The yeast Saccharomyces cerevisiae as a genetic system for obtaining variants of poliovirus protease 2A

Structure-Function Mutational Analysis and Prediction of the Potential Impact of High Risk Non-Synonymous Single-Nucleotide Polymorphism on Poliovirus 2A Protease Stability Using Comprehensive Informatics Approaches

Polio viral proteinase 2A performs several essential functions in genome replication. Its inhibition prevents viral replication, thus making it an excellent substrate for drug development. In this study, the three-dimensional structure of 2A protease was determined and optimized by homology modelling. To predict the molecular basis of the interaction of small molecular agonists, docking simulations were performed on a structurally diverse dataset of poliovirus 2A protease (PV2Apr°) inhibitors. Docking results were employed to identify high risk missense mutations that are highly damaging to the structure, as well as the function, of the protease. Intrinsic disorder regions (IDRs), drug binding sites (DBS), and protein stability changes upon mutations were also identified among them. Our results demonstrated dominant roles for Lys 15, His 20, Cys 55, Cys 57, Cys 64, Asp 108, Cys 109 and Gly 110, indicating the presence of various important drug binding sites of the protein. Upon subjecting these sites to single-nucleotide polymorphism (SNP) analysis, we observed that out of 155 high risk SNPs, 139 residues decrease the protein stability. We conclude that these missense mutations can affect the functionality of the 2A protease, and that identified protein binding sites can be directed for the attachment and inhibition of the target proteins.

Protease 2A induces stress granule formation during coxsackievirus B3 and enterovirus 71 infections

Background

Stress granules (SGs) are granular aggregates in the cytoplasm that are formed under a variety of stress situations including viral infection. Previous studies indicate that poliovirus, a member of Picornaviridae, can induce SG formation. However, the exact mechanism by which the picornaviruses induce SG formation is unknown.

Method

The localization of SG markers in cells infected with coxsackievirus B3 (CVB3) or enterovirus 71 (EV71) and in cells expressing each viral protein was determined via immunofluorescence assays or plasmid transfection. Eight plasmids expressing mutants of the 2A protease (2A^pro) of CVB3 were generated using a site-directed mutagenesis strategy. The cleavage efficiencies of eIF4G by CVB3 2A^pro and its mutants were determined via western blotting assays.

Results

In this study, we found that CVB3 infection induced SG formation, as evidenced by the co-localization of some accepted SG markers in viral infection-induced granules. Furthermore, we identified that 2A^pro of CVB3 was the key viral component that triggered SG formation. A 2A^pro mutant with the G122E mutation, which exhibited very low cleavage efficiency toward eIF4G, significantly attenuated its capacity for SG induction, indicating that the protease activity was required for 2A^pro to initiate SG formation. Finally, we observed that SGs also formed in EV71-infected cells. Expression of EV71 2A^pro alone was also sufficient to cause SG formation.

Conclusion

Both CVB3 and EV71 infections can induce SG formation, and 2A^pro plays a crucial role in the induction of SG formation during these infections. This finding may help us to better understand how picornaviruses initiate the SG response.

Electronic supplementary material

The online version of this article (doi:10.1186/s12985-014-0192-1) contains supplementary material, which is available to authorized users.

Translation without eIF2 promoted by poliovirus 2A protease

Poliovirus RNA utilizes eIF2 for the initiation of translation in cell free systems. Remarkably, we now describe that poliovirus translation takes place at late times of infection when eIF2 is inactivated by phosphorylation. By contrast, translation directed by poliovirus RNA is blocked when eIF2 is inactivated at earlier times. Thus, poliovirus RNA translation exhibits a dual mechanism for the initiation of protein synthesis as regards to the requirement for eIF2. Analysis of individual poliovirus non-structural proteins indicates that the presence of 2A^pro alone is sufficient to provide eIF2 independence for IRES-driven translation. This effect is not observed with a 2A^pro variant unable to cleave eIF4G. The level of 2A^pro synthesized in culture cells is crucial for obtaining eIF2 independence. Expression of the N-or C-terminus fragments of eIF4G did not stimulate IRES-driven translation, nor provide eIF2 independence, consistent with the idea that the presence of 2A^pro at high concentrations is necessary. The finding that 2A^pro provides eIF2-independent translation opens a new and unsuspected area of research in the field of picornavirus protein synthesis.

The multifaceted poliovirus 2A protease: regulation of gene expression by picornavirus proteases

After entry into animal cells, most viruses hijack essential components involved in gene expression. This is the case of poliovirus, which abrogates cellular translation soon after virus internalization. Abrogation is achieved by cleavage of both eIF4GI and eIF4GII by the viral protease 2A. Apart from the interference of poliovirus with cellular protein synthesis, other gene expression steps such as RNA and protein trafficking between nucleus and cytoplasm are also altered. Poliovirus 2A^pro is capable of hydrolyzing components of the nuclear pore, thus preventing an efficient antiviral response by the host cell. Here, we compare in detail poliovirus 2A^pro with other viral proteins (from picornaviruses and unrelated families) as regard to their activity on key host factors that control gene expression. It is possible that future analyses to determine the cellular proteins targeted by 2A^pro will uncover other cellular functions ablated by poliovirus infection. Further understanding of the cellular proteins hydrolyzed by 2A^pro will add further insight into the molecular mechanism by which poliovirus and other viruses interact with the host cell.

