly(C) tracts (61 to 146 C's) at the 5' nontranslated region of the genome, and variants of these viruses genetically engineered to truncate or substitute the poly(C) tracts have produced conflicting data on the role of the poly(C) tract in the virulence of these viruses. Analysis of the nucleotide sequence of an EMCV strain isolated from an aborted swine fetus (EMCV 30/87) revealed that the virus had a poly(C) tract that was 7- to 10-fold shorter than the poly(C) tracts of other EMCV strains and 4-fold shorter than that of Mengo virus. Subsequently, we investigated the virulence and pathogenesis of this naturally occurring short-poly(C)-tract-containing virus in rodents, pigs, and nonhuman primates. Infection of C57BL/6 mice, pigs, and cynomolgus macaques resulted in similar EMCV 30/87 pathogenesis, with the heart and brain as the primary sites of infections in all three animals, but with different disease phenotypes. Sixteen percent of EMCV 30/87-infected pigs developed acute fatal cardiac failure, whereas the rest of the pigs were overtly asymptomatic for as long as 90 days postinfection (p.i.), despite extensive myocardial and central nervous system (CNS) pathological changes. In contrast, mice infected with >/==" BORDER="0">4 PFU of EMCV 30/87 developed acute encephalitis that resulted in the death of all animals (n = 25) between days 2 and 7 p.i. EMCV 30/87-infected macaques remained overtly asymptomatic for 45 days, despite extensive myocardial and CNS pathological changes and viral persistence in more than 50% of the animals. The short poly(C) tract in EMCV 30/87 (CUC(5)UC(8)) was comparable to that of strain 2887A/91 (C(10)UCUC(3)UC(10)), another recent porcine isolate.

Genetic stability of attenuated mengovirus vectors with duplicate primary cleavage sequences

Short poly(C)-tract Mengoviruses have proven vaccine efficacy in many species of animals. A novel vector for the delivery of foreign proteins was created by insertion of a second autoproteolytic primary cleavage cassette linked to a multiple cloning site (MCS) into an attenuated variant of Mengo. Nineteen cDNAs from foreign sequences that ranged from 39 to 1653 bases were cloned into the MCS. The viral reading frame was maintained and translation resulted in dual, autocatalytic excision of the foreign peptides without disruption of any Mengo proteins. All cDNAs except those with the largest insertions produced viable virus. Active proteins such as GFP, CAT, and SIV p27 were expressed within infected cells. Relative to parental Mengo, the growth kinetics and genetic stability of each vector was inversely proportional to the size of the inserted sequence. While segments up to 1000 bases could be carried, inserts greater than 500-600 bases were usually reduced in size during serial passage. The limit on carrying capacity was probably due to difficulties in virion assembly or particle stability. Yet for inserts less than 500-600 bases, the Mengo vectors provided an effective system for the delivery of foreign epitopes into cells and mice.

Phenotypic characterization of three phylogenetically conserved stem-loop motifs in the mengovirus 3' untranslated region

An alignment of cardiovirus sequences led to the prediction of three conserved stem-loops in the 3' untranslated region (UTR) of mengovirus. Deletions of each stem were engineered in mengovirus cDNAs and also in mengovirus replicons, in which part of the viral capsid sequences were replaced with the firefly luciferase gene. The effect of deletion on RNA infectivity and plaque phenotype was evaluated after transfection of viral transcripts into HeLa cells or by luciferase assays of cellular extracts after transfection with RNA replicons. Stem I (mengovirus bases 7666 to 7687) was found to be dispensable for viral growth or exponential luciferase expression. Deletion of stem III (bases 7711 to 7721) was lethal to the virus, and the replicons were incapable of RNA synthesis. Deletion of stem II (DeltaII; bases 7692 to 7705) produced an intermediate phenotype, in that replicons had marginal RNA synthesis activity but transfection with genomic RNA usually failed to produce plaques after normal incubation times (31 h, 37 degrees C). In a few of the DeltaII transfections, however, plaques were observed after long incubation, especially if the cells received large amounts of RNA (3 microg per 3 x 10(6) cells). Viruses from two DeltaII-derived plaques were isolated and amplified. Their RNAs were converted into cDNA, sequenced, and mapped for genotype. Each maintained the DeltaII deletion and, in addition, had one or two reversion mutations, which were characterized by reverse genetics as responsible for the phenotypes. One reversion caused an amino acid change in the polymerase (3D(pol)), and the other was localized to the 3' UTR, upstream of stem I.

Characterization of genetically engineered mengoviruses in mice

We have shown that genetically engineered mengoviruses containing artificially shortened 5' noncoding poly(C) tracts (e.g., C0 or C13UC10) are dramatically attenuated in adult Swiss/ICR mice when compared to wild-type virus or to a genetically engineered virus containing a wild-type length poly(C) tract (C44UC10). To explore further the relationship between poly(C) tracts and virulence, we have conducted more extensive characterizations of several engineered viruses in the murine model. Both short and long poly(C) tract viruses were highly virulent in newborn mice, underscoring the importance of age in poly(C)-mediated attenuation. Virus vMC24, with a tract sequence of C13UC10, was as attenuated in 4-week-old BALB/c, C.C3-H2k/LiMcdJ, and DBA/2 mice as in Swiss/ICR mice. But it was more pathogenic for C57BL/6 mice, and highly virulent for C3H/Hej and C3H/Hen mice, demonstrating the importance of murine genotype. As expected from its virulence in all mouse strains, vMwt, with a poly(C) of C44UC10, induced higher levels of viremia than vMC24. The vMwt also induced higher levels of circulating interferon and had reduced pathogenicity in chemically immunosuppressed Swiss/ICR mice. Similar immunosuppression did not increase the virulence of vMC24. Collectively, the data suggest that endogenous immune components and the immune competence of the host play significant roles in determining the susceptibility of mice to mengovirus infection.

