Structural organization of a viral IRES depends on the integrity of the GNRA motif

Little is known about the tertiary structure of internal ribosome entry site (IRES) elements. The central domain of foot-and-mouth disease (FMDV) IRES, named 3 or I, contains a conserved GNRA motif, essential for IRES activity. We have combined functional analysis with RNA probing to define its structural organization. We have found that a UNCG motif does not functionally substitute the GNRA motif; moreover, binding of synthetic GNRA stem-loops to domain 3 was significantly reduced in RNAs bearing UCCG or GUAG substitutions. The apical region of domain 3 consists of a four-way junction where residues of the GNRA tetraloop are responsible for the organization of the adjacent stem-loops, as deduced from ribonucleases and dimethyl sulfate accessibility. A single A-to-G substitution in the fourth position of this motif led to a strong RNA reorganization, affecting several nucleotides away in the secondary structure of domain 3. The study of mutants bearing UNCG or GUAG tetraloops revealed lack of protection to chemical attack in native RNA at specific nucleotides relative to the parental GUAA, suggesting that the GNRA motif dictates the organization and stability of domain 3. This effect is likely mediated by the interaction with distant residues. Therefore, the GNRA motif plays a crucial role in the organization of IRES structure with important consequences on activity.     

Exploring IRES region accessibility by interference of foot-and-mouth disease virus infectivity

Translation initiation of picornavirus RNA is driven by an internal ribosome entry site (IRES) element located upstream of the initiator codon. RNA structure organization as well as RNA-protein interaction plays a fundamental role in internal initiation. IRES activity has been mainly analyzed in the context of reporter genes, lacking regions of the viral genome potentially affecting translation efficiency. With the aim to understand the vulnerability of the IRES and translation start region to small molecules in the context of the viral genome, we designed a set of customized RNase-resistant 2'O-methyl antisense oligoribonucleotides (2'OMe AONs) based on RNA structure data. These AONs were then used to monitor their capacity to interfere viral RNA translation, and thus, to inhibit virus yield. Foot-and-mouth disease virus (FMDV) RNA translation can be initiated at two in-frame AUG codons. We show here that a 2'OMe AON complementary to AUG2 inhibited viral multiplication more efficiently than the one that targeted AUG1. Furthermore, the response of the viral RNA to AONs targeting the IRES region denoted important differences between tissue culture cells and cell-free systems, reinforcing the need to analyze viral RNA response in living cells. Importantly, we have identified four specific motifs within the IRES element that are targets for viral inhibitors both in tissue culture cells and in cell-free systems. The identified targets define accessible regions to small molecules, which disturb either the RNA structural organization or the RNA-protein interactions needed to initiate translation in FMDV RNA.     

IRES interaction with translation initiation factors: functional characterization of novel RNA contacts with eIF3, eIF4B, and eIF4GII

Translation initiation promoted by picornavirus internal ribosome entry site (IRES) elements is dependent on the association of specific IRES sequences to the initiation factor eIF4G. However the RNA determinants interacting with other components of the translational machinery are still unknown. In this study, we have identified novel RNA-protein interactions between the foot-and-mouth disease virus (FMDV) IRES and three translation initiation factors. A doublet of 116/110 kDa that crosslinked to the FMDV IRES is a component of eIF3. We show here that domain 5 holds the preferential binding site for eIF3, although this complex initiation factor can establish multiple contacts with the IRES structure. We have also identified the phylogenetically conserved hairpin of domain 5 as the RNA motif responsible for eIF4B interaction. Mutation of this stem-loop structure abrogated eIF4B, but not eIF3, binding to the IRES. Remarkably, IRES mutants severely affected in their interaction with eIF4B showed a mild reduction in IRES activity when tested in the context of a bicistronic expression vector in transfected cells. Finally, we provide evidence of the interaction of eIF4GII with FMDV IRES, the RNA determinants for this interaction being shared with its functional homolog eIF4GI. The FMDV Lb protease generated a C-terminal fragment of eIF4GII that binds to the IRES as efficiently as the intact protein. Competition experiments showed that titration of eIF4B or p110/116 interaction with the FMDV IRES required a large excess of competitor relative to eIF4G, strongly suggesting that eIF4G-IRES interaction is a limiting factor to titrate the IRES. Comparative analysis of the activity of IRES mutants affected in domains 4 and 5 regarding their pattern of RNA-protein complex formation demonstrates that while binding of eIF4B with the FMDV IRES is dispensable, interaction of eIF4G is a central feature of the activity of this element.     

