A poliovirus 2A(pro) mutant unable to cleave 3CD shows inefficient viral protein synthesis and transactivation defects.

Four poliovirus mutants with modifications of tyrosine 88 in 2A(pro) were generated and introduced into the cloned poliovirus genome. Mutants Y88P and Y88L were nonviable, mutant Y88F showed a wild-type (WT) phenotype, and mutant Y88S showed a delayed cytopathic effect and formed small plaques in HeLa cells. Growth of Y88S in HeLa cells was restricted, giving rise to about 20% of the PFU production of the WT poliovirus. The 2A (Y88S) mutant synthesized significantly lower levels of viral proteins in HeLa cells than did the WT poliovirus, while the kinetics of p220 cleavage were identical for both viruses. Strikingly, the 2A (Y88S) mutant was unable to cleave 3CD, as shown by analysis of poliovirus proteins labeled with [35S]methionine or immunoblotted with a specific anti-3C serum. The ability of the Y88S mutant to form infectious virus and cleave 3CD can be complemented by the WT poliovirus. Synthesis of viral RNA was diminished in the Y88S mutant but less than the inhibition of translation of viral RNA. Experiments in which guanidine was used to inhibit poliovirus RNA synthesis suggest that the primary defect of the Y88S mutant virus is at the level of poliovirus RNA translation, while viral genome replication is much less affected. Transfection of HeLa cells infected with the WT poliovirus with a luciferase mRNA containing the poliovirus 5' untranslated sequence gives rise to a severalfold increase in luciferase activity. This enhanced translation of leader-luc mRNA was not observed when the transfected cells were infected with the 2A (Y88S) mutant. Moreover, cotransfection with mRNA encoding WT poliovirus 2A(pro) enhanced translation of leader-luc mRNA. This enhancement was much lower upon transfection with mRNA encoding 2A(Y88S), 2A(Y88L), or 2A(Y88P). These findings support the view that 2A(pro) itself, rather than the 3C' and/or 3D' products, is necessary for efficient translation of poliovirus RNA in HeLa cells.     

Growth of poliovirus in HeLa cells persistently infected with HVJ (Sendai virus)

The growth of poliovirus in a HeLa cell culture persistently infected with the hemagglutinating virus of Japan (HVJ, the Sendai strain of parainfluenza 1 virus) (HeLaHVJ) was studied. Plaques produced by poliovirus on HeLaHVJ cell monolayers were hazier, smaller and fewer than those on HeLa cells. HeLaHVJ cells were indistinguishable from normal HeLa cells with respect to adsorption rate and penetration efficiency of poliovirus. Extracellular yields of poliovirus in HeLaHVJ cells were lower, and the cytopathic changes were less than those in normal HeLa cells, while cell-associated virus growth in HeLaHVJ cells was nearly equal to that in HeLa cells. HeLaHVJ cells responded more effectively to the action of magnesium chloride, which facilitates virus release from infected cells, resulting in an cytopathic effects. No reduction in poliovirus yield could be detected in HeLa cells acutely infected with HVJ. The relationship between the inhibition of the release of poliovirus from HeLaHVJ cells and the persistent infection of the cells with HVJ is discussed.     

Kinetics of poliovirus uncoating in HeLa cells in a nonacidic environment.

Lysis of HeLa cells infected with poliovirus revealed intact virus; 135S particles, devoid of VP4 but containing the viral RNA; and 80S empty capsids. During infection the kinetics of poliovirus uncoating showed a continuous decrease of intact virus, while the number of 135S particles and empty shells increased. After 1.5 h of infection conformational transition to altered particles resulted in complete disappearance of intact virions. To investigate the mechanism of poliovirus uncoating, which has been suggested to depend on low pH in endosomal compartments of cells, we used lysosomotropic amines to raise the pH in these vesicles. In the presence of ammonium chloride, however, the kinetics of uncoating were similar to those for untreated cells, whereas in cells treated with methylamine, monensin, or chloroquine, uncoating was merely delayed by about 30 min. This effect could be attributed to a delay of virus entry into cells after treatment with methylamine and monensin, whereas chloroquine stabilized the viral capsid itself. Thus, elevation of endosomal pH did not affect virus uncoating. We therefore propose a mechanism of poliovirus uncoating which is independent of low pH.     

