Effects of poly(A)-binding protein on the interactions of translation initiation factor eIF4F and eIF4F.4B with internal ribosome entry site (IRES) of tobacco etch virus RNA

The Triticum Mosaic Virus Internal Ribosome Entry Site Relies on a Picornavirus-Like YX-AUG Motif To Designate the Preferred Translation Initiation Site and To Likely Target the 18S rRNA

Several viruses encode an internal ribosome entry site (IRES) at the 5' end of their RNA, which, unlike most cellular mRNAs, initiates translation in the absence of a 5' m7GpppG cap. Here, we report a uniquely regulated translation enhancer found in the 739-nucelotide (nt) sequence of the Triticum mosaic virus (TriMV) leader sequence that distinguishes the preferred initiation site from a plethora of IRES-encoded AUG triplets. Through deletion mutations of the TriMV 5' untranslated region (UTR), we show that the TriMV 5' UTR encodes a cis-acting picornaviral Y₁₆-X₁₁-AUG-like motif with a 16-nt polypyrimidine CU-tract (Y₁₆), at a precise, 11-nt distance (X₁₁) from the preferred 13th AUG. Phylogenetic analyses indicate that this motif is conserved among potyviral leader sequences with multiple AUGs. Consistent with a broadly conserved mechanism, the motif could be functionally replaced with known picornavirus YX-AUG motifs and is predicted to function as target sites for the 18S rRNA by direct base pairing. Accordingly, mutations that disrupted overall complementarity to the 18S rRNA markedly reduced TriMV IRES activity, as did the delivery of antisense oligonucleotides designed to block YX-AUG accessibility. To our knowledge, this is the first report of a plant viral IRES YX-AUG motif, and our findings suggest that a conserved mechanism regulates translation for multiple economically important plant and animal positive single-stranded RNA viruses.IMPORTANCE Uncapped viral RNAs often rely on their 5' leader sequences to initiate translation, and the Triticum mosaic virus (TriMV) devotes an astonishing 7% of its genome to directing ribosomes to the correct AUG. Here we uncover a novel mechanism by which a TriMV cis-regulatory element controls cap-independent translation. The upstream region of the functional AUG contains a 16-nt polypyrimidine tract located 11 nt from the initiation site. Based on functional redundancy with similar motifs derived from human picornaviruses, the motif is likely to operate by directing ribosome targeting through base pairing with 18S rRNA. Our results provide the first report of a broad-spectrum mechanism regulating translation initiation for both plant- and animal-hosted picornaviruses.

The 3' mRNA I-shaped structure of maize necrotic streak virus binds to eukaryotic translation factors for eIF4F-mediated translation initiation

Unlike the mRNAs of their eukaryotic hosts, many RNAs of viruses lack a 5' m⁷GpppN cap and the 3' polyadenosine tail, and yet they are translated efficiently. Plant RNA viruses, in particular, have complex structures within their mRNA UTRs that allow them to bypass some cellular translation control steps. In the 3' UTR of maize necrotic streak virus (MNeSV), an I-shaped RNA structure (ISS) has been shown to bind eukaryotic initiation factor (eIF)4F and to mediate viral translation initiation. A 5'-3' RNA "kissing-loop" interaction is required for optimal translation. However, the details of how the 3' ISS mediates translation initiation are not well understood. Here, we studied the binding of the 3' ISS with eIFs. The eIF4A-eIF4B complex was found to increase binding affinity of eIF4F with the 3' ISS by 4-fold (from K_D = 173 ± 34 nm to K_D = 48 ± 11 nm). Pre-steady-state analysis indicated that the eIF4A-eIF4B complex increased the RNA association rate and decreased the dissociation rate in an ATP-independent manner. Furthermore, our findings suggest that eIF4F could promote binding of the 3' ISS with the MNeSV 5'UTR, enhancing the long-distance kissing-loop interaction. However, the association of the 5'UTR with the 3' ISS-eIF4F complex did not increase 40S ribosomal subunit binding affinity. These quantitative results suggest a stepwise model in which the first committed step is eIF4F binding to the 3' ISS, followed by an interaction with the 5'UTR and subsequent 40S ribosomal subunit binding.

