Translation initiation factors induce DNA synthesis and transform NIH 3T3 cells

Several polypeptide factors that are essential for the initiation of protein synthesis bind to eukaryotic mRNAs and facilitate the formation of ribosome initiation complexes. Purified mRNA-binding translation initiation factors were microinjected into quiescent NIH 3T3 cells to study the possible growth-promoting role of these factors in living cells. We report that recombinant eIF-4E and rabbit reticulocyte eIF-4F induce a dose-dependent increase of DNA synthesis and morphologically transform NIH 3T3 cells. These results suggest that polypeptides involved in activating the rate-limiting step of protein synthesis (initiation complex formation) can be mitogenic and oncogenic when overexpressed in a cell by direct injection. Thus, eIF-4E and eIF-4F represent a class of proto-oncogenic proteins that is cytoplasmic, is involved in protein synthesis initiation, and is distinct from the proto-oncogenes that have been identified previously.     

Modulation of the mitogenic activity of eukaryotic translation initiation factor-4E by protein kinase C

Eukaryotic initiation factor-4E (eIF-4E) binds to the cap structure of eukaryotic mRNAs and is a component of the cap-binding protein complex eIF-4F. eIF-4E is present in cells in limiting concentrations and is phosphorylated both in vivo and in vitro by protein kinase C (PKC). Recently, eIF-4E has been implicated as an intracellular transducer of extracellular growth signals; microinjection of recombinant eIF-4E into quiescent NIH 3T3 cells induced DNA synthesis. In the present report, the mitogenic activity of eIF-4E was examined after coinjection with PKC. Recombinant eIF-4E was phosphorylated by PKC at the same amino acid that is phosphorylated in cultured cells and reticulocytes in response to phorbol ester. At limiting concentrations of eIF-4E, coinjection with PKC induced a fivefold increase in the mitogenic activity of eIF-4E. Injection of PKC alone or coinjection of eIF-4E with cAMP-dependent protein kinase (PKA) or the Raf protein had no effect. These results suggest that the mitogenic activity of eIF-4E is enhanced by PKC-specific phosphorylation and that phosphate addition is a rate-limiting step in eIF-4E activity.     

Simultaneous cytoplasmic redistribution of ribosomal protein L32 mRNA and phosphorylation of eukaryotic initiation factor 4E after mitogenic stimulation of Swiss 3T3 cells

Ribosomal protein L32 mRNA moved from messenger ribonucleoprotein particles into polysomes following serum activation of quiescent Swiss 3T3 cells. This redistribution of the mRNA into a translationally active state began by 1 h and was complete by 3 h after activation. In contrast, actin mRNA showed no translational control, being found predominantly in polysomes in both quiescent and activated cultures. The phosphorylation state of eukaryotic initiation factor (eIF) 4E, which binds mRNA caps, was examined in parallel. eIF-4E phosphorylation was elevated by 1 h following serum activation and reached a peak by 3-5 h. Treatment of resting cells with phorbol ester also simultaneously stimulated eIF-4E phosphorylation and the movement of L32 mRNA into polysomes. These results are consistent with a model in which mitogen-induced phosphorylation increases the pool of active eIF-4E molecules, which in turn cause the recruitment of translationally controlled mRNAs to actively synthesizing ribosomes.     

Preferential translation of heat shock mRNAs in HeLa cells deficient in protein synthesis initiation factors eIF-4E and eIF-4 gamma.

Expression of antisense RNA against eukaryotic translation initiation factor 4E (eIF-4E) in HeLa cells causes a reduction in the levels of both eIF-4E and eIF-4 gamma (p220) and a concomitant decrease in the rates of both cell growth and protein synthesis (De Benedetti, A., Joshi-Barve, S., Rinker-Schaffer, C., and Rhoads, R. E. (1991) Mol. Cell Biol. 11, 5435-5445). The synthesis of most proteins in the antisense RNA-expressing cells (AS cells) is decreased, but certain proteins continue to be synthesized. In the present study, we identified many of these as stress-inducible or heat shock proteins (HSPs). By mobilities on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by reactivity with monoclonal antibodies generated against human HSPs, four of these were shown to be HSP 90, HSP 70, HSP 65, and HSP 27. The steady-state levels of HSP 90, 70, and 27 were elevated in relation to total protein in AS cells. Pulse labeling and immunoprecipitation indicated that HSP 90 and HSP 70 were synthesized more rapidly in AS cells than in control cells. The accelerated synthesis of HSPs in the AS cells was not due, however, to increased mRNA levels; the levels of HSP 90 and 70 mRNAs either remained the same or decreased after induction of antisense RNA expression. Actin mRNA, a typical cellular mRNA, was found on high polysomes in control cells but shifted to smaller polysomes in AS cells, as expected from the general decrease in translational initiation caused by eIF-4E and eIF-4 gamma depletion. HSP 90 and 70 mRNAs showed the opposite behavior; they were associated with small polysomes in control cells but shifted to higher polysomes in AS cells. These results demonstrate that HSP mRNAs have little or no requirement in vivo for the cap-recognition machinery and suggest that these mRNAs may utilize an alternative, cap-independent mechanism of translational initiation.     

