Encephalomyocarditis virus internal ribosomal entry site RNA-protein interactions.

Translational initiation of encephalomyocarditis virus (EMCV) mRNA occurs by ribosomal entry into the 5' nontranslated region of the EMCV mRNA, rather than by ribosomal scanning. Internal ribosomal binding requires a cis-acting element termed the internal ribosomal entry site (IRES). IRES elements have been proposed to be involved in the translation of picornavirus mRNAs and some cellular mRNAs. Internal ribosome binding likely requires the interaction of trans-acting factors that recognize both the mRNA and the ribosomal complex. Five cellular proteins (p52, p57, p70, p72, and p100) cross-link the EMCV IRES or fragments of the IRES. For one of these proteins, p57, binding to the IRES correlates with translation. Recently, p57 was identified to be very similar, if not identical, to polypyrimidine tract-binding protein. On the basis of cross-linking results with 21 different EMCV IRES fragments and cytoplasmic HeLa extract or rabbit reticulocyte lysate as the source of polypeptides, consensus binding sites for p52, p57, p70, and p100 are proposed. It is suggested that each of these proteins recognizes primarily a structural feature of the RNA rather than a specific sequence.     

Riboproteomics of the hepatitis C virus internal ribosomal entry site

Hepatitis C virus (HCV) protein translation is mediated by a cis-acting RNA, an internal ribosomal entry site (IRES), located in the 5' nontranslated region of the viral RNA. To examine proteins bound to the IRES, which could include proteins important for its function as well as potential drug targets, we used shotgun peptide sequencing to identify proteins in quadruplicate protein affinity extracts of lysed Huh7 cells, obtained using a biotinylated IRES. Twenty-six proteins bound the HCV IRES but not a reversed complementary sequence RNA or vector RNA controls. These included five ribosomal subunits, nine eukaryotic initiation factor 3 subunits, and novel interacting proteins such as the cytoskeletal-related proteins actin, FHOS (formin homologue overexpressed in spleen) and MIP-T3 (microtubule interacting protein that associates with TRAF3). Other novel HCV IRES-binding proteins included UNR (upstream of N-ras), UNR-interacting protein, and the RNA-binding proteins PAI-1 (plasminogen activator inhibitor-1) mRNA binding protein and Ewing sarcoma breakpoint 1 region protein EWS. A large set of additional proteins bound both the HCV IRES and a reversed complementary IRES sequence control, including the known HCV interactors PTB (polypyrimidine tract binding protein), the La autoantigen, and nucleolin. The discovery of these novel HCV IRES-binding proteins suggests links between IRES biology and the cytoskeleton, signal transduction, and other cellular functions.     

Ribosomal protein S5 interacts with the internal ribosomal entry site of hepatitis C virus

Translational initiation of hepatitis C virus (HCV) genome RNA occurs via its highly structured 5' noncoding region called the internal ribosome entry site (IRES). Recent studies indicate that HCV IRES and 40 S ribosomal subunit form a stable binary complex that is believed to be important for the subsequent assembly of the 48 S initiation complex. Ribosomal protein (rp) S9 has been suggested as the prime candidate protein for binding of the HCV IRES to the 40 S subunit. RpS9 has a molecular mass of approximately 25 kDa in UV cross-linking experiments. In the present study, we examined the approximately 25-kDa proteins of the 40 S ribosome that form complexes with the HCV IRES upon UV cross-linking. Immunoprecipitation with specific antibodies against two 25-kDa 40 S proteins, rpS5 and rpS9, clearly identified rpS5 as the protein bound to the IRES. Thus, our results support rpS5 as the critical element in positioning the HCV RNA on the 40 S ribosomal subunit during translation initiation.     

Expression of a foreign protein by influenza A virus.

In this report we describe the rescue of a transfectant influenza A virus which stably expresses a heterologous protein, bacterial chloramphenicol acetyltransferase (CAT). The foreign sequences encoding CAT are expressed as part of an essential influenza virus segment, that coding for the neuraminidase (NA) protein. The novel way by which this was achieved involved inserting in frame the 16-amino-acid self-cleaving 2A protease of foot-and-mouth disease virus between the CAT and the NA coding sequences. The resultant gene produces a polyprotein which is proteolytically cleaved to release both CAT and NA. The intramolecular cleavage occurs at the C terminus of the 2A sequence between a glycine-proline dipeptide motif such that the released NA protein has an additional N-terminal proline residue. The transfectant virus is stable upon passage in tissue culture. CAT activity is expressed at high levels in cell culture supernatants and in the allantoic fluid of infected eggs. Since the chimeric segment must maintain the heterologous reading frame to retain viability, the virus stability is dependent upon concomitant synthesis of the heterologous protein. This design may be particularly appropriate for utilization of influenza virus as a mammalian expression vector.     