Suppressed Disassembly of Autolyzing p94/CAPN3 by N2A Connectin/Titin in a Genetic Reporter System

p94/calpain 3 is a skeletal muscle-specific member of the Ca(2+)-regulated cytosolic cysteine protease family, the calpains. Defective p94 protease activity originating from gene mutations causes a muscular dystrophy called calpainopathy, indicating the indispensability of p94 for muscle survival. Because of the existence of the p94-specific regions IS1 and IS2, p94 undergoes very rapid and exhaustive autolysis. To elucidate the physiological relevance of this unique activity, the autolytic profiles of p94 and the effect of the p94 binding protein, connectin/titin, on this process were investigated. In vitro analysis of p94 autolysis showed that autolysis in IS1 proceeds without immediate disassembly into fragments and that the newly identified cryptic autolytic site in IS2 is critical for disassembling autolyzed fragments. As a genetic system to assay p94 autolysis semiquantitatively, p94 was expressed in yeast as a hybrid protein between the DNA binding and activation domains of the yeast transcriptional activator Gal4. Transcriptional activation by the Gal4-p94:WT hybrid protein is precluded by p94 autolysis. Complete or partial loss of autolytic activity by C129S active site mutation, limb girdle muscular dystrophy type 2A pathogenic missense mutations, or PCR-based random mutagenesis could be detected by semiquantitative restoration of Gal4-dependent beta-galactosidase gene expression. Using this system, the N2A connectin fragment that binds to p94 was shown to suppress p94 autolytic disassembly. The proximity of the IS2 autolytic and connectin-binding sites in p94 suggested that N2A connectin suppresses IS2 autolysis. These data indicate the importance of p94-connectin interaction in the control of p94 functions by regulating autolytic decay of p94.

Individual expression of poliovirus 2Apro and 3Cpro induces activation of caspase-3 and PARP cleavage in HeLa cells

The expression of individual viral genes enables the study of their effects on cellular functions. Our group previously generated stable HeLa cell lines that efficiently express poliovirus proteases 2A (clone 2A7d) and 3C (clone 3C7) under the control of tetracycline [Virology 266 (2000a) 352; J. Virol. 74 (2000b) 2383]. Upon induction of these proteases, the cells undergo drastic morphological alterations and eventually die. The present paper characterizes, in detail, the cellular and molecular events that lead to cell death in these lines. Several signs of apoptosis were observed in both 2A7d- and 3C7-induced cells, such as nuclear fragmentation, DNA breakdown (as determined by TUNEL), and phosphatidylserine translocation. Protease 2A induces the cleavage of poly-ADP-ribose-polymerase (PARP). This is blocked by the caspase-3 inhibitor DEVD in both 2A7d-On and 3C7-On cells suggesting that this enzyme might account for PARP cleavage in both cell lines. The results indicate that both poliovirus proteases induce apoptosis by mechanisms involving caspase activation, although the kinetics of apoptosis differs.

A stable HeLa cell line that inducibly expresses poliovirus 2A(pro): effects on cellular and viral gene expression

A HeLa cell clone (2A7d) that inducibly expresses the gene for poliovirus protease 2A (2A(pro)) under the control of tetracycline has been obtained. Synthesis of 2A(pro) induces severe morphological changes in 2A7d cells. One day after tetracycline removal, cells round up and a few hours later die. Poliovirus 2A(pro) cleaves both forms of initiation factor eIF4G, causing extensive inhibition of capped-mRNA translation a few hours after protease induction. Methoxysuccinyl-Ala-Ala-Pro-Val-chloromethylketone, a selective inhibitor of 2A(pro), prevents both eIF4G cleavage and inhibition of translation but not cellular death. Expression of 2A(pro) still allows both the replication of poliovirus and the translation of mRNAs containing a picornavirus leader sequence, while vaccinia virus replication is drastically inhibited. Translation of transfected capped mRNA is blocked in 2A7d-On cells, while luciferase synthesis from a mRNA bearing a picornavirus internal ribosome entry site (IRES) sequence is enhanced by the presence of 2A(pro). Moreover, synthesis of 2A(pro) in 2A7d cells complements the translational defect of a poliovirus 2A(pro)-defective variant. These results show that poliovirus 2A(pro) expression mimics some phenotypical characteristics of poliovirus-infected cells, such as cell rounding, inhibition of protein synthesis and enhancement of IRES-driven translation. This cell line constitutes a useful tool to further analyze 2A(pro) functions, to complement poliovirus 2A(pro) mutants, and to test antiviral compounds.

