Modulation of the expression of poliovirus proteins in reticulocyte lysates

Elusive Trans-Acting Factors Which Operate with Type I (Poliovirus-like) IRES Elements

The phenomenon of internal initiation of translation was discovered in 1988 on poliovirus mRNA. The prototypic cis-acting element in the 5' untranslated region (5'UTR) of poliovirus mRNA, which is able to direct initiation at an internal start codon without the involvement of a cap structure, has been called an IRES (Internal Ribosome Entry Site or Segment). Despite its early discovery, poliovirus and other related IRES elements of type I are poorly characterized, and it is not yet clear which host proteins (a.k.a. IRES trans-acting factors, ITAFs) are required for their full activity in vivo. Here we discuss recent and old results devoted to type I IRESes and provide evidence that Poly(rC) binding protein 2 (PCBP2), Glycyl-tRNA synthetase (GARS), and Cold Shock Domain Containing E1 (CSDE1, also known as UNR) are major regulators of type I IRES activity.

Translational Control of the Picornavirus Phenotype

Picornaviruses are small animal viruses with positive-strand genomic RNA, which is translated using cap-independent internal translation initiation. The key role in this is played by ciselements of the 5"-untranslated region (5"-UTR) and, in particular, by the internal ribosome entry site (IRES). The function of translational ciselements requires both canonical translation initiation factors (eIFs) and additional IRES trans-acting factors (ITAFs). All known ITAFs are cell RNA-binding proteins which play a variety of functions in noninfected cells. Specific features of translational ciselements substantially affect the phenotype and, in particular, tissue tropism and pathogenic properties of picornaviruses. It is clear that, in some cases, the molecular mechanism involved is a change in interactions between viral ciselements and ITAFs. The properties and tissue distribution of ITAFs may determine the biological properties of other viruses that also use the IRES-dependent translation initiation. Since this mechanism is also involved in translation of several cell mRNAs, ITAF may contribute to the regulation of the most important aspects of the living activity in noninfected cells.

Specific interaction of a 25-kilodalton cellular protein, a 40S ribosomal subunit protein, with the internal ribosome entry site of hepatitis C virus genome

Translation initiation of hepatitis C virus (HCV) RNA is controlled by an internal ribosome entry site (IRES) contained in 5' noncoding region (NCR) and in several nucleotides of the coding region. The ability of a 25-kilodalton cellular protein (p25) to bind the HCV 5' NCR is correlated with the efficiency of translation initiation of HCV RNA, indicating that this protein plays a critical role in HCV translation (S. Fukushi, C. Kurihara, N. Ishiyama, F. B. Hoshino, A. Oya, and K. Katayama, J Virol 71, 1662-1666, 1997). We have extended the study for identification of the IRES region required for p25 binding. For this purpose, we have performed UV cross-linking competition analyses using 5'- or 3'- deleted mutants of the HCV 5' NCR as competitor RNAs for binding of p25 to wild-type HCV 5' NCR. Competitor RNAs lacking nucleotides (nt) 47-74 or nt 279-331 did not inhibit p25 binding to the HCV IRES, indicating that these regions are necessary for interaction of the p25 and HCV IRES. Since p25 binding was not observed in the IRES elements of encephalomyocarditis virus and poliovirus in UV cross-linking competition analyses, the p25 binding may be specific for the HCV IRES. p25 bound to the HCV IRES was detected when a purified 40S ribosomal subunit was used for UV cross-linking experiment, indicating that p25 is one of 40S ribosomal subunit proteins. These results reveal an unique interaction between the 40S ribosomal subunit and HCV IRES to contribute to translation initiation of the HCV genome.

A new internal ribosomal entry site 5' boundary is required for poliovirus translation initiation in a mouse system

Four mutants of the virulent Mahoney strain of poliovirus were generated by introducing mutations in nucleotides (nt) 128 to 134 of the genome, a region that contains a part of the stem-loop II (SLII) structure located within the internal ribosomal entry site (IRES; nt 120 to 590) (K. Shiroki, T. Ishii, T. Aoki, Y. Ota, W.-X. Yang, T. Komatsu, Y. Ami, M. Arita, S. Abe, S. Hashizume, and A. Nomoto, J. Virol. 71:1-8, 1997). These mutants (SLII mutants) replicated well in human HeLa cells but not in mouse TgSVA cells that had been established from the kidney of a poliovirus-sensitive transgenic mouse. Their neurovirulence in mice was also greatly attenuated compared to that of the parental virus. The poor replication activity of the SLII mutants in TgSVA cells appeared to be attributable to reduced activity of the IRES. Two and three naturally occurring revertants that replicated well in TgSVA cells were isolated from mutants SLII-1 and SLII-5, respectively. The revertants recovered IRES activity in a cell-free translation system from TgSVA cells and returned to a neurovirulent phenotype like that of the Mahoney strain in mice. Two of the revertant sites that affected the phenotype were identified as being at nt 107 and within a region from nt 120 to 161. A mutation at nt 107, specifically a change from uridine to adenine, was observed in all the revertant genomes and exerted a significant effect on the revertant phenotype. Exhibition of the full revertant phenotype required mutations in both regions. These results suggested that nt 107 of poliovirus RNA is involved in structures required for the IRES activity in mouse cells.