Coinfection with recombinant vaccinia viruses expressing poliovirus P1 and P3 proteins results in polyprotein processing and formation of empty capsid structures.

The assembly process of poliovirus occurs via an ordered proteolytic processing of the capsid precursor protein, P1, by the virus-encoded proteinase 3CD. To further delineate this process, we have isolated a recombinant vaccinia virus which expresses, upon infection, the poliovirus P1 capsid precursor polyprotein with an authentic carboxy terminus. Coinfection of HeLa cells with the P1-expressing vaccinia virus and with a second recombinant vaccinia virus which expresses the poliovirus proteinase 3CD resulted in the correct processing of P1 to yield the three individual capsid proteins VP0, VP3, and VP1. When extracts from coinfected cells were fractionated on sucrose density gradients, the VP0, VP3, and VP1 capsid proteins were immunoprecipitated with type 1 poliovirus antisera from fractions corresponding to a sedimentation consistent for poliovirus 75S procapsids. Examination of these fractions by electron microscopy revealed structures which lacked electron-dense cores and which corresponded in size and shape to those expected for poliovirus empty capsids. We conclude that the expression of the two poliovirus proteins P1 and 3CD in coinfected cells is sufficient for the correct processing of the capsid precursor to VP0, VP3, and VP1 as well as for the assembly of poliovirus empty capsid-like structures.     

Complete replication of poliovirus in vitro: preinitiation RNA replication complexes require soluble cellular factors for the synthesis of VPg-linked RNA.

Translation of poliovirion RNA in HeLa S10 extracts resulted in the formation of RNA replication complexes which catalyzed the asymmetric replication of poliovirus RNA. Synthesis of poliovirus RNA was detected in unfractionated HeLa S10 translation reactions and in RNA replication complexes isolated from HeLa S10 translation reactions by pulse-labeling with [32P]CTP. The RNA replication complexes formed in vitro contained replicative-intermediate RNA and were enriched in viral protein 3CD and the membrane-associated viral proteins 2C, 2BC, and 3AB. Genome-length poliovirus RNA covalently linked to VPg was synthesized in large amounts by the replication complexes. RNA replication was highly asymmetric, with predominantly positive-polarity RNA products. Both anti-VPg antibody and guanidine HCl inhibited RNA replication and virus formation in the HeLa S10 translation reactions without affecting viral protein synthesis. The inhibition of RNA synthesis by guanidine was reversible. The reversible nature of guanidine inhibition was used to demonstrate the formation of preinitiation RNA replication complexes in reaction mixes containing 2 mM guanidine HCl. Preinitiation complexes sedimented upon centrifugation at 15,000 x g and initiated RNA replication upon their resuspension in reaction mixes lacking guanidine. Initiation of RNA synthesis by preinitiation complexes did not require active protein synthesis or the addition of soluble viral proteins. Initiation of RNA synthesis by preinitiation complexes, however, was absolutely dependent on soluble HeLa cytoplasmic factors. Preinitiation complexes also catalyzed the formation of infectious virus in reaction mixes containing exogenously added capsid proteins. The titer of infectious virus produced in such trans-encapsidation reactions reached 4 x 10(7) PFU/ml. The HeLa S10 translation-RNA replication reactions represent an efficient in vitro system for authentic poliovirus replication, including protein synthesis, polyprotein processing, RNA replication, and virus assembly.     

Specific cell-surface alteration by enteroviruses as reflected by viral-attachment interference

Crowell, Richard L. (Hahnemann Medical College, Philadelphia, Pa.). Specific cell-surface alteration by enteroviruses as reflected by viral-attachment interference. J. Bacteriol. 91:198-204. 1966.-Exposure of HeLa cells to high levels of coxsackievirus B3 produced cells which were refractory to attachment of coxsackievirus B1, whereas poliovirus T2 attached normally. Under similar conditions, poliovirus T2 was found to interfere with the attachment of poliovirus T1 to HeLa cells without affecting the attachment rate of coxsackievirus B3. The data confirm earlier findings that the receptor sites on HeLa cells, which bind members of group B coxsackieviruses, are distinct from those for polioviruses. Quantitatively, coxsackieviruses B1 and B3 were found to be mutually exclusive in the attachment interference assay to suggest that they compete for the same receptors on the HeLa cell surface. The finding that input multiplicities of B3 virus which exceeded 500 saturated the homologous viral receptors of HeLa cells was unexpected, but was consistent with the results of interference assays. Excessive amounts of input virus did not, however, inhibit eclipse of homologous cell-associated virus. Attachment interference between enteroviruses occurred even though the interfering virus was eclipsed prior to addition of challenge virus. The finding that enterovirus attachment interference was reversible with acid pH suggested that attachment and eclipse of enterovirus does not result in a permanent alteration of the cell membrane and that these events occur at the cell surface.     