Riboproteomic analysis of polypeptides interacting with the internal ribosome-entry site element of foot-and-mouth disease viral RNA

Initiation of translation driven by internal ribosome entry site (IRES) elements depends upon the structural organization of this mRNA region. Besides translation initiation factors (eIFs), auxiliary proteins can also affect IRES activity. With the aim to identify proteins interacting with two unrelated IRESs present in the genome of foot-and-mouth disease virus (FMDV) and hepatitis C virus (HCV) we have used a proteomic approach. This procedure allowed the identification of 21 RNA-binding proteins interacting with discrete regions of the FMDV IRES, domains 3 and 5, and 16 interacting with domain III of the HCV IRES. In support of the binding specificity, the factors interacting with domain 3 differed from those interacting with domain 5, and included three poly(rC)-binding protein (PCBP) members, besides proliferation-associated 2G4 (PA2G4) and deleted-azoospermia 1 (DAZ1) protein. Around 71% of the identified factors associated with the FMDV IRES differ from those interacting with the HCV IRES. The group of proteins interacting with the FMDV or the HCV IRES includes eIF4B and 5 subunits of eIF3, respectively, known to interact with each of these RNAs, validating the results of this approach. According to the function of the identified proteins, 55% are involved in translation control, whereas 35% play a role in different aspects of RNA lifespan. Compilation of factors preferentially associated with FMDV or HCV IRES provides a basis for examining the strategies used by IRESs to recruit the translation machinery.     

The internal ribosome entry site (IRES) of hepatitis C virus visualized by electron microscopy

Translation of hepatitis C virus (HCV) RNA is initiated via the internal ribosome entry site (IRES), located within the 5' untranslated region. Although the secondary structure of this element has been predicted, little information on the tertiary structure is available. Here we report the first structural characterization of the HCV IRES using electron microscopy. In vitro transcribed RNA appeared as particles with characteristic morphology and gold labeling using a specific oligonucleotide confirmed them to be HCV IRES. Dimerization of the IRES by hybridization with tandem repeat oligonucleotides allowed the identification of domain III and an assignment of domains II and IV to distinct regions within the molecule. Using immunogold labeling, the pyrimidine tract binding protein (PTB) was shown to bind to domain III. Structure-function relationships based on the flexible hinge between domains II and III are suggested. Finally, the architecture of the HCV IRES was seen to be markedly different from that of a picornavirus, foot-and-mouth disease virus (FMDV).     

Evidence for an RNA chaperone function of polypyrimidine tract-binding protein in picornavirus translation

The cellular polypyrimidine tract-binding protein (PTB) is recruited by the genomic RNAs of picornaviruses to stimulate translation initiation at their internal ribosome entry site (IRES) elements. We investigated the contribution of the individual RNA recognition motif (RRM) domains of PTB to its interaction with the IRES of foot-and-mouth disease virus (FMDV). Using a native gel system, we found that PTB is a monomer, confirming recent reports that challenged the previous view that PTB is a dimer. Mapping the spatial orientation of PTB relative to the bound IRES RNA, we found that the two C-terminal RRM domains III and IV of PTB bind in an oriented way to the IRES. Domain III contacts the IRES stem-loop 2, while domain IV contacts the separate IRES 3' region. PTB domain I appears not to be involved directly in RNA binding, but domain II stabilizes the RNA binding conferred by domains III and IV. A PTB protein containing only these two C-terminal PTB domains is sufficient to enhance the entry of initiation factor eIF4G to the IRES and stimulate IRES activity, and the long-lived PTB-IRES interaction stabilized by domain II is not a prerequisite for this function. Thus, PTB most likely acts as an RNA chaperone to stabilize IRES structure and, in that way, augment IRES activity.     

Functional involvement of polypyrimidine tract-binding protein in translation initiation complexes with the internal ribosome entry site of foot-and-mouth disease virus.

The synthesis of picornavirus polyproteins is initiated cap independently far downstream from the 5' end of the viral RNA at the internal ribosome entry site (IRES). The cellular polypyrimidine tract-binding protein (PTB) binds to the IRES of foot-and-mouth disease virus (FMDV). In this study, we demonstrate that PTB is a component of 48S and 80S ribosomal initiation complexes formed with FMDV IRES RNA. The incorporation of PTB into these initiation complexes is dependent on the entry of the IRES RNA, since PTB and IRES RNA can be enriched in parallel either in 48S or 80S ribosomal complexes by stage-specific inhibitors of translation initiation. The formation of the ribosomal initiation complexes with the IRES occurs slowly, is temperature dependent, and correlates with the incorporation of PTB into these complexes. In a first step, PTB binds to the IRES, and then the small ribosomal subunit encounters this PTB-IRES complex. Mutations in the major PTB-binding site interfere simultaneously with the formation of initiation complexes, translation efficiency, and PTB cross-linking. PTB stimulates translation directed by the FMDV IRES in a rabbit reticulocyte lysate depleted of internal PTB, and the efficiency of translation can be restored to the original level by the addition of PTB. These results indicate that PTB plays an important role in the formation of initiation complexes with FMDV IRES RNA and in stimulation of internal translation initiation with this picornavirus.     