Eukaryotic translation initiation factor 4G (eIF4G) coordinates interactions with eIF4A, eIF4B, and eIF4E in binding and translation of the barley yellow dwarf virus 3' cap-independent translation element (BTE)

Barley yellow dwarf virus RNA, lacking a 5' cap and a 3' poly(A) tail, contains a cap-independent translation element (BTE) in the 3'-untranslated region that interacts with host translation initiation factor eIF4G. To determine how eIF4G recruits the mRNA, three eIF4G deletion mutants were constructed: (i) eIF4G601-1196, containing amino acids 601-1196, including the putative BTE-binding region, and binding domains for eIF4E, eIF4A, and eIF4B; (ii) eIF4G601-1488, which contains an additional C-terminal eIF4A-binding domain; and (iii) eIF4G742-1196, which lacks the eIF4E-binding site. eIF4G601-1196 binds BTE tightly and supports efficient translation. The helicase complex, consisting of eIF4A, eIF4B, and ATP, stimulated BTE binding with eIF4G601-1196 but not eIF4G601-1488, suggesting that the eIF4A binding domains may serve a regulatory role, with the C-terminal binding site having negative effects. eIF4E binding to eIF4G601-1196 induced a conformational change, significantly increasing the binding affinity to BTE. A comparison of the binding of eIF4G deletion mutants with BTEs containing mutations showed a general correlation between binding affinity and ability to facilitate translation. In summary, these results reveal a new role for the helicase complex in 3' cap-independent translation element-mediated translation and show that the functional core domain of eIF4G plus an adjacent probable RNA-binding domain mediate translation initiation.

A Unique 5' Translation Element Discovered in Triticum Mosaic Virus

Several plant viruses encode elements at the 5' end of their RNAs, which, unlike most cellular mRNAs, can initiate translation in the absence of a 5' m7GpppG cap. Here, we describe an exceptionally long (739-nucleotide [nt]) leader sequence in triticum mosaic virus (TriMV), a recently emerged wheat pathogen that belongs to the Potyviridae family of positive-strand RNA viruses. We demonstrate that the TriMV 5' leader drives strong cap-independent translation in both wheat germ extract and oat protoplasts through a novel, noncanonical translation mechanism. Translation preferentially initiates at the 13th start codon within the leader sequence independently of eIF4E but involves eIF4G. We truncated the 5' leader to a 300-nucleotide sequence that drives cap-independent translation from the 5' end. We show that within this sequence, translation activity relies on a stem-loop structure identified at nucleotide positions 469 to 490. The disruption of the stem significantly impairs the function of the 5' untranslated region (UTR) in driving translation and competing against a capped RNA. Additionally, the TriMV 5' UTR can direct translation from an internal position of a bicistronic mRNA, and unlike cap-driven translation, it is unimpaired when the 5' end is blocked by a strong hairpin in a monocistronic reporter. However, the disruption of the identified stem structure eliminates such a translational advantage. Our results reveal a potent and uniquely controlled translation enhancer that may provide new insights into mechanisms of plant virus translational regulation.

IMPORTANCE

Many members of the Potyviridae family rely on their 5' end for translation. Here, we show that the 739-nucleotide-long triticum mosaic virus 5' leader bears a powerful translation element with features distinct from those described for other plant viruses. Despite the presence of 12 AUG start codons within the TriMV 5' UTR, translation initiates primarily at the 13th AUG codon. The TriMV 5' UTR is capable of driving cap-independent translation in vitro and in vivo, is independent of eIF4E, and can drive internal translation initiation. A hairpin structure at nucleotide positions 469 to 490 is required for the cap-independent translation and internal translation initiation abilities of the element and plays a role in the ability of the TriMV UTR to compete against a capped RNA in vitro. Our results reveal a novel translation enhancer that may provide new insights into the large diversity of plant virus translation mechanisms.

Mechanism of cytoplasmic mRNA translation

Protein synthesis is a fundamental process in gene expression that depends upon the abundance and accessibility of the mRNA transcript as well as the activity of many protein and RNA-protein complexes. Here we focus on the intricate mechanics of mRNA translation in the cytoplasm of higher plants. This chapter includes an inventory of the plant translational apparatus and a detailed review of the translational processes of initiation, elongation, and termination. The majority of mechanistic studies of cytoplasmic translation have been carried out in yeast and mammalian systems. The factors and mechanisms of translation are for the most part conserved across eukaryotes; however, some distinctions are known to exist in plants. A comprehensive understanding of the complex translational apparatus and its regulation in plants is warranted, as the modulation of protein production is critical to development, environmental plasticity and biomass yield in diverse ecosystems and agricultural settings.

Molecular biology of potyviruses

Potyvirus is the largest genus of plant viruses causing significant losses in a wide range of crops. Potyviruses are aphid transmitted in a nonpersistent manner and some of them are also seed transmitted. As important pathogens, potyviruses are much more studied than other plant viruses belonging to other genera and their study covers many aspects of plant virology, such as functional characterization of viral proteins, molecular interaction with hosts and vectors, structure, taxonomy, evolution, epidemiology, and diagnosis. Biotechnological applications of potyviruses are also being explored. During this last decade, substantial advances have been made in the understanding of the molecular biology of these viruses and the functions of their various proteins. After a general presentation on the family Potyviridae and the potyviral proteins, we present an update of the knowledge on potyvirus multiplication, movement, and transmission and on potyvirus/plant compatible interactions including pathogenicity and symptom determinants. We end the review providing information on biotechnological applications of potyviruses.

