Cytopathology of Mengovirus infection. I. Relationship between cellular disintegration and virulence

Poliovirus-induced Cellular Injury

Protein leakage was used as a quantitative measure of poliovirus-induced cellular injury under suspended cell culture conditions. The requirements for protein leakage were studied in detail and it was established that events early in the infectious cycle which depend upon viral protein synthesis were responsible for cell damage. Extralysosomal beta-glucuronidase appeared in infected cells before the onset of protein leakage and release of newly synthesized virus. Hydrocortisone treatment of infected cells resulted in only a slight delay in the release of beta-glucuronidase from lysosomes and protein and virus from cells. These results suggest that events associated with poliovirus synthesis trigger the release of lysosomal hydrolases which in turn injure the plasma membrane, allowing cytoplasmic proteins and virus to leak out of the cell.

Cellular origin and ultrastructure of membranes induced during poliovirus infection

Poliovirus RNA replicative complexes are associated with cytoplasmic membranous structures that accumulate during viral infection. These membranes were immunoisolated by using a monoclonal antibody against the viral nonstructural protein 2C. Biochemical analysis of the isolated membranes revealed that several organelles of the host cell (lysosomes, trans-Golgi stack and trans-Golgi network, and endoplasmic reticulum) contributed to the virus-induced membranous structures. Electron microscopy of infected cells preserved by high-pressure freezing revealed that the virus-induced membranes contain double lipid bilayers that surround apparently cytosolic material. Immunolabeling experiments showed that poliovirus proteins 2C and 3D were localized to the same membranes as the cellular markers tested. The morphological and biochemical data are consistent with the hypothesis that autophagy or a similar host process is involved in the formation of the poliovirus-induced membranes.

The effect of mengovirus infection on lipid synthesis in cultured Ehrlich ascites tumor cells

The concept of generally increased lipid synthesis during the initial 2/3 of picornaviral infectious cycles, held by several authors, needs differentiation. In mengovirus-infected Ehrlich ascites tumor cells, an increase in the rate of synthesis of phosphatidylcholine could be confirmed, but for phosphatidylethanolamine constant to decreasing rates of synthesis were found. Moreover, phosphatidylinositol was increasingly synthesized in the midst of the infectious cycle. The changes observed might have their functional expression in the proliferation of smooth cytoplasmic membrane systems that provide the structural framework for the replication of picornaviral RNA and virus assembly. The alterations in the labeling patterns of phosphatidylinositol, phosphatidylglycerol and diphosphatidylglycerol late in virus infection point to increased turnover of these compounds, possibly mediated by phospholipase D. The formation of lysophosphatidylcholine (cytolytic effect) and bis(monoacylglyceryl)phosphate in the final phase of the infectious cycle might be correlated with the liberation of lysosomal enzymes and the development of the cytopathic effect.

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.

Effect of HTLV-III on the macromolecular synthesis in HTLV-I carrying cell line, MT-4

Upon infection of human T-cell leukemia virus type I (HTLV-I)-carrying human T-cell lines such as MT-4, HTLV-III, a probable etiologic agent of acquired immune deficiency syndrome (AIDS) caused fast and strong cytopathic effects leading ultimately to the death of the cells. Such effects were preceded by the rapid induction of HTLV-III antigens. Cell lines not infected with HTLV-I could, however, be subcultured after infection with HTLV-III, although they were also positive for HTLV-III antigens. To understand this cytopathogenicity of HTLV-III in HTLV-I bearing cells, macromolecular synthesis, including DNA synthesis and total protein synthesis, and also IL-2 receptor expression were investigated kinetically. In infected MT-4 cells DNA synthesis was markedly inhibited by HTLV-III after the HTLV-III antigen synthesis became evident. This inhibition occurred before cell damage was detected in terms of viable cell-growth, but after induction of HTLV-III antigen. Puromycin, at 40 micrograms/ml, caused no toxic changes in MT-4 cells over 3 days but prevented viral antigen synthesis and virus-induced cytopathic effect. Protein synthesis and IL-2 receptor expression were also inhibited at 4 and 5 days post infection. The degree of the effects and their kinetics suggest that they are the secondary effects of cytotoxicity by HTLV-III infection.

Apoptosis, lymphocytotoxicity and the containment of viral infections

It is generally agreed that cellular immunity plays an important role in limiting certain primary viral infections. Morphological studies indicate that cell death induced by T cells, K cells and NK cells takes the form of apoptosis, not classical necrosis. Killing of a virus-infected cell by either of these means prior to the assembly of infectious virus would clearly contain the infection. Our hypothesis is that the exclusive involvement of apoptosis in lymphocytotoxicity may have additional advantages in preventing virus dissemination. Firstly, a very early event in apoptosis is activation of endogenous, non-lysosomal endonuclease, and this might destroy virus. Secondly, apoptosis results in the formation of membrane-bounded cell fragments, which are phagocytosed intact and digested within the lysosomes of adjacent cells. In contrast, necrosis is characteristically associated with rupture of the cell membrane and release of cellular contents; its induction by non-budding viruses aids in spread of the infection.

