Permeabilization of cells during animal virus infection

Hygromycin B resistance mediates elimination of Leishmania virus from persistently infected parasites

A series of pX63-HYG derivatives encoding Leishmania RNA virus 1-4 (LRV1-4) sequences were electroporated into cells of Leishmania strain M4147, a virus-infected strain of L. guyanensis. After 6 weeks of drug selection (hygromycin B), transfected parasites lacked detectable quantities of viral genomic double-stranded RNA, viral capsid protein, and RNA-dependent RNA polymerase (RDRP) activity. Evidence of viral infection was not recovered upon removal of the drug. While viral RNA transcripts were produced from electroporated expression vectors, as determined by reverse transcription-PCR, viral antigens were not detected, suggesting that the antiviral effects of hygromycin B are mediated through translation inhibition. A short-term selection study suggests that the LRV1-4 elimination may not only be a function of hygromycin B as a protein synthesis inhibitor but also possibly related to the mechanism of hygromycin B resistance in Leishmania strains.

Modification of membrane permeability by animal viruses

Animal viruses permeabilize cells at two well-defined moments during infection: (1) early, when the virus gains access to the cytoplasm, and (2) during the expression of the virus genome. The molecular mechanisms underlying both events are clearly different; early membrane permeability is induced by isolated virus particles, whereas late membrane leakiness is produced by newly synthesized virus protein(s) that possess activities resembling ionophores or membrane-active toxins. Detailed knowledge of the mechanisms, by which animal viruses permeabilize cells, adds to our understanding of the steps involved in virus replication. Studies on early membrane permeabilization give clues about the processes underlying entry of animal viruses into cells; understanding gained on the modification by viral proteins of membrane permeability during virus replication indicates that membrane leakiness is required for efficient virus release from infected cells or virus budding, in the case of enveloped viruses. In addition, the activity of these membrane-active virus proteins may be related to virus interference with host cell metabolism and with the cytopathic effect that develops after virus infection.

Influenza virus M2 protein modifies membrane permeability in E. coli cells

The M2 protein of influenza virus is an integral membrane protein with ion channel activity. This protein has been expressed in E. coli cells in an inducible manner. Expression of the M2 protein causes rapid lysis of BL21(DE3) pLysS E. coli cells upon induction with IPTB. M2 protein increases membrane permeability to a number of hydrophylic molecules, such as ONPG, uridine or impermeant translation inhibitors. The behaviour of M2 in bacteria resembles that of other viral proteins, such as poliovirus 3A and Semliki Forest virus 6K.

Effects of the angiotensin II receptor antagonist losartan on herpes simplex virus-type 2 infection of cultured vero and cardiac neonatal myocytes

Previous studies indicate that captopril, an angiotensin II converting enzyme inhibitor, attenuates cardiomyopathy in a murine viral myocarditis model. Accordingly, we investigated the ability of captopril as well as angiotensin II (AII) and losartan, a nonpeptide AII receptor antagonist, to alter infection or replication of herpes simplex virus- type 2 (HSV-2) in cultured cardiac and vero cells. Neither captopril nor AII influenced the ability of HSV-2 to replicate in either cell type. Losartan, however, caused a dose dependent decrease in pfu ability on vero cells with an ED50 of 1.35 mM. In cultured myocytes, losartan (400 microM) reduced significantly %LDH released (54.9 +/- 7.5 vs 29.1 +/- 4.2 in infected controls) and % pfu released (40.9 +/- 8.4 vs 14.8 +/- 3.8 in infected controls) into the media. These results suggest that losartan attenuates deleterious effects of the virus by preventing release of the virus by the cells.