Revertant analysis of J-K mutations in the encephalomyocarditis virus internal ribosomal entry site detects an altered leader protein.

The internal ribosomal entry site (IRES) of picornaviruses consists of various sequence and structural elements that collectively impart translational function to the genome. By engineering substitution and deletion mutations into the J-K elements of the encephalomyocarditis virus IRES, translationally defective viruses with small-plaque phenotypes were generated. From these, 60 larger-plaque revertant viruses were isolated and characterized, and their sequences were compared with a structural model of the IRES. The data provide confirming evidence for the existence of helix J3 within stem J but suggest that helix J1 is 3 bp longer than previously estimated. They also suggest that previously modeled stems L and M should be replaced by an alternative structure. One reversion mutation was mapped to the leader protein coding region. This change of leader amino acid 20 from Pro to Ser increased the viral plaque size dramatically but did not alter the cell-free translational activity of the mutated, parental IRES.     

Ribosomal binding to the internal ribosomal entry site of classical swine fever virus

Most eukaryotic mRNAs require the cap-binding complex elF4F for efficient initiation of translation, which occurs as a result of ribosomal scanning from the capped 5' end of the mRNA to the initiation codon. A few cellular and viral mRNAs are translated by a cap and end-independent mechanism known as internal ribosomal entry. The internal ribosome entry site (IRES) of classical swine fever virus (CSFV) is approximately 330 nt long, highly structured, and mediates internal initiation of translation with no requirement for elF4F by recruiting a ribosomal 43S preinitiation complex directly to the initiation codon. The key interaction in this process is the direct binding of ribosomal 40S subunits to the IRES to form a stable binary complex in which the initiation codon is positioned precisely in the ribosomal P site. Here, we report the results of analyses done using enzymatic footprinting and mutagenesis of the IRES to identify structural components in it responsible for precise binding of the ribosome. Residues flanking the initiation codon and extending from nt 363-391, a distance equivalent to the length of the 40S subunit mRNA-binding cleft, were strongly protected from RNase cleavage, as were nucleotides in the adjacent pseudoknot and in the more distal subdomain IIId1. Ribosomal binding and IRES-mediated initiation were abrogated by disruption of helix 1b of the pseudoknot and very severely reduced by mutation of the protected residues in IIId1 and by disruption of domain IIIa. These observations are consistent with a model for IRES function in which binding of the region flanking the initiation codon to the decoding region of the ribosome is determined by multiple additional interactions between the 40S subunit and the IRES.     

Far upstream element binding protein 2 interacts with enterovirus 71 internal ribosomal entry site and negatively regulates viral translation

An internal ribosomal entry site (IRES) that directs the initiation of viral protein translation is a potential drug target for enterovirus 71 (EV71). Regulation of internal initiation requires the interaction of IRES trans-acting factors (ITAFs) with the internal ribosomal entry site. Biotinylated RNA-affinity chromatography and proteomic approaches were employed to identify far upstream element (FUSE) binding protein 2 (FBP2) as an ITAF for EV71. The interactions of FBP2 with EV71 IRES were confirmed by competition assay and by mapping the association sites in both viral IRES and FBP2 protein. During EV71 infection, FBP2 was enriched in cytoplasm where viral replication occurs, whereas FBP2 was localized in the nucleus in mock-infected cells. The synthesis of viral proteins increased in FBP2-knockdown cells that were infected by EV71. IRES activity in FBP2-knockdown cells exceeded that in the negative control (NC) siRNA-treated cells. On the other hand, IRES activity decreased when FBP2 was over-expressed in the cells. Results of this study suggest that FBP2 is a novel ITAF that interacts with EV71 IRES and negatively regulates viral translation.     