Quantitative and qualitative analyses of the immune responses induced by a multivalent minigene DNA vaccine

Vaccines containing minigenes - isolated antigenic epitopes encoded by short open reading frames - can, under certain circumstances, confer protective immunity upon the vaccinee. Here we evaluate the efficacy of the minigene vaccine approach using DNA immunization and find that, to be immunogenic, a minigene-encoded epitope requires a perfect "Kozak" translational initiation region. In addition, using intracellular cytokine staining, we show that immunization with a plasmid encoding a full-length protein induces epitope-specific CD8(+) T cells which are detectable directly ex vivo, and constitute approximately 2% of the vaccinee's splenic CD8(+) T cells. In contrast, such cells are undetectable directly ex vivo in recipients of a minigene vaccine. Nevertheless, the minigene plasmid does induce a low number of epitope-specific CD8(+) T cells, which can be amplified to detectable levels by in vivo stimulation. Indeed, 4 days after in vivo stimulation (by virus infection), all vaccinated mice - regardless of whether they had been vaccinated with the minigene or with the full-length gene - had similar numbers of epitope-specific CD8(+) T cells. However, despite these strong responses at 4 days post-infection, recipients of the minigene vaccine showed no enhanced ability to limit virus replication and dissemination. We therefore observe a dichotomy; minigene vaccinees are not protected, despite the presence of strong virus-specific immune responses at 4 days post-challenge. We suggest that the protective benefits of vaccination exert themselves very soon - perhaps within minutes or hours - after virus challenge. If the vaccine-induced immune response is too low to achieve this early protective effect, virus-specific T cells will expand rapidly, but ineffectually, leading to the strong but non-protective response measured at 4 days post-infection. Thus, vaccine-induced immunity should be monitored very early in infection, since the extent to which these responses may later be amplified is largely irrelevant to the protection observed.

Mengovirus and encephalomyocarditis virus poly(C) tract lengths can affect virus growth in murine cell culture

Many virulent aphthoviruses and cardioviruses have long homopolymeric poly(C) tracts in the 5' untranslated regions of their RNA genomes. A panel of genetically engineered mengo-type cardioviruses has been described which contain a variety of different poly(C) tract lengths. Studies of these viruses have shown the poly(C) tract to be dispensable for growth in HeLa cells, although the relative murine virulence of the viruses correlates directly and positively with tract length. Compared with wild-type mengovirus strain M, mutants with shortened poly(C) tracts grow poorly in mice and protectively immunize rather than kill recipient animals. In the present study, several murine cell populations were tested to determine whether, unlike HeLa cells, they allowed a differential amplification of viruses with long or short poly(C) tracts. Replication and cytopathic studies with four hematopoietically derived cell lines (CH2B, RAW 264.7, A20.J, and P815) and two murine fibroblast cell lines [L929 and L(Y)] demonstrated that several of these cell types indeed allowed differential virus replication as a function of viral poly(C) tract length. Among the most discerning of these cells, RAW 264.7 macrophages supported vigorous lytic growth of a long-tract virus, vMwt (C(44)UC(10)), but supported only substantially diminished and virtually nonlytic growth of vMC(24) (C(13)UC(10)) and vMC(0) short-tract viruses. The viral growth differences evident in all cell lines were apparent early and continuously during every cycle of virus amplification. The data suggest that poly(C) tract-dependent attenuation of mengovirus may be due in part to a viral replication defect manifest in similar hematopoietic-type cells shortly after murine infection. The characterized cultures should provide excellent tools for molecular study of poly(C) tract-mediated virulence.

Selective irreversible inactivation of replicating mengovirus by nucleoside analogues: a new form of viral interference

We describe the selective irreversible inhibition of mengovirus growth in cultured cells by a combination of two pyrrolopyrimidine nucleoside analogues, 5-bromotubercidin (BrTu) and tubercidin (Tu). At a concentration of 5 microgram/ml, BrTu reversibly blocked the synthesis of cellular mRNA and rRNA but did not inhibit either mengovirus RNA synthesis or multiplication. BrTu is a potent inhibitor of adenosine kinase, and low concentrations of BrTu (e.g., 0.5 microgram/ml), which did not by themselves inhibit cell growth, blocked phosphorylation of Tu and thus protected uninfected cells against irreversible cytotoxicity resulting from Tu incorporation into nucleic acids. In contrast, in mengovirus-infected cells, BrTu did not completely inhibit Tu incorporation into mengovirus RNA, allowing the formation of Tu-containing functionally defective polynucleotides that aborted the virus development cycle. This increased incorporation of Tu coupled to mengovirus infection could be attributed either to a reduction in the inhibitory action of BrTu and/or its nucleotide derivatives at the level of nucleoside and nucleotide kinases and/or, perhaps, to an effect upon the nucleoside transport system. The virus life cycle in nucleoside-treated cells progressed to the point of synthesis of negative strands and probably to the production of a few defective new positive strands. Irreversible virus growth arrest was achieved if the nucleoside mixture of BrTu (0.5 to 10 microgram/ml) and Tu (1 to 20 microgram/ml) was added no later than 30 min after virus infection and maintained for periods of 2 to 8 h. The cultures thus "cured" of mengovirus infection could be maintained and transferred for several weeks, during which they neither produced detectable virus nor showed a visible cytopathic effect; however, the infected and cured cells themselves, while metabolically viable, were permanently impaired in RNA synthesis and unable to divide. Although completely resistant to superinfecting picornaviruses, they retained the ability to support the growth of several other viruses (vaccinia virus, reovirus, and vesicular stomatitis virus), showing that cured cells had, in general, retained the metabolic and structural machinery needed for virus production. The resistance of cured cells to superinfection with picornaviruses seemed attributable neither to interferon action nor to destruction or blockade of virus receptors but more likely to the consumption of some host factor(s) involved in the expression of early viral functions during the original infection.