Characterization of a cyanobacterial RNase P ribozyme recognition motif in the IRES of foot-and-mouth disease virus reveals a unique structural element

Translation initiation driven by internal ribosome entry site (IRES) elements is dependent on the structural organization of the IRES region. Picornavirus IRES are organized in structural domains, in which the terminal stem-loops participate in functional RNA-protein interactions. However, the mechanistic role performed by the central domain during internal initiation has not been elucidated yet. Here we show that the foot-and-mouth-disease virus IRES contains a structural motif that serves in vitro as substrate for the Synechocystis sp. RNase P ribozyme, a structure-dependent endonuclease that participates in tRNA precursor processing. Recognition of the IRES substrate was dose dependent, required high magnesium concentration, and resulted in the formation of cleavage products with 5' phosphate and 3' hydroxyl ends. Mapping of the core recognition motif indicated that it overlapped with the apical region of the central domain. Two IRES constructs containing nucleotide substitutions in the apical region of the central domain that reorganized RNA structure displayed an altered pattern of cleavage by the cyanobacterial ribozyme generating new cleavage events in nearby residues. From these data it is inferred that the central domain of the IRES region has evolved a tRNA structural mimicry that renders it a substrate for RNase P ribozyme reaction. Recognition of this motif was affected in defective IRES mutants with a local RNA structure reorganization, suggesting that its structural preservation is required for IRES activity.     

A novel protein-RNA binding assay: functional interactions of the foot-and-mouth disease virus internal ribosome entry site with cellular proteins

Translation initiation on foot-and-mouth disease virus (FMDV) RNA occurs by a cap-independent mechanism directed by a highly structured element (approximately 435 nt) termed an internal ribosome entry site (IRES). A functional assay to identify proteins that bind to the FMDV IRES and are necessary for FMDV IRES-mediated translation initiation has been developed. In vitro-transcribed polyadenylated RNAs corresponding to the whole or part of the FMDV IRES were immobilized on oligo-dT Dynabeads and used to deplete rabbit reticulocyte lysate (RRL) of IRES-binding proteins. Translation initiation factors eIF4G, eIF4A, and eIF4B bound to the 3' domain of the FMDV IRES. Depletion of eIF4G from RRL by this region of the FMDV IRES correlated with the loss of translational capacity of the RRL for capped, uncapped, and FMDV IRES-dependent mRNAs. However, this depleted RRL still supported hepatitis C virus IRES-directed translation. Poly (rC) binding protein-2 bound to the central domain of the FMDV IRES, but depletion of RRL with this IRES domain had no effect on FMDV IRES-directed translation initiation.     

Tailoring the switch from IRES-dependent to 5′-end-dependent translation with the RNase P ribozyme

Translation initiation driven by internal ribosome entry site (IRES) elements is dependent on the structural organization of the IRES region. We have previously shown that a structural motif within the foot-and-mouth-disease virus IRES is recognized in vitro as substrate for the Synechocystis sp. RNase P ribozyme. Here we show that this structure-dependent endonuclease recognizes the IRES element in cultured cells, leading to inhibition of translation. Inhibition of IRES activity was dependent on the expression of the active ribozyme RNA subunit. Moreover, expression of the antisense sequence of the ribozyme did not inhibit IRES activity, demonstrating that stable RNA structures located upstream of the IRES element do not interfere with internal initiation. RNAs carrying defective IRES mutants that were substrates of the ribozyme in vivo revealed an increased translation of the reporter in response to the expression of the active ribozyme. In support of RNA cleavage, subsequent analysis of the translation initiation manner indicated a switch from IRES-dependent to 5′-end-dependent translation of RNase P target RNAs. We conclude that the IRES element is inactivated by expression in cis of RNase P in the cytoplasm of cultured cells, providing a promising antiviral tool to combat picornavirus infections. Furthermore, our results reinforce the essential role of the structural motif that serves as RNase P recognition motif for IRES activity.     