Mechanism of activation of protein synthesis initiation in mitogen-stimulated T lymphocytes

The pronounced stimulation of protein synthesis in T lymphocytes in response to mitogens is partly due to increased cell size and hence ribosome number. There is also a large increase in translation rate per ribosome as a result of an increased rate of initiation. In response to mitogen, levels of both eukaryotic initiation factor (eIF)-2 and guanine nucleotide exchange factor, GEF, increase in parallel with ribosomes which is consistent with a general increase in the translational machinery but cannot explain the increase in activity per ribosome. However, as total eIF-2 accumulates, the ratio of phosphorylated eIF-2 alpha (eIF-2(alpha P] to eIF-2 alpha decreases. Further, the levels of eIF-2(alpha P) and GEF in resting T lymphocytes are similar. As eIF-2(alpha P) inhibits GEF by effectively sequestering the exchange factor in an inactive 1:1 complex, the level of GEF available for protein synthesis initiation must be very low in resting cells. Hence, as GEF is synthesized and rises above the level of eIF-2(alpha P), there will be a disproportionate increase in GEF available for initiation compared with the increase in total GEF. This increase in available GEF is probably great enough to support the increase in translation rate per ribosome as well as the increase in ribosome number.     

Intracellular translation initiation factor levels in Saccharomyces cerevisiae and their role in cap-complex function

Knowledge of the balance of activities of eukaryotic initiation factors (eIFs) is critical to our understanding of the mechanisms underlying translational control. We have therefore estimated the intracellular levels of 11 eIFs in logarithmically growing cells of Saccharomyces cerevisiae using polyclonal antibodies raised in rabbits against recombinant proteins. Those factors involved in 43S complex formation occur at levels comparable (i.e. within a 0.5- to 2.0-fold range) to those published for ribosomes. In contrast, the subunits of the cap-binding complex eIF4F showed considerable variation in their abundance. The helicase eIF4A was the most abundant eIF of the yeast cell, followed by eIF4E at multiple copies per ribosome, and eIF4B at approximately one copy per ribosome. The adaptor protein eIF4G was the least abundant of the eIF4 factors, with a copy number per cell that is substoichiometric to the ribosome and similar to the abundance of mRNA. The observed excess of eIF4E over its functional partner eIF4G is not strictly required during exponential growth: at eIF4E levels artificially reduced to 30% of those in wild-type yeast, growth rates and the capacity for general protein synthesis are only minimally affected. This demonstrates that eIF4E does not exercise a higher level of rate control over translation than other eIFs. However, other features of the yeast life cycle, such as the control of cell size, are more sensitive to changes in eIF4E abundance. Overall, these data constitute an important basis for developing a quantitative model of the workings of the eukaryotic translation apparatus.     

Regulation of initiation factors during translational repression caused by serum depletion. Abundance, synthesis, and turnover rates

During growth in unreplenished medium, the fraction of active, polysomal ribosomes progressively decreases about 3-fold from 80-90% to only 20-40% due to a reduced rate of initiation. To assess whether the abundance of initiation factors could be involved in this repression of translational activity. HeLa cell cytoplasmic lysates were resolved by two-dimensional isoelectric focusing/sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and spots corresponding to the initiation factor proteins were quantitated. The relative abundance of most of the initiation factor proteins only decreases by 10-40% and roughly parallels that of the ribosomes. Measurement of the rates of synthesis and turnover of the initiation factor proteins establishes that during periods of active growth, synthesis and degradation occur coordinately with total cell protein. As growth rate decreases, the synthesis of some initiation factor proteins, particularly eukaryotic initiation factor (eIF)-3 subunits, becomes depressed. Serum stimulation of serum-depleted cells recruits most inactive ribosomes and mRNAs into polysomes, but most initiation factor mRNAs are not selectively recruited. The principal exceptions are eIF-3p24 which exhibits 4-5 fold enhanced synthesis and eIF-3p44 and eIF-4A whose syntheses are moderately stimulated.     

