A comparison of the binding of methylated cap analogues to wheat germ protein synthesis initiation factors 4F and (iso)4F

The binding of the 5'-terminal cap analogues m7GpppG and m7GTP to wheat germ protein synthesis initiation factors eIF-4F and eIF-(iso)4F as a function of pH, ionic strength, and temperature is described. Equilibrium binding data indicate that eIF-4F and eIF-(iso)4F have different mechanisms for interacting with the 5'-cap structure, but the complexes formed between m7GpppG and wheat germ factor eIF-(iso)4F more closely resemble complexes formed between this cap analogue and either mammalian eIF-4E or eIF-4F. The binding of these initiation factors to the hypermethylated cap analogues m2,7GMP, m2,7GpppG, and m2,2,7GpppG is also investigated. The differences in affinity of eIF-4F and eIF-(iso)4F for the hypermethylated 5'-terminal cap structures suggest that these factors may have discriminatory activity.     

Translational control in heat-shocked Drosophila embryos. Evidence for the inactivation of initiation factor(s) involved in the recognition of mRNA cap structure

Lysates from normally growing (25 degrees C) or heat shocked (37 degrees C, 45 min) Drosophila melanogaster embryos were obtained and the effect of analogues of the mRNA 5'-terminal cap, m7G(5')ppp(5')N structure and of potassium ions on their endogenous protein synthesis activity was studied. At optimal concentration of KCH3COO (75-80 mM), protein synthesis in normal lysates is strongly inhibited by cap analogues (m7GpppG, m7GDP, and m7GMP). At the same ionic conditions, heat shock lysates translate preferentially the heat shock messengers, and this translation is almost unaffected by the cap analogues. In contrast, residual synthesis of normal proteins in heat shock lysates was reduced by these compounds. By lowering the concentration of potassium ions it was possible to gradually reverse the inhibitory effect of the cap analogues in normal lysates and also to increase specifically the translation of normal mRNAs in heat shock lysates. Translation of normal mRNAs is also partial but specifically rescued by supplementing heat shock lysates with polypeptide chain initiation factors partially purified from rabbit reticulocytes. These data are consistent with the notion that the failure of normal mRNAs to be translated under heat shock conditions might be due, at least to some extent, to the inactivation of polypeptide chain initiation factor(s) involved in the recognition of the mRNA 5'-terminal cap structure.     

Influence of 5' proximal secondary structure on the translational efficiency of eukaryotic mRNAs and on their interaction with initiation factors

The effects of 5' proximal secondary structure in mRNA molecules on their translation and on their interaction with the eukaryotic initiation factors (eIF)-4F, eIF-4A, and eIF-4B have been examined. Secondary structures were generated in the 5' noncoding region of rabbit globin and reovirus mRNAs by means of hybridization with cDNA molecules. cDNAs hybridized to the first 15 bases downstream from the cap inhibited the translation of the mRNAs in both reticulocyte and wheat germ lysates. The degree of inhibition was directly related to the monovalent ion concentration and inversely related to reaction temperature. These hybrid structures also reduced the competitive ability of the messages. Hybrid structures beginning downstream from the first 15 bases did not inhibit the translation of beta-globin mRNA or reovirus s3 mRNA. None of the hybrid structures were detrimental to the interaction of the mRNAs with the 26-kDa cap binding protein of eIF-4F, as determined by chemical cross-linking assays. However, in the presence of ATP, hybrid structures immediately adjacent to the cap severely inhibited the cross-linking to the p46 subunit of eIF-4F or to additional eIF-4A or eIF-4B. In order to account for these observations, a two-step mechanism is proposed for the interaction of eIF-4F with the 5' end of an mRNA molecule. The first step involves a weak initial interaction of the p26 subunit with the cap. The second step requires the hydrolysis of ATP and results in the formation of a stable initiation factor-mRNA complex, which may involve eIF-4A and eIF-4B. This second step is inhibited by the presence of 5' proximal secondary structure. In any event, our results demonstrate that the effect of mRNA structure on translation rate depends strongly on its position with respect to the 5' end and that this effect is due at least in part to an inhibition of the action of initiation factors normally required for the unwinding of structure.     