Translation of capped viral mRNAs in poliovirus-infected HeLa cells.

HeLa cells doubly infected with Semliki Forest virus (SFV) and poliovirus synthesize either more poliovirus proteins or more SFV late proteins depending on the time of super-infection with poliovirus. Under some conditions, the infected cells translate uncapped poliovirus mRNA and capped 26S mRNA from SFV simultaneously, even though host protein synthesis has been shut down. Vesicular stomatitis virus (VSV) protein synthesis is depressed drastically when VSV-infected cells are super-infected with poliovirus. In cells doubly infected with VSV and encephalomyocarditis (EMC) virus or with VSV and SFV, dominance of one of the viruses depends on the time of addition of the challenge virus. The influence of external conditions on the relative translation of capped or uncapped viral mRNA in doubly infected cells has also been analysed.     

Isolation and characterization of HeLa cell lines blocked at different steps in the poliovirus life cycle.

Cotransfection of poliovirus RNA and R1, a poliovirus subgenomic RNA containing a deletion of nearly all of the capsid region, resulted in surviving cells, in contrast to the complete cell death observed after transfection with viral RNA. Cells that survived the cotransfection grew into colonies, produced infectious poliovirus, and underwent cycles of cell lysis (crisis periods) where less than 1% of the cells survived, followed by periods of growth. Poliovirus evolved during the persistent infection as judged by changes in plaque size. After passage for 6 months, a stable line called SOFIA emerged that no longer produced infectious virus and did not contain viral proteins or viral RNA. Cells frozen in liquid N2 while still in crisis and recultured 4 months later (named SOFIA N2) were also stabilized. After infection with poliovirus, SOFIA N2 cells showed a delay in the development of cytopathic effect, viral production, and cellular death when compared with HeLa cells. In contrast, SOFIA cells did not develop cytopathic effect and produced 10,000 times less virus than SOFIA N2 or HeLa cells. Viral production was delayed in SOFIA and SOFIA N2 cells transfected with poliovirus RNA when compared with HeLa cells, suggesting the presence of an intracellular block to poliovirus replication. Analysis of the cellular receptor for poliovirus by virus binding, an enzyme-linked immunosorbent assay, and in situ rosette assays with an antireceptor monoclonal antibody showed that receptors were expressed in SOFIA N2 cells but not in SOFIA cells. Echovirus 6, an enterovirus which uses a different cellular receptor, formed small plaques on SOFIA cells. Vesicular stomatitis virus formed plaques of similar size on SOFIA and HeLa cells, suggesting that the intracellular block was specific for enteroviruses. Cotransfection of the subgenomic replicon R1 with poliovirion RNA therefore resulted in the selection of HeLa cell variants containing blocks to poliovirus replication at the level of receptor and within the cell.     

Differential Inhibition of Attachment and Eclipse Activities of HeLa Cells for Enteroviruses

Receptor activities of HeLa cells were evaluated for ability to both attach and eclipse enteroviruses after exposure of cells to acid or heat. A modified procedure of acid (pH 1.5) elution of cell-associated virus, as compared with other procedures, provided a general method for the optimal recovery of receptor-bound enteroviruses. With this procedure, eclipse of virus operationally was considered to be that amount of virus infectivity which was determined initially to be cell-associated and which was not dissociable from the cells. HeLa cells killed by heating at 56 C for 30 min could not attach or eclipse poliovirus T1, but they attached and eclipsed coxsackieviruses B1 and B3, and they attached echovirus 6 but did not eclipse it. HeLa cells treated at pH 2.5 for 10 min at 2 C could not attach or eclipse poliovirus T1, but they attached coxsackieviruses B1 and B3 and echovirus 6, although these viruses were not eclipsed. These results showed that, within the operational definition of virus eclipse, the eclipse activity of HeLa cells for some viruses can be irreversibly inactivated without impairing the activity of the receptors for attaching these viruses. The data provided additional evidence that HeLa cells possess specific receptors for the different enteroviruses.     

