Iron regulatory protein prevents binding of the 43S translation pre-initiation complex to ferritin and eALAS mRNAs.

Translation of ferritin and erythroid 5-aminolevulinate synthase (eALAS) mRNAs is regulated by iron via mRNA-protein interactions between iron-responsive elements (IREs) and iron regulatory protein (IRP). In iron-depleted cells, IRP binds to single IREs located in the 5' untranslated regions of ferritin and eALAS mRNAs and represses translation initiation. The molecular mechanism underlying this translational repression was investigated using reconstituted, IRE-IRP-regulated, cell-free translation systems. The IRE-IRP interaction is shown to prevent the association of the 43S translation pre-initiation complex (including the small ribosomal subunit) with the mRNA. Studies with the spliceosomal protein U1A and mRNAs which harbour specific binding sites for this protein in place of an IRE furthermore reveal that the 5' termini of mRNAs are generally sensitive to repressor protein-mediated inhibition of 43S pre-initiation complex binding.     

Binding of the La autoantigen to the 5' untranslated region of a chimeric human translation elongation factor 1A reporter mRNA inhibits translation in vitro.

Human translation elongation factor 1A (EF1A) is a member of a large class of mRNAs, including ribosomal proteins and other translation elongation factors, which are coordinately translationally regulated under various conditions. Each of these mRNAs contains a terminal oligopyrimidine tract (TOP) that is required for translational control. A human growth hormone (hGH) expression construct containing the promoter region and 5' untranslated region (UTR) of EF1A linked to the hGH coding region (EF1A/hGH) was translationally repressed following rapamycin treatment in similar fashion to endogenous EF1A in human B lymphocytes. Mutation of two nucleotides in the TOP motif abolished the translational regulation. Gel mobility shift assays showed that both La protein from human B lymphocyte cytoplasmic extracts as well as purified recombinant La protein specifically bind to an in vitro-synthesized RNA containing the 5' UTR of EF1A mRNA. Moreover, extracts prepared from rapamycin-treated cells showed increased binding activity to the EF1A 5' UTR RNA, which correlates with TOP mRNA translational repression. In an in vitro translation system, recombinant La dramatically decreased the expression of EF1A/hGH construct mRNA, but not mRNAs lacking an intact TOP element. These results indicate that TOP mRNA translation may be modulated through La binding to the TOP element.     

Poly(A)-tail-promoted translation in yeast: implications for translational control.

The cap structure and the poly(A) tail synergistically activate mRNA translation in vivo. Recent work using Saccharomyces cerevisiae spheroplasts and a yeast cell-free translation system revealed that the poly(A) tail can function as an independent promotor for ribosome recruitment, to internal initiation sites within an mRNA. This raises the question of how regulatory upstream open reading frames and translational repressor proteins binding to the 5'UTR can function, as well as how regulated polyadenylation can support faithful activation of protein synthesis. We investigated the function of the regulatory upstream open reading frame 4 from the yeast GCN 4 gene and the effect of IRP-1 binding to an iron-responsive element introduced into the 5' UTR of reporter mRNAs. Both manipulations effectively block cap-dependent translation, whereas ribosome recruitment promoted by the poly(A) tail under non-competitive conditions can efficiently bypass both blocks. We show that the synergistic use of both, the cap structure and the poly-A tail enforced by mRNA competition reinstates the full extent of translational control by both types of 5' UTR regulatory elements. With a view towards regulated polyadenylation, we studied the function of poly(A) tails of defined length on the translation of capped mRNAs. We find that poly(A) tail elongation increases translational efficiency, particularly under competitive conditions. Our results integrate recent findings on the function of the poly(A) tail into an understanding of translational control.     