In vitro mutational and inhibitory analysis of the cis-acting translational elements within the 5' untranslated region of coxsackievirus B3: potential targets for antiviral action of antisense oligomers

The 5' untranslated region (5'UTR) of coxsackievirus B3 (CVB3) RNA forms a highly ordered secondary structure that has been implicated in controlling initiation of viral translation by internal ribosomal entry. To test this hypothesis, synthetic bicistronic RNAs, with all or part of the 5'UTR in the intercistronic space, were translated in rabbit reticulocyte lysates. In the presence of an upstream cistron, the chloramphenicol acetyltransferase gene, designed to block ribosomal scanning, the CVB3 5'UTR was capable of directing the internal initiation of translation of the downstream reporter gene (P1), confirming the presence of an internal ribosomal entry site (IRES). This finding was further supported by the data on predicted secondary structures within the 5'UTR. Of special note, analysis of various deletion mutants demonstrated that the IRES of CVB3 is located roughly at stem-loops G, H, and I spanning nucleotides (nt) 529 and 630. The region from nt 1 to 63 (stem-loop A) also appears important, and it may be an essential binding site for translation initiation factors. Based on these findings, in vitro translation inhibition assays using RNA fragments of the 5'UTR as inhibitor were performed. Both antisense and sense RNA segments transcribed from these two cis-acting regions and the surrounding sequence of the initiation codon AUG showed strong inhibition of viral protein synthesis. Antisense molecules may inhibit translation by blocking ribosome and initiation factor binding within the 5'UTR via specific hybridization to their viral RNA target sequences, while sense sequences may function by competing with viral RNA for ribosomes and/or translation initiation factors. These cis-acting translational elements may serve as potential targets for the antiviral action of oligomers.

A picornaviral protein synthesized out of frame with the polyprotein plays a key role in a virus-induced immune-mediated demyelinating disease

The DA strain and other members of the TO subgroup of Theiler's murine encephalomyelitis virus (TMEV) induce a chronic demyelinating disease with a restricted virus expression. This disease serves as an experimental model of multiple sclerosis; in both diseases the immune system contributes to a similar demyelinating pathology. Like all picornaviruses, TMEV encodes a polyprotein translated from one long open reading frame. The polyprotein is then processed into structural and non-structural viral proteins. Here, we demonstrate that the DA strain of TMEV has an additional alternative open reading frame that encodes a protein called L* that is present in infected cells. Virus with a mutation of L* has a dramatically decreased demyelinating activity, indicating that L* plays a critical role in TO subgroup-induced demyelinating disease. L* is associated with membranes, suggesting that L* may interact with the immune system and thereby mediate the viral-induced demyelinating disease.

Host cell proteins binding to domain IV of the 5' noncoding region of poliovirus RNA

Translation of poliovirus RNA occurs by the binding of ribosomes to an internal segment of RNA sequence within the 5' untranslated region of the viral RNA. This region is predicted to consist of six domains (I to VI) that possess complex secondary and tertiary structures. Domain IV is a large region in which alterations in the sequence or structure markedly reduce translational efficiency. In this study, we employed RNA mobility shift assays to demonstrate that a protein(s) from uninfected HeLa cell extracts, as well as from neuroblastoma extracts, interacts with the domain IV structure. A mutation in domain IV caused reduced binding of HeLa cell proteins and reduced translation both in vitro and in vivo, suggesting that the binding of at least one of these proteins plays a role in the mechanism of viral translation. UV cross-linking indicated that a protein(s) with a size of approximately 40 kDa interacted directly with the RNA. Using streptavidin beads to capture biotinylated RNA bound to proteins, we were able to visualize a number of HeLa and neuroblastoma cell proteins that interact with domain IV. These proteins have molecular masses of approximately 39, approximately 40, and approximately 42 kDa.

Internal translation initiation on poliovirus RNA: further characterization of La function in poliovirus translation in vitro

Initiation of poliovirus RNA translation by internal entry of ribosomes is believed to require the participation of trans-acting factors. The mechanism of action of these factors is poorly defined. The limiting amount of one of these factors, La protein, in rabbit reticulocyte lysates (RRL) has been postulated to partially explain the inefficient translation of poliovirus RNA in this system. To further characterize La activity in translation and to identify other potential limiting factors, we assayed the ability of La protein as well as purified initiation factors, eIF-2, guanine nucleotide exchange factor (GEF), eIF-4A, eIF-4B, eIF-4F, and eIF-3, to stimulate the synthesis of P1, the capsid precursor protein, in poliovirus type 1 (Mahoney) RNA-programmed RRL. Of the proteins tested, only La, GEF, and to some extent eIF-2 stimulated the synthesis of P1. The enhanced translation of P1 in response to La occurred concomitantly with the inhibition of synthesis of most aberrant polypeptides, resulting from initiation in the middle of the genome. Deletion of the carboxy-terminal half (214 amino acids) of La did not decrease its binding to the poliovirus 5' untranslated region but abrogated the stimulatory and correcting activity in translation. In contrast to La, GEF and eIF-2 stimulated the overall translation and increased the synthesis of aberrant products as well as P1. Neither La, GEF, nor any other factor stimulated translation of encephalomyocarditis virus RNA in RRL. The implications of these findings for the mechanism of internal translation initiation on picornavirus RNAs are discussed.

Host factors required for internal initiation of translation on poliovirus RNA

Translation of poliovirus RNA is initiated by entry of ribosomes into the nucleotide sequence (internal ribosomal entry site; IRES) within the 5'-untranslated region (5'-UTR). Efficiency of this translation initiation in rabbit reticulocyte lysates (RRL) was very low and was greatly enhanced by addition of the ribosomal salt-wash fraction (RSW) prepared from HeLa cells. This stimulating activity in the RSW was partially purified by gel-filtration column chromatography and its molecular weight was estimated to be higher than 240,000. Several proteins that bind specifically to the poliovirus IRES were detected in the active fraction. Among those, a 57 kDa protein, recognized by antibodies against polypyrimidide tract-binding protein (PTB), was found. In addition, La protein (52 kDa) which is a human antigen recognized by antibodies from patients with autoimmune disorders was also detected. Further purification on a hydroxylapatite column resulted in considerable loss of the stimulatory activity, accompanied by a reduction of the apparent molecular weight of active component(s). These results suggest that fully active HeLa cell stimulatory factors for the translation initiation on poliovirus RNA function in RRL as a large complex consisted of several components including PTB and La protein.

