Trichomonas vaginalis resistance to Mengo virus infection.

We have investigated the susceptibility of Trichomonas vaginalis to Mengo virus infection by comparing the outcome of Mengo virus or purified Mengo virus RNA infection in T. vaginalis and in CCL-1 mouse fibroblasts. While the adsorption and entry of Mengo virus into T. vaginalis occurred in the same manner as in fibroblasts, the uncoating was much slower. In addition, Mengo virus infection of T. vaginalis displayed no eclipse nor any subsequent production of infectious virus. Purified RNA failed to initiate productive infection in T. vaginalis, whereas it provoked viral replication in the fibroblast controls. It was shown by assessment of protein synthesis in T. vaginalis and mouse fibroblasts cell-free systems that the protozoan ribosomes were able to translate endogenous mRNA and poly-U, but not viral RNA.     

The use of a complementary DNA probe to detect accumulation of mengo RNA in infected cells pretreated with interferon.

Complementary DNA (cDNA) from Mengo virus RNA has been synthesized and used as a probe to measure the synthesis and accumulation of viral RNA in Mengo infected L cell cultures, treated or untreated with interferon. Under experimental conditions used (200 units interferon/ml and 50 virus plaque-forming units/cell) results show that there is some synthesis of Mengo virus RNA in cells treated with interferon. One hour after infection, treated cells contain three times less viral RNA than untreated cells; five hours after infection, this difference has increased to ten fold. As in the control, no fragmented Mengo virus RNA molecules were found in interferon treated cells. The smaller recovery of infectious particles from interferon treated cells as compared to RNA accumulation suggests that not only RNA accumulation is inhibited but also a step posterior in viral maturation.     

Trichomonas vaginalis Resistance to Mengo Virus Infection*

We have investigated the susceptibility of Trichomonas vaginalis to Mengo virus infection by comparing the outcome of Mengo virus or purified Mengo virus RNA infection in T. vaginalis and in CCL-1 mouse fibroblasts. While the adsorption and entry of Mengo virus into T. vaginalis occurred in the same manner as in fibroblasts, the uncoating was much slower. In addition, Mengo virus infection of T. vaginalis displayed no eclipse nor any subsequent production of infectious virus. Purified RNA failed to initiate productive infection in T. vaginalis, whereas it provoked viral replication in the fibroblast controls. It was shown by assessment of protein synthesis in T. vaginalis and mouse fibroblasts cell-free systems that the protozoan ribosomes were able to translate endogenous mRNA and poly-U, but not viral RNA.     

Functional aspects of the capsid structure of Mengo virus

The three-dimensional structure of the Mengo virus capsid has been determined at a resolution of 3.0 A. This achievement is discussed in an historical context, and the general features of picornavirus capsid design are presented. The dynamic functional aspects of the Mengo virus capsid--namely its ability to interact with specific receptors on host cells, to dissociate and release the viral genomic RNA into the cellular cytoplasm, to assemble with progeny RNA molecules and form new virions, and to alter its external surface in order to evade neutralization by circulating antibodies--are discussed. Comparisons with other picornaviruses whose capsid structures have also been elucidated (poliovirus serotype 1 and 3, human rhinovirus types 14 and 1A, and foot-and-mouth disease virus type O) illustrate both the similarities and the distinctive features of capsid design found within this family of mammalian viruses.     

Interactions of Polyoma and Mouse DNAs III. Mechanism of Polyoma Pseudovirion Formation

In primary mouse kidney cell cultures infected with polyoma virus, the processes leading to virion and pseudovirion formation were studied. By photometric DNA quantitation, we followed the kinetics of mouse and polyoma DNA synthesis and the formation of low-molecular-weight fragmented mouse DNA (mouse f-DNA). Virus was harvested at different times and analyzed for its proportion of pseudovirions. The following correlations between the intracellular events and the production of virions and pseudovirions were found. (i) Syntheses of cellular and viral DNA were closely linked, both in time and in rates of synthesis. (ii) An increase of mouse f-DNA could only be detected several hours after the onset of mouse and polyoma DNA replication; its formation coincided in time with the appearance of progeny virus. (iii) The proportion of pseudovirions was not dependent on the amount of mouse f-DNA formed, but seemed to be inversely related to the amount of viral DNA synthesized. This was borne out by experiments in which DNA synthesis was partially inhibited by mitomycin C or after a synchronized onset of DNA replication. Under these conditions, virus preparations with a two- to threefold increased proportion of pseudovirions were obtained as compared with those from uninhibited cultures. Virus isolated from the remaining monolayer always had a higher proportion of pseudovirions than virus isolated at the same time from the supernatant medium only; also, the proportion of pseudovirions increased slightly with time after infection. Thus, according to the experimental conditions used, polyoma virus preparations with a low (10 to 20%) or a high (60 to 80%) proportion of pseudovirions can be obtained.     