In vivo regulation of protein synthesis by phosphorylation of the alpha subunit of wheat eukaryotic initiation factor 2

The regulation of protein synthesis is a critical component in the maintenance of cellular homeostasis. A major mechanism of translational control in response to diverse abiotic and biotic stress signals involves the phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF2alpha). The pathway has been demonstrated in all eukaryotes except plants, although components of a putative plant pathway have been characterized. To evaluate the in vivo capability of plant eIF2alpha to participate in the translation pathway, we have used vaccinia virus recombinants that constitutively express wheat eIF2alpha and inducibly express the eIF2alpha dsRNA-stimulated protein kinase, PKR, in BSC-40 cells. Activation of PKR in cells expressing wild-type wheat eIF2alpha resulted in an inhibition of cellular and viral protein synthesis and an induction of cellular apoptosis correlating with phosphorylation of eIF2alpha on serine 51. Expression of a nonphosphorylatable mutant (51A) of plant eIF2alpha reversed the PKR-mediated translational block as well as the PKR-induced apoptosis. A direct interaction of the plant proteins with the mammalian translational initiation apparatus is supported by coimmunoprecipitation of wild-type plant eIF2alpha and the 51A mutant with mammalian eIF2gamma and the localization of the plant proteins in ribosome fractions. These findings suggest that plant eIF2alpha is capable of interacting with the guanine nucleotide exchange factor eIF2B within the context of the eIF2 holoenzyme and provide direct evidence for its ability to participate in phosphorylation-mediated translational control in vivo.     

Translational initiation factor expression and ribosomal protein gene expression are repressed coordinately but by different mechanisms in murine lymphosarcoma cells treated with glucocorticoids.

P1798 murine lymphosarcoma cells cease to proliferate upon exposure to 10(-7) M dexamethasone and exhibit a dramatic inhibition of rRNA and ribosomal protein synthesis (O. Meyuhas, E. Thompson, Jr., and R. P. Perry, Mol. Cell Biol. 7:2691-2699, 1987). These workers demonstrated that ribosomal protein synthesis is regulated primarily at the level of translation, since dexamethasone did not alter mRNA levels but shifted the mRNAs from active polysomes into inactive messenger ribonucleoproteins. We have examined the effects of dexamethasone on the biosynthesis of initiation factor proteins in the same cell line. The relative protein synthesis rates of eIF-4A and eIF-2 alpha were inhibited by about 70% by the hormone, a reduction comparable to that for ribosomal proteins. The mRNA levels of eIF-4A, eIF-4D, and eIF-2 alpha also were reduced by 60 to 70%, indicating that synthesis rates are proportional to mRNA concentrations. Analysis of polysome profiles showed that the average number of ribosomes per initiation factor polysome was only slightly reduced by dexamethasone, and little or no mRNA was present in messenger ribonucleoproteins. The results indicate that initiation factor gene expression is coordinately regulated with ribosomal protein synthesis but is controlled primarily by modulating mRNA levels rather than mRNA efficiency.     

Cap-independent translation initiation in Xenopus oocytes.

Eukaryotic cellular mRNAs contain a cap at their 5'-ends, but some viral and cellular mRNAs bypass the cap-dependent mechanism of translation initiation in favor of internal entry of ribosomes at specific RNA sequences. Cap-dependent initiation requires intact initiation factor eIF4G (formerly eIF-4gamma, eIF-4Fgamma or p220), whereas internal initiation can proceed with eIF4G cleaved by picornaviral 2A or L proteases. Injection of recombinant coxsackievirus B4 protease 2A into Xenopus oocytes led to complete cleavage of endogenous eIF4G, but protein synthesis decreased by only 35%. Co-injection of edeine reduced synthesis by >90%, indicating that eIF4G-independent synthesis involved ongoing initiation. The spectrum of endogenous proteins synthesized was very similar in the presence or absence of intact eIF4G. Translation of exogenous rabbit globin mRNA, by contrast, was drastically inhibited by eIF4G cleavage. The N-terminal cleavage product of eIF4G (cpN), which binds eIF4E, was completely degraded within 6-12 h, while the C-terminal cleavage product (cpC), which binds to eIF3 and eIF4A, was more stable over the same period. Thus, translation initiation of most endogenous mRNAs inXenopusoocytes requires no eIF4G, or perhaps only cpC, suggesting a cap-independent mechanism.     