Genetically engineered Mengo virus vaccination of multiple captive wildlife species

Encephalomyocarditis virus (EMCV), has caused the deaths of many species of animals in zoological parks and research institutions. The Audubon Park Zoo, (New Orleans, Louisiana, USA) attempted vaccination of several species with a killed EMCV vaccine with mixed results. This paper reports an attempt at vaccination against EMCV using a genetically engineered, live attenuated Mengo virus (vMC0) at the Audubon Park Zoo and Miami Metro Zoo, (Miami, Florida, USA) from December 1996 to June 1997. Several species of animals were vaccinated with vMC0, which is serologically indistinguishable from the field strain of EMCV. Serum samples were taken at the time of vaccination and again 21 days later, then submitted for serum neutralization titers against EMCV. The vaccinate species included red capped mangebey (Cercocebus torquatus), colobus (Colobus guereza), angolan colobus (Colobus angolensis), ruffed lemur (Lemur variegatus ruber and Lemur variegatus variegatus), back lemur (Lemur macaco), ring-tailed lemur (Lemur catta), siamang (Hylobates syndactylus), diana guenon (Cercopithicus diana), spider monkey (Ateles geoffroyi), common marmoset (Callithrix jacchus), talapoin monkey (Cercopithecus talapoin), Brazilian tapir (Tapirus terrestris), Baird's tapir (Tapirus bairdii), Malayan tapir (Tapirus indicus), dromedary camel (Camelus dromedarius), bactrian camel (Camelus bactrianus), gerenuk (Litocranius walleri), guanaco (Lama glama guanicoe), black duiker (Cephalophus niger), Vietnamese potbellied pig (Sus scrofa), babirusa (Babyrousa babyrussa), collard peccary (Tayass tajacu), and African crested porcupine (Hystrix africaeaustralis). The vaccine response was variable, with high virus neutralizing antibody titer responses in some primate species and mixed to poor responses for other species. No ill effects were seen with vaccination.

Study of the immunogenicity of different recombinant Mengo viruses expressing HIV1 and SIV epitopes

Recombinant Mengo viruses expressing heterologous genes have proven to be safe and immunogenic in both mice and primates, and to be able to induce both humoral and cellular immune responses (Altmeyer et al., 1995, 1996). Several recombinant Mengo viruses expressing either a large region (aa 65-206) of the HIV1 nef gene product, or cytotoxic T lymphocyte (CTL) epitopic regions from the SIV Gag (aa 182-190), Nef (aa 155-178) and Pol (aa 587-601) gene products were engineered. The heterologous antigens were expressed either as fusion proteins with the Mengo virus leader (L) protein, or in cleaved form through autocatalytic cleavage by the foot-and-mouth disease virus 2A protein. Rhesus macaques and BALB/c mice inoculated with the Mengo virus SIV recombinants failed to develop CTL responses against the SIV gene products, while one of the HIV-Nef recombinants induced a weak CTL response in mice directed to an HIV1 Nef peptide spanning positions 182-198. In contrast, BALB/c mice immunized with vaccinia virus recombinants expressing HIV1 Nef developed a strong CTL response to the 182-198 peptide and also responded to a second peptide spanning positions 73-81. These results indicate that Mengo virus recombinants expressing HIV1 Nef and SIV CTL epitopes are weak immunogens. One of the fusion recombinants expressing SIV CTL epitopes failed to infect macaques even when used at high doses, while the recombinant expressing HIV1 Nef as a fusion protein failed to infect BALB/c mice. These results demonstrate that the expression of certain heterologous sequences as fusion proteins with L can result in the loss of the ability of the recombinant to infect normally susceptible animals.

Genetic analysis of mengovirus protein 2A: its function in polyprotein processing and virus reproduction

To examine the functional requirements of mengovirus 2A for virus reproduction, a series of mutants with overlapping deletions within the 2A region of mengovirus, and two chimeric constructs in which 2A is replaced either by Theiler's murine encephalomyelitis virus (TMEV) 2A or by coxsackie B3 virus (CBV3) 2Apro were generated. In vitro polyprotein synthesis showed that in both deletion mutants and the TMEV 2A chimeric construct, viral 3C protease (3Cpro)-mediated cleavage at the VP1-2A junction was disturbed, which resulted in decreased formation of mature capsid proteins and accumulation of the P1-2A precursor. 2Apro-mediated processing of the chimeric VP1-2Apro junction was highly efficient. Although the resulting L-P1 precursor was cleaved at the L-VP4 junction, further processing of the P1 precursor was abrogated. Two deletion mutant viruses and a TMEV 2A chimeric virus were obtained after transfection. The CBV 2Apro construct did not result in viable virus. Deletion mutant virus production was less than 3% compared to wild-type virus production, whereas chimeric virus production was reduced to 25%. Although inhibition of host-cell translation was identical in wild-type and mutant virus-infected cells, viral protein and RNA synthesis were reduced in cells infected with mutant virus, independently of the impaired P1-2A processing. It is concluded that mengovirus 2A may play a functional role in either virus translation or replication, and that the functional aspects of mengovirus and TMEV 2A cannot be exchanged. The results also confirm that the processing cascade of L-P1-2A occurs sequentially and is probably regulated by subsequent conformational transitions of the cleavage products after each proteolytic event. The sequential release of L and 2A may be essential in the context of their function in virus replication.

