The mechanism of translation initiation on Type 1 picornavirus IRESs

Picornavirus Type 1 IRESs comprise five principal domains (dII–dVI). Whereas dV binds eIF4G, a conserved AUG in dVI was suggested to stimulate attachment of 43S ribosomal preinitiation complexes, which then scan to the initiation codon. Initiation on Type 1 IRESs also requires IRES trans‐acting factors (ITAFs), and several candidates have been proposed. Here, we report the in vitro reconstitution of initiation on three Type 1 IRESs: poliovirus (PV), enterovirus 71 (EV71), and bovine enterovirus (BEV). All of them require eIF2, eIF3, eIF4A, eIF4G, eIF4B, eIF1A, and a single ITAF, poly(C) binding protein 2 (PCBP2). In each instance, initiation starts with binding of eIF4G/eIF4A. Subsequent recruitment of 43S complexes strictly requires direct interaction of their eIF3 constituent with eIF4G. The following events can differ between IRESs, depending on the stability of dVI. If it is unstructured (BEV), all ribosomes scan through dVI to the initiation codon, requiring eIF1 to bypass its AUG. If it is structured (PV, EV71), most initiation events occur without inspection of dVI, implying that its AUG does not determine ribosomal attachment.     

Factor requirements for translation initiation on the Simian picornavirus internal ribosomal entry site

The Simian picornavirus type 9 (SPV9) 5'-untranslated region (5' UTR) has been predicted to contain an internal ribosomal entry site (IRES) with structural elements that resemble domains of hepacivirus/pestivirus (HP) IRESs. In vitro reconstitution of initiation confirmed that this 5' UTR contains an IRES and revealed that it has both functional similarities and differences compared to HP IRESs. Like HP IRESs, the SPV9 IRES bound directly to 40S subunits and eukaryotic initiation factor (eIF) 3, depended on the conserved domain IIId for ribosomal binding and consequently for function, and additionally required eIF2/initiator tRNA to yield 48S complexes that formed elongation-competent 80S ribosomes in the presence of eIF5, eIF5B, and 60S subunits. Toeprinting analysis revealed that eIF1A stabilized 48S complexes, whereas eIF1 induced conformational changes in the 40S subunit, likely corresponding to partial opening of the entry latch of the mRNA-binding channel, that were exacerbated by eIF3 and suppressed by eIF1A. The SPV9 IRES differed from HP IRESs in that its function was enhanced by eIF4A/eIF4F when the IRES was adjacent to the wild-type coding sequence, but was less affected by these factors or by a dominant negative eIF4A mutant when potentially less structured coding sequences were present. Exceptionally, this IRES promoted binding of initiator tRNA to the initiation codon in the P site of 40S subunits independently of eIF2. Although these 40S/IRES/tRNA complexes could not form active 80S ribosomes, this constitutes a second difference between the SPV9 and HP IRESs. eIF1 destabilized the eIF2-independent ribosomal binding of initiator tRNA.     

The novel mechanism of initiation of picornavirus RNA translation

The initiation of translation of picornaviral RNAs takes place by an unusual mechanism whereby ribosomes bind directly to an internal site rather than scan the RNA from the 5′-end. This internal entry mechanism requires a 450-nucleotide segment of the picornavirus 5′-untranslated region. The ribosome binds initially to a site at the 3′-end of this segment, and then may scan the RNA to reach the authentic initiation site. This novel mechanism may be of relevance to the translation of some cellular mRNAs.     

Polypyrimidine tract-binding protein stimulates the poliovirus IRES by modulating eIF4G binding

Tethered hydroxyl‐radical probing has been used to determine the orientation of binding of polypyrimidine tract‐binding protein (PTB) to the poliovirus type 1 (Mahoney) (PV‐1(M)) internal ribosome entry site/segment (IRES)—the question of which RNA‐binding domain (RBD) binds to which sites on the IRES. The results show that under conditions in which PTB strongly stimulates IRES activity, a single PTB is binding to the IRES, a finding which was confirmed by mass spectrometry of PTB/IRES complexes. RBDs1 and 2 interact with the basal part of the Domain V irregular stem loop, very close to the binding site of eIF4G, and RBDs3 and 4 interact with the single‐stranded regions flanking Domain V. The binding of PTB is subtly altered in the presence of the central domain (p50) of eIF4G, and p50 binding is likewise modified if PTB is present. This suggests that PTB stimulates PV‐1(M) IRES activity by inducing eIF4G to bind in the optimal position and orientation to promote internal ribosome entry, which, in PV‐1(M), is at an AUG triplet 30 nt downstream of the base of Domain V.     