Dissipation of the calcium gradient in human erythrocytes results in increased heat production

Heat production rates were measured by a microcalorimetric method in suspended human erythrocytes in the absence and presence of different concentrations of the divalent cationophore A23187. Determinations were carried out during 60 min under static conditions on erythrocytes incubated in various isotonic media at 37 degrees C, pH 7.35. In incubations containing the ionophore, time-power curves showed an early peak followed by a descending slope levelling off at a steady state after 30-60 min. In contrast, the controls lacked the early peak, showing hyperbolic ascending curve profiles before reaching steady state. The appearance of the early peak in the presence of ionophore was dependent upon the composition of the medium, both Mg2+ ions and glucose being decisive. Likewise, dose-response relationships concerning heat production at 60 min depended on the composition of the media. In a basic incubation medium lacking Mg2+ and glucose, no effect was seen on heat production by the ionophore (1-3 mumol/l). Rather modest effects were obtained by the ionophore at 2 and 3 mumol/l when Mg2+ was present. A clear-cut dose-response relationship was observed in a Mg2+ and glucose enriched medium for the ionophore from 1-3 mumol/l. The significant increase in heat production observed at 60 min with 2 mumol/l of A23187 in the Mg2+ and glucose enriched medium was abolished by 1 mmol/l EGTA. Calmidazolium, a calmodulin antagonist, could only marginally reduce the ionophoric effect on heat production. It was concluded that the appearance of the early peak was not the result of an increase in glycolytic rate but rather a consequence of the ionophoric action on the Ca2+ gradient.

Protein synthesis in vaccinia virus-infected cells. I. Effect of hypertonic shock recovery

Human Hep-2 cells were submitted to hypertonic shock (210 mM NaCl) to block host protein synthesis before infection with vaccinia virus. With the start of infection, the medium isotonicity (116 mM NaCl) was restored, and the effect of viral infection on the recovery of host polyribosomes and protein synthesis was studied. Although host translation blockage was released together with infection, vaccinia virus did not affect immediately host protein synthesis. During the first hour of recovery, infected cells could perfectly rebuild the polyribosome profile and recuperate the rate of protein synthesis. Also, during recovery, formation of the initiation complex for protein synthesis was not affected by viral infection. In this period, viral mRNA and proteins were detected by slot blot and SDS-polyacrylamide gel electrophoresis. The inhibitory effect of vaccinia virus on host translation was observed after the second hour of infection. These findings suggest that vaccinia virus-mediated shutoff occurs in a later period during infection, in parallel with viral mRNA accumulation in the polyribosomes and after the on-set of viral DNA replication.

Effect of rotavirus infection on intracellular calcium homeostasis in cultured cells

The effect of rotavirus infection on intracellular [Ca2+] was studied in a model system (MA-104 cells). In cells infected at high multiplicity with the OSU strain of rotavirus, production of infectious viruses was maximal at 6 hr postinfection. Cell death, as measured by incorporation of ethidium bromide, started at 6 hr and was complete at 15 hr postinfection. At 4 hr postinfection, intracellular [Ca2+], measured by quin2 fluorescence, was not modified, but Ca2+ permeability was increased. With progression of the infection, intracellular [Ca2+] and Ca2+ pools increased due to the failure of regulatory mechanisms to compensate increased Ca2+ entry. These effects were blocked by cycloheximide added up to 5 hr postinfection, but not by actinomycin D. Reduced extracellular [Ca2+] afforded protection of cell death induced by infection, under conditions at which production of infectious viruses was not affected. The cytopathic effect of rotavirus on host cells appears to be mediated by an increase in intracellular [Ca2+] induced by the synthesis of a viral product. The failure of ionic homeostasis of the enterocyte might be involved in the development of diarrhea.

Modification of membrane permeability by animal viruses

Animal viruses modify membrane permeability during lytic infection. There is a co-entry of macromolecules and virion particules during virus penetration and a drastic change in transport and membrane permeability at the late stages of the lytic cycle. Both events are of importance to understand different molecular aspects of viral infection, as virus entry into the cell and the interference of virus infection with cellular metabolism. Other methods of cell permeabilization of potential relevance to understand the mechanism of viral damage of the membrane are also discussed.