Eukaryotic initiation factor (eIF) 4F binding to barley yellow dwarf virus (BYDV) 3'-untranslated region correlates with translation efficiency

Eukaryotic initiation factor (eIF) 4F binding to mRNA is the first committed step in cap-dependent protein synthesis. Barley yellow dwarf virus (BYDV) employs a cap-independent mechanism of translation initiation that is mediated by a structural BYDV translation element (BTE) located in the 3'-UTR of its mRNA. eIF4F bound the BTE and a translationally inactive mutant with high affinity, thus questioning the role of eIF4F in translation of BYDV. To examine the effects of eIF4F in BYDV translation initiation, BTE mutants with widely different in vitro translation efficiencies ranging from 5 to 164% compared with WT were studied. Using fluorescence anisotropy to obtain quantitative data, we show 1) the equilibrium binding affinity (complex stability) correlated well with translation efficiency, whereas the "on" rate of binding did not; 2) other unidentified proteins or small molecules in wheat germ extract prevented eIF4F binding to mutant BTE but not WT BTE; 3) BTE mutant-eIF4F interactions were found to be both enthalpically and entropically favorable with an enthalpic contribution of 52-90% to ΔG° at 25 °C, suggesting that hydrogen bonding contributes to stability; and 4) in contrast to cap-dependent and tobacco etch virus internal ribosome entry site interaction with eIF4F, poly(A)-binding protein did not increase eIF4F binding. Further, the eIF4F bound to the 3' BTE with higher affinity than for either m(7)G cap or tobacco etch virus internal ribosome entry site, suggesting that the 3' BTE may play a role in sequestering host cell initiation factors and possibly regulating the switch from replication to translation.

Poly(A) binding proteins: are they all created equal?

The PABP family of proteins were originally thought of as a simple shield for the mRNA poly(A) tail. Years of research have shown that PABPs interact not only with the poly(A) tail, but also with specific sequences in the mRNA, having a general and specific role on the metabolism of different mRNAs. The complexity of PABPs function is increased by the interactions of PABPs with factors involved in different cellular functions. PABPs participate in all the metabolic pathways of the mRNA: polyadenylation/deadenylation, mRNA export, mRNA surveillance, translation, mRNA degradation, microRNA-associated regulation, and regulation of expression during development. In this review, we update information on the roles of PABPs and emerging data on the specific interactions of PABP homologs. Specific functions of individual members of PABPC family in development and viral infection are beginning to be elucidated. However, the interactions are complex and recent evidence for exchange of nuclear and cytoplasmic forms of the proteins, as well as post-translational modifications, emphasize the possibilities for fine-tuning the PABP metabolic network.

Poly(A)-binding protein increases the binding affinity and kinetic rates of interaction of viral protein linked to genome with translation initiation factors eIFiso4F and eIFiso4F·4B complex

VPg of turnip mosaic virus (TuMV) was previously shown to interact with translation initiation factor eIFiso4F and play an important role in mRNA translation [Khan, M. A., et al. (2008) J. Biol. Chem.283, 1340-1349]. VPg competed with cap analogue for eIFiso4F binding and competitively inhibited cap-dependent translation and enhanced cap-independent translation to give viral RNA a significant competitive advantage. To gain further insight into the cap-independent process of initiation of protein synthesis, we examined the effect of PABP and/or eIF4B on the equilibrium and kinetics of binding of VPg to eIFiso4F. Equilibrium data showed the addition of PABP and/or eIF4B to eIFiso4F increased the binding affinity for VPg (K(d) = 24.3 ± 1.6 nM) as compared to that with eIFiso4F alone (K(d) = 81.3 ± 0.2.4 nM). Thermodynamic parameters showed that binding of VPg to eIFiso4F was enthalpy-driven and entropy-favorable with the addition of PABP and/or eIF4B. PABP and eIF4B decreased the entropic contribution by 67% for binding of VPg to eIFiso4F. The decrease in entropy involved in the formation of the eIFiso4F·4B·PABP-VPg complex suggested weakened hydrophobic interactions for complex formation and an overall conformational change. The kinetic studies of eIFiso4F with VPg in the presence of PABP and eIF4B show 3-fold faster association (k(2) = 182 ± 9.0 s(-1)) compared to that with eIFiso4F alone (k(2) = 69.0 ± 1.5 s(-1)) . The dissociation rate was 3-fold slower (k(-2) = 6.5 ± 0.43 s(-1)) for eIFiso4F with VPg in the presence of PABP and eIF4B (k(-2) = 19.0 ± 0.9 s(-1)). The addition of PABP and eIF4B decreased the activation energy of eIFiso4F with VPg from 81.0 ± 3.0 to 44.0 ± 2.4 kJ/mol. This suggests that the presence of both proteins leads to a rapid, stable complex, which serves to sequester initiation factors.