eIF2-dependent and eIF2-independent modes of initiation on the CSFV IRES: a common role of domain II

Specific interactions of the classical swine fever virus internal ribosomal entry site (IRES) with 40S ribosomal subunits and eukaryotic translation initiation factor (eIF)3 enable 43S preinitiation complexes containing eIF3 and eIF2-GTP-Met-tRNA(iMet) to bind directly to the initiation codon, yielding 48S initiation complexes. We report that eIF5B or eIF5B/eIF3 also promote Met-tRNA(iMet) binding to IRES-40S complexes, forming 48S complexes that can assemble elongation-competent ribosomes. Although 48S complexes assembled both by eIF2/eIF3- and eIF5B/eIF3-mediated Met-tRNA(iMet) recruitment were destabilized by eIF1, dissociation of 48S complexes formed with eIF2 could be out-competed by efficient subunit joining. Deletion of IRES domain II, which is responsible for conformational changes induced in 40S subunits by IRES binding, eliminated the sensitivity of 48S complexes assembled by eIF2/eIF3- and eIF5B/eIF3-mediated mechanisms to eIF1-induced destabilization. However, 48S complexes formed by the eIF5B/eIF3-mediated mechanism on the truncated IRES could not undergo efficient subunit joining, as reported previously for analogous complexes assembled with eIF2, indicating that domain II is essential for general conformational changes in 48S complexes, irrespective of how they were assembled, that are required for eIF5-induced hydrolysis of eIF2-bound GTP and/or subunit joining.     

Human initiation factor eIF3 subunit b interacts with HCV IRES RNA through its N-terminal RNA recognition motif

Many viral mRNAs contain a 5′-UTR RNA element called internal ribosome-entry site (IRES), which bypasses the requirement of some canonical initiation factors allowing cap-independent translation. The IRES of hepatitis-C virus drives translation by directly recruiting 40S ribosomal subunits and binds to eIF3 which plays a critical role in both cap-dependent and cap-independent translation. However, the molecular basis for eIF3 activity in either case remains enigmatic. Here we report that subunit b of the eIF3 complex directly binds to HCV IRES domain III via its N-terminal-RRM. Because eIF3b was previously shown to be involved in eIF3j binding, biological implications are discussed.     

DUG is a novel homologue of translation initiation factor 4G that binds eIF4A

To elucidate the molecular mechanisms of cell death, we have cloned a new gene, designated death-upregulated gene (DUG), from rat insulinoma cells. DUG is constitutively expressed at very low levels in normal cells but is dramatically upregulated in apoptotic cells following serum/glucose starvation or death receptor ligation by Fas ligand. The DUG mRNA is present in two splicing forms: a long form that encodes a protein of 469 amino acids and a short form that gives rise to a polypeptide of 432 amino acids. The predicted DUG protein sequence contains two putative nuclear localization signals and multiple phosphorylation sites for protein kinases and two conserved MA3 domains. Importantly, DUG is homologous to eukaryotic translation initiation factor (eIF) 4G and binds to eIF4A presumably through MA3 domains. Upon transfection, DUG inhibits both intrinsic and extrinsic pathways of apoptosis. Thus, DUG is a novel homologue of eIF4G that regulates apoptosis.     

Internal translation initiation on the foot-and-mouth disease virus IRES is affected by ribosomal stalk conformation

A human cell line, in which expression of the ribosomal stalk proteins P1 and P2 has been suppressed by RNAi technology, has been used to test how the loss of these proteins affects IRES-dependent translation. Foot-and-mouth disease virus (FMDV) IRES-dependent translation from a bicistronic construct is about three fold higher in the P1/P2-depleted cells than in control cells in the presence of Lb protease. By contrast, no effect on Hepatitis C virus (HCV) IRES translation was observed. These results emphasize the functional heterogeneity of the IRES and they highlight a functional connection between the ribosomal stalk and picornavirus IRES-dependent translation.     