Cell-dependent role for the poliovirus 3' noncoding region in positive-strand RNA synthesis

We previously reported the isolation of a mutant poliovirus lacking the entire genomic RNA 3' noncoding region. Infection of HeLa cell monolayers with this deletion mutant revealed only a minor defect in the levels of viral RNA replication. To further analyze the consequences of the genomic 3' noncoding region deletion, we examined viral RNA replication in a neuroblastoma cell line, SK-N-SH cells. The minor genomic RNA replication defect in HeLa cells was significantly exacerbated in the SK-N-SH cells, resulting in a decreased capacity for mutant virus growth. Analysis of the nature of the RNA replication deficiency revealed that deleting the poliovirus genomic 3' noncoding region resulted in a positive-strand RNA synthesis defect. The RNA replication deficiency in SK-N-SH cells was not due to a major defect in viral translation or viral protein processing. Neurovirulence of the mutant virus was determined in a transgenic mouse line expressing the human poliovirus receptor. Greater than 1,000 times more mutant virus was required to paralyze 50% of inoculated mice, compared to that with wild-type virus. These data suggest that, together with a cellular factor(s) that is limiting in neuronal cells, the poliovirus 3' noncoding region is involved in positive-strand synthesis during genome replication.     

The clathrin endocytic pathway in viral infection.

How important is the clathrin-dependent endocytic pathway for entry of viruses into host cells? While it is widely accepted that Semliki Forest virus (SFV), an enveloped virus, requires this pathway there are conflicting data concerning the closely related Sindbis virus, as well as varying results with picornaviruses such as human rhinovirus 14 (HRV 14) and poliovirus. We have examined the entry mode of SFV, Sindbis virus, HRV 14 and poliovirus using a method that identifies single infected cells. This assay takes advantage of the observation that the clathrin-dependent endocytic pathway is specifically and potently arrested by overexpression of dynamin mutants that prevent clathrin-coated pit budding. Using HeLa cells and conditions of low multiplicity of infection to favor use of the most avid pathway of cell entry, it was found that SFV, Sindbis virus and HRV 14 require an active clathrin-dependent endocytic pathway for successful infection. In marked contrast, infection of HeLa cells by poliovirus did not appear to require the clathrin pathway.     

Preparation of Poliovirus Labeled with Phosphorus-33

Phosphorus-33 ((33)P), a weak (0.25 Mev) beta-emitting isotope of phosphorus with a half-life of 25 days, has been used to label poliovirus in cell culture. HeLa cell monolayers were depleted of phosphate and then labeled by incubating at 37 C in a medium (LM) containing about 10 muCi of (33)P as orthophosphate per ml. Labeled cells were infected at a high multiplicity with poliovirus type 1 and incubated for 8 hr in LM medium. Virus from infected cells was then concentrated and purified. Virus purity was confirmed by comparison of virus infectivity and radioactivity after CsCl density gradient centrifugation and by observing purified virus preparations with electron microscopy. With the method described, yields of about 10(10) to 5 x 10(10) plaque-forming units (PFU) of highly purified poliovirus with specific activities of about 3 x 10(-4) to 10(-3) disintegrations per min per PFU have been obtained from 1.5 x 10(8) to 3.0 x 10(8) HeLa cells.     

Requirements for entry of poliovirus RNA into cells at low pH.

HeLa S3 cells were protected against infection by poliovirus type I by the presence of monensin and N,N'-dicyclohexylcarbodiimide (DCCD), compounds elevating the pH of acidic intracellular compartments. The protection was fully overcome by exposing the cells to pH 5.5 and lower, and at approximately pH 6.1 it was reduced by half. Measurements of the ability of the virus to enter the detergent phase under conditions where Triton X-114 was separated from water indicated that the virus is hydrophilic at neutral pH, and that it exposes hydrophobic regions at low pH. When the cells were pretreated with acetic acid, which reduces the intracellular pH, virus entry was inhibited, indicating that a pH gradient across the membrane is necessary for infection. Under all conditions which induced infection, the virus particles were altered to more slowly sedimenting material. Also, virus bound to aldehyde-fixed cells was altered when exposed to low pH at 37 degrees C. The data indicate that poliovirus bound to receptors on cells exposes hydrophobic regions at low pH, and that at physiological temperature it undergoes alteration. This alteration may be a necessary, but not sufficient requirement for infection.     

