Monensin and nigericin prevent the inhibition of host translation by poliovirus, without affecting p220 cleavage.

Addition of monensin or nigericin after poliovirus entry into HeLa cells prevents the inhibition of host protein synthesis by poliovirus. The infected cells continue to synthesize cellular proteins at control levels for at least 8 h after infection in the presence of the ionophore. Cleavage of p220 (gamma subunit of eukaryotic initiation factor 4 [eIF-4 gamma]), a component of the translation initiation factor eIF-4F, occurs to the same extent in poliovirus-infected cells whether or not they are treated with monensin. Two hours after infection there is no detectable intact p220, but the cells continue to translate cellular mRNAs for several hours at levels similar to those in uninfected cells. Nigericin or monensin prevented the arrest of host translation at all the multiplicities of poliovirus infection tested. At high multiplicities of infection, an unprecedented situation was found: cells synthesized poliovirus and cellular proteins simultaneously. Superinfection of vesicular stomatitis virus-infected HeLa cells with poliovirus led to a profound inhibition of vesicular stomatitis virus protein synthesis, while nigericin partially prevented this blockade. Drastic inhibition of translation also took place in influenza virus-infected Vero cells treated with nigericin and infected with poliovirus. These findings suggest that the translation of newly synthesized mRNAs is dependent on the integrity of p220, while ongoing cellular protein synthesis does not require an intact p220. The target of ionophore action during the poliovirus life cycle was also investigated. Addition of nigericin at any time postinfection profoundly blocked the synthesis of virus RNA, whereas viral protein synthesis was not affected if nigericin was added at 4 h postinfection. These results agree well with previous findings indicating that inhibitors of phospholipid synthesis or vesicular traffic interfere with poliovirus genome replication. Therefore, the action of nigericin on the vesicular system may affect poliovirus RNA synthesis. In conclusion, monensin and nigericin are potent inhibitors of poliovirus genome replication that prevent the shutoff of host translation by poliovirus while still permitting cleavage of p220.     

Hybrid proteins between Pseudomonas aeruginosa exotoxin A and poliovirus 2Apro cleave p220 in HeLa cells.

Cleavage of p220, a component of the initiation factor eIF-4F, has been correlated with the inhibition of host translation during poliovirus infection. To obtain p220 cleavage in the absence of any other poliovirus gene products, hybrid proteins containing Pseudomonas aeruginosa exotoxin A and poliovirus protease 2Apro have been constructed. The addition of the hybrid molecules to cultured cells did not lead to substantial p220 cleavage. However, the simultaneous presence of the hybrid toxin with replicationally inactive chicken adenovirus particles results in efficient cleavage of p220 in the intact cells. Under these conditions, cellular translation continues unabated for several hours, arguing against a direct requirement for intact p220 in each round of the initiation of translation of cellular mRNAs.     

Proteolysis of the p220 component of the cap-binding protein complex is not sufficient for complete inhibition of host cell protein synthesis after poliovirus infection.

Infection of cells with poliovirus results in the complete shutoff of host protein synthesis. It is presumed that proteolysis of the p220 component of the cap-binding protein complex that is required for the translation of host mRNAs is responsible for the shutoff phenomenon. In this paper, we show that when cells are infected with poliovirus in the presence of guanidine or 3-methylquercetin, both inhibitors of poliovirus replication, complete cleavage of p220 occurs by 3.5 h postinfection. However, under these conditions only 55 to 77% of host protein synthesis is suppressed. Results obtained with extracts prepared from poliovirus-infected cells were similar to those obtained in vivo. These results suggest that complete inhibition of host protein synthesis after poliovirus infection requires at least one event in addition to proteolysis of p220. Thus, proteolysis of p220 is probably necessary but not sufficient for total suppression of host protein synthesis after poliovirus infection.     