Control of Cyclin-Dependent Kinase Inhibitor p27 Expression by Cap-Independent Translation

p27 is a key regulator of cell proliferation through inhibition of G(1) cyclin-dependent kinase (CDK) activity. Translation of the p27 mRNA is an important control mechanism for determining cellular levels of the inhibitor. Nearly all eukaryotic mRNAs are translated through a mechanism involving recognition of the 5' cap by eukaryotic initiation factor 4E (eIF4E). In quiescent cells eIF4E activity is repressed, leading to a global decline in translation rates. In contrast, p27 translation is highest during quiescence, suggesting that it escapes the general repression of translational initiation. We show that the 5' untranslated region (5'-UTR) of the p27 mRNA mediates cap-independent translation. This activity is unaffected by conditions in which eIF4E is inhibited. In D6P2T cells, elevated cyclic AMP levels cause a rapid withdrawal from the cell cycle that is correlated with a striking increase in p27. Under these same conditions, cap-independent translation from the p27 5'-UTR is enhanced. These results indicate that regulation of internal initiation of translation is an important determinant of p27 protein levels.     

eIF4B controls survival and proliferation and is regulated by proto-oncogenic signaling pathways

Messenger RNA translation, or protein synthesis, is a fundamental biological process affecting cell growth, survival and proliferation. Initiation is the rate limiting and hence the most regulated step of translation. In eukaryotes, translation initiation is facilitated by multiple protein factors collectively called eIFs (for eukaryotic translation initiation factors). The complex consisting of the eIF4 group factors including the mRNA cap-binding eIF4E protein, large scaffolding protein eIF4G and RNA helicase eIF4A is assisted by the eIF4B co-factor to unwind local secondary structures and create a ribosome landing pad on mRNA. Recruitment of the ribosome and augmentation in the mRNA scanning process culminates in the positioning of the ribosome over the start codon. Deregulated translational control is believed to play an important role in oncogenic transformation. Indeed, many eIFs are bona fide proto-oncogenes. In many types of human cancers, eIFs are either overexpressed or ectopically activated by Ras-MAPK and PI3K-mTOR signaling cascades, resulting in increased survival and accelerated proliferation. In this review we will analyze the bulk of data describing eIF4B and its role in cell survival and proliferation. Recent studies have shown that eIF4B is phosphorylated and activated by Ras-MAPK and PI3K-mTOR signaling cascades. In addition, eIF4B regulates translation of proliferative and pro-survival mRNAs. Moreover, eIF4B depletion in cancer cells attenuates proliferation, sensitizes them to genotoxic stress driven apoptosis. Taken together, these findings identify eIF4B as a potential target for development of anti-cancer therapies.     

Translation initiation factors are differentially regulated in cereals during development and following heat shock

The level of protein synthetic activity varies greatly in plants during development or following many environmental stresses. In order to determine whether these global changes in protein synthesis involve changes in the expression of the translational machinery itself, the expression patterns of the initiation factors (eIFs) during cereal seed development, germination, and in leaves following a heat shock were investigated. The expression patterns of initiation factors during seed development fell into four classes: those whose levels were high during early to mid-development but decreased during late seed development (eIF4 A, eIFiso4E, eIFiso4G, and most eIF3 subunits); those whose levels increased from early to mid-development followed by a decrease during late seed development (eIF4B, eIF4E, eIF2α, eIF2β, and PABP); those whose levels steadily increased throughout seed development (eIF4G); and those whose levels remained constant (the p34 subunit of eIF3). In contrast to these observations, the expression patterns of the factors appeared to be coordinately regulated during early germination although differences were observed at later stages. Following a heat shock, the changes in initiation factor expression in wheat leaves fell into two classes, those whose level increased (eIF4G, eIFiso4G, eIF3, and PABP) and those whose level remained unchanged (eIF4 A, eIF4B, eIF4E, eIFiso4E). These observations reveal the complexity of the expression patterns of the initiation factors during seed development, germination, and following thermal stress and may have mechanistic importance for the selective translation of certain mRNAs under these conditions.     

Phosphorylation of eukaryotic initiation factor (eIF) 2 alpha and inhibition of eIF-2B in GH3 pituitary cells by perturbants of early protein processing that induce GRP78.

Agents that mobilize sequestered intracellular Ca2+, including ionophore A23187, EGTA, thapsigargin, and Cbz-Gly-Phe-NH2 (where Cbz is benzyloxycarbonyl), or mild reducing agents, such as dithiothreitol, disrupt early protein processing in the endoplasmic reticulum (ER), inhibit translational initiation, and trigger the induction of GRP78, an ER resident protein. Inhibition of translational initiation in response to acute treatment (15-30 min) of intact GH3 pituitary cells with each of these agents was accompanied by an average 5-fold increase in the amount of phosphorylated eukaryotic initiation factor (eIF) 2 alpha and a 50% reduction in eIF-2B activity. With continued exposure to A23187 (3 h) rates of amino acid incorporation partially recovered, eIF-2 alpha became dephosphorylated, and the inhibition of eIF-2B activity was abolished. These chronic effects were blocked by actinomycin D. Accumulating evidence that the ER may regulate rates of translational initiation through a signaling system altering the activity of eIF-2 is discussed.     