The poliovirus 135S particle is infectious.

The molecular mechanism of cell entry by unenveloped viruses is poorly understood. The picornaviruses poliovirus, human rhinovirus, and coxsackievirus convert to an altered form (the 135S or A particle) upon interaction with receptors on susceptible cells at 37 degrees C. The 135S particle is thought to be a necessary intermediate because it accumulates inside susceptible cells soon after infection and drugs which inhibit conversion of the virus to this form also prevent infection. However, since a variable fraction of the altered 135S particles is reported to elute unproductively from the surface of susceptible cells, their precise role remains unclear. We have found that poliovirus 135S particles can infect Chinese hamster ovary (CHO) and murine L cells, neither of which are susceptible to infection by native poliovirus. The infectivity of the particles in tissue culture appears to be between 10(3) to 10(5) times less than that of poliovirus on HeLa cells. The 135S particle infectivity was not sensitive to RNase but was greatly reduced by proteolytic treatment. Proteolysis specifically removed the newly exposed N terminus of VP1, a feature which has previously been shown to mediate interactions of the particle with lipid membranes. These results demonstrate that although the infectivity of the 135S particle appears to be receptor independent, it nonetheless requires some property associated with the protein coat. In particular, the N terminus of VP1 plays an important role in the infection process. Our findings are consistent with the hypothesis that the 135S particle is an intermediate in the normal cell entry pathway of poliovirus infection.     

Modulation of poliovirus replicative fitness in HeLa cells by deoptimization of synonymous codon usage in the capsid region

We replaced degenerate codons for nine amino acids within the capsid region of the Sabin type 2 oral poliovirus vaccine strain with corresponding nonpreferred synonymous codons. Codon replacements were introduced into four contiguous intervals spanning 97% of the capsid region. In the capsid region of the most highly modified virus construct, the effective number of codons used (N(C)) fell from 56.2 to 29.8, the number of CG dinucleotides rose from 97 to 302, and the G+C content increased from 48.4% to 56.4%. Replicative fitness in HeLa cells, measured by plaque areas and virus yields in single-step growth experiments, decreased in proportion to the number of replacement codons. Plaque areas decreased over an approximately 10-fold range, and virus yields decreased over an approximately 65-fold range. Perhaps unexpectedly, the synthesis and processing of viral proteins appeared to be largely unaltered by the restriction in codon usage. In contrast, total yields of viral RNA in infected cells were reduced approximately 3-fold and specific infectivities of purified virions (measured by particle/PFU ratios) decreased approximately 18-fold in the most highly modified virus. The replicative fitness of both codon replacement viruses and unmodified viruses increased with the passage number in HeLa cells. After 25 serial passages (approximately 50 replication cycles), most codon replacements were retained, and the relative fitness of the modified viruses remained well below that of the unmodified virus. The increased replicative fitness of high-passage modified virus was associated with the elimination of several CG dinucleotides. Potential applications for the systematic modulation of poliovirus replicative fitness by deoptimization of codon usage are discussed.     

Effect of poliovirus on deoxyribonucleic acid synthesis in HeLa cells

Ackermann, W. W. (University of Michigan, Ann Arbor), D. C. Cox, H. Kurtz, C. D. Powers, and S. J. Davies. Effect of poliovirus on deoxyribonucleic acid synthesis in HeLa cells. J. Bacteriol. 91:1943-1952. 1966.-Both poliovirus and arginine stimulated deoxyribonucleic acid (DNA) synthesis in cultures of HeLa cells which were preconditioned by incubation in a medium deficient in arginine. However, the number of cells producing DNA was unaffected. DNA synthesis in such preconditioned cells was 10 to 20% of the maximal value obtained with a full complement of amino acids. Inhibition of DNA synthesis was produced in these cultures either by increasing the multiplicity of exposure above 40 plaque-forming units of virus per cell or by increasing the concentration of the deficient amino acid at the time of virus addition. Inhibition of DNA synthesis resulted from a reduction in the fraction of cells producing DNA. The concentration of arginine required for viral inhibition of DNA synthesis is greater than that for viral multiplication.     