La autoantigen enhances and corrects aberrant translation of poliovirus RNA in reticulocyte lysate

Translation initiation on poliovirus RNA occurs by internal binding of ribosomes to a sequence within the 5' untranslated region. We have previously characterized a HeLa cell protein, p52, that binds to a fragment of the poliovirus 5' untranslated region (K. Meerovitch, J. Pelletier, and N. Sonenberg, Genes Dev. 3:1026-1034, 1989). Here we report the purification of the HeLa p52. Protein microsequencing identified p52 as La autoantigen. The La protein is a human antigen that is recognized by antibodies from patients with autoimmune disorders such as systemic lupus erythematosus and Sjögren's syndrome. We show that the La protein stimulates translation of poliovirus RNA, but not brome mosaic virus, tobacco mosaic virus, and alfalfa mosaic virus 4 RNA, translation in a reticulocyte lysate. In addition, La corrects aberrant translation of poliovirus RNA in a reticulocyte lysate. Subcellular immunolocalization showed that La protein is mainly nuclear, but after poliovirus infection, La is redistributed to the cytoplasm. Our results suggest that La protein is involved in poliovirus internal initiation of translation and might function through a similar mechanism in the translation of cellular mRNAs.

A cis-acting element within the hepatitis A virus 5'-non-coding region required for in vitro translation

Every picornavirus studied thus far has a sequence within the 5'-non-coding region that is required for internal ribosome binding and translation of the polyprotein. In an attempt to identify this region in hepatitis A virus we constructed a truncated hepatitis A virus (HAV) cDNA clone that contains the entire 736 bp 5' non-coding region (5'-NCR) and 754 base pairs of the viral capsid coding region (P1) under control of the SP6 promoter. In vitro transcription and translation of this transcript in a rabbit reticulocyte lysate yielded a protein product of about 29 kDa as analyzed by autoradiography following sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). A series of mutations of this construct have defined a minimal sequence between bases 347 and 734 in the 5'-NCR that is required for efficient in vitro translation. The deleted constructs (D 523-734 and D 632-734) showed a reduced ability to translate in the rabbit reticulocyte lysate system in comparison with the full-length 5'-NCR construct, pH1489. The translation of these deleted constructs was artificially restored by the addition of a 5'-terminal methylated cap structure, m7GpppG, to the RNA. This increase in translational efficiency could be competed away with cap analog (m7GDP) thus indicating that this region is required for cap-independent internal ribosome binding for HAV translation.

Specific interactions of HeLa cell proteins with proposed translation domains of the poliovirus 5' noncoding region

To determine which sequences or structures in the poliovirus 5' noncoding region (5'NCR) are involved in binding proteins used for internal ribosome binding and protein synthesis initiation, translation competition assays were performed in rabbit reticulocyte lysates in the presence and absence of HeLa cell extract. The results revealed two functional domains in the poliovirus 5'NCR. One, requiring nucleotides (nts) 457 to 626, binds proteins that are required for translation of all mRNAs and that are present in both reticulocyte lysates and HeLa cell extracts. Another, contained within nts 286 to 456, interacts with proteins that are specific for poliovirus translation and are present in HeLa cells but not in significant amounts in rabbit reticulocyte lysates. In order to detect HeLa cell proteins that interact stably with the 5'NCR of poliovirus, UV cross-linking was used. At least four major protein-RNA complexes were identified, three of which were shown by RNA competition analysis to bind specifically to defined domains within the 5'NCR. Protein A (54 kDa) cross-linked to RNA sequences and/or structures located between nts 457 and 626; proteins B (48 kDa) and C (38 kDa) bound to nts 286 to 456.

Yeast cells are incapable of translating RNAs containing the poliovirus 5' untranslated region: evidence for a translational inhibitor

We have expressed in the yeast Saccharomyces cerevisiae a full-length poliovirus cDNA clone under the control of the GAL10 promoter to better characterize the effect of poliovirus on host cell metabolism. We find that yeast cells are unable to translate poliovirus RNA in vivo and that this inhibition is mediated through the 5' untranslated region of the viral RNA. The in vivo inhibition of translation of poliovirus RNA and P2CAT RNA (which contains the 5' untranslated region fused upstream of the bacterial chloramphenicol transferase gene) can be mimicked in vitro in yeast translation lysates. In fact, a trans-acting inhibitor present in yeast lysates can inhibit translation of either poliovirus or P2CAT RNA in HeLa cell translation lysates. In contrast, when the inhibitor is added to translations programmed with chloramphenicol acetyltransferase RNA, yeast prepro-alpha-factor RNA, or an RNA containing the internal ribosome entry site of encephalomyocarditis virus, no inhibition is seen. The inhibitory activity has been partially purified by DEAE-Sephacel chromatography. The partially purified inhibitor is heat stable, escapes phenol extraction, is resistant to proteinase K and DNase I treatment, and is sensitive to RNase A digestion, suggesting that the inhibitor is an RNA. In an in vitro translation assay, the inhibitory activity can be overcome by increasing the concentration of HeLa cell lysate but not P2CAT RNA, suggesting that the inhibitor interacts (directly or indirectly) with one or more components of the HeLa cell translational machinery rather than with the viral RNA.

Translation of poliovirus RNA: role of an essential cis-acting oligopyrimidine element within the 5' nontranslated region and involvement of a cellular 57-kilodalton protein

Translation of poliovirus RNA is initiated by cap-independent internal entry of ribosomes into the 5' nontranslated region. This process is dependent on elements within the 5' nontranslated region (the internal ribosomal entry site) and may involve novel translation factors. Systematic mutation of a conserved oligopyrimidine tract has revealed a cis-acting element that is essential for translation in vitro. The function of this element is related to its position relative to other cis-acting domains. This element is part of a more complex structure that interacts with several cellular factors, but changes in protein binding after mutation of this element were not detected in a UV cross-linking assay. A 57-kDa protein from the ribosomal salt wash fraction of HeLa cells was identified that binds upstream of the oligopyrimidine tract. Translation of poliovirus mRNA in vitro was strongly and specifically inhibited by competition with the p57-binding domain (nucleotides 260 to 488) of the 5' nontranslated region of encephalomyocarditis virus, indicating a probable role for p57 in poliovirus translation. p57 is likely to be identical to the ribosome-associated factor that binds to and is necessary for the function of the internal ribosomal entry site of encephalomyocarditis virus RNA.