Specific interference between two unrelated internal ribosome entry site elements impairs translation efficiency

Internal ribosome entry site (IRES) elements allow simultaneous synthesis of multiple proteins in eukaryotic cells. Here, two unrelated IRESs that perform efficiently in bicistronic constructs, the picornavirus foot-and-mouth disease virus (FMDV) and the cellular immunoglobulin heavy chain binding protein (BiP) IRES, were used to generate a tricistronic vector. Functional analysis of the tricistronic RNA evidenced that the efficiency of protein synthesis under the control of BiP IRES was lower than that of the FMDV IRES, relative to the efficiency measured in bicistronic vectors. A specific competition between these elements was verified using two separate mono- or bicistronic constructs in vivo and in vitro. In contrast, no interference was detected with the hepatitis C virus (HCV) IRES. The interference effect of FMDV IRES was observed in cis and trans, in support of competition for common transacting factors different than those used in cap- and HCV-dependent initiation.     

IRES-driven translation is stimulated separately by the FMDV 3'-NCR and poly(A) sequences

The 3′ end region of foot-and-mouth disease virus (FMDV) consists of two distinct elements, a 90 nt untranslated region (3′-NCR) and a poly(A) tract. Removal of either the poly(A) tract or both the 3′-NCR and the poly(A) tract abrogated infectivity in susceptible cells in the context of a full-length cDNA clone. We have addressed the question of whether the impairment of RNA infectivity is related to defects at the translation level using a double approach. First, compared to the full-length viral RNA, removal of the 3′ sequences reduced the efficiency of translation in vitro. Secondly, a stimulatory effect of the 3′ end sequences on IRES-dependent translation was found in vivo using bicistronic constructs. RNAs carrying the FMDV 3′ end sequences linked to the second cistron showed a significant stimulation of IRES-dependent translation, whereas cap-dependent translation was not affected. Remarkably, IRES-dependent stimulation exerted by the poly(A) tract or the 3′-NCR seems to be the result of two separate events, as the 3′-NCR alone enhanced IRES activity on its own. Under conditions of FMDV Lb protease-induced translation shut-off, the stimulation of IRES activity reached values above 6-fold in living cells. A northern blot analysis indicated that IRES stimulation was not the consequence of a change in the stability of the bicistronic RNA produced in transfected cells. Analysis of the RNA-binding proteins interacting with a mixture of 3′ end and IRES probes showed an additive pattern. Altogether, our results strongly suggest that individual signals in the viral 3′ end ensure stimulation of FMDV translation.     

A preformed compact ribosome-binding domain in the cricket paralysis-like virus IRES RNAs

The internal ribosome site RNA of the cricket paralysis-like viruses (CrPV-like) binds directly to the ribosome, assembling the translation machinery without initiation factors. This mechanism does not require initiator tRNA, and translation starts from a non-AUG codon. A wealth of biochemical data has yielded a working model for this process, but the three-dimensional structure and biophysical characteristics of the unbound CrPV-like IRES RNAs are largely unexplored. Here, we demonstrate that the CrPV-like IRESes prefold into a two-part structure in the presence of magnesium ions. The largest part is a prefolded compact RNA domain that shares folding and structural characteristics with other compactly folded RNAs such as group I intron RNAs and RNase P RNA. Chemical probing reveals that the CrPV-like IRES' compact domain contains RNA helices that are packed tightly enough to exclude solvent, and analytical ultracentrifugation indicates a large change in the shape of the IRES upon folding. Formation of this compact domain is necessary for binding of the 40S subunit, and the structural organization of the unbound IRES RNA is consistent with the hypothesis that the IRES is functionally and structurally preorganized before ribosome binding.     

Structural basis for the biological relevance of the invariant apical stem in IRES-mediated translation

RNA structure plays a fundamental role in internal initiation of translation. Picornavirus internal ribosome entry site (IRES) are long, efficient cis-acting elements that recruit the ribosome to internal mRNA sites. However, little is known about long-range constraints determining the IRES RNA structure. Here, we sought to investigate the functional and structural relevance of the invariant apical stem of a picornavirus IRES. Mutation of this apical stem revealed better performance of G:C compared with C:G base pairs, demonstrating that the secondary structure solely is not sufficient for IRES function. In turn, mutations designed to disrupt the stem abolished IRES activity. Lack of tolerance to accept genetic variability in the apical stem was supported by the presence of coupled covariations within the adjacent stem-loops. SHAPE structural analysis, gel mobility-shift and microarrays-based RNA accessibility revealed that the apical stem contributes to maintain IRES RNA structure through the generation of distant interactions between two adjacent stem-loops. Our results demonstrate that a highly interactive structure constrained by distant interactions involving invariant G:C base pairs plays a key role in maintaining the RNA conformation necessary for IRES-mediated translation.     