Functional characterization of eukaryotic mRNA cap binding protein complex: effects on translation of capped and naturally uncapped RNAs

We examined the effects of a eukaryotic mRNA cap binding protein (CBP) complex purified by cap analogue affinity chromatography [Edery, I., Humebelin, M., Darveau, A., Lee, K.A. W., Milburn, S., Hershey, J.W.B., Trachsel, H., & Sonenberg, N. (1983) J. Biol. Chem. 258, 11398 11403], on translation of several capped and naturally uncapped mRNAs in extracts prepared from poliovirus-infected or mock-infected HeLa cells. The CBP complex has activity that restores capped mRNA (globin, tobacco mosaic virus, and others) function in extracts from poliovirus-infected HeLa cells. Translation of two naturally uncapped RNAs (poliovirus and mengovirus RNAs), the translation of which is not restricted in extracts from poliovirus-infected cells, is also not stimulated by the CBP complex. Translation of several capped eukaryotic mRNAs (vesicular stomatitis virus, reovirus, and tobacco mosaic virus) in extracts from mock-infected cells is inhibited when the potassium ion concentration is increased. However, translation of capped AMV-4 RNA, which has negligible secondary structure at its 5' end, is resistant to this inhibition. Furthermore, the CBP complex reverses the high salt induced inhibition of translation of the former mRNAs. Since mRNA secondary structure is more stable at elevated salt concentrations, these data are consistent with a model in which the CBP complex has a role in melting mRNA secondary structure involving 5'-proximal sequences, to facilitate ribosome binding.     

Binding of inosine-substituted mRNA to reticulocyte ribosomes and eukaryotic initiation factors 4A and 4B requires ATP

We examined the hypothesis that initiation of eukaryotic protein synthesis involves ATP-dependent melting of 5'-cap-proximal secondary structure in mRNA by eukaryotic initiation factors 4A and 4B. In reticulocyte lysate depleted of ribonucleoside triphosphates by pretreatment with hexokinase/glucose, initiation complex formation by native reovirus mRNA showed a strict requirement for ATP. The corresponding mRNA synthesized with ITP in place of GTP to minimize secondary structure also required ATP for binding to 40 S ribosomal subunits in complexes characteristic of initiation. In a partial reaction without ribosomes, purified eukaryotic initiation factors 4A and 4B bound and cross-linked to the capped 5'-end of oxidized mRNA. This interaction was ATP-dependent with inosine-substituted or bromouridine-containing reovirus RNAs as observed previously with native mRNA. The results indicate that if initiation involves ATP-dependent denaturation of mRNA, the effect must occur after initiation factor-mediated attachment of mRNA to the 40 S ribosomal subunit.     

Removal of 5''-terminal m7G from eukaryotic mRNAs by potato nucleotide pyrophosphatase and its effect on translation.

The procedure for isolation of nucleotide pyrophosphatase (E.C. 3.6.1.9.) from potato has been modified to yield an endonuclease-free preparation purified 2300-fold. The enzyme was used for specific cleavage of pyrophosphate linkages in the 5'-terminal cap (m7GpppN) of several eukaryotic messenger RNAs. Enzymatic removal of 5'-terminal pm7G from reovirus, rabbit globin and Artemia salina mRNAs resulted in an almost complete loss (greater than 80%) of their template activities in a cell-free protein synthesizing system from wheat germ. Incubation with nucleotide pyrophosphatase did not decrease the translation of phage f2 RNA in an Escherichia coli cell-free system.     

Phosphorylation of the proto-oncogene product eukaryotic initiation factor 4E is a common cellular response to tumor necrosis factor

The initiation of mRNA translation is regulated by the reversible phosphorylation of several initiation factors. We report here that tumor necrosis factor-alpha (TNF) rapidly stimulates phosphorylation of one such factor, an mRNA cap binding protein, in several cell types which are important in vitro models of TNF action. This protein has been purified, sequenced, and identified as the proto-oncogene product eukaryotic initiation factor 4E. These data show that phosphorylation of a key component of the cellular translational machinery is a common early event in the various actions of TNF in diverse cell types.     

Biochemical characterisation of cap-poly(A) synergy in rabbit reticulocyte lysates: the eIF4G-PABP interaction increases the functional affinity of eIF4E for the capped mRNA 5'-end