Tandem mengovirus 5' pseudoknots are linked to viral RNA synthesis, not poly(C)-mediated virulence

The RNA genomes from the cardioviruses, hepatoviruses, and aphthoviruses encode two to five tandem pseudoknots within their 5' untranslated regions. These pseudoknots lie adjacent to a pyrimidine-rich sequence, which in cardio- and aphthoviruses takes the form of a homopolymeric poly(C) tract. Seven deletion mutations within mengovirus pseudoknots PK(B) and PK(C) were created and characterized. tested in tissue culture, mengovirus genomes with alterations in PK(C) were viable but had small plaque phenotypes. Larger plaque revertants were isolated and partially characterized, and each proved to be a second-site pseudorevertant with (unmapped) changes elsewhere in the genome. The infectious PK(C) mutant viruses were highly lethal to mice, and deletions in this motif did not affect mengovirus virulence in the same manner as deletions in the adjacent poly(C) tract. In contrast, deletions in PK(B), or deletions which spanned PK(B) + PK(C), produced nonviable genomes. Cell-free translations directed by any of the altered PK sequences gave normal polyprotein amounts relative to wild-type mengovirus. But viral RNA accumulation during HeLa cell infection was dramatically impaired, even with the least disruptive of the PK(C) changes, suggesting the pseudoknots play an essential though undefined role in RNA synthesis and moreover that an intact PK(B) structure is critical to this function.

The immunogenic and pathogenic potential of short poly(C) tract Mengo viruses

We have shown previously that genetically engineered Mengo viruses with artificial deletions in their 5' noncoding polyribocytidylic acid (poly(C)) tracts are highly attenuated for the natural murine host and also for other animals such as baboons, macaques, and domestic pigs. The present report further characterizes select short poly(C) tract Mengo viruses in the natural murine host. A positive correlation was found between the length of the poly(C) tract and murine virulence, as measured by virus brain titers and brain lesion scores after infection. Histological examination of brain tissue collected from infected animals clearly showed that the short poly(C) tract viruses did not induce the devastating pathological effects characteristic of animals inoculated with wild-type virus. Instead, the short-tract Mengo viruses proved excellent immunological agents. A dose of only 100 plaque-forming units of vMC24 (poly(C) tract: C13UC10), injected subcutaneously, protected 80% of recipient animals against a normally lethal dose of encephalomyocarditis virus. The protection was long-lived, and animals similarly immunized with vMCo virus (poly(C) tract: Co) still had protective neutralizing antibody titers up to 16 months after inoculation. In addition, the short-tract viruses proved genetically stable, in that the vMC24 virus did not yield detectable pathogenic revertants even after multiple, forced passages in 4-week-old mice. These studies suggest that Mengo viruses containing deletions in their poly(C) tracts are biologically safe and potent immunogens and imply that they may have uses as cardiovirus vaccines.

Mutational analysis of the mengovirus poly(C) tract and surrounding heteropolymeric sequences

Previously, we described three mengovirus mutants derived from cDNA plasmids, containing shortened poly(C) tracts (C8, C12, and C13UC10), that exhibited strong attenuation for virulence in mice yet grew like wild-type virus in HeLa cells. Thirteen additional mutants hav now been constructed and characterized. Five of these differ only in poly(C) length, including one with a precise deletion of the tract. The other mutants bear deletions into the regions juxtaposing poly(C). Studies with HeLa cells confirm the essential dispensability of mengovirus's poly(C) tract but reveal a subtle, measurable correlation between poly(C) length and plaque diameter. Virulence studies with mice also revealed a strong correlation between poly(C) length and virulence. For the poly(C)-flanking mutations, the 15 bases directly 5' of the tract proved dispensable for virus viability, whereas the 20 to 30 bases 3' of poly(C) were critical for growth, thus implicating this region in the basal replication of the virus.

Protection of non-murine mammals against encephalomyocarditis virus using a genetically engineered Mengo virus

Genetically engineered Mengo viruses with artificial deletions in the 5' noncoding poly(C) tracts are highly attenuated for pathogenicity when introduced as live vaccines into the natural murine host. Inoculation produces lifelong protective immunity without disease or viral persistence. This report extends the vaccination studies to non-murine hosts, including baboons, macaques and domestic pigs, all of which are susceptible to severe cardiovirus epizootics. All animals of these species that were inoculated with vMC24, an engineered strain of Mengo, seroconverted. When the immunized animals were challenged, they were protected against lethal doses of encephalomyocarditis virus (EMCV) derived from currently circulating epizootic strains. In baboons, the neutralizing antibody titers induced by vMC24 were significantly higher than from an inactivated EMCV vaccine. Moreover, terminal histopathology on baboons (inoculated intramuscularly), macaques (inoculated intracerebrally), and pigs (inoculated intramuscularly) showed few, if any, gross lesions characteristic of EMCV-like disease, in the vMC24 vaccinates. We suggest that genetically engineered, short poly(C) Mengo viruses may be universally potent attenuated vaccines for many types of animals and can possibly provide safe, efficacious protection against all cardioviruses of the EMCV serotype.

Characterization of Mengo virus neutralization epitopes. II. Infection of mice with an attenuated virus

A panel of five neutralizing monoclonal antibodies was generated from mice immunized with an attenuated strain of Mengo virus. Four of the antibodies were used to select mutants of Mengo virus which were able to escape neutralization by the selecting antibody, but it was not possible to select mutants which could escape neutralization by the fifth antibody. The capsid coding region of the RNA genome of each mutant was directly sequenced to identify the mutation(s) responsible for the neutralization escape phenotype. These results are compared to those of a previous study in which immunogenic determinants recognized by neutralizing antibodies generated against pentameric capsid subunits were located on the external surface of the Mengo virion. We have confirmed the existence of the previously identified immunogenic determinant in VP3 (site 2) as well as an immunodominant determinant in VP2 (site 1). Two previously uncharacterized determinants, located in surface loops of VP1 (sites 3 and 4A), were also identified. None of the mutations conferring the neutralization escape phenotype was found near the surface depressions on the virion which are believed to be the receptor binding sites.