Poliovirus translation initiation: differential effects of directed and selected mutations in the 5' noncoding region of viral RNAs

We have analyzed the translational defects of a number of mutations in the 5' noncoding region of poliovirus type 1 RNA. These mutations fall into three categories: (1) two mutations which resulted in temperature sensitive (ts) viruses, (2) the second-site mutations responsible for the reversion of the two ts viruses, and (3) mutations which were lethal to virus production. RNAs containing either of the ts mutations translated in vitro at levels significantly lower than wild-type levels. RNAs containing the respective second-site reversions had corrected these translational defects to levels corresponding to their viral growth potentials. Unlike in vitro translation of wild-type poliovirus RNA, translation of the RNAs which gave rise to ts mutant viruses was not stimulated by the addition of an S10 fraction from an uninfected HeLa cell extract to a rabbit reticulocyte lysate (RRL). In vitro translation of the mutant RNAs (corresponding to the ts viruses) in a RRL was stimulated by factors present in a ribosomal salt wash (RSW) from a HeLa extract, although the levels of stimulation were only half those seen for wild-type. These results suggest that the stimulatory factors present in the RSW have a decreased affinity for the mutant RNA templates but can, to some extent interact, with such RNAs if provided in high enough concentration. The in vitro translation of RNAs containing either of the lethal mutations was not stimulated by factors present in the S10 or the RSW. Taken together, our data suggest a correlation between the ability of a genetically altered RNA to respond to translation stimulatory factors in vitro and the ability of that mutation to be recovered in infectious virus. In addition, we have identified the in vivo-selected reversion of translational defects for two different ts viruses.

Translation of hepatitis A virus RNA in vitro: aberrant internal initiations influenced by 5' noncoding region

Hepatitis A virus (HAV) RNAs were translated in vitro in rabbit reticulocyte lysates. The pattern of proteins synthesized from full-length HAV RNA was highly complex, consisting of a continuous spectrum of polypeptides ranging from less than 20,000 to greater than 200,000 Da. The pattern was not significantly altered by varying incubation times, ion, or other reaction parameters, or by the addition of HeLa or BS-C-1 cell extracts to the translation reactions. Plasmids engineered with mutations in the 3C coding region produced transcripts which directed the synthesis of the same overall pattern of polypeptide products as those transcribed from wild-type sequences, suggesting that protein processing by 3C did not generate the complex set of protein products. Translation of RNA containing only the P3 coding region of HAV, directly adjacent to the HAV 5' noncoding region, generated a set of protein products which precisely matched a subset of those synthesized from full-length HAV RNA. The translation products of P3 RNA, full-length RNA, and mutant 3C-containing RNAs were analyzed by immunoprecipitation with antisera specific for 3D, VP1, and 2C sequences; several products were subjected to N-terminal sequence analysis. All together, the results demonstrate that translation of HAV RNA in rabbit reticulocyte lysates initiates predominantly at a large number of internal AUG codons, especially those in the P3 coding region. A minor population of products is initiated from sites in the P1 and P2 regions. The latter proteins undergo some proteolytic processing, at unidentified sites, catalyzed by 3C protein sequences. Replacement of the HAV 5' noncoding region with encephalomyocarditis virus 5' end sequences increased initiation at the correct polyprotein start site and both reduced and altered the products generated by internal initiation.

Identification of essential amino acid residues in the functional activity of poliovirus 2A protease

Proteolytic processing of poliovirus polyprotein is carried out by the products of two viral genes, 2A and 3C. 2A protease catalyzes cleavage of the polyprotein of type 1 poliovirus at two sites, one a cis cleavage at the 2A N-terminus and the other a trans cleavage within the 3D polymerase. In addition to polyprotein cleavage activity, 2A protease also indirectly induces cleavage of the p220 component of the cap-binding protein complex, which results in selective inhibition of host protein synthesis. Molecular genetic and biochemical analyses of 2A protease were performed to test its putative homology to small trypsin-like serine proteases and to examine the roles of individual amino acids in the reaction mechanism of 2A protease. A recombinant plasmid containing poliovirus 1C, 1D, and 2A gene sequences was expressed in a cell-free transcription/translation system, resulting in synthesis of a precursor protein that underwent efficient self-processing and produced mature 2A protease. To identify residues involved in the catalytic center and/or substrate-binding loops, we generated a series of 2A mutants by site-specific mutagenesis of this plasmid. Mutants were then expressed in vitro and tested for autocatalytic cis cleavage activity, trans cleavage of the 1D/2A junction, and trans-activation of p220-specific protease. Our data suggest that the conserved His20, Asp38, and Cys109 residues recently proposed to be equivalent to the catalytic triad of known serine proteases may comprise the catalytic triad of 2A protease. Surprisingly, Asp38 could be replaced with glutamic acid and retain autocatalytic function. Other amino acid substitutions at Tyr88, Tyr89, and Thr124 suggested that these residues lie in loops involved in substrate binding. Biochemical studies with protease inhibitors indicate that 2A protease activity is blocked by inhibitors specific for serine and cysteine proteases. Overall, the results are consistent with the hypothesis that 2A proteinase is structurally similar to the trypsin-like family of serine proteases with the substitution of cysteine 109 as the active site nucleophile.

Alternative translation initiation site in the DA strain of Theiler's murine encephalomyelitis virus

Polyprotein processing studies of Theiler's murine encephalomyelitis virus (TMEV), a group of mouse picornaviruses, demonstrated synthesis of a protein we have called l during in vitro translations from the RNA of DA, a demyelinating strain of TMEV, but not GDVII, an acute neurovirulent strain. We have proposed that l is synthesized from an alternative initiation site in the DA leader (L) coding area out of phase with the polyprotein reading frame (R. P. Roos, W.-P. Kong, B. L. Semler, J. Virol. 63:5344-5353, 1989). We now provide support for this proposal from experiments involving in vitro translation of three separate mutations of an infectious DA cDNA clone: DA"l"-1, which contains a base mismatch at the putative initiation codon of l, DAL-1, which contains a base mismatch at the presumed authentic initiation site of L at the beginning of the polyprotein; and DAL:NheI, which contains nucleotides coding for a four-amino-acid insertion in the L coding area with a termination codon in the l reading frame. Our results demonstrate that the DA strain uses an alternative initiation site and reading frame to in vitro synthesize l. l may have a role in the biological activity of the virus.

