Monocistronic mRNAs containing defective hepatitis C virus-like picornavirus internal ribosome entry site elements in their 5' untranslated regions are efficiently translated in cells by a cap-dependent mechanism

The initiation of protein synthesis on mRNAs within eukaryotic cells is achieved either by a 5' cap-dependent mechanism or through internal initiation directed by an internal ribosome entry site (IRES). Picornavirus IRES elements, located in the 5' untranslated region (5'UTR), contain extensive secondary structure and multiple upstream AUG codons. These features can be expected to inhibit cap-dependent initiation of translation. However, we have now shown that certain mutant hepatitis C virus-like picornavirus IRES elements (from porcine teschovirus-1 and avian encephalomyelitis virus), which are unable to direct internal initiation, are not significant barriers to efficient translation of capped monocistronic mRNAs that contain these defective elements within their 5'UTRs. Moreover, the translation of these mRNAs is highly sensitive to the expression of an enterovirus 2A protease (which induces cleavage of eIF4G) and is also inhibited by hippuristanol, a specific inhibitor of eIF4A function, in contrast to their parental wild-type IRES elements. These results provide a possible basis for the evolution of viral IRES elements within the context of functional mRNAs that are translated by a cap-dependent mechanism.     

Re-programming of translation following cell stress allows IRES-mediated translation to predominate

There is now an overwhelming body of evidence to suggest that internal ribosome entry is required to maintain the expression of specific proteins during patho-physiological situations when cap-dependent translation is compromised, for example, following heat shock or during mitosis, hypoxia, differentiation and apoptosis. Translational profiling has been used by several groups to assess the extent to which alternative mechanisms of translation initiation selectively recruit mRNAs to polysomes during cell stress. The data from these studies have shown that under each condition 3-5% of coding mRNAs remain associated with the polysomes. Importantly, the genes identified in each of these studies do not show a significant amount of overlap, suggesting that 10-15% of all mRNAs have the capability for their initiation to occur via alternative mechanism(s).     

Alternative Ways to Think about Cellular Internal Ribosome Entry

Internal ribosome entry sites (IRESs) are specialized mRNA elements that allow recruitment of eukaryotic ribosomes to naturally uncapped mRNAs or to capped mRNAs under conditions in which cap-dependent translation is inhibited. Putative cellular IRESs have been proposed to play crucial roles in stress responses, development, apoptosis, cell cycle control, and neuronal function. However, most of the evidence for cellular IRES activity rests on bicistronic reporter assays, the reliability of which has been questioned. Here, the mechanisms underlying cap-independent translation of cellular mRNAs and the contributions of such translation to cellular protein synthesis are discussed. I suggest that the division of cellular mRNAs into mutually exclusive categories of “cap-dependent” and “IRES-dependent” should be reconsidered and that the implications of cellular IRES activity need to be incorporated into our models of cap-dependent initiation.     

转录激活因子1(ATF1)内部核糖体进入位点的鉴定及活性分析

蛋白质翻译起始通常有两种机制,一是依赖帽结构的翻译,另一种是依赖5′非翻译区的内部核糖体进入位点(IRES).在后一种方式中,在某些IRES反式作用因子,如La蛋白、多聚嘧啶串结合蛋白1等的参与下,直接招募核糖体小亚基到mRNA的翻译起始位点,启始翻译.研究发现,参与细胞生长、分化、细胞周期进程、凋亡和压力调控的相关蛋白中通常含有IRES元件.基于功能,我们提出假说：转录激活因子1(ATF1)的5′-UTR可能具有IRES活性.为验证假说,首先构建了含全长ATF1 5′-UTR的双荧光素酶报告质粒|质粒转染结合报告酶活性分析显示,ATF1 5′-UTR在Bel7402、HCT-8和HEK293细胞中表现出不同的IRES活性|而此IRES活性与5′-UTR中的隐藏启动子无关.同时还发现,ATF1 5′-UTR在NIH3T3细胞中却没有IRES活性.与此结果相一致,Western印迹检测ATF1在这几种细胞系中的表达.结果显示,Bel7402、HCT 8和HEK293中ATF1蛋白质表达水平较高,而在NIH3T3中却极低. ATF1 5′-UTR的系列5′-删除突变及报告酶分析证明,ATF1 5′-UTR的完整性对其IRES活性大小发挥重要作用|其中5′端的204 bp序列对其IRES活性贡献较大. RNA-蛋白免疫共沉淀实验揭示,ATF1 5′-UTR可与La和PTBP1蛋白结合|抑制La和PTBP1蛋白质的表达,并可减低HEK293细胞中ATF1蛋白质表达水平.这些结果提示,La和PTBP1蛋白（两种ITAFs）为ATF1 5′-UTR发挥IRES活性所必需.总之,上述结果证明,ATF1 5′-UTR具有IRES活性,其活性发挥依赖与La和PTBP1蛋白的结合.上述发现为进一步研究La和PTBP1表达及亚细胞定位对ATF1 IRES调控机制的影响奠定了基础.     

