The vaccinia virus K3L gene product potentiates translation by inhibiting double-stranded-RNA-activated protein kinase and phosphorylation of the alpha subunit of eukaryotic initiation factor 2.

Interferon resistance of vaccinia virus is mediated by specific inhibition of phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha) by the double-stranded-RNA-activated (DAI) protein kinase. Vaccinia virus encodes a homolog of eIF-2 alpha, K3L, the deletion of which renders the virus sensitive to interferon treatment. We have studied the mechanism by which this protein product elicits interferon resistance in a transient DNA transfection system designed to evaluate regulators of eIF-2 alpha phosphorylation. In this system, translation of a reporter gene mRNA is inefficient because of eIF-2 phosphorylation mediated by the DAI protein kinase. Cotransfection of the K3L gene enhances translation of the reporter mRNA in this system. The K3L protein inhibits eIF-2 alpha phosphorylation and DAI kinase activation, apparently without being phosphorylated itself. Inhibition of protein synthesis, elicited by expression of a mutant Ser-51----Asp eIF-2 alpha designed to mimic a phosphorylated serine, is not relieved by the presence of K3L, suggesting that K3L cannot bypass a block imposed by eIF-2 alpha phosphorylation. The results suggest that K3L acts as a decoy of eIF-2 alpha to inhibit DAI kinase autophosphorylation and activation. Another vaccinia virus gene product, K1L, which is required for growth of vaccinia virus on human cells, does not enhance translation in this assay.     

Structural requirements for double-stranded RNA binding, dimerization, and activation of the human eIF-2 alpha kinase DAI in Saccharomyces cerevisiae.

The protein kinase DAI is activated upon viral infection of mammalian cells and inhibits protein synthesis by phosphorylation of the alpha subunit of translation initiation factor 2 (eIF-2 alpha). DAI is activated in vitro by double-stranded RNAs (dsRNAs), and binding of dsRNA is dependent on two copies of a conserved sequence motif located N terminal to the kinase domain in DAI. High-level expression of DAI in Saccharomyces cerevisiae cells is lethal because of hyperphosphorylation of eIF-2 alpha; at lower levels, DAI can functionally replace the protein kinase GCN2 and stimulate translation of GCN4 mRNA. These two phenotypes were used to characterize structural requirements for DAI function in vivo, by examining the effects of amino acid substitutions at matching positions in the two dsRNA-binding motifs and of replacing one copy of the motif with the other. We found that both copies of the dsRNA-binding motif are required for high-level kinase function and that the N-terminal copy is more important than the C-terminal copy for activation of DAI in S. cerevisiae. On the basis of these findings, we conclude that the requirements for dsRNA binding in vitro and for activation of DAI kinase function in vivo closely coincide. Two mutant alleles containing deletions of the first or second binding motif functionally complemented when coexpressed in yeast cells, strongly suggesting that the active form of DAI is a dimer. In accord with this conclusion, overexpression of four catalytically inactive alleles containing different deletions in the protein kinase domain interfered with wild-type DAI produced in the same cells. Interestingly, three inactivating point mutations in the kinase domain were all recessive, suggesting that dominant interference involves the formation of defective heterodimers rather than sequestration of dsRNA activators by mutant enzymes. We suggest that large structural alterations in the kinase domain impair an interaction between the two protomers in a DAI dimer that is necessary for activation by dsRNA or for catalysis of eIF-2 alpha phosphorylation.     

Translational control by influenza virus: suppression of the kinase that phosphorylates the alpha subunit of initiation factor eIF-2 and selective translation of influenza viral mRNAs.