Spherical aggregates of coxsackie B4 virus particles in mouse pancreas

A high titer culture of Coxsackie B4 virus was used to induce pancreatitis in newborn mice. In animals sacrificed 1 or 2 days after intraperitoneal inoculation, we observed cytonecrosis consistent with picornaviral infection as well as necrosis indicative of pancreatitis. In addition, we observed aggregates of particles which seem to be Coxsackie B4 virus particles, some arranged in the typical picornaviral crystalloid lattice formation and others arranged into spherical masses approximately 102 nm in diameter. Depending upon the depth and orientation of section through the spherical aggregates, the particles were arranged into two patterns which were readily distinguishable. When the plane of section was through the center of the sphere, 10 particles circularly arranged around a dense particle core were observed. When the sphere was cut tangentially, the particles were arranged in a zig-zag pattern so that there were two concentric layers of at least 6 particles per layer, with no central core. Both crystalloid and spherical aggregates were observed free within acinocyte cytoplasm, and within autophagic vacuoles, cytosegresomes, and fine granular bodies of acinocytes, and within phagocytic vacuoles of macrophages. We conclude that the spherical aggregates represent a distinct crystalloid form of Coxsackie B4 virus during its replicative cycle, which may eventually develop into the more typical picornaviral crystalloid lattice configuration and that the spherical aggregates are located in foci of viral synthesis. Marked pathogenicity of Coxsackie B4 virus in the newborn mouse pancreas should be considered a factor in the observations noted.

Encephalomyocarditis (EMC) virus infection of the femoral vein of newborn mice

The EMC virus was found to infect and injure the femoral veins of newborn mice. EMC viral crystals were found in the advential fibroblasts of these veins. In view of the extensive damage observed in the extremely small amount of tissue examined electron microscopically, the extent of the viral phlebitis must have been considerable. The relationship of these findings to the pathogenesis of thrombophlebitis in man provokes interesting speculations.

Response of cultured mammalian cells to diphtheria toxin. V. Concurrent resistance to ribonucleic acid viruses in diphtheria toxin-resistant KB cell strains

It was determined that KB-R cell strains, isolated from the KB cell line and resistant to diphtheria toxin, also resist infection by poliovirus, Mengo virus, vesicular stomatitis virus, and Newcastle disease virus. This resistance manifests itself by reduction in yields of progeny virus (a reduction of more than 2 logs in some cases), reduced production of viral-specific ribonucleic acid (RNA), and delayed cytopathic effect. In three KB-R strains tested, resistance was related to a step which falls between adsorption of virus and uncoating or release of viral messenger RNA. In two of these three strains, a second resistance mechanism was also active, causing a reduced production of viral-specific RNA. A relationship between the resistance to diphtheria toxin and the resistance to viral infection of the KB-R strains is considered. It has been postulated that the native diphtheria toxin molecule must be "activated" at the surface of a susceptible cell by a proteolytic process before it can enter the cell and inhibit protein synthesis. It is also known that the eclipse of some viruses occurs at or near the cell membrane and involves proteolytic activity. Resistance to viruses and toxin in the KB-R strains may result from the loss or modification of related labilizing or activating principles associated with the surface receptors for these agents.

Effect of double-stranded viral RNA on mammalian cells in culture

During bovine enterovirus infection of Ehrlich ascites tumor cells, large amounts of double-stranded RNA accumulate. Addition of this double-stranded RNA to uninfected cells leads to rapid cell death. This is not a result of infectious virus production. Neither single-stranded RNA nor heat-denatured double-stranded RNA has this effect. Similar experiments with synthetic double-stranded polymers, poly(I).poly(C) and poly(A).poly(U), show that they are only slightly toxic at the concentrations used. The effect of the double-stranded RNA is nonspecific for cells of different origins. The implications of this finding in relation to the cytopathic effects of picornavirus and to cancer chemotherapy are discussed.

Delay of mengovirus-induced cytopathology in mitotic L-cells

The time course and extent of mengovirus production were the same in metaphase-arrested and interphase L-cells, yet the expression of cytopathology was delayed several hours in metaphase cells.