Cap-independent polysomal association of natural mRNAs encoding c-myc, BiP, and eIF4G conferred by internal ribosome entry sites.

Sequence elements that can function as internal ribosome entry sites (IRES) have been identified in 5' noncoding regions of certain uncapped viral and capped cellular mRNA molecules. However, it has remained largely unknown whether IRES elements are functional when located in their natural capped mRNAs. Therefore, the polysomal association and translation of several IRES-containing cellular mRNAs was tested under conditions that severely inhibited cap-dependent translation, that is, after infection with poliovirus. It was found that several known IRES-containing mRNAs, such as BiP and c-myc, were both associated with the translation apparatus and translated in infected cells when cap-dependent translation of most host-cell mRNAs was blocked, indicating that the IRES elements were functional in their natural mRNAs. Curiously, the mRNAs that encode eukaryotic initiation factor 4GI (eIF4GI) and 4GII (eIF4GII), two proteins with high identity and similar functions in the initiation of cap-dependent translation, were both associated with polysomes in infected cells. The 5'-end sequences of eIF4GI mRNA were isolated from a cDNA expression library and shown to function as an internal ribosome entry site when placed into a dicistronic mRNA. These findings suggest that eIF4G proteins can be synthesized at times when 5' cap-dependent mRNA translation is blocked, supporting the notion that eIF4G proteins are needed in both 5' cap-independent and 5' cap-dependent translational initiation mechanisms.     

The 5' UTR of HIV-1 full-length mRNA and the Tat viral protein modulate the programmed -1 ribosomal frameshift that generates HIV-1 enzymes

Translation of the full-length messenger RNA (mRNA) of the human immunodeficiency virus type 1 (HIV-1) generates the precursor of the viral enzymes via a programmed -1 ribosomal frameshift. Here, using dual-luciferase reporters, we investigated whether the highly structured 5' untranslated region (UTR) of this mRNA, which interferes with translation initiation, can modulate HIV-1 frameshift efficiency. We showed that, when the 5' UTR of HIV-1 mRNA occupies the 5' end of the reporter mRNA, HIV-1 frameshift efficiency is increased about fourfold in Jurkat T-cells, compared with a control dual-luciferase reporter with a short unstructured 5' UTR. This increase was related to an interference with cap-dependent translation initiation by the TAR-Poly(A) region at the 5' end of the messenger. HIV-1 mRNA 5' UTR also contains an internal ribosome entry site (IRES), but we showed that, when the cap-dependent initiation mode is available, the IRES is not used or is weakly used. However, when the ribosomes have to use the IRES to translate the dual-luciferase reporter, the frameshift efficiency is comparable to that of the control dual-luciferase reporter. The decrease in cap-dependent initiation and the accompanying increase in frameshift efficiency caused by the 5' UTR of HIV-1 mRNA is antagonized, in a dose-dependent way, by the Tat viral protein. Tat also stimulates the IRES-dependent initiation and decreases the corresponding frameshift efficiency. A model is presented that accounts for the variations in frameshift efficiency depending on the 5' UTR and the presence of Tat, and it is proposed that a range of frameshift efficiencies is compatible with the virus replication.     

Archaeal translation initiation factor aIF2 can substitute for eukaryotic eIF2 in ribosomal scanning during mammalian 48S complex formation

Heterotrimeric translation initiation factor (IF) a/eIF2 (archaeal/eukaryotic IF 2) is present in both Eukarya and Archaea. Despite strong structural similarity between a/eIF2 orthologs from the two domains of life, their functional relationship is obscure. Here, we show that aIF2 from Sulfolobus solfataricus can substitute for its mammalian counterpart in the reconstitution of eukaryotic 48S initiation complexes from purified components. aIF2 is able to correctly place the initiator Met-tRNA_i into the P-site of the 40S ribosomal subunit and accompany the entire set of eukaryotic translation IFs in the process of cap-dependent scanning and AUG codon selection. However, it seems to be unable to participate in the following step of ribosomal subunit joining. In accordance with this, aIF2 inhibits rather than stimulates protein synthesis in mammalian cell-free system. The ability of recombinant aIF2 protein to direct ribosomal scanning suggests that some archaeal mRNAs may utilize this mechanism during translation initiation.     