The 5′ cap and 3′ poly(A) tail of eukaryotic mRNAs cooperate to synergistically stimulate translation initiation in vivo. We recently described mammalian cytoplasmic extracts which, following ultracentrifugation to partially deplete them of ribosomes and associated initiation factors, reproduce cap–poly(A) synergy in vitro. Using these systems, we demonstrate that synergy requires interaction between the poly(A)-binding protein (PABP) and the eukaryotic initiation factor (eIF) 4F holoenzyme complex, which recognises the 5′ cap. Here we further characterise the requirements and constraints of cap–poly(A) synergy in reticulocyte lysates by evaluating the effects of different parameters on synergy. The extent of extract depletion and the amounts of different initiation factors in depleted extracts were examined, as well as the effects of varying the concentrations of KCl, MgCl₂ and programming mRNA and of adding a cap analogue. The results presented demonstrate that maximal cap–poly(A) synergy requires: (i) limiting concentrations of ribosome-associated initiation factors; (ii) precise ratios of mRNA to translation machinery (low concentrations of ribosome-associated initiation factors and low, non-saturating mRNA concentrations); (iii) physiological concentrations of added KCl and MgCl₂. Additionally, we show that the eIF4G–PABP interaction on mRNAs which are capped and polyadenylated significantly increases the affinity of eIF4E for the 5′ cap.     

Interaction of a limited set of proteins with different mRNAs and protection of 5''-caps against pyrophosphatase digestion in initiation complexes.

A variety of 5'-3H-methyl-labeled, oxidized viral mRNAs were used as probes for detecting in wheat germ initiation complexes proteins that interact with, and can be cross-linked to, the 5'-cap structure. A limited and reproducible set of specific proteins was obtained with the different mRNAs. The binding of these proteins to the 5'-end of mRNA apparently results in protection against nucleotide pyrophosphatase digestion of the cap even in initiation complexes in which the 5'-end is susceptible to pancreatic RNase digestion. Cross-linked proteins from mammalian initiation complexes comigrated with several of the subunits of similarly treated eIF-3. A model for cap binding protein interaction with mRNA cap during initiation of translation is suggested.     

Stopped-flow kinetic analysis of eIF4E and phosphorylated eIF4E binding to cap analogs and capped oligoribonucleotides: evidence for a one-step binding mechanism

Recruitment of eukaryotic mRNA to the 48 S initiation complex is rate-limiting for protein synthesis under normal conditions. Binding of the 5' -terminal cap structure of mRNA to eIF4E is a critical event during this process. Mammalian eIF4E is phosphorylated at Ser-209 by Mnk1 and Mnk2 kinases. We investigated the interaction of both eIF4E and phosphorylated eIF4E (eIF4E(P)) with cap analogs and capped oligoribonucleotides by stopped-flow kinetics. For m(7)GpppG, the rate constant of association, k(on), was dependent on ionic strength, decreasing progressively up to 350 mm KCl, but the rate constant of dissociation, k(off), was independent of ionic strength. Phosphorylation of eIF4E decreased k(on) by 2.1-2.3-fold at 50-100 mm KCl but had progressively less effect at higher ionic strengths, being negligible at 350 mm. Contrary to published evidence, eIF4E phosphorylation had no effect on k(off). Several observations supported a simple one-step binding mechanism, in contrast to published reports of a two-step mechanism. The kinetic function that best fit the data changed from single- to double-exponential as the eIF4E concentration was increased. However, measuring k(off) for dissociation of a pre-formed eIF4E.m(7)GpppG complex suggested that the double-exponential kinetics were caused by dissociation of eIF4E dimers, not a two-step mechanism. Addition of a 12-nucleotide chain to the cap structure increased affinity at high ionic strength for both eIF4E (24-fold) and eIF4E(P) (7-fold), primarily due to a decrease in k(off). This suggests that additional stabilizing interactions between capped oligoribonucleotides and eIF4E, which do not occur with cap analogs alone, act to slow dissociation.     

The role of mRNA competition in regulating translation. III. Comparison of in vitro and in vivo results

Competition of encephalomyocarditis virus, reovirus, and L-cell mRNAs for a message-discriminatory component was studied in vitro. The data were analyzed qualitatively to determine the relative initiation efficiencies among the various mRNAs. The effects of potassium chloride concentration, magnesium acetate concentration, and m7G methylation on mRNA competition in vitro were also studied. These results were correlated with translation rates in vivo for the same mRNAs, to determine if the sites of competition in vitro and in vivo are the same. It was found that under a particular set of magnesium acetate and potassium chloride concentrations, the order of mRNA initiation efficiencies was the same both in vivo and in vitro, suggesting that the same limiting message-discriminatory factor is regulating initiation rates in both cases. This can only be accomplished in a competitive situation when RNA is in molar excess relative to the discriminatory component.     