Exogenous phospholipase C permeabilizes mammalian cells to proteins

Mammalian cells treated with low concentrations of phospholipase C become permeable to the protein toxin alpha-sarcin. A similar permeabilization is not induced upon treatment with other lipases such as phospholipase A2, sphingomyelinase, or cholesterol esterase. Concentrations of 10 micrograms/ml alpha-sarcin almost completely blocked translation in HeLa cells treated with 0.3 U/ml phospholipase C (PL-C) for 1 h. In contrast, 200 micrograms/ml of alpha-sarcin had no effect at all on protein synthesis in untreated cells. Other macromolecules such as horseradish peroxidase and luciferase also enter into cells if they are treated with phospholipase C. This permeabilization method is fully reversible. As soon as 5 min after PL-C removal, the cells become impermeable to alpha-sarcin. Other metabolites such as uridine nucleotides are partially released after PL-C incubation, whereas the content of 86Rb+ remains at control levels, probably because the Na+/K+ ATPase activity increases.

Cell surface effects of human immunodeficiency virus

Cell killing by human immunodeficiency virus (HIV) is thought to contribute to many of the defects of the acquired immunodeficiency syndrome (AIDS). Two types of cytopathology are observed in HIV-infected cultured cells: cell-cell fusion and killing of single cells. Both killing processes appear to involve cell surface effects of HIV. A model is proposed for the HIV-mediated cell surface processes which could result in cell-cell fusion and single cell killing. The purpose of this model is to define the potential roles of individual viral envelope and cell surface molecules in cell killing processes and to identify alternative routes to the establishment of persistently-infected cells. Elucidation of HIV-induced cell surface effects may provide the basis for a rational approach to the design of antiviral agents which are selective for HIV-infected cells.

Proteins are cointernalized with virion particles during early infection

Mammalian cells infected with enveloped or naked animal viruses become permeabilized to several proteins. The entry of alpha-sarcin, horseradish peroxidase, and luciferase is greatly increased during the early stages of viral infection. This process is promoted by uv-inactivated SFV, but not by heat-inactivated virions, suggesting that the process does not require viral gene expression. The entry of alpha-sarcin has been monitored both by its effects on protein synthesis and by indirect immunofluorescence. Increased entry of alpha-sarcin and luciferase is clearly observed in animal virus-infected cells by fluorescence microscopy. Chloroquine blocks the coentry of alpha-sarcin with enveloped, but not with naked, viruses. These results have implications to elucidate the mechanisms involved in virus entry.

L929 cells infected with temperature sensitive mutants of vesicular stomatitis virus: virus replication is necessary for induction of changes in membrane permeability

Infection of L929 murine cells with vesicular stomatitis virus (VSV) results in inhibition of host protein synthesis and appearance of membrane alterations at a time when cells are still actively engaged in viral protein synthesis. VSV temperature-sensitive (ts) mutants have been used to explore the role(s) played by the virus-coded proteins in the genesis of these effects. Cells were infected with each of five ts mutants representing the known complementation groups of VSV Indiana serotype, and incubated at permissive (32 degrees C) and non-permissive temperatures (39 degrees C). Protein synthesis in the presence and absence of Hygromycin B (Hyg. B) was analyzed during virus infection via incorporation of 35S-methionine in acid-precipitable material and SDS-polyacrylamide gel electrophoresis. Data indicate that mutants belonging to groups I (L protein), II (NS protein) and IV (N protein) do not inhibit host protein synthesis and do not induce any membrane changes when grown at the non-permissive temperature. Mutants of group III (M protein) and V (G protein), instead, do inhibit cell protein synthesis and induce membrane changes also when grown at the non-permissive temperature; this suggests that these effects do not correlate with the biological activity of these proteins and their interaction with the cellular membrane. On the other hand, mutants exhibiting defective steps of nucleocapsid replication are apparently unable to induce these effects once more suggesting that virus replication per se is essential, as also indirectly shown by experiments employing cycloheximide to mimic shut-off.