Correlation Between the Antiviral Effect of Interferon Treatment and the Inhibition of In Vitro mRNA Translation in Noninfected L cells

When noninfected L-cell suspension cultures are treated with interferon (specific activities superior to 10(6) reference units per mg of protein), the cell-free cytoplasmic extracts obtained are inactive for the translation of exogenous natural mRNAs. The dose-response curve shows that comparable amounts of interferon are required to produce a 50% reduction of Mengo virus multiplication in vivo and Mengo RNA translation in vitro. With higher doses of interferon, Mengo RNA translation is completely abolished, while poly U translation and endogenous protein synthesis are only slightly affected. The inactivation of Mengo RNA translation is reversible; after removal of interferon, normal translation activity is regained together with the ability to support Mengo virus multiplication. Fractionation of the cell-free extracts shows that the effect is localized in the fraction which can be washed off the ribosomes by high salt. These results establish that interferon induces a block in genetic translation in noninfected L cells.     

Destruction of L Cells by Mengo Virus: Use of Interferon to Study the Mechanism

Interferon, when added to L cells, inhibited the synthesis of infectious Mengo viral ribonucleic acid, hemagglutinins, and infectious virus by 85 to 95%. Serum-blocking antigens were also reduced by the action of interferon, but threefold excess amounts of these antigens accumulated in interferon-treated cultures above the amounts expected for the quantity of infectious virus that was produced in these cultures. Radioautographic analysis showed that 28 to 36% of the cells of an interferon-treated population synthesized viral ribonucleic acid and 36 to 47% produced viral antigens as determined by an immunofluorescence technique. Despite the reductions in synthesis of viral components, all cells in an interferon-treated culture underwent cytopathic effects at the same time as cells in infected cultures which had not been treated with interferon. The results are compatible with the hypothesis that the cell destruction which results from the infection of L cells with Mengo virus is due to a protein which is coded for by the virus but is not a component of the mature virion.     

Studies of two temperature-sensitive mutants of Mengo virus.

Studies of the synthesis of viral ribonucleates and polypeptides in cells infected with two RNA- ts mutants of Mengo virus (ts 135 and ts 520) have shown that when ts 135 infected cells are shifted from the permissive (33 degrees C) to the nonpermissive (39 degrees C) temperature: (i) the synthesis of all three species of viral RNA (single stranded, replicative form, and replicative intermediate) is inhibited to about the same extent, and (ii) the posttranslational cleavage of structural polypeptide precursors A and B is partially blocked. Investigations of the in vivo and in vitro stability of the viral RNA replicase suggest that the RNA- phentotype reflects a temperature-sensitive defect in the enzyme. The second defect does not appear to result from the inhibition of viral RNA synthesis at 39 degrees C, since normal cleavage of polypeptides A and B occurs in wt Mengo-infected cells in which viral RNA synthesis is blocked by cordycepin, and at the nonpermissive temperature in ts 520 infected cells. Considered in toto, the evidence suggests that ts 135 is a double mutant. Subviral (53S) particles have been shown to accumulate in ts 520 (but not ts 135) infected cells when cultures are shifted from 33 to 39 degrees C. This observation provides supporting evidence for the proposal that this recently discovered particle is an intermediate in the assembly pathway of Mengo virions.     

Theiler's virus and Mengo virus induce cross-reactive cytotoxic T lymphocytes restricted to the same immunodominant VP2 epitope in C57BL/6 mice.

C57BL/6 mice develop a virus-specific cytotoxic T-lymphocyte (CTL) response after intraperitoneal inoculation with either the DA strain of Theiler's virus or Mengo virus, two members of the Cardiovirus genus. These CTLs contribute to viral clearance in the case of Theiler's virus but do not protect the mice from the fatal encephalomyelitis caused by Mengo virus. In this study we show that DA and Mengo virus-induced CTLs are cross-reactive. The cross-reactivity is due to a conserved, H-2Db-restricted epitope located between amino acid residues 122 and 130 of the VP2 capsid protein (VP2(122-130)). This epitope is immunodominant in C57BL/6 mice infected with Theiler's virus. The VP2(122-130) epitope, initially identified for Mengo virus, is the first CTL epitope described for Theiler's virus.     