Potassium salts influence the fidelity of mRNA translation initiation in rabbit reticulocyte lysates: unique features of encephalomyocarditis virus RNA translation

It is widely assumed that in vitro translation of mRNA is more efficient in the presence of potassium acetate rather than KCl, that the optimum concentration of potassium acetate is higher than for KCl, and that uncapped RNAs exhibit a lower optimum salt concentration than capped mRNAs. When these assumptions were examined using several different mRNA species in four batches of rabbit reticulocyte lysate, some notable exceptions were found. The translation of encephalomyocarditis virus (EMCV) RNA exhibited a salt optimum unusually high for an uncapped mRNA, and was very much more efficient and accurate with KCl rather than potassium acetate. It was also unique in being strongly activated by low concentrations (5-10 mM) KSCN in the presence of 90 mM potassium acetate. For the translation of other uncapped RNAs (poliovirus RNA, cowpea mosaic virus (CPMV) M RNA and bacteriophage MS2 RNA) amino acid incorporation at the optimum potassium acetate level was significantly greater than could be achieved using KCl. However, KCl was found to be restrictive and potassium acetate permissive for the synthesis of abnormal products thought to arise from initiation at incorrect sites, with the result that KCl gave a product pattern closer to that observed in vivo. In the particular case of the reticulocyte lysate system, accurate translation therefore requires the use of KCl rather than potassium acetate, but the choice of salt was found to be less critical in cell-free extracts from HeLa or L-cells.

The 5'-untranslated region of picornaviral genomes

Picornaviruses are small naked icosahedral viruses with a single-stranded RNA genome of positive polarity. According to current taxonomy, the family includes four genera: Enterouirus (polioviruses, coxsackieviruses, echoviruses, and other enteroviruses), Rhinovirus, Curdiouirus [encephalomyocarditis virus (EMCV), mengovirus, Theiler's murine encephalomyelitis virus (TMEV)], and Aphthouirus [foot-and-mouth disease viruses (FMDV)]. There are also some, as yet, unclassified picornaviruses [e.g., hepatitis A virus (HAW] that should certainly be assessed as a separate genus. Studies on the molecular biology of picornaviruses might be divided into two periods: those before and after the first sequencing of the poliovirus genome. The 5'-untranslated region (5-UTR) of the viral genome was one of the unexpected problems. This segment proved to be immensely long: about 750 nucleotides or ∼10% of the genome length. There were also other unusual features (e.g., multiple AUG triplets preceding the single open reading frame (ORF) that encodes the viral polyprotein). This chapter shows that the picornaviral 5-UTRs are not only involved in such essential events as the synthesis of viral proteins and RNAs that could be expected to some extent, although some of the underlying mechanisms appeared to be quite a surprise, but also may determine diverse biological phenotypes from the plaque size or thermosensitivity of reproduction to attenuation of neurovirulence. Furthermore, a close inspection of the 5-UTR structure unravels certain hidden facets of the evolution of the picornaviral genome. Finally, the conclusions drawn from the experiments with the picornaviral5-UTRs provide important clues for understanding the functional capabilities of the eukaryotic ribosomes.

Echovirus 22 is an atypical enterovirus

Although echovirus 22 (EV22) is classified as an enterovirus in the family Picornaviridae, it is atypical of the enterovirus paradigm, typified by the polioviruses and the coxsackie B viruses. cDNA reverse transcribed from coxsackievirus B3 (CVB3) RNA does not hybridize to genomic RNA of EV22, and conversely, cDNA made to EV22 does not hybridize to CVB3 genomic RNA or to molecular clones of CVB3 or poliovirus type 1. EV22 cDNA does not hybridize to viral RNA of encephalomyocarditis virus or to a molecular clone of Theiler's murine encephalomyelitis virus, members of the cardiovirus genus. The genomic RNA of EV22 cannot be detected by the polymerase chain reaction using generic enteroviral primers. EV22 does not shut off host cell protein synthesis, and the RNA of EV22 is efficiently translated in vitro in rabbit reticulocyte lysates. Murine enterovirus-immune T cells recognize and proliferate against EV22 as an antigen in vitro, demonstrating that EV22 shares an epitope(s) common to enteroviruses but not found among other picornaviruses.

Selection of the 5'-proximal translation initiation site is influenced by mRNA and eIF-2 concentrations

A cDNA clone of the influenza virus NS (non-structural protein) gene in a vector carrying a bacteriophage T7 RNA polymerase promoter was manipulated so as to reiterate the initiation site to give two in-frame AUG codons 57 nucleotide residues apart. Each initiation site was in either a preferred context (...AUAAUGG...) or a less favourable context (...UUUAUGG...) and the four possible permutations were constructed. When capped mRNA transcripts of these clones were translated in the rabbit reticulocyte lysate system, products from initiation at both AUG codons were observed. At low RNA concentrations the frequency of initiation at the 5'-proximal AUG codon rather than the second was higher when the first AUG codon was in the preferred context, in qualitative agreement with the scanning ribosome model. However, a completely unexpected finding was that the ratio of initiation at the first AUG codon to initiation at the second decreased with increasing mRNA concentration, irrespective of the particular context involved. Several lines of evidence indicated that the increased frequency of initiation at the second AUG codon was not due solely to the lower density of ribosome loading per mRNA at high RNA concentrations, and may therefore be the result of high RNA concentrations out-titring the capacity of endogenous reticulocyte factors responsible for preferential initiation at the 5'-proximal AUG codon. The effect of supplementing the system with purified initiation factors was examined. Only eIF-2 was capable of decreasing the frequency of initiation at the second AUG codon and promoting use of the first AUG at high mRNA concentrations; eIF-3, 4A, 4B, 4C + 4D, 4F and 5 were inactive.