Flow cytometric evaluation of anti-herpes drugs

A rapid means of screening drugs for toxicity and anti-herpes simplex virus activity was developed based on the flow cytometric detection of HSV induced changes in cellular DNA content. Subconfluent monolayers of human diploid fibroblasts (HEL 299) were assayed for DNA content with propidium iodide 24 h after infection with HSV-1 (multiplicity of infection 1-10) and treatment with the drug to be tested. Infection was detected by a broadening of the normal diploid and tetraploid peaks and presence of greater than 4-n DNA staining. Inhibition of viral DNA synthesis and maintenance of the normal growth pattern of control cells was indication of antiviral activity. Toxicity of the compound was indicated by the loss of S phase and tetraploid cell populations. Using this assay, we evaluated the activities of one experimental and two established antiviral agents.

Control of membrane permeability in animal cells by divalent cations

The permeability of several cell lines, including HeLa, L929, 3T6 and 3T3, to various compounds is affected by the concentration of divalent cations in the culture medium. In the absence of Mg2+ ions but with 4-8 mM CaCl2 in the medium, HeLa and L929 cells become permeabilized, as measured by the entry of the aminoglycoside antibiotic hygromycin B. However, 3T3 and 3T6 cells become much more permeable when calcium and magnesium are both absent from the medium. Addition of Mg2+ above 2 mM abolishes the permeabilization induced by Ca2+. Basic pH favors permeabilization, whereas acidic pH inhibits the entry of hygromycin B. Increased entry of macromolecules, such as the toxin alpha-sarcin, horseradish peroxidase (HRP) and luciferase, is also observed under permeabilization conditions, suggesting that this method could be of general use, since it is not harmful to cells and is fully reversible. Exit of 86Rb+ ions and [3H]uridine-labelled nucleotides was also assayed. We did not observe increased release of these compounds from preloaded cells under various calcium concentrations. Finally, the effects of several inhibitors of endocytosis and other membrane functions on the permeabilization inhibitors of endocytosis and other membrane functions on the permeabilization process were also analysed. The entry of alpha-sarcin was not affected by nifedipine, dibucaine or mepacrine, but was partially inhibited by NH4Cl, amantadine and chloroquine.

Increased sensitivity of virus-infected cells to inhibitors of protein synthesis does not correlate with changes in plasma membrane permeability

Semliki Forest virus-infected BHK cells or herpes simplex virus-infected Vero cells were incubated with the protein synthesis inhibitors hygromycin B and gougerotin. Infected cells take up no more [3H]hygromycin or [3H]gougerotin than do mock-infected cells, at a time p.i. at which either compound is more inhibitory to protein synthesis in infected, than in mock-infected cells. The concentrations of hygromycin and gougerotin required to inhibit protein synthesis in intact cells (irrespective of whether they are infected or not) are several orders of magnitude higher than those required in either permeabilized cells or in cell-free systems. Infected cells take up 86Rb+ at the same rate as mock-infected cells, their intracellular content of K+ is the same, and the activity of the Na+ pump is the same. It is concluded that the increased efficacy of hygromycin and gougerotin in virus-infected cells is a consequence of altered intracellular compartmentation and that increases in permeability of the plasma membrane, if any, are so small as to be undetectable by direct methods.

Increased sugar transport in BHK cells infected with Semliki Forest virus or with herpes simplex virus

Infection of BHK cells by SFV increases the rate of uptake of [3H]MeGlc and of [3H]dGlc at approximately 2 hours p.i. Infection by HSV increases the uptake of [3H]MeGlc and [3H]dGlc at approximately 10 hours p.i.; the increased uptake is prevented by acyclovir. It is concluded that an increased sugar uptake by infected cells reflects an increased rate of transport across the plasma membrane and is the result of cellular changes caused by virus infection.

External ATP permeabilizes transformed cells to macromolecules

External ATP under certain ionic conditions render transformed cells permeable to the translation inhibitor hygromycin B. With this method the protein toxin alpha-sarcin selectively penetrates into 3T6 cells, as compared to 3T3 cells. This entry is enhanced by ATP synthesis blockers such as CCCP. Other proteins, such as horseradish peroxidase and luciferase, also pass selectively in 3T6 cells under permeabilization conditions.