Activation of cap-independent translation by variant eukaryotic initiation factor 4G in vivo

Protein synthesis is tightly controlled by assembly of an intricate ribonucleoprotein complex at the m⁷GTP-cap on eukaryotic mRNAs. Ensuing linear scanning of the 5′ untranslated region (UTR) is believed to transfer the preinitiation complex to the initiation codon. Eukaryotic mRNAs are characterized by significant 5′ UTR heterogeneity, raising the possibility of differential control of translation initiation rate at individual mRNAs. Curiously, many mRNAs with unconventional, highly structured 5′ UTRs encode proteins with central biological roles in growth control, metabolism, or stress response. The 5′ UTRs of such mRNAs may influence protein synthesis rate in multiple ways, but most significantly they have been implicated in mediating alternative means of translation initiation. Cap-independent initiation bypasses strict control over the formation of initiation intermediates at the m⁷GTP cap. However, the molecular mechanisms that favor alternative means of ribosome recruitment are not understood. Here we provide evidence that eukaryotic initiation factor (eIF) 4G controls cap-independent translation initiation at the c-myc and vascular endothelial growth factor (VEGF) 5′ UTRs in vivo. Cap-independent translation was investigated in tetracycline-inducible cell lines expressing either full-length eIF4G or a C-terminal fragment (Ct) lacking interaction with eIF4E and poly(A) binding protein. Expression of Ct, but not intact eIF4G, potently stimulated cap-independent initiation at the c-myc/VEGF 5′ UTRs. In vitro RNA-binding assays suggest that stimulation of cap-independent translation initiation by Ct is due to direct association with the c-myc/VEGF 5′ UTR, enabling 43S preinitiation complex recruitment. Our work demonstrates that variant translation initiation factors enable unconventional translation initiation at mRNA subsets with distinct structural features.     

The oncomicropeptide APPLE promotes hematopoietic malignancy by enhancing translation initiation

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PABP/purine-rich motif as an initiation module for cap-independent translation in pattern-triggered immunity

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真核生物mRNA翻译起始机制研究进展

在真核生物中,mRNA翻译是一个复杂的多步骤过程,包括起始、延伸和终止3个阶段。其中,起始阶段的调控是影响mRNA翻译的关键。目前已经发现,mRNA翻译起始方式有多种,以最早发现的m ⁷G帽依赖性扫描机制最为经典,但当细胞处于逆境,经典起始机制受到抑制时,其他类型的起始机制会将其替代以保证翻译的顺利进行。本文对目前已发现的真核生物mRNA不同翻译起始机制特别是经典起始机制的替代机制进行了综述,旨在为深入认识真核生物基因在翻译水平上的表达调控提供参考。     

HIV-2 genomic RNA contains a novel type of IRES located downstream of its initiation codon

Eukaryotic translation initiation begins with assembly of a 48S ribosomal complex at the 5' cap structure or at an internal ribosomal entry segment (IRES). In both cases, ribosomal positioning at the AUG codon requires a 5' untranslated region upstream from the initiation site. Here, we report that translation of the genomic RNA of human immunodeficiency virus type 2 takes place by attachment of the 48S ribosomal preinitiation complex to the coding region, with no need for an upstream 5' untranslated RNA sequence. This unusual mechanism is mediated by an RNA sequence that has features of an IRES with the unique ability to recruit ribosomes upstream from its core domain. A combination of translation assays and structural studies reveal that sequences located 50 nucleotides downstream of the AUG codon are crucial for IRES activity.     