Cytotoxic T cell response to Mengo virus in mice: effector cell phenotype and target proteins

The Mengo virus specific cytotoxic T lymphocyte (CTL) response was investigated after intraperitoneal infection of mice with the attenuated Mengo virus strain vMC24. A high level of CTL activity was detected in spleen cell cultures obtained from infected C3H/HeJ (H-2k) or C57BL/6 (H-2b) mice after a secondary in vitro stimulation with Mengo virus-infected cells. The CTL activity, which was MHC class I-restricted, was shown to be mediated by CD8+ T cells. Recombinant vaccinia viruses that expressed capsid proteins VP0, VP1 or VP3 were produced and used to identify the protein(s) recognized by the Mengo virus-specific CTLs. In both C3H/HeJ and C57BL/6 mice, analysis of CTL activity against target cells expressing each capsid protein showed that VP0 was the only capsid protein recognized by the CD8+ CTLs. The CTL epitope(s) could be further located in the C-terminal half of VP0, i.e. in capsid protein VP2. Moreover, using unlabelled target cells expressing VP0 as cold competitors, we were able to almost completely inhibit recognition and lysis of Mengo virus-infected cells by specific CD8+ CTLs. Thus, the CTL response directed against VP2 was immunodominant in both C3H/HeJ- and C57BL/6-infected mice.

Attenuated Mengo virus: a new vector for live recombinant vaccines

Several features make Mengo virus an excellent candidate for use as a vaccine vector. The virus has a wide host range, including rodents, pigs, monkeys, and most likely humans, and expresses its genome exclusively in the cytoplasm of the infected cell. Stable attenuated strains exist which are deleted for part of the 5' noncoding region of the genome. Here we report an attenuated Mengo virus recombinant, vLCMG4, that encodes an immunodominant cytotoxic T-lymphocyte epitope of the lymphocytic choriomeningitis virus (LCMV) nucleo-protein. vLCMG4 induced protective immunity against lethal LCMV infection after a single, low-dose immunization in BALB/c mice and elicited an LCMV-specific CD8+ cytotoxic T lymphocyte response. This demonstrates the potential of recombinant Mengo virus vaccines to confer protection against infectious diseases by the induction of cellular immune responses.

Encephalomyocarditis viruses with short poly(C) tracts are more virulent than their mengovirus counterparts

We have constructed three cDNA clones of encephalomyocarditis virus strain R (EMCV-R) with poly(C) tracts of C4, C9, and C20. RNA transcribed from these cDNAs was infectious to HeLa cells, and the resultant viruses grew well in this system, albeit with plaque sizes that were proportional to the poly(C) length. When injected into mice, the progeny viruses were only slightly less pathogenic than EMCV-R, and the observed degree of attenuation was not nearly as dramatic as for equivalent mengoviruses with similar short poly(C)s. Short-tract poly(C)-mediated attenuation is therefore highly dependent on viral genomic context.

Attenuated Mengo virus as a vector for immunogenic human immunodeficiency virus type 1 glycoprotein 120

Introduction of a sequence encoding 147 amino acids from human immunodeficiency virus type I (HIV-1) strain MN glycoprotein gp120 into the RNA genome of the stably attenuated Mengo virus strain vM16 yielded an infectious recombinant virus, vMLN450, which expressed the heterologous HIV-1 sequence along with the normal Mengo virus proteins. The HIV-1 gp120 sequence, fused to the amino terminus of the short, nonstructural Mengo virus leader polypeptide was recognized by a gp120 V3 loop-specific monoclonal antibody. When inoculated into mice, recombinant virus vMLN450 elicited a high-titer anti-HIV-1 antibody response as well as an HIV-1MN-specific cytotoxic cellular immune response. An anti-HIV-1 antibody response could also be detected in cynomolgus monkeys after a single immunization. We propose that attenuated Mengo virus can serve as an effective expression vector in cell systems and various animal species and offers another approach to the development of new, live recombinant vaccines.

Proteolytic processing of the cardioviral P2 region: primary 2A/2B cleavage in clone-derived precursors

The primary 2A/2B cleavage within cardiovirus polyprotein was examined by construction of cDNA plasmids which linked fragments from the P2 region of encephalomyocarditis virus (EMCV) and Mengovirus genomes to the EMCV 5' nontranslated region. When RNA transcripts from these clones were tested in reticulocyte extracts, the synthesized proteins were cotranslationally processed at the 2A/2B site. No viral segments outside of the P2 region were required for this activity. Engineered deletions which removed the amino-terminal two-thirds of protein 2A or the carboxyl half of protein 2B had no effect on this scission, nor did insertions into a Ser-Ala-Phe sequence (SAF) within 2B, which is conserved in most cardio- and aphthoviruses. In contrast, mutations which disrupted a conserved Asn-Pro-Gly-Pro (NPGP) sequence abolished primary scission. Precursors thus inactivated were unable to serve as substrate when simultaneously expressed with active (wild-type) 2AB sequences. Microsequencing placed the EMCV primary cleavage site between the Gly/Pro pair within the NPGP sequence. It was also determined that endogenous viral protease 3C is the previously unidentified agent responsible for cardiovirus 1D/2A scission, a cleavage that is part of the primary processing reaction in poliovirus.

Molecular and structural basis of hemagglutination in mengovirus

The molecular and structural basis of mengovirus hemagglutination (HA) was investigated by the comparison of nucleotide sequences of the entire capsid coding regions of an HA+ variant, two HA- mutants, 205 and 280, and two HA+ revertants of 205. The mutants were selected after acridine mutagenesis of mengovirus-37A, a heat-stable and HA+ variant that is neurotropic in mice. HA+ revertants of mutant 205 were isolated from brain tissue of mice inoculated with mutant 205. The nucleotide sequences were determined by consensus RNA sequencing using genomic RNA templates from purified virions. Two nucleotide differences were observed in the VP1 coding region of the RNA genomes of mutants 205 and 280 in comparison to the RNA sequences of 37A and the revertants. Interpretation of these data predict substitutions of two consecutive amino acids at residues 1231 (K to R) and 1232 (P to S) of VP1 which form part of the H-I loop of VP1 found at the icosahedral fivefold axis. Analysis of the amino acid substitutions in the context of the three-dimensional structure of the mengovirus-M capsid indicated that hemagglutination most likely involves residues found at the icosahedral fivefold axis and probably does not involve the residues that form the putative cellular receptor binding site (the "pit"). Eleven amino acid differences were observed between the structural proteins of mengovirus-M and 37A, five in VP1, three in VP2, and three in VP3.