Inhibition of host cell protein synthesis in poliovirus-infected cells

Poliovirus infection of HeLa cells in culture causes rapid inhibition of host cell protein synthesis, while viral proteins are synthesized at high levels. This inhibition correlates with the inactivation of eukaryotic initiation factor 4F (eIF-4F), by proteolytic cleavage of its γ-subunit, p220. eIF-4F is required for the translation of capped mRNAs. Poliovirus RNA is uncapped and is translated by a cap independent mechanism. The poliovirus protease, 2A^pro, is required for p220 cleavage, but induces this cleavage indirectly by activating a host protease that catalyzes p220 cleavage. Eukaryotic initiation factor 3 is also required for p220 cleavage, but its role in the cleavage reaction is unknown.     

Restriction of translation of capped mRNA in vitro as a model for poliovirus-induced inhibition of host cell protein synthesis: relationship to p220 cleavage.

Poliovirus infection of HeLa cells results in a rapid inhibition of host protein synthesis by a mechanism that does not affect the translation of poliovirus RNA. It has been suggested that this virus-induced translational control results from inactivation of the cap-binding protein complex, and it has been shown that the 220-kilodalton component(s) (p220) of the cap-binding protein complex is cleaved in infected HeLa cells to form antigenically related polypeptides of 100 to 130 kilodaltons. We have previously described an activity in infected cells that specifically restricts translation of capped mRNA in rabbit reticulocyte lysates. Here, we describe further refinements and characterization of restriction assay. We determined that the assay is a good in vitro model for study of host cell shutoff by several criteria: (i) translation was inhibited in both instances at the step involving mRNA binding to ribosomes; (ii) translation of capped mRNA was specifically inhibited, whereas translation of poliovirus RNA was not; (iii) restriction activity appeared in infected cells with kinetics which parallel host cell shutoff; and (iv) restriction activity, like the specific inhibition of host translation, appeared in cells infected in the presence of guanidine-HCl. The restricting activity was partially purified from poliovirus-infected cells and was compared with the virus-induced p220 cleavage activity. Both activities copurified through numerous cell fractionation and biochemical fractionation procedures. However, specific restriction of capped mRNA translation in reticulocyte lysates occurred without complete cleavage of the endogenous p220.     

Inhibition of HeLa cell protein synthesis under heat shock conditions in the absence of initiation factor eIF-2 alpha phosphorylation

Subjecting a HeLa cell suspension culture to an increase in incubation temperature (from 37 degrees to 42 degrees C) results in the rapid cessation of polypeptide chain synthesis followed by a gradual increase in the synthesis of a class of polypeptides referred to as the heat-shock proteins. It has been proposed that the initial, rapid shutoff of protein synthesis (less than 20 min) is due to the phosphorylation of initiation factor eIF-2 in its alpha subunit, a modification known to result in the inhibition of polypeptide synthesis. Using an in vitro translation system derived from heat-shocked HeLa cells grown in suspension culture, we were unable to find any evidence implicating eIF-2 alpha phosphorylation in the initial shutoff of translation during the heat shock response. These results suggest that the rapid inhibition of protein synthesis observed under heat shock conditions is mediated by a mechanism(s) other than eIF-2 alpha phosphorylation.     

Inhibition of translation in cells infected with a poliovirus 2Apro mutant correlates with phosphorylation of the alpha subunit of eucaryotic initiation factor 2.

A poliovirus type 2 Lansing mutant was constructed by inserting 6 base pairs into the 2Apro region of an infectious cDNA clone, resulting in the addition of a leucine and threonine into the polypeptide sequence. The resulting small-plaque mutant, 2A-2, had a reduced viral yield in HeLa cells and synthesized viral proteins inefficiently. Infection with the mutant did not lead to specific inhibition of host cell protein synthesis early in infection, and this defect was attributed to a failure to induce cleavage of the cap-binding complex protein p220. At late times after infection with the mutant virus, both cellular and viral protein syntheses were severely inhibited. To explain this global inhibition of protein synthesis, the phosphorylation state of the alpha subunit of eucaryotic initiation factor 2 (eIF-2 alpha) was examined. eIF-2 alpha was phosphorylated in both R2-2A-2- and wild-type-virus-infected cells, indicating that poliovirus does not encode a function that blocks phosphorylation of eIF-2 alpha. The kinetics and extent of eIF-2 alpha phosphorylation correlated with the production of double-stranded RNA in infected cells, suggesting that eIF-2 alpha is phosphorylated by P1/eIF-2 alpha kinase. When HeLa cells were infected with R2-2A-2 in the presence of 2-aminopurine, a protein kinase inhibitor, much higher virus titers were produced, cleavage of p220 occurred, and host cell protein synthesis was specifically inhibited. Since phosphorylation of eIF-2 alpha was not inhibited by 2-aminopurine, we propose that 2-aminopurine rescues the ability of R2-2A-2 to induce cleavage of p220 by inhibition of a second as yet unidentified kinase.     