Selective translation of influenza viral mRNAs occurs after influenza virus superinfection of cells infected with the VAI RNA-negative adenovirus mutant dl331 (M. G. Katze, Y.-T. Chen, and R. M. Krug, Cell 37:483-490, 1984). Cell extracts from these doubly infected cells catalyze the initiation of essentially only influenza viral protein synthesis, reproducing the in vivo situation. This selective translation is correlated with a 5- to 10-fold suppression of the dl331-induced kinase that phosphorylates the alpha subunit of eucaryotic initiation factor eIF-2. This strongly suggests that influenza virus encodes a gene product that, analogous to the adenoviral VAI RNA, prevents the shutdown of overall protein synthesis caused by an eIF-2 alpha kinase turned on by viral infection. Adenoviral mRNA translation was restored to the extract from the doubly infected cells by the addition of the guanine nucleotide exchange factor eIF-2B, which is responsible for the normal recycling of eIF-2 during protein synthesis. This indicates that the residual kinase in the doubly infected cells leads to a limitation in functional (nonsequestered) eIF-2B and hence functional (GTP-containing) eIF-2 and that under these conditions influenza viral mRNAs are selectively translated over adenoviral mRNAs. Addition of double-stranded RNA to the extracts from these cells restored the eIF-2 alpha kinase to a level approaching that seen in extracts from cells infected with dl331 alone and caused the inhibition of influenza viral mRNA translation. This suggests that the putative influenza viral gene product acts against the double-stranded RNA activation of the kinase and indicates that influenza viral mRNA translation is also linked to the level of functional eIF-2. Our results thus indicate that a limitation in functional eIF-2 which causes a nonspecific reduction in the rate of initiation of protein synthesis results in the preferential translation of the better mRNAs (influenza viral mRNAs) at the expense of the poorer mRNAs (adenoviral mRNAs).     

Translational stimulation by reovirus polypeptide sigma 3: substitution for VAI RNA and inhibition of phosphorylation of the alpha subunit of eukaryotic initiation factor 2.

COS cells transfected with plasmids that activate DAI depend on expression of virus-associated I (VAI) RNA to prevent the inhibitory effects of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha) kinase (DAI) and restore the translation of vector-derived dihydrofolate reductase mRNA. This VAI RNA requirement could be completely replaced by reovirus polypeptide sigma 3, consistent with its double-stranded RNA (dsRNA)-binding activity. S4 gene transfection of 293 cells also partially restored adenovirus protein synthesis after infection with the VAI-negative dl331 mutant. In dl331-infected 293 cells, eIF-2 alpha was present mainly in the acidic, phosphorylated form, and trans complementation with polypeptide sigma 3 or VAI RNA decreased the proportion of eIF-2 alpha (P) from approximately 85 to approximately 30%. Activation of DAI by addition of dsRNA to extracts of S4 DNA-transfected COS cells required 10-fold-higher levels of dsRNA than extracts made from cells that were not producing polypeptide sigma 3. In extracts of reovirus-infected mouse L cells, the concentration of dsRNA needed to activate DAI was dependent on the viral serotype used for the infection. Although the proportion of eIF-2 alpha (P) was greater than that in uninfected cells, most of the factor remained in the unphosphorylated form, even at 16 h after infection, consistent with the partial inhibition of host protein synthesis observed with all three viral serotypes. The results indicate that reovirus polypeptide sigma 3 participates in the regulation of protein synthesis by modulating DAI and eIF-2 alpha phosphorylation.     

Expression of mutant eukaryotic initiation factor 2 alpha subunit (eIF-2 alpha) reduces inhibition of guanine nucleotide exchange activity of eIF-2B mediated by eIF-2 alpha phosphorylation.