Identification of features in 5' terminal fragments from reovirus mRNA which are important for ribosome binding

Four types of experiments were carried out with reovirus messenger RNAs or with 5′ terminal fragments of known sequence to identify features in mRNA which appear to be important for formation of initiation complexes with ribosomes. With a number of reovirus mRNAs, 40S initiation complexes had been previously shown to protect a significantly larger segment of the RNA (including the 5′ terminal m7G) than that protected by 80S initiation complexes. Each 80S-protected sequence had an AUG codon and was a subset of the 40S-protected sequence from the same message. When 40S- and 80S-protected fragments were tested for ability to rebind to ribosomes, the 80S-protected fragments showed considerably lower binding ability, implying that the “extra” sequences protected by 40S initiation complexes contribute to ribosome attachment. Nevertheless, wheat germ ribosomes select the same 5′ terminal initiation site in each reovirus mRNA, irrespective of the presence or absence of m7G on the message. This was demonstrated by comparing fingerprints of the ribosome-protected regions obtained with methylated versus unmethylated RNA. The contribution of m7G to formation of initiation complexes is therefore quantitative rather than qualitative. Limited T1 RNAase digestion of isolated 5′ terminal fragments from several reovirus messages generated a series of smaller fragments which were analyzed for ability to rebind to ribosomes. Partial digestion products up to 30 nucleotides in length which retained the 5′ cap but not the AUG codon were unable to associate stably with ribosomes, whereas every AUG-containing fragment that was analyzed was able to form initiation complexes. The efficiency of binding of certain AUG-containing fragments, however, was reduced by removal of either the 5′ terminal region, including the cap, or of sequences comprising the beginning of the coding region, on the 3′ side of the AUG. Complex formation between messenger RNA and ribosomes was inhibited by the trinucleotide AUG, but not by various other oligonucleotides. Although the inhibition was specific, a vast excess of trinucleotide was required for moderate inhibition of 80S complex formation, and the same concentration of AUG failed to inhibit formation of 40S initiation complexes.     

Translation-Competent Extracts fromSaccharomyces cerevisiae:Effects of L-A RNA, 5′ Cap, and 3′ Poly(A) Tail on Translational Efficiency of mRNAs

Yeast genetics has proven fruitful in the identification of key players that are involved in translational initiation. However, the exact roles of many translation initiation factors in translation initiation remain unknown. This has been due to lack of a suitablein vitrotranslation system in which the mode of action of certain translation factors can be studied. This report describes the preparation of cell-freeSaccharomyces cerevisiaelysates that can mediate the translation of exogenously added mRNAs. Optimal translation required the absence of viral L-A RNA in the lysate and the presence of both a 5′ cap and a 3′ poly(A) tail on the mRNAs. A cooperative effect of cap and poly(A) tail on translation initiation was observed, a property that has been found to operate in intact yeast cells as well. In addition, the yeast lysates mediated translational initiation through several viral internal ribosome entry sites, demonstrating that the yeast translation apparatus can perform internal initiation. Thus, these lysates may be useful in the biochemical analysis of cap-dependent and cap-independent translation events.     

ATP-dependent unwinding of messenger RNA structure by eukaryotic initiation factors

Interaction of protein synthesis initiation factors with mRNA has been studied in order to characterize early events in the eukaryotic translation pathway. Individual reovirus mRNAs labeled with 32P in the alpha position relative to the m7G cap and eukaryotic initiation factor (eIF)-4A, -4B, and -4F purified from rabbit reticulocytes were employed. It was found that eIF-4A causes a structural change in mRNA, as evidenced by a nuclease sensitivity test: addition of high concentrations of eIF-4A greatly increase the nuclease sensitivity of the mRNA, suggesting that this factor can melt or "unwind" mRNA structure. ATP is required for this reaction. At low concentrations of eIF-4A, addition of eIF-4B is required for maximal unwinding activity. Thus eIF-4B enhances eIF-4A activity. Addition of eIF-4F also makes the mRNA sensitive to nuclease indicating a similar unwinding role to that of eIF-4A. Stoichiometric comparisons indicate that eIF-4F is more than 20-fold more efficient than eIF-4A in catalyzing this reaction. The unwinding activity of eIF-4F is inhibited by m7GDP, while that of eIF-4A is not. This suggests that eIF-4A functions independent of the 5' cap structure. Our results also suggest that the unwinding activity of eIF-4F is located in the 46,000-dalton polypeptide of this complex, which has shown by others to be similar or identical to eIF-4A.     