Activation of hemin-regulated initiation factor-2 kinase in heat-shocked HeLa cells

Protein synthesis was drastically inhibited in HeLa cells incubated for 5 min at 42.5 degrees C, but it resumed after 20 min at a rate about 50% that of control cells. After 10 min of heat shock, the binding of Met-tRNAf to 40 S ribosomal subunits was greatly reduced and a polypeptide identified by immunoprecipitation with the alpha subunit of eukaryotic initiation factor-2 (eIF-2) was phosphorylated. Extracts prepared from control and heat-shocked cells were assayed for in vitro protein synthesis. Both extracts were active when supplemented with hemin, but the extract from heat-shocked cells had little initiation activity without this addition. A Mr 90,000 polypeptide and eIF-2 alpha were phosphorylated in this extract, but hemin or an antibody which inhibits the protein kinase designated heme-controlled repressor reduced this phosphorylation. These findings implicated heme-controlled repressor as the kinase at least in part responsible for eIF-2 alpha phosphorylation. Furthermore, the initial inhibition of protein synthesis and eIF-2 alpha phosphorylation after heat shock were reduced by adding hemin to intact HeLa cells. These cells synthesized heat-shock proteins with some delay relative to cells without added hemin. The binding of Met-tRNAf to 40 S ribosomal subunits was inhibited by about 50% in extracts prepared from cells heat-shocked for 40 min, and eIF-2 alpha phosphorylation was increased in these cells. These results suggest that heme-controlled repressor is activated in heat-shocked cells and that eIF-2 alpha phosphorylation limits mRNA translation even after partial recovery of protein synthesis.     

The cap-binding protein complex in uninfected and poliovirus-infected HeLa cells

In poliovirus-infected HeLa cells, the mechanism of protein synthesis initiation factor recognition of m7G cap groups on mRNA is impaired. Translation of capped host cell mRNAs is inhibited, whereas translation of uncapped poliovirus mRNA proceeds exclusively. The site of this defect has been localized to the cap-binding protein complex (CBPC). To elucidate the specific structural and functional defects of the CBPC following poliovirus infection, the CBPC and/or its polypeptide components were purified from uninfected and poliovirus-infected HeLa cells. The CBPC from uninfected cells consisted of tightly associated 24- and 220-kDa polypeptides; minor amounts of polypeptides of 40, 44, and 80 kDa also consistently co-purified with the p24/p220 cores. No evidence of a 50-kDa, eIF-4A-related polypeptide subunit of the CBPC was obtained. The CBPC from poliovirus-infected cells had undergone major structural alterations. The 220-kDa component was absent; antigenically related (100-130 kDa) degradation products were present instead. The 24-kDa component co-purified with the p220 degradation products, but other components were missing. The association of the infected cell CBPC components was quite labile compared with that demonstrated by the components of CBPC from uninfected cells. Differential stimulation of capped, but not uncapped mRNAs in a cell-free translation assay was demonstrated by unmodified CBPC. Conversely, modified CBPC from poliovirus-infected cells differentially stimulated in vitro translation of uncapped poliovirus mRNA but not capped mRNAs. The implications of these results for the mechanism of cap-independent translation are briefly discussed.     

Characterization of poliovirus 2A proteinase by mutational analysis: residues required for autocatalytic activity are essential for induction of cleavage of eukaryotic initiation factor 4F polypeptide p220.