Restriction of poliovirus RNA translation in a human monocytic cell line

The infection of the human monocytic cell line U-937 by poliovirus was characterized by a low level of virus production and a slow progression of the cytopathic effect. Infection took place in greater than 99% of the cells as revealed by a limiting dilution assay. No viral protein synthesis was evident in the infected U-937 cells when analyzed by polyacrylamide gel electrophoresis. However, a low level of poliovirus RNA translation was detected by immunofluorescence analysis using a mixture of polyclonal antisera against non-structural proteins. Although there was only a low level of viral protein synthesis, a gradual accumulation of viral mRNA took place in U-937 cells as revealed by RNA blot analysis. Similar results were obtained when the erythroleukemic cell line K-562 was used as a host cell for poliovirus. RNA extracted from infected U-937 cells was efficiently translated in rabbit reticulocyte extracts giving rise to a pattern of viral polypeptides similar to that detected when virion-purified RNA was the template used for the in vitro translation assay, suggesting that the poliovirus RNA present in infected U-937 cells is functional. The existence in U-937 cells of a discriminatory mechanism which differentially interferes with poliovirus RNA translation is discussed.

Poliovirus translation: a paradigm for a novel initiation mechanism

All eukaryotic cellular mRNAs, and most viral mRNAs, are blocked at their 5' ends with a cap structure (m7GpppX, where X is any nucleotide). Poliovirus, along with a small number of other animal and plant viral mRNAs, does not contain a 5' cap structure. Since the cap structure functions to facilitate ribosome binding to mRNA, translation of polio-virus must proceed by a cap-independent mechanism. Consistent with this, recent studies have shown that ribosomes can bind to an internal region within the long 5' noncoding sequence of poliovirus RNA. Possible mechanisms for cap-independent translation are discussed. Cap-independent translation of poliovirus RNA is of major importance to the mechanism of shut-off of host protein synthesis after infection. Moreover, it is likely to play a role in determining poliovirus neurovirulence and attenuation.

Chimeric picornavirus polyproteins demonstrate a common 3C proteinase substrate specificity

Cross-species proteolytic processing was demonstrated by the 3C proteinases of human rhinovirus 14 and coxsackievirus B3 on poliovirus-specific polypeptide precursors. Chimeric picornavirus cDNA genomes were constructed in a T7 transcription vector in which the poliovirus 3C coding region was substituted with the corresponding allele from human rhinovirus 14 or coxsackievirus B3. In vitro translation and processing of the polypeptides encoded by the chimeric genomes demonstrated that the proteolytic processing of poliovirus P2 region (nonstructural) proteins could be functionally substituted by the heterologous proteinases. In contrast, the 3C proteinase activities expressed from the chimeric genomes were incapable of recognizing the poliovirus-specific processing sites within the capsid precursor. Since the amino acid sequences flanking and inclusive of the P2 region cleavage sites of the three viruses are not stringently conserved, these results provide evidence for the existence of common conformational determinants necessary for 3C-mediated processing.

A cellular protein that binds to the 5'-noncoding region of poliovirus RNA: implications for internal translation initiation

Initiation of translation on poliovirus mRNA occurs by internal binding of ribosomes to a region within the 5'-noncoding portion of the mRNA. The mechanistic details and trans-acting factors involved in this event are not understood fully. We used a mobility-shift electrophoresis assay to identify a specific RNA-protein complex, which can form between an RNA fragment that contains nucleotides 559-624 of the poliovirus 5' UTR (untranslated region) and a component or components of a HeLa cell extract. Complex formation was reduced greatly in a reticulocyte lysate or a wheat-germ extract. A 52-kD polypeptide (p52) has been identified as part of the protein-RNA complex by use of an UV cross-linking assay. This polypeptide apparently is not a known translation initiation or elongation factor. The possible involvement of p52 in translation initiation of poliovirus protein synthesis is discussed.

On the fidelity of mRNA translation in the nuclease-treated rabbit reticulocyte lysate system

As a test of the fidelity of the rabbit reticulocyte lysate system, we have examined the products of translation of various different influenza virus mRNAs, produced by in vitro transcription. A common finding with all mRNA species was that the ratio of full-length translation product to incomplete products decreased with increasing mRNA concentration. These short products are a mixture of (i) polypeptides initiated at the authentic initiation site but terminated prematurely, and (ii) polypeptides initiated at internal sites and terminated at the correct site. Analysis of mRNA stability during the translation assay showed very little degradation, quite insufficient to be the principle cause of incomplete product synthesis. Investigation of the influence of various parameters on the ratio of full-length to incomplete products leads to the conclusion that a high fidelity of translation can be obtained provided certain precautions are followed: the use of capped, rather than uncapped, mRNAs at low concentrations, with KCl concentrations about 20 mM above the level that gives maximum incorporation.

Initiation of protein synthesis by internal entry of ribosomes into the 5' nontranslated region of encephalomyocarditis virus RNA in vivo

Expression vectors that yield mono-, di-, and tricistronic mRNAs upon transfection of COS-1 cells were used to assess the influence of the 5' nontranslated regions (5'NTRs) on translation of reporter genes. A segment of the 5'NTR of encephalomyocarditis virus (EMCV) allowed translation of an adjacent downstream reporter gene (CAT) regardless of its position in the mRNAs. A deletion in the EMCV 5'NTR abolishes this effect. Poliovirus infection completely inhibits translation of the first cistron of a dicistronic mRNA that is preceded by the capped globin 5'NTR, whereas the second cistron preceded by the EMCV 5'NTR is still translated. We conclude that the EMCV 5'NTR contains an internal ribosomal entry site that allows cap-independent initiation of translation. mRNA containing the adenovirus tripartite leader is also resistant to inhibition of translation by poliovirus.