Regulation of protein synthesis in virus-infected animal cells

This chapter summarizes the structural features that govern the translation of viral mRNAs: where the synthesis of a protein starts and ends, how many proteins can be produced from one mRNA, and how efficiently. It focuses on the interplay between viral and cellular mRNAs and the translational machinery. That interplay, together with the intrinsic structure of viral mRNAs, determines the patterns of translation in infected cells. It also points out some possibilities for translational regulation that can only be glimpsed at present, but are likely to come into focus in the future. The mechanism of selecting the initiation site for protein synthesis appears to follow a single formula. The translational machinery displays a certain flexibility that is exploited more frequently by viral than by cellular mRNAs. Although some of the parameters that determine efficiency have been identified, how efficiently a given mRNA will be translated cannot be predicted by summing the known parameters.

Modification of membrane permeability during Semliki Forest virus infection

Modification of membrane permeability has been analyzed in Semliki Forest virus (SFV)-infected cells by means of translation inhibitors not permeable to normal cells. A higher inhibition of protein synthesis in the infected cells is only observed with those antibiotics that do not easily pass the cell membrane, but not with others, permeable to cells, such as anisomycin, cycloheximide, trichodermin, etc. It does not, therefore, seem that the suggestion of M. A. Gray, K. J. Micklem, and C. A. Pasternak [Eur. J. Biochem. 135, 299-302, (1983)] that protein synthesis in virus-infected cells is more susceptible to translation inhibitors in general is correct. Both low- and high-molecular weight compounds enter the cell very early during SFV infection. This permeabilization is blocked by compounds known to increase the pH of coated vesicles, such as NH4Cl and chloroquine. Inhibition of energy production by means of N3Na and 2'-deoxyglucose also blocks this process. The optimal external pH for this early permeabilization is around 7-8. Acidic pH inhibits the entry of these impermeant antibiotics promoted by SFV. Analysis of 86Rb+ content in SFV-infected HeLa cells also indicates that a drastic decline in this cation takes place, in agreement with previous findings, but disagreeing with the previous results. A parallel between the decrease in this cation and the blockade of protein synthesis is apparent, throughout the course of infection. In addition to the early permeabilization that takes place during virus entry, increased entry of hygromycin B and alpha-sarcin also occurs in SFV-infected cells from 2 to 3 hr postinfection, but not when late viral replication is blocked by means of interferon treatment.

pppA2'p5A' blocks vesicular stomatitis virus replication in intact cells

pppA2'p5'A blocked the production of infectious vesicular stomatitis virus in HeLa cells. When this compound was present from the beginning of infection, a selective inhibitory effect was observed in viral protein synthesis. Thus, cellular translation was not affected even after 10 h of incubation with this compound, and the bulk of viral proteins was not synthesized. However, this effect was not observed with ATP, GTP, or the core A2'p5'A. The step blocked by pppA2'p5'A is located early during virus infection, but adsorption, entry, and virus uncoating seemed to be unaffected by this compound. Analysis of the antiviral spectrum of pppA2'p5'A indicated that it is active against poliovirus, encephalomyocarditis virus, and Semliki Forest virus and shows no effect against herpes simplex virus type 1 and adenovirus type 5.

Action of oligomycin on cultured mammalian cells. Permeabilization to translation inhibitors

Oligomycin, an inhibitor of ATP synthesis, has been used as a model to study the effects of ATP depletion on macromolecular synthesis and modification of membrane permeability. Protein synthesis is totally blocked by the antibiotic, whereas RNA and DNA synthesis are less inhibited. Different concentrations of monovalent and divalent cations do not revert the inhibition of protein synthesis. Measurement of cellular ATP and 86Rb+ content indicate that the blockade of translation depends on the ATP content. A significant decrease in cellular ATP does not lead to the reduction of monovalent ions in the cell, although hyperpolarization of the cell membrane does take place. An increased membrane permeability to some inhibitors develops when the cells are hyperpolarized by oligomycin.