The poliovirus proteinase 2A is autocatalytically released from the poliovirus polyprotein by cotranslational cleavage at its own amino terminus, resulting in separation of structural and nonstructural protein precursors. Cleavage is a prerequisite for further processing of the structural protein precursor and consequently for poliovirus encapsidation. A second function of 2Apro is in the rapid shutoff of host cell protein synthesis that occurs upon infection with poliovirus. This is associated with proteolytic cleavage of the p220 component of eukaryotic initiation factor eIF-4F, which is induced but not directly catalyzed by 2Apro. We introduced single-amino-acid substitutions in the 2Apro-coding region of larger poliovirus precursors that were subsequently translated in vitro and thus demonstrated that His-20, Asp-38, and Cys-109 (which constitute the putative catalytic triad) are essential for, and that His-117 is an important determinant of, the autocatalytic activity of 2Apro. This is consistent with the proposal that 2Apro is structurally related to a subclass of trypsinlike serine proteinases. Moreover, 2Apro containing a Cys109Ser substitution retained a small but significant autocatalytic activity. Cleavage of p220 was not induced by those mutants that had reduced proteolytic activity, indicating that the cellular factor that cleaves p220 is probably activated by 2Apro-catalyzed proteolytic cleavage.     

Modification of eukaryotic initiation factor 4F during infection by influenza virus.

Influenza virus infection of cells is accompanied by a striking shutoff of cellular protein synthesis, resulting in the exclusive translation of viral mRNAs. The mechanism for control of cellular protein synthesis by influenza virus is poorly understood, but several translation properties of influenza virus mRNAs which are potentially involved have been described. Influenza virus mRNAs possess the surprising ability to translate in the presence of inhibitory levels of inactive (phosphorylated) eukaryotic initiation factor 2 (eIF-2). In addition, influenza virus mRNAs were shown to be capable of translating in cells during the late phase of adenovirus infection but not in cells infected by poliovirus. Since both adenovirus and poliovirus facilitate virus-specific translation by impairing the activity of initiation factor eIF-4F (cap-binding protein complex) but through different mechanisms, we investigated the translation properties of influenza virus mRNAs in more detail. We show that influenza virus infection is associated with the significant dephosphorylation and inactivation of eIF-4E (cap-binding protein), a component of eIF-4F, and accordingly that influenza virus mRNAs possess a moderate ability to translate by using low levels of eIF-4F. We also confirm the ability of influenza virus mRNAs to translate in the presence of high levels of inactive (phosphorylated) eIF-2 but to a more limited extent than reported previously. We suggest a potential mechanism for the regulation of protein synthesis by influenza virus involving a decreased requirement for large pools of active eIF-4F and eIF-2.     

Adenovirus late protein synthesis is resistant to the inhibition of translation induced by poliovirus

Inhibition of host protein synthesis after poliovirus infection has been suggested to be a consequence of the proteolytic degradation of a p220 polypeptide necessary to translate capped mRNAs. However, the synthesis of several adenovirus late proteins on capped mRNAs was resistant to poliovirus inhibition. Thus, the hexon protein was still made 8 h after poliovirus superinfection. The synthesis of other adenovirus proteins such as the fiber was much more sensitive to poliovirus-induced inhibition than the hexon, either in the absence or in the presence of guanidine. Detailed densitometric analyses clearly showed the differential behavior of several adenovirus late mRNAs to poliovirus shut-off of translation. This is striking in view of the fact that a common leader sequence in the 5' termini is present in the adenovirus late mRNAs. The use of 3-methyl quercetin, an inhibitor of poliovirus RNA synthesis (Castrillo, J. L., Vanden Berghe, D., and Carrasco, L. (1986) Virology 152, 219-227), showed that translation of several capped adenovirus mRNAs took place in poliovirus-infected cells after the synthesis of host proteins had ceased. The poliovirus mRNA and the adenovirus mRNA coding for the hexon protein are very efficient mRNAs and have a leader sequence of more than 740 and 250 nucleotides, respectively, with very rich secondary structures making it difficult to predict how the scanning model will operate on these two mRNAs.     