The scanning model for translation: an update

The small (40S) subunit of eukaryotic ribosomes is believed to bind initially at the capped 5'-end of messenger RNA and then migrate, stopping at the first AUG codon in a favorable context for initiating translation. The first-AUG rule is not absolute, but there are rules for breaking the rule. Some anomalous observations that seemed to contradict the scanning mechanism now appear to be artifacts. A few genuine anomalies remain unexplained.

Conserved structural domains in the 5'-untranslated region of picornaviral genomes: an analysis of the segment controlling translation and neurovirulence

A model of secondary structure common for the central part (ca. 400 nucleotides) of the 5'-untranslated regions (5'-UTR) of all the so far sequenced genomes of polioviruses, coxsackieviruses, and rhinoviruses was derived on the basis of evolutionary and thermodynamic considerations. According to the model, this part of the genome comprises three domains, which appear to be involved, at least in the poliovirus genome, in the control of viral neurovirulence and in vitro translation. Some salient features of this model were supported by investigating RNAs of five poliovirus and one coxsackievirus strains with respect to their accessibility to modifications with dimethyl sulfate and sensitivity to single-strand- and double-strand-specific nucleases. In contrast to the previous suggestion, no major changes in the conformation of the Sabin vaccine poliovirus type 3 5'-UTR due to the transition in position 472 were observed. The biological relevance of the conserved primary and secondary structure elements in the picornaviral 5'-UTRs is discussed.

Effect of mutations and deletions in a bicistronic mRNA on the synthesis of influenza B virus NB and NA glycoproteins

The mRNA derived from influenza B virus RNA segment 6 is functionally bicistronic and encodes the NB and NA glycoproteins in different, overlapping reading frames. NB protein synthesis is initiated at the 5'-proximal AUG codon, and 4 nucleotides downstream there is a second AUG codon which is used to initiate NA protein synthesis. The nucleotide sequence context of the first AUG codon conforms closely with the established 5'-CC(A/G)CCAUGG-3' consensus sequence (M. Kozak, Nucleic Acids Res. 15:8125-8148, 1987), which should favor initiation of NB protein synthesis at this site, yet NB and NA are found to accumulate in approximately equal amounts in infected cells. To determine the features important for allowing initiation at the second 5'-proximal AUG codon, we made changes in the 5'-terminal region of the mRNA, including deletions, insertions, and site-specific mutations. The recombinant DNA molecules were expressed in eucaryotic cells, and the accumulation of NB and NA was quantitated. The data indicate that changes in the immediate sequence around the first AUG codon do not make a large difference in the amounts of NB and NA that accumulate, but that when the first AUG codon is displaced from its normal position it is now quite efficient at preventing downstream initiation events. In addition, the data indicate that an element of the B/NB/NA mRNA 5' untranslated leader region acts in cis to enhance the expression of NB and NA.

Relationship of p220 cleavage during picornavirus infection to 2A proteinase sequencing

Infection of HeLa cells by poliovirus results in an abrupt inhibition of host cell protein synthesis. It is thought that the mechanism of this inhibition involves proteolytic cleavage of the p220 component of the cap-binding protein complex, thereby causing functional inactivation of the cap-binding protein complex and preventing capped (cellular) mRNAs from binding ribosomes. Current data suggest that the viral proteinase 2A indirectly induces p220 cleavage via alteration or activation of a second proteinase of cellular origin. We present evidence that translation of poliovirus proteinase 2A sequences in vitro activates p220 cleavage. We have also aligned published picornavirus 2A amino acid sequences for maximum homology, and we show that the picornaviruses can be divided into two classes based on the presence or absence of a highly conserved 18-amino acid sequence in the carboxy-terminal portion of 2A. This conserved 2A sequence is homologous with the active site of the cysteine proteinase 3C common to all picornaviruses. We show that picornaviruses which contain the putative 2A active site sequence (e.g., enteroviruses and rhinoviruses) will induce cleavage of p220 in vivo. Conversely, we show that two cardioviruses (encephalomyocarditis virus and Theiler's encephalomyelitis virus) do not encode this putative proteinase sequence in the 2A region and do not induce cleavage of p220 in vivo. The foot-and-mouth disease virus (FMDV) 2A sequence represents an apparent deletion and consists of only 16 amino acids, most homologous with the carboxy terminus of the cardiovirus 2A sequence. It does not contain the putative cysteine proteinase active site. However, FMDV infection induces complete cleavage of BK cell p220, and translation of FMDV RNA in vitro induces an activity that cleaves HeLa cell p220. The data predict that an alternate FMDV viral protease is responsible for the induction of p220 cleavage.

Point mutations modify the response of poliovirus RNA to a translation initiation factor: a comparison of neurovirulent and attenuated strains

Upon translation of poliovirus RNA in reticulocyte lysates, initiation occurs largely "incorrectly," that is, at sites in the middle of the viral genome rather than at the beginning of the polyprotein reading frame; the anomaly appears to be due to an initiation factor deficiency. Here, a fraction which stimulated initiation at the correct site, provisionally called "initiation correcting factor" (ICF), was partially purified from Krebs-2 cells. The ICF activity appeared to copurify with a complex of initiation factors eIF-2 and eIF-2B. The ability of ICF to stimulate, in reticulocyte lysates, the correct initiation of translation on the RNAs from neurovirulent and attenuated type 1 and type 3 poliovirus strains was investigated. Like crude initiation factor preparations, ICF appeared to be relatively less active with the RNAs from attenuated strains, the difference being especially pronounced for the type 3 strains. For the latter strains, the data suggested an important role of the nucleotide at, and perhaps around, position 472 in determining a response to the addition of ICF. It is proposed that interaction of a specific segment of the viral RNA with one or more of initiation factors plays an important part in the mechanism of translation of the picornavirus genomes, poliovirus attenuation, and, possibly, pathogenesis of poliomyelitis.