Polyoma Pseudovirions II. Influence of Host Cell on Pseudovirus Production

The type of host cell influenced the relative amounts of pseudovirions and polyoma virions produced. The infection of primary mouse embryo cells resulted in the production of particles that were predominantly pseudovirions. Infection of baby mouse kidney or 3T3D cells yielded mainly infectious polyoma virus. The length of time that infection was allowed to continue also affected the amount of pseudovirions relative to polyoma virions. The longer the viral infection was allowed to proceed, the greater the quantity of pseudovirions produced. Pseudovirion production could be correlated with the fragmentation of host cell DNA to a size of approximately 3 x 10(6) daltons. The fragmentation of host cell DNA was much more extensive in primary mouse embryo cells than in the other cell types.     

Role of the Spike Glycoprotein of Human Middle East Respiratory Syndrome Coronavirus (MERS-CoV) in Virus Entry and Syncytia Formation

Little is known about the biology of the emerging human group c betacoronavirus, Middle East Respiratory Syndrome coronavirus (MERS-CoV). Because coronavirus spike glycoproteins (S) mediate virus entry, affect viral host range, and elicit neutralizing antibodies, analyzing the functions of MERS-CoV S protein is a high research priority. MERS-CoV S on lentivirus pseudovirions mediated entry into a variety of cell types including embryo cells from New World Eptesicus fuscus bats. Surprisingly, a polyclonal antibody to the S protein of MHV, a group a murine betacoronavirus, cross-reacted in immunoblots with the S2 domain of group c MERS-CoV spike protein. MERS pseudovirions released from 293T cells contained only uncleaved S, and pseudovirus entry was blocked by lysosomotropic reagents NH₄Cl and bafilomycin and inhibitors of cathepsin L. However, when MERS pseudovirions with uncleaved S protein were adsorbed at 4°C to Vero E6 cells, brief trypsin treatment at neutral pH triggered virus entry at the plasma membrane and syncytia formation. When 293T cells producing MERS pseudotypes co-expressed serine proteases TMPRSS-2 or -4, large syncytia formed at neutral pH, and the pseudovirions produced were non-infectious and deficient in S protein. These experiments show that if S protein on MERS pseudovirions is uncleaved, then viruses enter by endocytosis in a cathepsin L-dependent manner, but if MERS-CoV S is cleaved, either during virus maturation by serine proteases or on pseudovirions by trypsin in extracellular fluids, then viruses enter at the plasma membrane at neutral pH and cause massive syncytia formation even in cells that express little or no MERS-CoV receptor. Thus, whether MERS-CoV enters cells within endosomes or at the plasma membrane depends upon the host cell type and tissue, and is determined by the location of host proteases that cleave the viral spike glycoprotein and activate membrane fusion.     

Further studies on the relative antiviral efficacies of interferons induced by poly I:C and Mengo virus.

Mouse serum interferons induced by polyI:C, vesicular stomatitis virus (VSV), reovirus, and Mengo virus were assayed in monolayers of mouse L-929 cells by the plaque-reduction method using both VSV and Mengo as challenge viruses. Titers obtained with Mengo virus as challenge were all lower than with VSV. With the interferons induced by VSV, reovirus, and ployI:C, the reductions were of the order of two- to three-fold. With Mengo virus-induced interferon the reduction was much greater (about 17-fold). This offers an explanation for the observation that, unit for unit (measured by the plaque reduction of VSV), Mengo virus-induced interferon is only about 1/10 as effective as polyI:C-induced interferon in protecting mice against lethal infection with Mengo virus. The data are consistent with the hypothesis that an interferon antagonist is produced in the serum of mice infected with Mengo virus. This antagonist, which is not produced in mice inoculated with polyI:C, or reovirus, effectively blocks the antiviral action of interferon during Mengo virus infections, both in vivo and in vitro.     

Polyoma Pseudovirions I. Sequence of Events in Primary Mouse Embryo Cells Leading to Pseudovirus Production

The relationship of the intracellular events leading to the production of polyoma pseudovirions in primary mouse embryo cells has been investigated. Replication of polyoma deoxyribonucleic acid (DNA) began 18 hr after infection. Assembly of viral capsid protein occurred 12 hr later. Intracellular fragments of host cell DNA, of the size found in pseudovirions, were first detected 36 hr after infection. The amount of intracellular 14S host DNA that was produced during infection was seven times greater than the amount of polyoma DNA synthesized. The relative pool sizes of polyoma DNA and 14S DNA at the time of virus assembly may dictate the amounts of polyoma virus and pseudovirus produced.     