Degradation of cellular proteins during poliovirus infection: studies by two-dimensional gel electrophoresis.

Picornaviruses encode for their own proteinases, which are responsible for the proteolytic processing of the polyprotein encoded in the viral genome to produce the mature viral polypeptides. The two poliovirus proteinases, known as proteins 2A and 3C, use the poliovirus-encoded polyprotein as a substrate. The possibility that these poliovirus proteinases also degrade cellular proteins remains largely unexplored. High-resolution two-dimensional gel electrophoresis indicates that a few cellular proteins disappear after poliovirus infection. Thus, at least nine acidic and five basic cellular proteins, ranging in Mr from 120 to 30 kilodaltons, are clearly degraded during poliovirus infection of HeLa cells. The degradation of these cellular polypeptides is very specific because it does not occur upon infection of HeLa cells with encephalomyocarditis virus or Semliki Forest virus. Moreover, inhibitors of poliovirus replication, such as cycloheximide or 3-methylquercetin, block the disappearance of these polypeptides. These results suggest that the input virions are not responsible for this degradation and that active poliovirus replication is required for the proteolysis to occur. Analysis of the time course of the disappearance of these polypeptides indicates that it does not occur during the first 2 h of infection, clearly suggesting that this phenomenon is not linked to the poliovirus-induced shutoff of host protein synthesis. This conclusion is strengthened by the finding that 3-methylquercetin blocks proteolysis without preventing shutoff of host translation.     

Purification of a HeLa cell receptor protein for group B coxsackieviruses.

Coxsackievirus B3 (CB3) firmly attaches to HeLa cells, forming a specific complex between the virus and its receptor on the cell surface. We extracted this virus-receptor complex (VRC) with the detergents sodium deoxycholate and Triton X-100. The VRC was identified by its sedimentation coefficient (140S), which was less than that of virions (155S). Formation of the VRC from cell lysates and 3H-CB3 occurred with the same specificity as did attachment of virions to cells, in that its formation was blocked by unlabeled CB3 but not by poliovirus. The VRC was purified 30,000-fold by differential and sucrose gradient centrifugation. Iodination with Na125I revealed that the purified VRC consisted of the normal CB3 proteins and one additional protein (RP-a) with an approximate molecular weight of 49,500. RP-a was eluted from the VRC and was shown to rebind with CB3 and CB1 virions but not with poliovirus type 1. We propose that Rp-a is a protein in the plasma membrane receptor complex which is responsible for the specific recognition and binding of the group B coxsackieviruses.     

Shutoff of HeLa cell protein synthesis by encephalomyocarditis virus and poliovirus: a comparative study.

Previous experimental results have suggested that poliovirus and encephalomyocarditis (EMC) virus employ very different mechanisms for shutting off host protein synthesis. However, this conclusion is suspect, inasmuch as different cell types were used for the two viruses; hence the apparent mechanistic differences might be specific for cell type and not virus type. To test this possibility we compared shutoff mechanisms in poliovirus- and EMC virus-infected HeLa cells. Striking differences were seen: poliovirus-induced shutoff was much more rapid and extensive than that induced by EMC virus; relative translation rates of certain host proteins were inhibited to different extents by the two viruses; initiation factors prepared from poliovirus-infected cells were specifically defective for translation of capped mRNA's in vitro, whereas those from EMC virus-infected cells were not. These results indicate that EMC virus and poliovirus employ different mechanisms for the shutoff of HeLa cell protein synthesis. This conclusion is consistent with much earlier work and indicates that many differences previously reported are specific to virus type.     

Encephalomyocarditis Viral RNA Can Be Translated Under Conditions of Poliovirus-Induced Translation Shutoff In Vivo

Superinfection with poliovirus of HeLa cells already infected with encephalomyocarditis (EMC) virus does not inhibit translation of EMC viral mRNA, whereas residual host translation is completely inhibited. This result indicates that the cap recognition factors inactivated by poliovirus are not required for translation of EMC viral mRNA in vivo, in agreement with previous in vitro experiments. This raises the question of why EMC virus has evolved a capindependent translation mechanism.