Multiple binding of repressed mRNAs by the P-body protein Rck/p54

Translational repression is achieved by protein complexes that typically bind 3' UTR mRNA motifs and interfere with the formation of the cap-dependent initiation complex, resulting in mRNPs with a closed-loop conformation. We demonstrate here that the human DEAD-box protein Rck/p54, which is a component of such complexes and central to P-body assembly, is in considerable molecular excess with respect to cellular mRNAs and enriched to a concentration of 0.5 mM in P-bodies, where it is organized in clusters. Accordingly, multiple binding of p54 proteins along mRNA molecules was detected in vivo. Consistently, the purified protein bound RNA with no sequence specificity and high nanomolar affinity. Moreover, bound RNA molecules had a relaxed conformation. While RNA binding was ATP independent, relaxing of bound RNA was dependent on ATP, though not on its hydrolysis. We propose that Rck/p54 recruitment by sequence-specific translational repressors leads to further binding of Rck/p54 along mRNA molecules, resulting in their masking, unwinding, and ultimately recruitment to P-bodies. Rck/p54 proteins located at the 5' extremity of mRNA can then recruit the decapping complex, thus coupling translational repression and mRNA degradation.     

Recruitment of the Puf3 protein to its mRNA target for regulation of mRNA decay in yeast

The Puf family of RNA-binding proteins regulates mRNA translation and decay via interactions with 3' untranslated regions (3' UTRs) of target mRNAs. In yeast, Puf3p binds the 3' UTR of COX17 mRNA and promotes rapid deadenylation and decay. We have investigated the sequences required for Puf3p recruitment to this 3' UTR and have identified two separate binding sites. These sites are specific for Puf3p, as they cannot bind another Puf protein, Puf5p. Both sites use a conserved UGUANAUA sequence, whereas one site contains additional sequences that enhance binding affinity. In vivo, presence of either site partially stimulates COX17 mRNA decay, but full decay regulation requires the presence of both sites. No other sequences outside the 3' UTR are required to mediate this decay regulation. The Puf repeat domain of Puf3p is sufficient not only for in vitro binding to the 3' UTR, but also in vivo stimulation of COX17 mRNA decay. These experiments indicate that the essential residues involved in mRNA decay regulation are wholly contained within this RNA-binding domain.     

Pyrimidine tract binding protein and La autoantigen interact differently with the 5' untranslated regions of lentiviruses and oncoretrovirus mRNAs

Retrovirus genomic mRNA exhibits a several hundred nucleotides-long untranslated region (5' UTR) which encloses many control elements required for retrovirus replication. In addition, this 5' UTR contains translation regulatory elements, such as internal ribosome entry sites (IRESes) that have been described in oncoretroviruses, as well as in lentiviruses. UV cross-linking experiments suggested that the pyrimidine tract binding protein (PTB), a cellular protein known to regulate the activity of several picornaviral IRESes, binds to human T-cell leukemia virus (HTLV)-I RNA but not to lentiviral human immunodeficiency virus (HIV)-1, HIV-2 or simian immunodeficiency virus RNAs. To calculate the affinity of such RNA-protein interactions, we developed a new method based on the BIAcore technology. The absence of affinity of PTB for lentiviral RNAs was confirmed, whereas its affinity for HTLV-I RNAs was 1000-fold lower than for picornaviral RNAs. The BIAcore technology also revealed a significant affinity of the La autoantigen, previously described for its involvement in translational control of viral mRNAs, for HIV-1 and HTLV-I RNAs. Addition of recombinant PTB to in vitro translation experiments weakly enhanced translation initiation in the presence of HTLV-I IRES, suggesting that such an IRES requires additional trans-acting factors.     

Insulin-mediated suppression of apolipoprotein B mRNA translation requires the 5' UTR and is characterized by decreased binding of an insulin-sensitive 110-kDa 5' UTR RNA-binding protein

Insulin has been shown to acutely regulate hepatic apolipoprotein B (apoB) secretion at both translational and post-translational levels; however, mechanisms of apoB mRNA translational control are largely unknown. Recent studies of apoB untranslated regions (UTRs) revealed a potentially important role for cis-trans interactions at the 5' and 3' UTRs. In the present paper, deletion constructs of the UTR regions of apoB revealed that the 5' UTR was necessary and sufficient for insulin to inhibit synthesis of apoB15. Metabolic radiolabeling and in vitro translation experiments in the presence of protease inhibitors confirmed that the effect of insulin on the apoB 5' UTR was translational in nature. Using the nondenaturing electrophoretic mobility shift assay (EMSA), protein-RNA complexes were detected binding to the apoB 5' and 3' UTRs. Denaturing EMSA identified a 110-kDa protein interacting at the 5' UTR. Nondenaturing EMSA determined that insulin altered binding of large protein complexes to the 5' UTR. Binding specificity was determined by competition with both specific and nonspecific competitors. Insulin treatment decreased binding of the 110-kDa protein to the 5' UTR as visualized by EMSA. Absence of insulin increased binding of this trans-acting factor to the 5' UTR by 2-fold. Analysis of the 3' UTR showed no significant insulin-mediated changes in binding of trans-acting factors. We thus propose the existence of a novel RNA-binding insulin-sensitive factor that binds to the 5' UTR and may regulate apoB mRNA translation. Perturbations in hepatic insulin signaling as observed in insulin-resistant states may alter cis-trans interactions at the 5' UTR, leading to alterations in the rate of apoB mRNA translation, thus contributing to apoB-lipoprotein overproduction.     