Recombination of 5' subgenomic RNA3a with genomic RNA3 of Brome mosaic bromovirus in vitro and in vivo

RNA-RNA recombination salvages viral RNAs and contributes to their genomic variability. A recombinationally-active subgenomic promoter (sgp) has been mapped in Brome mosaic bromovirus (BMV) RNA3 (Wierzchoslawski et al., 2004. J. Virol.78, 8552-8864) and mRNA-like 5' sgRNA3a was characterized (Wierzchoslawski et al., 2006. J. Virol. 80, 12357-12366). In this paper we describe sgRNA3a-mediated recombination in both in vitro and in vivo experiments. BMV replicase-directed co-copying of (-) RNA3 with wt sgRNA3a generated RNA3 recombinants in vitro, but it failed to when 3'-truncated sgRNA3a was substituted, demonstrating a role for the 3' polyA tail. Barley protoplast co-transfections revealed that (i) wt sgRNA3a recombines at the 3' and the internal sites; (ii) 3'-truncated sgRNA3as recombine more upstream; and (iii) 5'-truncated sgRNA3 recombine at a low rate. In planta co-inoculations confirmed the RNA3-sgRNA3a crossovers. In summary, the non-replicating sgRNA3a recombines with replicating RNA3, most likely via primer extension and/or internal template switching.

Poly(A) tail affects equilibrium and thermodynamic behavior of tobacco etch virus mRNA with translation initiation factors eIF4F, eIF4B and PABP

We have investigated the effects of poly(A)-tail on binding of eIF4F, eIF4B and PABP with tobacco etch virus (TEV) IRES RNA. The fluorescence anisotropy data showed that the addition of poly(A)(20) increases the binding affinity of eIF4F·4B and eIF4F·PABP complexes to IRES RNA ~2- and 4-fold, respectively. However, the binding affinity of eIF4F with PK1 was enhanced ~11-fold with the addition of PABP, eIF4B, and poly(A)(20) together. Whereas, poly(A)(20) alone increases the binding affinity of eIF4F·4B·PABP with PK1 RNA about 3-fold, showing an additive effect rather than the large increase in affinity as shown for cap binding. Thermodynamic data showed that PK1 RNA binding to protein complexes in the presence of poly(A)(20) was enthalpy-driven and entropy-favorable. Poly(A)(20) decreased the entropic contribution 75% for binding of PK1 RNA to eIF4F·4B·PABP as compared to eIF4F alone, suggesting reduced hydrophobic interactions for complex formation and an overall conformational change. Overall, these results demonstrate the first direct effect of poly(A) on the equilibrium and thermodynamics of eIF4F and eIF4F·4B·PABP with IRES-RNA.

Kinetic mechanism for the binding of eIF4F and tobacco Etch virus internal ribosome entry site rna: effects of eIF4B and poly(A)-binding protein

The wheat germ eukaryotic translation initiation factor (eIF) 4F binds tightly to the mRNA internal ribosome entry site (IRES) of tobacco etch virus (TEV) to promote translation initiation. When eIF4F is limiting, TEV is preferentially translated compared with host cell mRNA. To gain insight into the dynamic process of protein synthesis initiation and the mechanism of binding, the kinetics of eIF4F binding to TEV IRES were examined. The association rate constant (k(on)) and dissociation rate constant (k(off)) for eIF4F binding to IRES were 59 +/- 2.1 micro s(-1) and 12.9 +/- 0.3 s(-1), respectively, comparable with the rates for capped RNA. Binding of eIF4E or eIF4F to the cap of mRNA is the rate-limiting step for initiation of cap-dependent protein synthesis. The concentration dependence of the reactions suggested a simple one-step association mechanism. However, the association rate was reduced more than 10-fold when KCl concentration was increased from 50 to 300 mm, whereas the dissociation rate constant was increased 2-fold. The addition of eIF4B and poly(A)-binding protein enhanced the association rate of eIF4F approximately 3-fold. These results suggest a mechanism where eIF4F initially binds electrostatically, followed by a conformational change to further stabilize binding. Poly(A)-binding protein and eIF4B mainly affect the eIF4F/TEV association rate. These results demonstrate the first direct kinetic measurements of translation initiation factor binding to an IRES.