Sensitization of Chemo-Resistant Human Chronic Myeloid Leukemia Stem-Like Cells to Hsp90 Inhibitor by SIRT1 Inhibition

Development of effective therapeutic strategies to eliminate cancer stem-like cells (CSCs), which play a major role in drug resistance and disease recurrence, is critical to improve cancer treatment outcomes. The current investigation was undertaken to examine the effectiveness of the combination treatment of Hsp90 inhibitor and SIRT1 inhibitor in inhibiting the growth of chemo-resistant stem-like cells isolated from human chronic myeloid leukemia K562 cells. Inhibition of SIRT1 by use of SIRT1 siRNA or SIRT1 inhibitors (amurensin G and EX527) effectively potentiated sensitivity of Hsp90 inhibitors (17-AAG and AUY922) in CD44^high K562 stem-like cells expressing high levels of CSC-related molecules including Oct4, CD34, β-catenin, c-Myc, mutant p53 (mut p53), BCRP and P-glycoprotein (P-gp) as well as CD44. SIRT1 depletion caused significant down-regulation of heat shock factor 1 (HSF1)/heat shock proteins (Hsps) as well as these CSC-related molecules, which led to the sensitization of CD44^high K562 cells to Hsp90 inhibitor by SIRT1 inhibitor. Moreover, 17-AAG-mediated activation of HSF1/Hsps and P-gp-mediated efflux, major causes of Hsp90 inhibitor resistance, was suppressed by SIRT1 inhibitor in K562-CD44^high cells. Our data suggest that combined treatment with Hsp90 inhibitor and SIRT1 inhibitor could be an effective therapeutic approach to target CSCs that are resistant to current therapies.     

Hsp90 regulates protein synthesis by activating the heme-regulated eukaryotic initiation factor 2α (eIF-2α) kinase in rabbit reticulocyte lysates

Heat shock protein 90 (Hsp90), an abundant and ubiquitous cytoplasmic protein has recently been indicated to participate in the regulation of protein synthesis by interacting with the heme-regulated eukaryotic initiation factor 2α (eIF-2α) kinase, also known as the heme-regulated inhibitor (HRI). However, there exists an ambiguity on the exact nature of its action. In this investigation, the interaction of Hsp90 and HRI has been examined bothin vitro using purified proteins, andin situ in rabbit reticulocyte lysates subjected to heat shock and treatment with N-ethylmaleimide (NEM), a sulfhydryl reagent known to induce stress response. During heat shock or NEM-treatment of reticulocyte lysates, Hsp90 co-immunoprecipitated with activated HRI by anti-HRI monoclonal antibodies. Furthermore, the amount of Hsp90 being associated with HRI was a function of duration of heat shock and was correlated with the extent of HRI activation. Interestingly, simultaneous heat shock and NRM-treatment of reticulocyte lysates led to maximal association of HRI and Hsp90, leaving nearly no free HRI in the lysates.In vitro, with the purified proteins, the autokinase and the eIF-2α kinase activities of HRI were enhanced when HRI was pre-incubated with Hsp90, both in the presence and absence of hemin. These data, therefore, clearly demonstrate that Hsp90 interacts with HRI during stress, and that this association leads to activation of HRI and thereby inhibition of protein synthesis at the level of initiation. Considering the ubiquitous nature of Hsp90 and the presence of HRI or HRI-like eIF-2α kinase activity in a number of organisms, it is highly possible that Hsp90 may universally mediate down regulation of global protein synthesis during stress response.     

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.     

The p220 component of eukaryotic initiation factor 4F is a substrate for multiple calcium-dependent enzymes

Eukaryotic initiation factor 4F (eIF-4F) is a multisubunit protein that functions in the first step of the binding of capped mRNAs to the small ribosomal subunit. Its largest polypeptide component, p220, is cleaved following poliovirus infection. This is thought to inactivate eIF-4F function, thereby preventing cap-dependent initiation of translation of cellular mRNAs. In this report, we show that p220 in extracts of uninfected HeLa cells is specifically lost in the presence of calcium. The responsible activities have been partially purified and identified as the calcium-dependent, neutral, cysteine proteases calpains I and II. In addition, a third calcium-dependent activity was resolved from the calpains and also results in the loss of p220. This activity has properties similar to a transglutaminase and copurifies with tissue transglutaminase through several chromatographic steps. None of these calcium-dependent activities appears to mediate p220 cleavage in poliovirus-infected cells.