The emerging roles of translation factor eIF4E in the nucleus

The emerging field of nuclear eIF research has yielded many surprises and led to the dissolution of some dogmatic/ideological viewpoints of the place of translation in the regulation of gene expression. Eukaryotic initiation factors (eIFs) are classically defined by their cytoplasmic location and ability to regulate the initiation phase of protein synthesis. For instance, in the cytoplasm, the m7G cap-binding protein eIF4E plays a distinct role in cap-dependent translation initiation. Disruption of eIF4E's regulatory function drastically effects cell growth and may lead to oncogenic transformation. A growing number of studies indicate that many eIFs, including a substantial fraction of eIF4E, are found in the nucleus. Indeed, nuclear eIF4E participates in a variety of important RNA-processing events including the nucleocytoplasmic transport of specific, growth regulatory mRNAs. Although unexpected, it is possible that some eIFs regulate protein synthesis within the nucleus. This review will focus on the novel, nuclear functions of eIF4E and how they contribute to eIF4E's growth-activating and oncogenic properties. Both the cytoplasmic and nuclear functions of eIF4E appear to be dependent on its intrinsic ability to bind to the 5' m7G cap of mRNA. For example, Promyelocytic Leukemia Protein (PML) potentially acts as a negative regulator of nuclear eIF4E function by decreasing eIF4E's affinity for the m7G cap. Therefore, eIF4E protein is flexible enough to utilize a common biochemical activity, such as m7G cap binding, to participate in divergent processes in different cellular compartments.     

eIF4B controls survival and proliferation and is regulated by proto-oncogenic signaling pathways

Messenger RNA translation or protein synthesis, is a fundamental biological process affecting cell growth, survival and proliferation. Initiation is the rate limiting and hence the most regulated step of translation. In eukaryotes, translation initiation is facilitated by multiple protein factors collectively called eIFs (for eukaryotic translation initiation factors). The complex consisting of the eIF4 group factors including the mRNA cap-binding eIF4E protein, large scaffolding protein eIF4G and RNA helicase eIF4A is assisted by the eIF4B co-factor to unwind local secondary structures and create a ribosome landing pad on mRNA. Recruitment of the ribosome and augmentation in the mRNA scanning process culminates in the positioning of the ribosome over the start codon. Deregulated translational control is believed to play an important role in oncogenic transformation. Indeed, many eIFs are bona fide proto-oncogenes. In many types of human cancers, eIFs are either overexpressed or ectopically activated by Ras-MAPK and PI3K-mTOR signaling cascades, resulting in increased survival and accelerated proliferation. In this review we will analyze the bulk of data describing eIF4B and its role in cell survival and proliferation. Recent studies have shown that eIF4B is phosphorylated and activated by Ras-MAPK and PI3K-mTOR signaling cascades. In addition, eIF4B regulates translation of proliferative and pro-survival mRNAs. Moreover, eIF4B depletion in cancer cells attenuates proliferation, sensitizes them to genotoxic stress-driven apoptosis. Taken together, these findings identify eIF4B as a potential target for development of anti-cancer therapies.Key words: eIF4B, translation, signaling, structured 5′UTR, helicase activity, survival, proliferation, apoptosis     

Translation initiation factor modifications and the regulation of protein synthesis in apoptotic cells

The rate of protein synthesis is rapidly down-regulated in mammalian cells following the induction of apoptosis. Inhibition occurs at the level of polypeptide chain initiation and is accompanied by the phosphorylation of the alpha subunit of initiation factor eIF2 and the caspase-dependent cleavage of initiation factors eIF4G, eIF4B, eIF2alpha and the p35 subunit of eIF3. Proteolytic cleavage of these proteins yields characteristic products which may exert regulatory effects on the translational machinery. Inhibition of caspase activity protects protein synthesis from long-term inhibition in cells treated with some, but not all, inducers of apoptosis. This review describes the initiation factor modifications and the possible signalling pathways by which translation may be regulated during apoptosis. We discuss the significance of the initiation factor cleavages and other changes for protein synthesis, and the implications of these events for our understanding of the cellular changes associated with apoptosis.