A potential RNA drug target in the hepatitis C virus internal ribosomal entry site

Subdomain IlId from the hepatitis C virus (HCV) internal ribosome entry site (IRES) has been shown to be essential for cap-independent translation. We have conducted a structural study of a 27-nt fragment, identical in sequence to IlId, to explore the structural features of this subdomain. The proposed secondary structure of IlId is comprised of two 3 bp helical regions separated by an internal loop and closed at one end by a 6-nt terminal loop. NMR and molecular modeling were used interactively to formulate a validated model of the three-dimensional structure of IlId. We found that this fragment contains several noncanonical structural motifs and non-Watson-Crick base pairs, some of which are common to other RNAs. In particular, a motif characteristic of the rRNA alpha-sarcin/ricin loop was located in the internal loop. The terminal loop, 5'-UUGGGU, was found to fold to form a trinucleotide loop closed by a trans-wobble U.G base pair. The sixth nucleotide was bulged out to allow stacking of this U.G pair on the adjacent helical region. In vivo mutational analysis in the context of the full IRES confirmed the importance of each structural motif within IIId for IRES function. These findings may provide clues as to host cellular proteins that play a role in IRES-directed translation and, in particular, the mechanism through which host ribosomes are sequestered for viral function.     

Suppression of hepatitis A virus genome translation and replication by siRNAs targeting the internal ribosomal entry site

Small interfering RNAs (siRNAs) targeting the coding region of hepatitis A virus (HAV) were shown to specifically inhibit viral genome replication. Compared to the coding region, the HAV internal ribosomal entry site (IRES) in the 5' non-coding region is highly sequence-conserved and folds into stable secondary structures. Here, we report efficient and sustained RNA interference mediated by both RNase III-prepared siRNA (esiRNA) and vector-derived short hairpin RNAs (shRNAs) that are targeted to various domains of the HAV IRES. Using reporter constructs, and the DNA-based HAV replicon system, we found that shRNAs targeting the HAV IRES domains IIIc and V sustainably suppressed genome translation and replication whereas the IRES domains IIIa and IV were resistant to RNA interference. Our study suggests that some HAV IRES domains might be used as a universal and effective target for specific inhibition of HAV infection.     

Far upstream element binding protein 1 activates translation of p27Kip1 mRNA through its internal ribosomal entry site

The cyclin dependent kinase inhibitor p27 plays an important role in controlling the eukaryotic cell cycle by regulating progression through G1 and entry into S phase. It is often elevated during differentiation and under conditions of cellular stress. In contrast, it is commonly downregulated in cancer cells and its levels are generally inversely correlated with favorable prognosis. The cellular levels of p27 are regulated, in part, by translational control mechanisms. The 5′-untranslated region (5′-UTR) of the p27 mRNA harbors an internal ribosome entry site (IRES) which may facilitate synthesis of p27 in certain conditions. In this study, Far Upstream Element (FUSE) Binding Protein 1 (FBP1) was shown to directly bind to the human p27 5′-UTR and to promote IRES activity. An eight-nucleotide element downstream of a U-rich region within the 5′-UTR was important for FBP1 binding and p27 IRES activity. Overexpression of FBP1 enhanced endogenous p27 levels and stimulated translation initiation. In contrast, repression of FBP1 by siRNA transfection downregulated endogenous p27 protein levels. Using rabbit reticulocyte lysates, FBP1 stimulated p27 mRNA translation in vitro. The central domain of FBP1, containing four K homology motifs, was required for p27 5′-UTR RNA binding and the N terminal domain was important for translational activation. These findings indicate that FBP1 is a novel activator of p27 translation upon binding to the 5′-UTR.     

The picornavirus avian encephalomyelitis virus possesses a hepatitis C virus-like internal ribosome entry site element

Avian encephalomyelitis virus (AEV) is a picornavirus that causes disease in poultry worldwide, and flocks must be vaccinated for protection. AEV is currently classified within the hepatovirus genus, since its proteins are most closely related to those of hepatitis A virus (HAV). We now provide evidence that the 494-nucleotide-long 5' untranslated region of the AEV genome contains an internal ribosome entry site (IRES) element that functions efficiently in vitro and in mammalian cells. Unlike the HAV IRES, the AEV IRES is relatively short and functions in the presence of cleaved eIF4G and it is also resistant to an inhibitor of eIF4A. These properties are reminiscent of the recently discovered class of IRES elements within certain other picornaviruses, such as porcine teschovirus 1 (PTV-1). Like the PTV-1 IRES, the AEV IRES shows significant similarity to the hepatitis C virus (HCV) IRES in sequence, function, and predicted secondary structure. Furthermore, mutational analysis of the predicted pseudoknot structure at the 3' end of the AEV IRES lends support to the secondary structure we present. AEV is therefore another example of a picornavirus harboring an HCV-like IRES element within its genome, and thus, its classification within the hepatovirus genus may need to be reassessed in light of these findings.     