Some thoughts about translational regulation: forward and backward glances

This review discusses the need to re-examine some popular but unproven ideas about regulation of translation in eukaryotes. Translational control is invoked often on superficial grounds, such as a discrepancy between mRNA and protein levels which could be explained instead by rapid turnover of the protein. It is essential to verify that there is translational control (i.e., essential to rule out alternative mechanisms) before asking how translation is regulated. Many of the postulated control mechanisms are dubious. It is easy to create artifactual regulation (a slight increase or decrease in translation) by over-expressing recombinant RNA-binding proteins. The internal-initiation hypothesis is the source of other misunderstandings. Recent claims about the involvement of internal ribosome entry sequences (IRESs) in cancer and other diseases are discussed. The scanning model for initiation provides a more credible framework for understanding many aspects of translation, including ways to restrict the production of potent regulatory proteins which would be harmful if over-expressed. The rare production in eukaryotes of dicistronic mRNAs (e.g., from retrotransposons) raises questions about how the 3' cistron gets translated. Some proposed mechanisms are discussed, but the available evidence does not allow resolution of the issue.     

Localized IRES-Dependent Translation of ER Chaperone Protein mRNA in Sensory Axons

Transport of neuronal mRNAs into distal nerve terminals and growth cones allows axonal processes to generate proteins autonomous from the cell body. While the mechanisms for targeting mRNAs for transport into axons has received much attention, how specificity is provided to the localized translational apparatus remains largely unknown. In other cellular systems, protein synthesis can be regulated by both cap-dependent and cap-independent mechanisms. The possibility that these mechanisms are used by axons has not been tested. Here, we have used expression constructs encoding axonally targeted bicistronic reporter mRNAs to determine if sensory axons can translate mRNAs through cap-independent mechanisms. Our data show that the well-defined IRES element of encephalomyocarditis virus (EMCV) can drive internal translational initiation of a bicistronic reporter mRNA in distal DRG axons. To test the potential for cap-independent translation of cellular mRNAs, we asked if calreticulin or grp78/BiP mRNA 5'UTRs might have IRES activity in axons. Only grp78/BiP mRNA 5'UTR showed clear IRES activity in axons when placed between the open reading frames of diffusion limited fluorescent reporters. Indeed, calreticulin's 5'UTR provided an excellent control for potential read through by ribosomes, since there was no evidence of internal initiation when this UTR was placed between reporter ORFs in a bicistronic mRNA. This study shows that axons have the capacity to translate through internal ribosome entry sites, but a simple binary choice between cap-dependent and cap-independent translation cannot explain the specificity for translation of individual mRNAs in distal axons.     

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。     

Y-box Binding Protein 1: Providing a New Angle on Translational Regulation

Current models of translational regulation are mostly focused on how translational factors engage a messenger mRNA to the ribosome to initiate translation. Since the majority of mRNAs in eukaryotes are translated in a cap-dependent manner, the mRNA 5’ cap-binding protein eIF4E was characterized as a key player responsible for the recruitment of mRNAs to the initiation complex. The availability of eIF4E is believed to be especially critical for translational activation of mRNAs with extensive secondary structures in their 5’UTRs, many of which code for labile regulatory proteins essential for cell growth or viability. Surprisingly, little attention is paid to the other side of translational control, e.g., to define mechanisms responsible for translational silencing and storage of the above messages. In this review, we discuss the possibility that eIF4E per se may not be sufficient to release mRNAs from translational block. We found that many growth- and stress-related mRNAs are associated with the translational repressor YB-1, which can compete with the eIF4E-driven translation initiation complex for binding to the capped 5’ mRNA terminus. Moreover, the cap-dependent repressor activity of YB-1 appears to be negatively regulated via Akt-mediated phosphorylation of the Ser-102 residue of YB-1. Taken together with recent evidence suggesting that translational activation of growth-related messages is a primary cellular response to activation of Ras-Erk and PI3K-Akt signaling pathways, our data suggest that differential expression of specific mRNA subsets is regulated by the PI3K-Akt pathway and achieved via coordinated activation of the components of translational machinery and inactivation of general translational repressors such as YB-1.     