The implications of structured 5' untranslated regions on translation and disease

Translational control is a key step in eukaryotic gene expression. The majority of translational control occurs at the level of initiation, thus implicating the 5' untranslated region as a major site of translational regulation. Many growth-related mRNAs have atypical 5' UTRs, which are often long and GC-rich. Such features promote formation of stable secondary structure, and many mRNAs encoding proteins involved in cell growth, proliferation and apoptosis have structured 5' UTRs, which in many cases harbour internal ribosome entry sites (IRESs) and upstream open-reading frames (uORFs). In this review we discuss how secondary structural elements in the 5' UTR can regulate translation and how mutations that perturb these secondary structural elements can have implications for disease and tumourigenesis.     

Translational repression: biological activity of plasmid-encoded bacteriophage T4 RegA protein

The RegA protein of bacteriophage T4 is a translational repressor that regulates expression of several phage early mRNAs. We have cloned wild-type and mutant alleles of the T4 regA gene under control of the heat-inducible, plasmid-borne leftward promoter (PL) of phage lambda. Expression of the cloned regA+ gene resulted in the synthesis of a protein that closely resembled phage-encoded RegA protein in biological properties. It repressed its own synthesis (autogenous translational control) as well as the synthesis of specific T4-encoded proteins that are known from other studies to be under RegA-mediated translational control. Cloned mutant alleles of regA exhibited derepressed synthesis of the mutant regA gene products and were ineffective in trans against RegA-sensitive mRNA targets. The effects of plasmid-encoded RegA proteins were also demonstrated in experiments using two compatible plasmids in uninfected Escherichia coli. The two-plasmid assays confirm the sensitivities of several cloned T4 genes to RegA-mediated translational repression and are well-suited for genetic analysis of RegA target sites. Repression specificity in this system was demonstrated by using wild-type and operator-constitutive translational initiation sites of T4 rIIB fused to lacZ. The results show that no additional T4 products are required for RegA-mediated translational repression. Additional evidence is provided for the proposal that uridine-rich mRNA sequences are preferred targets for the repressor. Surprisingly, plasmid-generated RegA protein represses the synthesis of some E. coli proteins and appears to enhance selectively the synthesis of others. The RegA protein may have multiple functions, and its binding sites are not restricted to phage mRNAs.     

Characterization of the 5' and 3' untranslated regions in murine mdm2 mRNAs

The murine double minute 2 (mdm2) gene is essential for embryogenesis in mice that express the p53 tumor suppressor protein. Mdm2 levels must be regulated tightly because overexpression of mdm2 contributes to tumorigenesis. We investigated whether the 5' and 3' untranslated regions (UTRs) of murine mdm2 affect the expression of MDM2 proteins. Induction of mdm2 expression by p53 results in synthesis of an mdm2 mRNA with a short 5' UTR. The long 5' UTR increases internal initiation of translation of a minor MDM2 protein, p76(MDM2), without affecting the efficiency of translation of the full-length p90(MDM2). We discovered two alternative 3' untranslated regions in murine mdm2 mRNA expressed in the testis. The longer 3' UTR contains a consensus instability element, but mdm2 mRNAs containing the long and short 3' UTRs have comparable half-lives. The 3' UTRs do not affect either initiation codon use or translation efficiency. Thus, the murine 5' UTR, but not the 3'UTR, influences the ratio of the two MDM2 proteins but neither UTR affects MDM2 abundance significantly.     