Host-dependent restriction of mengovirus replication

Mengovirus infection of a restrictive cell line, Maden's bovine kidney (MDBK), results in a virus yield 1,000-fold less than that obtained from productively infected cell lines such as L cells or Ehrlich ascites tumor cells (EAT). Cells of both types of host systems are infected with comparable efficiencies and are completely killed as a consequence of infection. Infective center assays, coupled with the observation of total cell killing, suggest that comparable numbers of cells synthesize viral antigen and release virus in both types of host system. Viral-specific ribonucleic acid (RNA) synthesis is initiated and proceeds in an identical fashion for approximately 4 hr after the infection of MDBK, EAT, or L-cells. At this time, viral RNA synthesis in MDBK ceases, whereas viral RNA synthesis in EAT and L-cells continues at a linear rate. These results indicate that none of the early viral events leading to the initiation of viral-specific RNA synthesis constitutes the primary site of mengovirus restriction in MDBK. Rather it appears that the cessation of viral RNA synthesis in restrictive cells constitutes the primary limiting event. Based on its delayed interaction with mengovirus RNA synthesis, it appears that the host-related restrictive agent is initially compartmentalized and then released as a consequence of infection subsequent to those early events in mengovirus infection leading to the initiation and continued synthesis of viral RNA.

Mengovirus-induced cytopathic effect in L-cells: protective effect of interferon

The effect of interferon on mengovirus-induced cytopathic effect (CPE) in L cells, the cut-off of host-cell protein synthesis, and production of mature virus were found to be dependent on the concentration of interferon. CPE and inhibition of host protein synthesis were not affected until the concentration of interferon was increased 100-fold over that required to reduce viral yields by 90%.

Contrasting effects of polycations on plaquing efficiency of encephalomyocarditis virus variants

Polycation treatment of L cell monolayers affected plaquing efficiency of both the r(+) and r variants of the encephalomyocarditis virus. Plaque formation by r(+) variant was decreased markedly by three structurally different types of synthetic basic polymers, diethylaminoethyl dextran, hexadimethrene (polybrene), and basic polyamino acids. In contrast, these same substances increased substantially the number of plaques formed by the r variant. The effect on the two variants was observed when polycations were applied to the cells before or simultaneously with the introduction of virus. The molar concentration and size of the polymer proved important. Thus, basic polyamino acids of low molecular weight were significantly more inhibitory for the r(+) variant than were those of high molecular weight. On the other hand, plaquing efficiency of the r variant was increased by relatively large polyamino acids, but not by polymers of small size. Basic polyamino acids inhibited r(+) plaque formation to a greater degree at low than at high pH values. However, plaquing efficiency of the r variant in polycation-treated cultures was not affected by changes in pH. Basic polymers appear to bind to cell membranes and affect either attachment or uptake of the viruses. The evidence suggests that the substances influence by different mechanisms the interaction of the r(+) and r variants with 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.

Mengovirus replication in Novikoff rat hepatoma and mouse L cells: effects on synthesis of host-cell macromolecules and virus-specific synthesis of ribonucleic acid

Novikoff cells (strain N1S1-67) and L-67 cells, a nutritional mutant of the common strain of mouse L cells which grows in the same medium as N1S1-67 cells, were infected with mengovirus under identical experimental conditions. The synthesis of host-cell ribonucleic acid (RNA) by either type of cell was not affected quantitatively or qualitatively until about 2 hr after infection, when viral RNA synthesis rapidly displaced the synthesis of cellular RNA. The rate of synthesis of protein by both types of cells continued at the same rate as in uninfected cells until about 3 hr after infection, and a disintegration of polyribosomes occurred only towards the end of the replicative cycle, between 5 and 6 hr. The time courses and extent of synthesis of single-stranded and double-stranded viral RNA and of the production of virus were very similar in both types of cells, in spite of the fact that the normal rate of RNA synthesis and the growth rate of uninfected N1S1-67 cells are about three times greater than those of L-67 cells. In both cells, the commencement of viral RNA synthesis coincided with the induction of viral RNA polymerase, as measured in cell-free extracts. Viral RNA polymerase activity disappeared from infected L-67 cells during the period of production of mature virus, but there was a secondary increase in activity in both types of cells coincidental with virus-induced disintegration of the host cells. Infected L-67 cells, however, disintegrated and released progeny virus much more slowly than N1S1-67 cells. The two strains of cells also differed in that replication of the same strain of mengovirus was markedly inhibited by treating N1S1-67 cells with actinomycin D prior to infection; the same treatment did not affect replication in L-67 cells.

Enhancement of St. Louis arbovirus plaque formation by neutral red

Experiments with St. Louis encephalitis (SLE) virus have shown that neutral red enhances the plaque size in duck embryo cell cultures. This may represent a new method for genetic studies of SLE virus population. In a mosquito pool specimen NR(+) and NR(-) particles were demonstrated. By intracerebral passage in mice, there is a selection of NR(+) particles. Similar effects were not shown for eastern, western, and California encephalitis viruses. Plaques formed by the latter virus, however, were significantly reduced in number by neutral red.