Characterization of Mengo virus neutralization epitopes

A set of four monoclonal antibodies which neutralized the infectivity of Mengo virus was used to select 20 non-neutralizable (escape) mutants. Altered amino acids were identified by sequence analyses of the capsid-coding regions of the mutant virus genomes. Mutations were found predominantly in proteins VP2 and VP3, while mutations in VP1 were detected only as second mutations. The Mengo virus VP2 mutations at amino acid residues 2144, 2145, 2147, and 2148 align with site Nlm II in human rhinovirus-14 and site 2 in polioviruses 1 and 3. The mutation at 2075 as well as those at 3057, 3061, and 3068 in VP3 correspond to site 3 in poliovirus. These alignments notwithstanding, the results of cross-neutralization experiments indicate the existence of a single composite neutralization site on the Mengo virion. Considering the three-dimensional structure of the Mengo capsid, the amino acids which are altered in the escape mutants are all exposed on the outer surface and none are found in the "pit," the probable site for binding of a cellular receptor. The VP3 mutations are located in the VP3 "knob" and the VP2 mutations on a nearby ridge. Together these mutations define a set of epitopes within a single composite antigenic determinant which forms a crescent-shaped area around the three-fold icosahedral axes of the Mengo virion.

The alpha subunit of eucaryotic initiation factor 2 is phosphorylated in mengovirus-infected mouse L cells

Infection of mouse L cells with mengovirus resulted in the activation of a protein kinase (PK) that selectively phosphorylated the small, 38,000-molecular-weight alpha subunit of eucaryotic initiation factor 2 (eIF-2) in vitro. The mengovirus-activated kinase was detected in vitro approximately 3 h after virus adsorption. The ratio of phosphorylated to unphosphorylated eIF-2 also increased in vivo between 3 and 7 h after adsorption. The virus-activated kinase fractionated with the ribosomal pellet and had a high affinity for DEAE-cellulose and Mono Q ion-exchange columns. Gel electrophoresis of the kinase activity eluting from the Mono Q column and silver staining of the gel revealed only one protein band with a molecular mass of 70 kilodaltons. The optimal assay conditions for the mengovirus-activated kinase paralleled those of the double-stranded RNA-activated PK (dsRNA-PK). Lysates from infected cells contained elements capable of activating partially purified dsRNA-PK. These elements were identified as double-stranded RNA by their sensitivity to double-stranded RNase. The phosphorylation of the alpha subunit of eIF-2 coincided with the synthesis of dsRNA in infected cells, suggesting that the mengovirus-activated kinase is the dsRNA-PK. The phosphorylation of the alpha subunit of eIF-2 correlated with the global inhibition of protein synthesis that occurs at late times after infection.

pH 2 instability of a mutant of mengovirus is related to its interferon sensitivity

The is-1 mutant of mengovirus is 100 times more sensitive to interferon (IFN) than wild type, as measured by a yield reduction assay in the G3 line of mouse L cells, and is also much more readily inactivated at pH 2. Neither isolated nor encapsidated RNA is degraded under these conditions, which suggests that the pH-sensitive region resides on the virus coat. One-third of the viruses selected for resistance to low pH also showed enhanced resistance to IFN. Attempts to isolate IFN resistant strains directly from is-1 stocks were unsuccessful. These results suggest that either a capsid protein or its precursor is an active anti-IFN agent.

Attenuation of Mengo virus through genetic engineering of the 5' noncoding poly(C) tract

The murine cardioviruses, such as the Mengo and encephalomyocarditis viruses, and the bovine aphthoviruses, such as foot-and-mouth disease virus, are distinguished among positive-strand RNA viruses by the presence of long homopolymeric poly(C) tracts within their 5' noncoding sequences. Although the specific lengths (60-350 bases) and sequence discontinuities (for example, uridine residues) that sometimes disrupt the homopolymer have served to characterize natural viral isolates, the biological function of the poly(C) region has never been clear. We now report that complementary DNA-mediated truncation of the Mengo virus poly(C) tract dramatically attenuates the pathogenicity of the virus in mice. Animals injected with viruses with short tracts not only survived inoculation of up to 50 micrograms live virus (10(11) plaque-forming units) but consistently produced high titres of neutralizing antibodies, which conferred long-term immunogenic protection from (normally) lethal virus challenge. We propose that analogous synthetic strains of foot and mouth disease virus could serve as the basis for new attenuated vaccines.

Cloning and synthesis of infectious cardiovirus RNAs containing short, discrete poly(C) tracts

Mengovirus RNA transcripts with 5' noncoding poly(C) tracts of C8, C12, and C13UC10 have been synthesized in vitro from cDNA clones and shown to be infectious to HeLa cells. A chimeric clone has also been constructed which links the 5' end from one mengovirus clone (299 nucleotides, containing C13UC10) to a 7,424-base fragment derived from the 3' end of encephalomyocarditis (EMC) virus. Progeny virus isolated after transfection with the clone-derived RNAs had the same poly(C) tracts, mengovirus-specific sequences, or EMC virus-specific sequences as the transcript from which it was derived. Although the cloned poly(C) tracts were considerably shorter than those found in viral RNA from mengovirus (C50UC10) or EMC virus (C115UCUC3UC10), the growth characteristics of the progeny viruses in HeLa cells were indistinguishable from those of the parental viruses, indicating the length of this tract does not play a significant restrictive role for cardiovirus infectivity in tissue culture.