The requirement for eukaryotic initiation factor 4A (elF4A) in translation is in direct proportion to the degree of mRNA 5' secondary structure

Eukaryotic initiation factor (elF) 4A functions as a subunit of the initiation factor complex elF4F, which mediates the binding of mRNA to the ribosome. elF4A possesses ATPase and RNA helicase activities and is the prototype for a large family of putative RNA helicases (the DEAD box family). It is thought that the function of elF4A during translation initiation is to unwind the mRNA secondary structure in the 5' UTR to facilitate ribosome binding. However, the evidence to support this hypothesis is rather indirect, and it was reported that elF4A is also required for the translation of mRNAs possessing minimal 5' UTR secondary structure. Were this hypothesis correct, the requirement for elF4A should correlate with the degree of mRNA secondary structure. To test this hypothesis, the effect of a dominant-negative mutant of mammalian elF4A on translation of mRNAs with various degrees of secondary structure was studied in vitro. Here, we show that mRNAs containing stable secondary structure in the 5' untranslated region are more susceptible to inhibition by the elF4A mutant. The mutant protein also strongly inhibits translation from several picornavirus internal ribosome entry sites (IRES), although to different extents. UV crosslinking of elF4F subunits and elF4B to the mRNA cap structure is dramatically reduced by the elF4A mutant and RNA secondary structure. Finally, the elF4A mutant forms a more stable complex with elF4G, as compared to the wild-type elF4A, thus explaining the mechanism by which substoichiometric amounts of mutant elF4A inhibit translation.     

How strong is the case for regulation of the initiation step of translation by elements at the 3' end of eukaryotic mRNAs?

The belief that initiation of translation requires communication between the 5' and 3' ends of the mRNA guides--or misguides--the interpretation of many experiments. The closed-loop model for initiation creates the expectation that sequences at the 3' end of eukaryotic mRNAs should regulate translation. This review looks closely at the evidence in three prominent cases where such regulation is claimed. The mRNAs in question encode 15-lipoxygenase, ceruloplasmin, and histones. Vertebrate histone mRNAs lack a poly(A) tail, instead of which a 3' stem-loop structure is said to promote translation by binding a protein which purportedly binds initiation factors. The proffered evidence for this hypothesis has many flaws. Temporal control of 15-lipoxygenase production in reticulocytes is often cited as another well-documented example of translational regulation via the 3' untranslated region, but inspection of the evidence reveals significant gaps and contradictions. Solid evidence is lacking also for the idea that a ribosomal protein binds to and shuts off translation of ceruloplasmin mRNA. Some viral RNAs that lack a poly(A) tail have alternative 3' structures which are said to promote translation via circularization of the mRNA, but in no case has this been shown convincingly. Interpretation of many experiments is compromised by possible effects of the 3' structures on mRNA stability rather than translation. The functional-half-life assay, which is often employed to rule out effects on mRNA stability, might not be adequate to settle the question. Other issues, such as the possibility of artifacts caused by overexpression of RNA-binding proteins, can complicate studies of translational regulation. There is no doubt that elements at the 3' end of eukaryotic mRNAs can regulate gene expression in a variety of ways. It has not been shown unequivocally that one of these ways involves direct participation of the 3' untranslated region in the initiation step of translation.     

The involvement of mRNA secondary structure in protein synthesis

Translation initiation in eukaryotes is a complex process involving many factors. A key step in this process is the binding of mRNA to the 43S preinitiation complex. This is generally the rate-limiting step in translation initiation and consequently a major determinant of mRNA translational efficiency. The primary and secondary structure of the mRNA 5' noncoding region have been implicated in modulating translational efficiency. Translational efficiency was shown to be inversely proportional to the degree of secondary structure at the mRNA 5' noncoding region. Furthermore, it was shown that cap-binding proteins that interact with the 5' cap structure (m7GpppN) of eukaryotic mRNAs are involved in the "unwinding" of the mRNA secondary structure, in an ATP hydrolysis mediated event, to facilitate ribosome binding. Thus, cap-binding proteins can potentially regulate mRNA translation. Here, we discuss the available data supporting the notion that eukaryotic 5' mRNA secondary structure plays an important role in translation initiation and the possible regulation of this process.