Compartmentalisation and localisation of the translation initiation factor (eIF) 4F complex in normally growing fibroblasts

Previous observations of association of mRNAs and ribosomes with subcellular structures highlight the importance of localised translation. However, little is known regarding associations between eukaryotic translation initiation factors and cellular structures within the cytoplasm of normally growing cells. We have used detergent-based cellular fractionation coupled with immunofluorescence microscopy to investigate the subcellular localisation in NIH3T3 fibroblasts of the initiation factors involved in recruitment of mRNA for translation, focussing on eIF4E, the mRNA cap-binding protein, the scaffold protein eIF4GI and poly(A) binding protein (PABP). We find that these proteins exist mainly in a soluble cytosolic pool, with only a subfraction tightly associated with cellular structures. However, this "associated" fraction was enriched in active "eIF4F" complexes (eIF4E.eIF4G.eIF4A.PABP). Immunofluorescence analysis reveals both a diffuse and a perinuclear distribution of eIF4G, with the perinuclear staining pattern similar to that of the endoplasmic reticulum. eIF4E also shows both a diffuse staining pattern and a tighter perinuclear stain, partly coincident with vimentin intermediate filaments. All three proteins localise to the lamellipodia of migrating cells in close proximity to ribosomes, microtubules, microfilaments and focal adhesions, with eIF4G and eIF4E at the periphery showing a similar staining pattern to the focal adhesion protein vinculin.     

Multimerization of poly(rC) binding protein 2 is required for translation initiation mediated by a viral IRES

The cellular protein, poly(rC) binding protein 2 (PCBP2), is known to function in picornavirus cap-independent translation. We have further examined the RNA binding properties and protein-protein interactions of PCBP2 necessary for translation. We have studied its putative multimerization properties utilizing the yeast two-hybrid assay and in vitro biochemical methods, including glutathione S-transferase (GST) pull-down assays and gel filtration. Through genetic analysis, the multimerization domain has been localized to the second K-homologous (KH) RNA binding domain of the protein between amino acids 125 and 158. To examine the function of multimerization in poliovirus translation, we utilized the truncated protein, DeltaKH1-PCBP2, which is capable of multimer formation, but does not bind poliovirus stem-loop IV RNA (an interaction required for translation). Utilizing RNA binding and in vitro translation assays, this protein was shown to act as a dominant negative, suggesting that PCBP2 multimerization functions in poliovirus translation and RNA binding. Additionally, PCBP2 containing a deletion in the multimerization domain (DeltaKH2-PCBP2) was not able to bind poliovirus stem-loop IV RNA and could not rescue translation in extracts that were depleted of endogenous PCBP2. Results from these experiments suggest that the multimerization of PCBP2 is required for efficient RNA binding and cap-independent translation of poliovirus RNA. By examining the functional interactions of the cellular protein PCBP2, we have discovered a novel determinant in the mechanism of picornavirus cap-independent translation.     

Insulin inhibition of apolipoprotein B mRNA translation is mediated via the PI-3 kinase/mTOR signaling cascade but does not involve internal ribosomal entry site (IRES) initiation

Although insulin normally activates global mRNA translation, it has a specific inhibitory effect on translation of apolipoprotein B (apoB) mRNA. This suggests that insulin induces a unique signaling cascade that leads to specific inhibition of apoB mRNA translation despite global translational stimulation. Recent studies have revealed that insulin functions to regulate apoB mRNA translation through a mechanism involving the apoB mRNA 5' untranslated region (5' UTR). Here, we further investigate the role of downstream insulin signaling molecules on apoB mRNA translation, and the mechanism of apoB mRNA translation itself. Transfection studies in HepG2 cells expressing deletion constructs of the apoB 5' UTR showed that the cis-acting region responding to insulin was localized within the first 64 nucleotides. Experiments using chimeric apoB UTR-luciferase constructs transfected into HepG2 cells followed by treatment with wortmannin, a PI-3K inhibitor, and rapamycin, an mTOR inhibitor, showed that signaling via PI-3K and mTOR pathways is necessary for insulin-mediated inhibition of chimeric 5' UTR-luciferase expression. In vitro translation of chimeric cRNA confirmed that the effects observed were translational in nature. Furthermore, using RNA-EMSA we found that wortmannin pretreatment blocked insulin-mediated inhibition of the binding of RNA-binding factor(s), migrating near the 110 kDa marker, to the 5' UTR. Radiolabeling studies in HepG2 cells also showed that insulin-mediated control of the synthesis of endogenously expressed full length apoB100 is mediated via the PI-3K and mTOR pathways. Finally, using dual-cistronic luciferase constructs we demonstrate that apoB 5' UTR may have weak internal ribosomal entry (IRES) translation which is not affected by insulin stimulation, and may function to stimulate basal levels of apoB mRNA translation.