Identification of the TXNIP IRES and characterization of the impact of regulatory IRES trans-acting factors

Translation is a tightly regulated process and is predominantly controlled at the level of its initiation. Translation initiation mostly occurs in a cap-dependent manner. Under stress conditions when cap-dependent translation is hampered, internal ribosome entry sites (IRESes) allow for cap-independent translation of certain mRNAs. IRES-dependent translation is commonly regulated by RNA-interacting proteins, known as IRES trans-acting factors (ITAFs). In the present study, we found the 5′ untranslated region (UTR) of the thioredoxin-interacting protein (TXNIP) mRNA to be bound by the ITAF hnRNPA1. Upon verification of an IRES element within the 5′UTR of TXNIP, we determined additional interacting proteins, which predominantly appeared to interact with the IRES-regulatory second half of the 5′UTR. Amongst these PTB emerged as an inhibitory ITAF, whereas FBP3 and GEMIN5 appeared to contain TXNIP IRES-enhancing properties. In summary, we identified and characterized a novel IRES within the 5′UTR of TXNIP, which is regulated by the ITAFs PTB, FBP3, and GEMIN5.     

Translation initiation by the c-myc mRNA internal ribosome entry sequence and the poly(A) tail

Eukaryotic mRNAs possess a poly(A) tail that enhances translation via the (7)mGpppN cap structure or internal ribosome entry sequences (IRESs). Here we address the question of how cellular IRESs recruit the ribosome and how recruitment is augmented by the poly(A) tail. We show that the poly(A) tail enhances 48S complex assembly by the c-myc IRES. Remarkably, this process is independent of the poly(A) binding protein (PABP). Purification of native 48S initiation complexes assembled on c-myc IRES mRNAs and quantitative label-free analysis by liquid chromatography and mass spectrometry directly identify eIFs 2, 3, 4A, 4B, 4GI, and 5 as components of the c-myc IRES 48S initiation complex. Our results demonstrate for the first time that the poly(A) tail augments the initiation step of cellular IRES-driven translation and implicate a distinct subset of translation initiation factors in this process. The mechanistic distinctions from cap-dependent translation may allow specific translational control of the c-myc mRNA and possibly other cellular mRNAs that initiate translation via IRESs.     

Re-programming of translation following cell stress allows IRES-mediated translation to predominate.

There is now an overwhelming body of evidence to suggest that internal ribosome entry is required to maintain the expression of specific proteins during patho-physiological situations when cap-dependent translation is compromised, for example, following heat shock or during mitosis, hypoxia, differentiation and apoptosis. Translational profiling has been used by several groups to assess the extent to which alternative mechanisms of translation initiation selectively recruit mRNAs to polysomes during cell stress. The data from these studies have shown that under each condition 3-5% of coding mRNAs remain associated with the polysomes. Importantly, the genes identified in each of these studies do not show a significant amount of overlap, suggesting that 10-15% of all mRNAs have the capability for their initiation to occur via alternative mechanism(s).     

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.     

Structure and functions of the translation initiation factor eIF4E and its role in cancer development and treatment

In eukaryotic cells, protein synthesis is a complex and multi-step process that has several mechanisms to start the translation including cap-dependent and cap-independent initiation. The translation control of eukaryotic gene expression occurs principally at the initiation step. In this context, it is critical that the eukaryotic translation initiation factor eIF4E bind to the 7-methylguanosine (m7G) cap present at the 5′-UTRs of most eukaryotic mRNAs. Combined with other initiation factors, eIF4E mediates the mRNA recruitment on ribosomes to start the translation. Moreover, the eIF4E nuclear bodies are involved in the export of specific mRNAs from the nucleus to the cytoplasm. In this review, we focus on the eIF4E structure and its physiological functions, and describe the role of eIF4E in cancer development and progression and the current therapeutic strategies to target eIF4E.     

Enhancement of IRES-mediated translation of the c-myc and BiP mRNAs by the poly(A) tail is independent of intact eIF4G and PABP

The poly(A) tail at the 3' end of mRNAs enhances 5' cap-dependent translation initiation. We show that it also enhances IRES-directed translation of two cellular mRNAs in vitro and in vivo. The underlying mechanisms, however, differ fundamentally. In contrast to cap-dependent translation, IRES-driven translation continues to be enhanced by the poly(A) tail following proteolytic cleavage of eIF4G. Moreover, the poly(A) tail stimulates IRES-mediated translation even in the presence of PAIP2 or following effective depletion of the poly(A) binding protein (PABP) from HeLa cell extracts. The PABP-eIF4G bridging complex that is critical for cap-dependent translation is thus dispensable for the enhancement of the IRESs by the poly(A) tail. The polyadenylated mRNA translation from cellular IRESs is also profoundly sensitive to eIF4A activity in vitro. These mechanistic and molecular distinctions implicate the potential for a new layer of translational control mechanisms.