Continuous heat shock enhances translational initiation directed by internal ribosomal entry site

Many cellular mRNAs contain internal ribosomal entry sites (IRES) that become functional under conditions of cellular stress, when the rate of protein synthesis for most cellular mRNA is reduced. Internal ribosomal entry increases in response to hypoxia, cell differentiation, apoptosis, gamma irradiation, and heat shock. Heat shock is the principal cellular stress in which general cap-dependent translation is inhibited. On the other hand, heat shock induces the preferential translation of a small class of mRNA, called heat shock protein (HSP) mRNAs, which probably occurs because little or no eIF4F activity is required for their translation. In this study, we found that continuous heat stress enhances expression of the heat shock protein BiP at the level of translation. Interestingly, heat stress also enhanced the viral IRES-dependent translation of encephalomyocarditis virus and hepatitis C virus but not poliovirus. Although several BiP inducers increased BiP protein expression, BiP IRES-dependent translation was enhanced only during heat shock, suggesting that heat shock is a specific inducer for BiP IRES-dependent translation. Taken together, these results indicate that the mechanism of IRES-dependent translation can be used during heat shock and suggest that this translational mechanism may be critical to the survival and proliferation of cells under stress.     

Structural analysis of the interaction of the pyrimidine tract-binding protein with the internal ribosomal entry site of encephalomyocarditis virus and foot-and-mouth disease virus RNAs.

Initiation of translation of a subset of eukaryotic mRNAs results from internal ribosomal entry. This process is exemplified by encephalomyocarditis virus (EMCV), which contains an internal ribosomal entry site (IRES) within its 5' nontranslated region that is approximately 450-nt long and consists of a series of stem-loops designated H-L. We have previously identified a cellular 58-kDa polypeptide that binds specifically to this IRES and that is implicated in its function as the pyrimidine tract-binding protein PTB. We have now mapped PTB binding sites directly on the IRES elements of EMCV and the related foot-and-mouth disease virus (FMDV) using structure-specific enzymatic probes and base-specific chemical probes. PTB bound to six sites on the EMCV IRES: site 1 (UCUU401) is upstream of domain H, site 2 is the basal helix of domain H (nt 407-410 and 440-443), site 3 (UCUUU423) is the apical loop of domain H, site 4 is the apical helix and adjacent internal bulged loop of domain K, site 5 (CUUUA750) is the apical loop of domain K, and site 6 (CCUUU815) is downstream of domain L. PTB bound to sites on the FMDV IRES that correspond precisely to EMCV sites 3, 5, and 6. These sites have the consensus sequence CUUU and form two groups that are located near to the 5' and 3' borders of these IRES elements. Their position, and the effects of mutation of them on IRES function are consistent with PTB's role in IRES-mediated initiation being to bind to multiple sites in the IRES, thereby stabilizing a specific active conformation.     

Duck Hepatitis A virus possesses a distinct type IV internal ribosome entry site element of picornavirus

Sequence analysis of duck hepatitis virus type 1 (DHV-1) led to its classification as the only member of a new genus, Avihepatovirus, of the family Picornaviridae, and so was renamed duck hepatitis A virus (DHAV). The 5' untranslated region (5' UTR) plays an important role in translation initiation and RNA synthesis of the picornavirus. Here, we provide evidence that the 651-nucleotide (nt)-long 5' UTR of DHAV genome contains an internal ribosome entry site (IRES) element that functions efficiently in vitro and within BHK cells. Comparative sequence analysis showed that the 3' part of the DHAV 5' UTR is similar to the porcine teschovirus 1 (PTV-1) IRES in sequence and predicted secondary structure. Further mutational analyses of the predicted domain IIId, domain IIIe, and pseudoknot structure at the 3' end of the DHAV IRES support our predicted secondary structure. However, unlike the case for the PTV-1 IRES element, analysis of various deletion mutants demonstrated that the optimally functional DHAV IRES element with a size of approximately 420 nt is larger than that of PTV-1 and contains other peripheral domains (Id and Ie) that do not exist within the type IV IRES elements. The domain Ie, however, could be removed without significant loss of activity. Surprisingly, like the hepatitis A virus (HAV) IRES element, the activity of DHAV IRES could be eliminated by expression of enterovirus 2A protease. These findings indicate that the DHAV IRES shares common features with type IV picornavirus IRES elements, whereas it exhibits significant differences from type IV IRESs. Therefore, we propose that DHAV possesses a distinct type IV IRES element of picornavirus.     

Host range phenotype induced by mutations in the internal ribosomal entry site of poliovirus RNA.