Mechanism of Mengo Virus-Induced Cell Injury in L Cells: Use of Inhibitors of Protein Synthesis to Dissociate Virus-Specific Events

L cells were infected with Mengo virus in the presence of varying concentrations of protein synthesis inhibitors (azetidine-2-carboxylic acid, p-fluorophenylalanine, puromycin), and examined with respect to the effects of the inhibitors on several features of virus-induced cell injury. The virus-specific events in the cells could be dissociated into three groups, based on their sensitivity to the inhibitors: (i) viral ribonucleic acid (RNA) synthesis, bulk viral protein synthesis, and infectious particle production, all of which were prevented by low inhibitor concentrations; (ii) the cytopathic effect (CPE) and stimulation of phosphatidylcholine synthesis, which were sensitive to intermediate concentrations of the inhibitors; and (iii) the virus-induced inhibitions of host RNA and protein synthesis, which were resistart to the inhibitors of protein synthesis except at very high concentrations. It is concluded from this that the virus-induced CPE and stimulation of phosphatidylcholine synthesis are not consequences of the inhibition of cellular RNA or protein synthesis. Analysis of the virus-specific protein and RNA synthesized at several concentrations of azetidine and puromycin suggests that the CPE may be induced by a viral protein precursor. Virus-induced inhibition of host RNA and protein synthesis occurred at azetidine concentrations which blocked the synthesis of over 99.7% of the total viral RNA and over 99% of the viral double-stranded RNA (dsRNA). Calculations show that this would correspond to less than 150 dsRNA molecules per infected cell, resulting in a dsRNA-polysome ratio of less than 1:1,000; this indicates that host protein synthesis cannot be inhibited by an irreversible binding of dsRNA to polysomes.     

Bovine papillomavirus type 1 infection is mediated by SNARE syntaxin 18

Events that lead to viral infections include the binding of the virus to the target cells, internalization of the virus into the cells, and the ability of the viral genome to be expressed. These steps are mediated by cellular and viral proteins and are temporally regulated. The papillomavirus capsid consists of two virally encoded capsid proteins, L1 and L2. Much is known about the role of the major capsid protein L1 compared to what is known of the role of the L2 protein. We identified the interaction of the L2 protein with SNARE protein syntaxin 18, which mediates the trafficking of vesicles and their cargo between the endoplasmic reticulum, the cis-Golgi compartment, and possibly the plasma membrane. Mutations of L2 residues 41 to 44 prevented the interaction of L2 protein with syntaxin 18 in cotransfection experiments and resulted in noninfectious pseudovirions. In this paper, we describe that syntaxin 18 colocalizes with infectious bovine papillomavirus type 1 (BPV1) pseudovirions during infection but does not colocalize with the noninfectious BPV1 pseudovirions made with an L2 mutant at residues 41 to 44. We show that an antibody against BPV1 L2 residues 36 to 49 (alpha L2 36-49) binds to in vitro-generated BPV1 pseudoviral capsids and does not coimmunoprecipitate syntaxin 18- and BPV1 L2-transfected proteins. alpha L2 36-49 was able to partially or completely neutralize infection of BPV1 pseudovirions and genuine virions. These results support the dependence of syntaxin 18 during BPV1 infection and the ability to interfere with infection by targeting the L2-syntaxin 18 interaction and further define the infectious route of BPV1 mediated by the L2 protein.     

Inhibition of Mengo virus by interferon

Gauntt, Charles J. (The University of Texas, Austin), and Royce Z. Lockart, Jr. Inhibition of Mengo virus by interferon. J. Bacteriol. 91:176-182. 1966.-The inhibition of Mengo virus replication in L cells resulting from interferon was studied quantitatively. Interferon was titrated on L cells with Western equine encephalomyelitis (WEE) virus as the challenge virus. One protective unit (PU) of interferon is the least amount of interferon which prevents cytopathic effects when a large multiplicity of WEE virus is added subsequent to overnight incubation with interferon. Ten PU of interferon reduced the yields of Mengo virus by about 90%. Larger doses of interferon, up to 220 PU, caused no further reduction in the amount of virus produced. Plaque formation by Mengo virus was also reduced in number by about 85 to 90%, but could not be further reduced. The plaques which formed on interferon-treated cells were reduced in size. We were unable to obtain a virus population with increased resistance to interferon action by use of five successive growth cycles in interferon-treated cultures. Analysis of the cell population for the proportion of cells able to act as infectious centers revealed that incubation of cells with 10 PU of interferon decreased the proportion of virus-yielding cells by 80%. The yield of virus per virus-producing cell was decreased by 40 to 60%. Despite the reduction in yields, plaques, and infectious centers resulting from interferon, all doses of interferon failed to prevent the complete destruction of the cells. Experiments with puromycin indicated that the cytopathic effects observed in L cells infected with Mengo virus required that a virus-directed protein be synthesized between 4 and 5 hr postinfection. The evidence suggested, therefore, that the Mengo virus genome was able to code for new protein synthesis in the absence of the production of infectious virus.     