Constitutive expression of (2'-5') oligo A synthetase confers resistance to picornavirus infection

Study of the mechanisms by which interferon (IFN) treatment of cells induces resistance to virus infections has been complicated by the multiple biochemical changes induced. Over 20 proteins are increased by IFN, including the double-stranded (ds) RNA-activated protein kinase, (2'-5') oligo A synthetase, surface proteins such as the major histocompatibility complex (MHC) proteins, and various proteins with unknown functions. The availability of cloned complementary DNAs for several IFN-induced proteins now allows us to probe their roles in IFN action. For instance, the murine Mx protein has been shown to confer resistance, to influenza virus. We studied chinese hamster ovary (CHO) cell clones expressing high constitutive levels of (2'-5') A synthetase as a result of transfection with the cDNA encoding the enzyme form which has a relative molecular mass (Mr) of 40K. Elevated enzyme correlates directly with resistance to infection by a picornavirus such as Mengo, but does not make the cells resistant to vesicular stomatitis virus (VSV).

Biological properties of mengovirus: characterization of avirulent, hemagglutination-defective mutants

Biological properties of two mengovirus mutants, 205 and 280, were compared to those of wild-type virus. The mutants exhibited alterations in plaque morphology, hemagglutination, and virulence in mice, but were not temperature-sensitive. Agglutination of human erythrocytes by mengovirus was dependent on the presence of sialic acid on the erythrocyte surface; however, free sialic acid failed to inhibit hemagglutination. Glycophorin, the major sialoglycoprotein of human erythrocyte membranes, exhibited receptor specificity for wild-type virus, but not for mutants 205 or 280. Cross-linking studies indicated that glycophorin exhibited binding specificity for the alpha (1 D) structural protein. The LD50 titers for wild-type mengovirus were 7 and 1500 plaque forming units (PFU) in mice infected intracranially (IC) and intraperitoneally (IP), respectively. However, mice infected IC or IP with 10(6) or 10(7) PFU of mutant 205 or 280 did not exhibit symptoms indicative of virus infection. Revertants were isolated from the brains of mice infected with mutant 205, but not from the brains of mice infected with mutant 280. The biological characterization of the revertants indicated that hemagglutination and virulence may be phenotypically-linked traits.

A kinase able to phosphorylate exogenous protein synthesis initiation factor eIF-2 alpha is present in lysates of mengovirus-infected L cells

Infection of mouse L929 cells by mengovirus resulted in the expression of a kinase activity that selectively phosphorylated the small, 38,000-molecular-weight subunit of eucaryotic initiation factor 2 and histone H2. This kinase activity was independent of host cell RNA synthesis and was located in the postribosomal supernatant (S-100 fraction) early after infection (up to 3 h). At later times after infection (5 h), kinase activity was also associated with the polysome fraction. The kinase present in the S-100 fraction bound strongly to DEAE-cellulose, its peak activity eluting at 0.5 M KCl. Kinase activity was independent of the presence of exogenous double-stranded RNA, and KCl at concentrations greater than 0.1 M inhibited eucaryotic initiation factor 2 phosphorylation. The 67,000-molecular-weight phosphoprotein activated in interferon-treated cells by double-stranded RNA was not detected by standard phosphorylation assays in lysates from mengovirus-infected cells. Labeling of this protein in vivo during 5 h of infection was also not detected. The DEAE-cellulose-purified mengovirus kinase inhibited protein synthesis in reticulocyte lysates, and the inhibition was not reversible by high concentrations of poly(I).poly(C).

Poliovirus genome RNA hybridizes specifically to higher eukaryotic rRNAs

The RNA genome of poliovirus hybridizes to 28S and 18S rRNAs of higher eukaryotes under stringent conditions. The hybridization detected by Northern blot analyses is specific since little or no signal was detected for yeast or prokaryotic rRNAs or other major cellular RNAs. Southern blot analysis of DNA clones of mouse rRNA genes leads us to conclude that several regions of 28S rRNA, and at least one region in 18S rRNA, are involved in the hybridization to polio RNA, and that G/C regions are not responsible for this phenomenon. We have precisely mapped one of these hybridizing regions in both molecules. Computer analysis confirms that extensive intermolecular base-pairing (81 out of 104 contiguous bases in the rRNA strand) could be responsible for this one particular site of interaction (polio genome, bases 5075-5250; 28S rRNA, bases 1097-1200). We discuss the possible functional and/or evolutionary significance of this novel type of interaction.

A comparative study on the translation of cardiovirus RNAs in rabbit reticulocyte lysates

In rabbit reticulocyte lysates the RNAs of encephalomyocarditis (EMC) virus, mengovirus, and Mous-Elberfeld (ME) virus directed the synthesis of similar sets of products. Moreover, the viral protease synthesized from any one of the three viral RNAs could cause cleavage of the viral capsid precursor proteins synthesized from any of the three RNAs. However, the three RNAs differed in their dependence on tRNA supplementation (to the lysates) for effective translation. In the absence of tRNA supplementation, synthesis of 5'-derived proteins of EMC viral RNA proceeded normally, but little synthesis of the proteins coded by the remaining portion of the viral genome occurred. In the case of mengoviral RNA, omission of tRNA supplementation caused mostly a generalized reduction of the synthesis of all viral proteins. In contrast, synthesis of ME viral proteins stopped almost completely in the absence of tRNA supplementation.

Multiple homologies of oligonucleotide size exist between nucleic acids of picornaviruses

A semi-quantitative analysis of hybrid formation between restriction enzyme-generated subgenomic fragments of cloned cDNA prepared from RNA of foot-and-mouth disease virus (FMDV) strain O1K and radiolabelled RNA from bovine enterovirus, bovine rhinovirus or Mengo virus indicated that the hybrids were of oligonucleotide size. They were located in those parts of the FMDV O1K genome that code for the two capsid proteins VP3 and VP1 and the precursor protein P52 as well as at the 3' end. No hybridization was observed with poliovirus type 1 RNA.