Effect of viral infection on host protein synthesis and mRNA association with the cytoplasmic cytoskeletal structure

We studied the association of several eucaryotic viral and cellular mRNAs with cytoskeletal fractions derived from normal and virus-infected cells. We found that all mRNAs appear to associate with the cytoskeletal structure during protein synthesis, irrespective of their 5' and 3' terminal structures: e.g., poliovirus that lacks a 5' cap structure or reovirus and histone mRNAs that lack a 3' poly A tail associated with the cytoskeletal framework to the same extent as capped, polyadenylated actin mRNA. Cellular (actin) and viral (vesicular stomatitis virus and reovirus) mRNAs were released from the cytoskeletal framework and their translation was inhibited when cells were infected with poliovirus. In contrast, actin mRNA was not released from the cytoskeleton during vesicular stomatitis virus infection although actin synthesis was inhibited. In addition, several other conditions under which protein synthesis is inhibited did not result in the release of mRNAs from the cytoskeletal framework. We conclude that the association of mRNA with the cytoskeletal framework is required but is not sufficient for protein synthesis in eucaryotes. Furthermore, the shut-off of host protein synthesis during poliovirus infection and not vesicular stomatitis virus infection occurs by a unique mechanism that leads to the release of host mRNAs from the cytoskeleton.     

Purification and characterization of protein synthesis initiation factor eIF-4E from the yeast Saccharomyces cerevisiae

A 24 000-dalton protein [yeast eukaryotic initiation factor 4E (eIF-4E)] was purified from yeast Saccharomyces cerevisiae postribosomal supernatant by m7GDP-agarose affinity chromatography. The protein behaves very similarly to mammalian protein synthesis initiation factor eIF-4E with respect to binding to and elution from m7GDP-agarose columns and cross-linking to oxidized reovirus mRNA cap structures. Yeast eIF-4E is required for translation as shown by the strong and specific inhibition of cell-free translation in a yeast extract by a monoclonal antibody directed against yeast eIF-4E.     

Inhibition of translation in L-cell lysates by free polyadenylic acid: differences in sensitivity among different mRNAs and possible involvement of an initiation factor

Free polyadenylic acid specifically inhibits in vitro translation of naturally polyadenylated mRNAs in L-cell lysates. The polynucleotide affects the initiation of protein synthesis but has no apparent effect on elongation of polypeptide chains. Reovirus mRNA, naturally devoid of a poly(A) tail, is much less sensitive to this inhibition than are naturally polyadenylated mRNAs. Reovirus mRNA that was polyadenylated in vitro is not more sensitive than normal reovirus mRNA. The degree of inhibition of translation varies for the different reovirus mRNA species. The addition of proteins contained in a high salt wash of ribosomes can mitigate the inhibition of translation of naturally polyadenylated mRNAs by free polyadenylic acid. Altogether these results suggest that the inhibition by polyadenylic acid may be mediated by its interaction with a cellular (initiation) factor. The various sensitivities exhibited by different mRNAs may indicate differences in requirement for this factor.     

5'-Conformation of capped alfalfa mosaic virus ribonucleic acid 4 may reflect its independence of the cap structure or of cap-binding protein for efficient translation

Most eukaryotic mRNAs are characterized by the presence of a 5'-terminal cap structure (m7GpppN), and removal of the cap or translation of capped mRNAs in the presence of cap analogues (m7G) results in most cases in a significant decrease in the translational efficiency of the mRNAs. One way of explaining the importance of the 5'-cap is that cap-binding proteins recognize the cap structure, destabilize the mRNA secondary structure, and thus allow the 40S ribosomal subunit to bind to the mRNA [Sonenberg, N., Guertin, D., Cleveland, D., & Trachsel, H. (1981) Cell (Cambridge, Mass.) 27, 563-572]. Our data and those of others indicate that the translational efficiency of alfalfa mosaic virus RNA 4 (AMV-4 RNA), a naturally capped RNA, is not affected significantly by cap analogues or by removal of the cap. In order to examine the potential relationship between the function of the cap structure and secondary structure at the 5'-mRNA terminus, partial enzymatic digestion of capped AMV-4 RNA with single strand specific and double strand specific nucleases has been performed, and the experimental data have been compared with computer-generated models of AMV-4 secondary structure. In addition, the in vitro translatability of AMV-4 has been examined as a function of increasing potassium concentration, conditions that are likely to increase mRNA secondary structure. The nuclease-digestion results demonstrate that under native ionic conditions, the 5'-terminus of AMV-4 RNA is predominantly single stranded, although computer modeling and double-strand nuclease digestions indicate that the 5'-terminus can form weak base pairs with internal regions of the molecule.(ABSTRACT TRUNCATED AT 250 WORDS)