An internal 5'-noncoding region required for translation of poliovirus RNA in vitro

A truncated poliovirus RNA that contains the entire 5'-noncoding region as well as some capsid protein-coding sequences was produced from cloned cDNA inserted into an SP6 transcription vector and subsequently was translated in a mixed rabbit reticulocyte-HeLa cell lysate. Deletions or modifications of regions of the 5'-noncoding sequences had significant effects upon the efficiency of translation. The presence of a 60-nucleotide sequence located at positions 567 to 627 appeared to be essential for active ribosome binding and translation of this uncapped RNA.

Translational efficiency of poliovirus mRNA: mapping inhibitory cis-acting elements within the 5' noncoding region

Poliovirus mRNA contains a long 5' noncoding region of about 750 nucleotides (the exact number varies among the three virus serotypes), which contains several AUG codons upstream of the major initiator AUG. Unlike most eucaryotic mRNAs, poliovirus does not contain a m7GpppX (where X is any nucleotide) cap structure at its 5' end and is translated by a cap-independent mechanism. To study the manner by which poliovirus mRNA is expressed, we examined the translational efficiencies of a series of deletion mutants within the 5' noncoding region of the mRNA. In this paper we report striking translation system-specific differences in the ability of the altered mRNAs to be translated. The results suggest the existence of an inhibitory cis-acting element(s) within the 5' noncoding region of poliovirus (between nucleotides 70 and 381) which restricts mRNA translation in reticulocyte lysate, wheat germ extract, and Xenopus oocytes, but not in HeLa cell extracts. In addition, we show that HeLa cell extracts contain a trans-acting factor(s) that overcomes this restriction.

Synthesis of the infectious pancreatic necrosis virus polyprotein, detection of a virus-encoded protease, and fine structure mapping of genome segment A coding regions

Full-length and truncated genome segment A-specific infectious pancreatic necrosis virus cDNA was subcloned into plasmid transcription vectors, and runoff transcripts were produced in vitro. These transcripts were translated in cell-free rabbit reticulocyte lysates and the translation products were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Virus-specific polypeptides were gel purified and mapped by partial proteolysis with N-chlorosuccinimide and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Peptide profiles were compared with those of the corresponding polypeptides purified from infectious pancreatic necrosis virus-infected cells or prepared by in vitro translation of denatured genomic RNA. The cDNA directed the synthesis of authentic pVP2, VP3, and NS polypeptides as well as a number of previously undescribed polypeptides. A 101,000-molecular-weight polypeptide was isolated and shown to be the unprocessed infectious pancreatic necrosis virus polyprotein. The NS polypeptide appears to be a virus-encoded protease responsible for the cleavage of pVP2 from the polyprotein. The carboxy terminus of NS was mapped to within three or four amino acids on the polyprotein. The most likely internal translation start sites responsible for NS and VP3 production in vitro were also mapped.

Processing determinants required for in vitro cleavage of the poliovirus P1 precursor to capsid proteins

We generated defined alterations in poliovirus protein-processing substrates and assayed the effects of these alterations with an in vitro expression system. A complete cDNA copy of the poliovirus genome was inserted into a bacteriophage T7 transcription vector. Using this expression template, we produced RNA transcripts containing defined regions of the poliovirus capsid precursor polypeptide (P1) and RNA transcripts containing mutations in the P1 and P2 regions. In vitro translation of P1-derived transcripts allowed us to characterize the 3C-mediated cleavage of P1 to capsid proteins. We demonstrated that, for either posttranslational or cotranslational cleavage at any of the Q-G amino acid pairs within P1, almost the entire P1 precursor is required. We also demonstrated that minimal sequences 3' to the 2A coding sequence are required to generate active 2A proteinase in vitro and that two specific four-amino-acid insertions in protein 2C do not alter 2A- or 3C-mediated processing of the poliovirus polyprotein. In addition, we demonstrated that substantial deletion of P1 sequences does not alter 2A-mediated cleavage of the Y-G site at the P1-P2 junction. These results allowed us to compare the P1 sequences required for 2A- versus 3C-mediated processing of the capsid precursor, and we discuss these results in the context of the three-dimensional structure of the capsid proteins.

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.

Mapping of the large RNA genome segment of infectious pancreatic necrosis virus by hybrid arrested translation

Segment A, the larger dsRNA segment of IPNV which encodes three of the four virus-coded polypeptides (preVP2, VP3, and NS) was cloned and physically mapped. The plus and minus RNA strands of the virus genome were separated and the A+ and B+ RNA strands were identified. A nested set of cDNA subclones, coterminal with the 5' end of A+ RNA, were used in hybrid arrested translation experiments. Hybrid arrest conditions which blocked the 5' two-thirds of A+ RNA allowed the in vitro synthesis of only VP3, while hybridization of the RNA to cDNA representing the 5' half of A+ RNA allowed the synthesis of both NS and VP3 but not of preVP2. In vitro translation of A+ RNA yielded all three polypeptides. It is, therefore, concluded that the order of the three polypeptides on A+ RNA is 5'-preVP2-NS-VP3-3'. These results imply that internal initiation of translation could take place on the RNA at least in vitro at sites located hundreds of nucleotides downstream from the first in-phase AUG codon near the 5' end.

In vitro molecular genetics as a tool for determining the differential cleavage specificities of the poliovirus 3C proteinase

We describe a completely in vitro system for generating defined poliovirus proteinase mutations and subsequently assaying the phenotypic expression of such mutations. A complete cDNA copy of the entire poliovirus genome has been inserted into a bacteriophage T7 transcription vector. We have introduced proteinase and/or cleavage site mutations into this cDNA. Mutant RNA is transcribed from the altered cDNA template and is subsequently translated in vitro. Employing such a system, we provide direct evidence for the bimolecular cleavage events carried out by the 3C proteinase. We show that specific genetically-altered precursor polypeptides containing authentic Q-G cleavage sites will not act as substrates for 3C either in cis or in trans. We also provide evidence that almost the entire P3 region is required to generate 3C proteinase activity capable of cleaving the P1 precursor to capsid proteins. However, only the 3C portion of P3 is required to generate 3C proteinase activity capable of cleaving P2 and its processing products.