Genomic RNA of mengovirus. VI. Translation of its two cistrons in lysates of interferon-treated cells

The addition of low levels (40 ng/ml) of the synthetic double-stranded polyribonucleotide poly I:C to lysates of interferon-treated L-cells resulted in a strong inhibition (70 to 75%) of the in vitro translation of mengovirus RNA. Under these conditions, the rates of incorporation of [35S]methionine or formyl-[35S]methionine were depressed to a comparable extent. The sequences of mengovirus RNA recognized by ribosomes of interferon-treated cells at initiation of translation were compared with those present in initiation complexes formed by ribosomes of untreated controls. Fingerprint analysis revealed that the same sequences of mengovirus RNA were protected against nuclease attack by the 80S and the 40S initiation complexes formed in vitro in lysates of control or interferon-treated L-cells. Mengovirus RNA-coded proteins were labeled at their N-terminal end with formyl-[35S]methionine and digested to completion with trypsin. The resulting fragments were separated by high-voltage paper electrophoresis. Two different formyl-[35S]methionine-labeled N termini were resolved. Further analyses supported the notion that the two radioactive peaks originated in the initiation of translation at two different sites. This pattern did not change when mengovirus RNA was translated in lysates of interferon-treated cells.

Translational control by messenger RNA competition for eukaryotic initiation factor 2

Translation of globin mRNA in a micrococcal nuclease-treated reticulocyte lysate was studied in the presence of increasing amounts of Mengovirus RNA, under conditions in which the number of translation initiation events remains constant as judged by the transfer of label from N-formyl[35S]methionyl-tRNAf into protein. The translation of globin mRNA is progressively inhibited by low concentrations of Mengovirus RNA, free of detectable traces of double-stranded RNA, concomitant with the increasing synthesis of Mengovirus RNA-directed products. On a molar basis, Mengovirus RNA apparently competes about 35 times more effectively than globin mRNA for a critical component in translation. The competition is relieved by the addition of highly purified eukaryotic initiation factor 2 (eIF-2). Addition of eIF-2 does not stimulate overall protein synthesis, but shifts it in favor of globin synthesis. No stimulation of globin mRNA translation by eIF-2 is seen when Mengovirus RNA is absent. These experiments show that Mengovirus RNA competes, directly or indirectly, with globin mRNA for eIF-2. In direct binding experiments using isolated mRNA and eIF-2, Mengovirus RNA is shown to compete with globin mRNA for eIF-2 and to exhibit a 30-fold higher affinity for this factor. The binding of Mengovirus RNA to eIF-2 is much more resistant to increasing salt concentrations than is the binding of globin mRNA, again reflecting its high affinity. These results reveal a direct correlation between the ability of these mRNA species to compete in translation and their ability to bind to initiation factor eIF-2. They suggest that the affinity of a given mRNA species for eIF-2 is essential in determining its translation, relative to that of other mRNA species. Messenger RNA competition for eIF-2 may contribute significantly to the selective translation of viral RNA in infected cells.

Genomic RNA of mengovirus V. Recognition of common features by ribosomes and eucaryotic initiation factor 2

Binding of ribosomes to the 32P-labeled genomic RNA of mengovirus was studied in lysates of mouse L929 and Krebs ascites cells under conditions for initiation of translation. Upon total digestion with RNase T1, the 32P-labeled RNA protected in either 40S or 80S initiation complexes yielded four unique, large oligonucleotides. Each of these oligonucleotides occurred once in the viral RNA molecule. The same four oligonucleotides were recovered from 80S initiation complexes formed in lysates in which unlabeled mengovirus RNA had been translated extensively, indicating that recognition by ribosomes was not modulated detectably by a viral translation product. The recognition of intact, 32P-labeled mengovirus RNA by eucaryotic initiation factor 2 (eIF-2) was examined by direct complex formation. Fingerprint analysis of the RNA protected by eIF-2 against RNase T1 digestion yielded three T1 oligonucleotides that were identical to three of the four oligonucleotides protected in either 40S or 80S initiation complexes. A physical map of the large T1 oligonucleotides of the mengovirus RNA molecule was constructed, and the four protected oligonucleotides were found to map internally, within the region between the polycytidylate tract and the 3' end. For either ribosomes or eIF-2, the protected oligonucleotides could not be arranged in a continuous sequence, suggesting that they constitute at least two widely separated domains. These results show that ribosomes recognize and blind to more than a single sequence in mengovirus RNA, located internally in regions that are far removed from the 5' end of the molecule. eIF-2 itself binds with high specificity to mengovirus RNA, recognizing apparently three of the four sequences recognized by ribosomes.

Studies on an interferon-sensitive mutant of mengovirus: effects on host RNA and protein syntheses

Interferon induces an activity which strongly inhibits the growth of is-1, an interferon-response mutant of mengovirus. This activity is not expressed in protected cells infected with either is+ (the wild-type parent) or vaccinia virus, or in cells infected with is-1 in the presence of actinomycin D. A failure of is-1 to shut off host RNA and/or protein synthesis could explain these observations. The present paper, however, shows that is-1 and is+ are equally effective in suppressing host synthesis, and suggests that is+ actively inhibits the interferon-mediated activity directed against is-1.

Fragility of the rhinovirus type 14 genome to incubation at 60 degrees

Rhinovirus type 14 (RV14) genomic RNA, but not mengovirus or coxsackievirus B3 genomic RNA, fragmented to acid-insoluble RNA species during incubation in aqueous buffers at 60 degrees. Incubation of RV14 genomic RNA in high concentrations of dimethyl sulfoxide at 60 degrees did not result in fragmentation, suggesting that fragmentation was not a result of pre-existing nicks. RV14RNA that was treated with proteinase K prior to incubation at 60 degrees did not undergo fragmentation. The association of protein(s) with RV14 virion RNA was demonstrated by radiolabeling with amino acids. These results showed that protein(s) associated with RV14 genomic RNA was in some manner responsible for fragmentation of the RNA during incubation at 60 degrees.