Poliovirus protease 3C(pro) kills cells by apoptosis

The tetracycline-based Tet-Off expression system has been used to analyze the effects of poliovirus protease 3C(pro) on human cells. Stable HeLa cell clones that express this poliovirus protease under the control of an inducible, tightly regulated promoter were obtained. Tetracycline removal induces synthesis of 3C protease, followed by drastic morphological alterations and cellular death. Degradation of cellular DNA in nucleosomes and generation of apoptotic bodies are observed from the second day after 3C(pro) induction. The cleavage of poly(ADP-ribose) polymerase, an enzyme involved in DNA repair, occurs after induction of 3C(pro), indicating caspase activation by this poliovirus protease. The 3C(pro)-induced apoptosis is blocked by the caspase inhibitor z-VAD-fmk. Our findings suggest that the protease 3C is responsible for triggering apoptosis in poliovirus-infected cells by a mechanism that involves caspase activation.

Genetic selection of poliovirus 2Apro-binding peptides

The yeast two-hybrid system has been used to identify mammalian clones that interact with poliovirus 2A proteinase (2Apro). Eight clones which encode previously unidentified human proteins were selected from a HeLa cell cDNA expression library. In addition, five clones encoding short peptides that interact with poliovirus 2Apro were also identified. The lengths of these peptides range from 6 to 30 amino acids, but all of them contain the Leu-X-Thr-Z motif (X represents any amino acid; Z represents a hydrophobic residue). This sequence is invariably located just at the carboxy terminus of each peptide. This approach raises the possibility of designing substrate analogue inhibitors of 2Apro. Thus, two nonhydrolyzable peptides containing the Leu-X-Thr-Z motif prevented cleavage of eukaryotic initiation factor 4G by poliovirus 2Apro in vitro. A more general method for identifying peptides with antiproteinase activity is discussed.

Mutational analysis of poliovirus 2Apro. Distinct inhibitory functions of 2apro on translation and transcription

Transient expression of poliovirus 2Apro in mammalian cells by means of the recombinant vaccinia virus vT7 expression system leads to drastic inhibition of both cellular and vaccinia virus gene expression (Aldabe, R., Feduchi, E., Novoa, I., and Carrasco, L. (1995) FEBS Lett. 377, 1-5; Aldabe, R., Feduchi, E., Novoa, I., and Carrasco, L. (1995) Biochem. Biophys. Res. Commun. 215, 928-936). To obtain further insights into the molecular basis of this inhibition, a number of 2Apro variants were generated and expressed in COS-1 cells. The effect of these variants on cellular translation, on vaccinia virus-specific translation, and on transcription of the reporter gene luciferase was analyzed. The ability of the different 2Apro variants to block cellular translation depends on their capacities to cleave eIF-4G. The blockade exerted by 2Apro on transcription of the luciferase gene reinforces the notion that this protease is a potent inhibitor of RNA polymerase II-mediated transcription. Some of the 2Apro variants tested failed to block luciferase transcription, despite the fact that eIF-4G cleavage and inhibition of translation were observed. Two reconstituted polioviruses mutated in 2Apro were defective in inhibiting luciferase transcription, yet were still able to cleave eIF-4G and block translation. These findings indicate that 2Apro interferes with cellular gene expression at both the transcriptional and translational levels. Moreover, these two effects probably reflect the inactivation of different host proteins by poliovirus 2Apro.

Identification of regions of poliovirus 2BC protein that are involved in cytotoxicity

The expression of poliovirus 2BC protein in yeast and mammalian cells leads to a number of metabolic and morphological alterations, such as growth inhibition, intracellular membrane proliferation, blockade of the exocytic pathway, and enhanced membrane permeability. Yeast cells that express poliovirus 2BC in an inducible manner were used to identify the regions of 2BC implicated in the modifications of these cellular functions. Several 2BC deletion mutants were generated to define the minimal portion of 2BC required to alter these activities. Additional deletion mutants that were obtained by random mutagenesis followed by selection in yeast cells provided new insights into the structure and mechanism of action of 2BC. The activity responsible for membrane proliferation is located in 2C, while the activities responsible for membrane permeabilization and inhibition of the exocytic pathway are located in 2B. Several regions of 2B and 2C required for the different functions of 2BC were identified. Thus, the integrity of the N termini of both 2B and 2C is necessary for 2BC-induced cytotoxicity. It is also possible to separate the different cellular alterations provoked by 2BC by the use of several 2BC variants. Deletion of amino acids 52 to 65 in 2B generates a 2BC deletion variant, 2bC deltaAvrII, that still blocks yeast growth but is unable to enhance membrane permeability or to inhibit the exocytic pathway. On the other hand, 2Bcl28*.32b and 2Bcl28*.3c, which contain only 73 and 77 amino acids of 2B, interfere with yeast division and enhance membrane permeability but affect the exocytic pathway only weakly and do not induce membrane proliferation. Our findings indicate that Saccharomyces cerevisiae represents a useful model system to analyze the functions of poliovirus 2BC and show the feasibility of separating the activities assigned to this protein.