Protein synthesis in extracts from interferon-treated Mengo virus infected cells

We previously showed in intact L cells that interferon treatment did not modify the shut-off of cellular RNA and protein synthesis induced by infection with Mengo virus although viral replication is inhibited (1,2). We have also demonstrated that inhibition of host protein synthesis was not due to degradation of messengers since cellular mRNA could be extracted from interferon-treated infected cells and efficiently translated in a reticulocyte lysate(2). Cellular mRNA was not degraded although 2–5A was present as reported here. We prepared cell-free systems from such cells at a time when cellular shut-off was fully established. The undegraded messengers remained untranslated under cell-free protein synthesis conditions and almost no polysomes were detected. The decreased amount of [³⁵S]Met-tRNA-40S complex observed in these lysates might account for the inhibition of protein synthesis at the level of initiation.     

Antiviral activity of a thymic factor in experimental viral infections. I. Thymic hormonal effect on survival, interferon production and NK cell activity in Mengo virus-infected mice

A partially purified thymic factor, thymostimulin (TS), significantly increased the survival rate of adult, immune-intact mice infected with the neurotropic Mengo virus. TS treatment was begun after virus inoculation by daily i.p. injections. In untreated C57BL/6 mice, LD50 was reached with 1 X 10(4) PFU, but 10-fold more virus (i.e., 1 X 10(5) PFU) was needed to reach LD50 in TS-treated animals. TS effect on survival, though, could be observed with several virus doses (1 X 10(3) to 1 X 10(6) PFU) (p less than 0.001). A significant effect on survival was also observed with outbred ICR mice (p less than 0.005). Serum interferon (IFN) levels in the Mengo virus-infected mice were relatively low (average peak 300 U/ml), but were significantly increased (two- to ninefold) in the TS-treated mice. Peak serum levels were reached earlier in TS than in control animals (24 hr and 72 hr, respectively). Both acid-labile and acid-stable type I IFN production were augmented by TS in the Mengo virus-infected mice. Natural killer activity was also enhanced by TS, in particular on the second day after virus inoculation. In addition, MP-virus was used as a second, unrelated virus challenge. This virus caused a nonlethal infection, with relatively high levels of serum IFN (average peak 10,000 U/ml). TS increased IFN levels (two- to eight-fold) also in this challenge system. In conclusion, TS causes a nonspecific enhancement of endogenous production of IFN and has a significant effect on the survival of lethally infected mice. The data indicate a potential application of thymic factors for the treatment of viral infections.     

Properties of morphologically variant haploid frog cells formed by combined treatment with Mengo virus and the polyene antibiotic mediocidin.

Comparisons have been made of cell surface glycoproteins, concanavalin A agglutinability, and cloning efficiencies in liquid media of ICR 2A (haploid frog cells), ICR 2A M (three cloned populations of haploid frog cells resistant to 5 microgram per ml of the polyene antibiotic mediocidin), and ICR 2A M/MV cells (five cloned populations of morphologically variant haploid frog cells produced by exposure of the parental cells to the combined effects of mediocidin and an RNA mammalian virus, Mengo virus). Independently isolated ICR 2A M/MV clones exhibited altered cell surface glycoproteins, increased concanavalin A agglutinability, and enhanced cloning efficiency in liquid media when compared with ICR 2A parental cells. In contrast, ICR 2A M cells had properties similar to ICR 2A cells, with the exception of the former's increased resistance to mediocidin. The differences in properties between ICR 2A M/MV and ICR 2A cells suggest that alterations resembling transformation have occurred in ICR 2A M/MV cells as a consequence of combined treatment with mediocidin and Mengo virus.     

Picornaviruses of two different genera have similar structures

Crystals of Mengo virus were used to collect three-dimensional X-ray diffraction data to 7 Å resolution. A self-rotation function showed the precise orientation of the Mengo particles in the crystal unit cell. A cross-rotation function against similar data of cubic rhinovirus crystals showed a peak when the orientations of these two icosahedral viruses were superimposed. This demonstrates similarity of capsid construction between two picornaviruses of different taxonomic genera.