Translation Initiation Factor eIF4B Interacts with a Picornavirus Internal Ribosome Entry Site in both 48S and 80S Initiation Complexes Independently of Initiator AUG Location

Most eukaryotic initiation factors (eIFs) are required for internal translation initiation at the internal ribosome entry site (IRES) of picornaviruses. eIF4B is incorporated into ribosomal 48S initiation complexes with the IRES RNA of foot-and-mouth disease virus (FMDV). In contrast to the weak interaction of eIF4B with capped cellular mRNAs and its release upon entry of the ribosomal 60S subunit, eIF4B remains tightly associated with the FMDV IRES during formation of complete 80S ribosomes. Binding of eIF4B to the IRES is energy dependent, and binding of the small ribosomal subunit to the IRES requires the previous energy-dependent association of initiation factors with the IRES. The interaction of eIF4B with the IRES in 48S and 80S complexes is independent of the location of the initiator AUG and thus independent of the mechanism by which the small ribosomal subunit is placed at the actual start codon, either by direct internal ribosomal entry or by scanning. eIF4B does not greatly rearrange its binding to the IRES upon entry of the ribosomal subunits, and the interaction of eIF4B with the IRES is independent of the polypyrimidine tract-binding protein, which enhances FMDV translation.     

The hepatitis C virus internal ribosome entry site adopts an ion-dependent tertiary fold.

Hepatitis C virus (HCV) contains an internal ribosome entry site (IRES) located in the 5' untranslated region of the genomic RNA that drives cap-independent initiation of translation of the viral message. The approximate secondary structure and minimum functional length of the HCV IRES are known, and extensive mutagenesis has established that nearly all secondary structural domains are critical for activity. However, the presence of an IRES RNA tertiary fold and its functional relevance have not been established. Using chemical and enzymatic probes of the HCV IRES RNA in solution, we show that the IRES adopts a unique three-dimensional structure at physiological salt concentrations in the absence of additional cofactors or the translation apparatus. Folding of the IRES involves cooperative uptake of magnesium and is driven primarily by charge neutralization. This tertiary structure contains at least two independently folded regions which closely correspond to putative binding sites for the 40 S ribosomal subunit and initiation factor 3 (eIF3). Point mutations that inhibit IRES folding also inhibit its function, suggesting that the IRES tertiary structure is essential for translation initiation activity. Chemical and enzymatic probing data and small-angle X-ray scattering (SAXS) experiments in solution show that upon folding, the IRES forms an extended structure in which functionally important loops are exposed. These results suggest that the 40 S ribosomal subunit and eIF3 bind an HCV IRES that is prefolded to spatially organize recognition domains.     

Interconversion between Parallel and Antiparallel Conformations of a 4H RNA junction in Domain 3 of Foot-and-Mouth Disease Virus IRES Captured by Dynamics Simulations

RNA junctions are common secondary structural elements present in a wide range of RNA species. They play crucial roles in directing the overall folding of RNA molecules as well as in a variety of biological functions. In particular, there has been great interest in the dynamics of RNA junctions, including conformational pathways of fully base-paired 4-way (4H) RNA junctions. In such constructs, all nucleotides participate in one of the four double-stranded stem regions, with no connecting loops. Dynamical aspects of these 4H RNAs are interesting because frequent interchanges between parallel and antiparallel conformations are thought to occur without binding of other factors. Gel electrophoresis and single-molecule fluorescence resonance energy transfer experiments have suggested two possible pathways: one involves a helical rearrangement via disruption of coaxial stacking, and the other occurs by a rotation between the helical axes of coaxially stacked conformers. Employing molecular dynamics simulations, we explore this conformational variability in a 4H junction derived from domain 3 of the foot-and-mouth disease virus internal ribosome entry site (IRES); this junction contains highly conserved motifs for RNA-RNA and RNA-protein interactions, important for IRES activity. Our simulations capture transitions of the 4H junction between parallel and antiparallel conformations. The interconversion is virtually barrier-free and occurs via a rotation between the axes of coaxially stacked helices with a transient perpendicular intermediate. We characterize this transition, with various interhelical orientations, by pseudodihedral angle and interhelical distance measures. The high flexibility of the junction, as also demonstrated experimentally, is suitable for IRES activity. Because foot-and-mouth disease virus IRES structure depends on long-range interactions involving domain 3, the perpendicular intermediate, which maintains coaxial stacking of helices and thereby consensus primary and secondary structure information, may be beneficial for guiding the overall organization of the RNA system in domain 3.