Most poliovirus strains infect only primates. The host range (HR) of poliovirus is thought to be primarily determined by a cell surface molecule that functions as poliovirus receptor (PVR), since it has been shown that transgenic mice are made poliovirus sensitive by introducing the human PVR gene into the genome. The relative levels of neurovirulence of polioviruses tested in these transgenic mice were shown to correlate well with the levels tested in monkeys (H. Horie et al., J. Virol. 68:681-688, 1994). Mutants of the virulent Mahoney strain of poliovirus have been generated by disruption of nucleotides 128 to 134, at stem-loop II within the 5' noncoding region, and four of these mutants multiplicated well in human HeLa cells but poorly in mouse TgSVA cells that had been established from the kidney of the poliovirus-sensitive transgenic mouse. Neurovirulence tests using the two animal models revealed that these mutants were strongly attenuated only in tests with the mouse model and were therefore HR mutants. The virus infection cycle in TgSVA cells was restricted by an internal ribosomal entry site (IRES)-dependent initiation process of translation. Viral protein synthesis and the associated block of cellular protein synthesis were not observed in TgSVA cells infected with three of four HR mutants and was evident at only a low level in the remaining mutant. The mutant RNAs were functional in a cell-free protein synthesis system from HeLa cells but not in those from TgSVA and mouse neuroblastoma NS20Y cells. These results suggest that host factor(s) affecting IRES-dependent translation of poliovirus differ between human and mouse cells and that the mutant IRES constructs detect species differences in such host factor(s). The IRES could potentially be a host range determinant for poliovirus infection.     

The sequence element of the internal ribosome entry site and a 25-kilodalton cellular protein contribute to efficient internal initiation of translation of hepatitis C virus RNA.

Translation of hepatitis C virus (HCV) RNA is initiated by internal entry of ribosomes into the 5' noncoding region (NCR). This process depends on genomic elements within the 5' NCR called the internal ribosome entry site (IRES) and may involve host factors. The alpha-branch structure (nucleotides 47 to 67) of the HCV IRES is considered a cis-acting element critical for translation initiation because it is indispensable for translation in vitro (S. Fukushi, K. Katayama, C. Kurihara, N. Ishiyama, F. B. Hoshino, T. Ando, and A. Oya, Biochem. Biophys. Res. Commun. 199:425-432, 1994). In order to further characterize the function of the alpha-branch, we determined whether sequence exchange within the alpha-branch had any effect on translation initiation. An in vitro translation study revealed that the stem sequences of this region played an important role in efficient IRES function. In addition to several HeLa cell proteins, which had a binding affinity for the 5' NCR, a novel 25-kDa protein that specifically interacted with the HCV IRES was discovered. The binding affinity of the 25-kDa protein for the 5' NCR was correlated with the efficiency of translation initiation of HCV RNA, indicating a critical role for the 25-kDa protein in HCV translation.     

Folding of pyrimidine-enriched RNA fragments from the vicinity of the internal ribosomal entry site of hepatitis A virus.

Two RNA fragments from the region just upstream of the internal ribosome entry site of Hepatitis A virus (HAV) were studied, a 35mer (HAV-35), 5'U4C3U3C3U4C3U3C2UAU2C3U33(4), and a 23mer (HAV-23), 5(4)U4C3U3C3U4C3U33(4). Secondary structural predictions and nuclease digestion patterns obtained with genomic RNAs suggested that they link two stable Watson-Crick (WC) hairpins in the genomic RNA and do not form conventional WC secondary structure, but do fold to form a condensed, stacked 'domain'. To obtain more information, folding of HAV-23 and -35 RNA fragments was characterized using 1H nuclear magnetic resonance, in H2O as a function of pH and temperature, circular dichroism as a function of NaCl concentration, pH and temperature, and square-wave voltammetry as a function of pH. The results indicate that these oligo-nucleotides form intramolecular structures that contain transient U*U base pairs at pH 7 and moderate ionic strength (100 mM NaCl). This folded structure becomes destabilized and loses the U*U base pairs above and below neutral pH, especially at ionic strengths above 0.1. All of the cytidine protons exchange relatively rapidly with solvent protons (exchange lifetimes shorter than 1 ms), so the structure contains few if any C*CH+base pairs at neutral pH, but can apparently form them at pH values below 6. We present a series of possible models in which chain folding draws the strand termini closer together, possibly serving to pull the attached WC hairpin domains together and providing a functional advantage by nucleating reversible formation of a more viable RNA substrate.