The inhibition of protein synthesis that occurs upon phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha) at serine 51 correlates with reduced guanine nucleotide exchange activity of eIF-2B in vivo and inhibition of eIF-2B activity in vitro, although it is not known if phosphorylation is the cause of the reduced eIF-2B activity in vivo. To characterize the importance of eIF-2 alpha phosphorylation in the regulation of eIF-2B activity, we studied the overexpression of mutant eIF-2 alpha subunits in which serine 48 or 51 was replaced by an alanine (48A or 51A mutant). Previous studies demonstrated that the 51A mutant was resistant to phosphorylation, whereas the 48A mutant was a substrate for phosphorylation. Additionally, expression of either mutant partially protected Chinese hamster ovary (CHO) cells from the inhibition of protein synthesis in response to heat shock treatment (P. Murtha-Riel, M. V. Davies, J. B. Scherer, S. Y. Choi, J. W. B. Hershey, and R. J. Kaufman, J. Biol. Chem. 268:12946-12951, 1993). In this study, we show that eIF-2B activity was inhibited in parental CHO cell extracts upon addition of purified reticulocyte heme-regulated inhibitor (HRI), an eIF-2 alpha kinase that phosphorylates Ser-51. Preincubation with purified HRI also reduced the eIF-2B activity in extracts from cells overexpressing wild-type eIF-2 alpha. In contrast, the eIF-2B activity was not readily inhibited in extracts from cells overexpressing either the eIF-2 alpha 48A or 51A mutant. In addition, eIF-2B activity was decreased in extracts prepared from heat-shocked cells overexpressing wild-type eIF-2 alpha, whereas the decrease in eIF-2B activity was less in heat-shocked cells overexpressing either mutant 48A or mutant 51A. While the phosphorylation at serine 51 in eIF-2 alpha impairs the eIF-2B activity, we propose that serine 48 acts to maintain a high affinity between phosphorylated eIF-2 alpha and eIF-2B, thereby inactivating eIF-2B activity. These findings support the hypothesis that phosphorylation of eIF-2 alpha inhibits protein synthesis directly through reducing eIF-2B activity and emphasize the importance of both serine 48 and serine 51 in the interaction with eIF-2B and regulation of eIF-2B activity.     

RNA-binding proteins TIA-1 and TIAR link the phosphorylation of eIF-2 alpha to the assembly of mammalian stress granules

In response to environmental stress, the related RNA-binding proteins TIA-1 and TIAR colocalize with poly(A)(+) RNA at cytoplasmic foci that resemble the stress granules (SGs) that harbor untranslated mRNAs in heat shocked plant cells (Nover et al. 1989; Nover et al. 1983; Scharf et al. 1998). The accumulation of untranslated mRNA at SGs is reversible in cells that recover from a sublethal stress, but irreversible in cells subjected to a lethal stress. We have found that the assembly of TIA-1/R(+) SGs is initiated by the phosphorylation of eIF-2alpha. A phosphomimetic eIF-2alpha mutant (S51D) induces the assembly of SGs, whereas a nonphosphorylatable eIF-2alpha mutant (S51A) prevents the assembly of SGs. The ability of a TIA-1 mutant lacking its RNA-binding domains to function as a transdominant inhibitor of SG formation suggests that this RNA-binding protein acts downstream of the phosphorylation of eIF-2alpha to promote the sequestration of untranslated mRNAs at SGs. The assembly and disassembly of SGs could regulate the duration of stress- induced translational arrest in cells recovering from environmental stress.     

Abrogation of translation initiation factor eIF-2 phosphorylation causes malignant transformation of NIH 3T3 cells.

The interferon induced double-stranded RNA-activated kinase, PKR, has been suggested to act as a tumor suppressor since expression of a dominant negative mutant of PKR causes malignant transformation. However, the mechanism of transformation has not been elucidated. PKR phosphorylates translation initiation factor eIF-2 alpha on Ser51, resulting in inhibition of protein synthesis and cell growth arrest. Consequently, it is possible that cell transformation by dominant negative PKR mutants is caused by inhibition of eIF-2 alpha phosphorylation. Here, we demonstrate that in NIH 3T3 cells transformed by the dominant negative PKR mutant (PKR delta 6), eIF-2 alpha phosphorylation is dramatically reduced. Furthermore, expression of a mutant form of eIF-2 alpha, which cannot be phosphorylated on Ser51 also caused malignant transformation of NIH 3T3 cells. These results are consistent with a critical role of phosphorylation of eIF-2 alpha in control of cell proliferation, and indicate that dominant negative PKR mutants transform cells by inhibition of eIF-2 alpha phosphorylation.     

Control of translation in adenovirus-infected cells.

The initiation of protein synthesis in adenovirus-infected cells is regulated during the late phase in two ways, which may be related. The overall translation rate is maintained by a small viral RNA, VA RNAI, which prevents the phosphorylation of initiation factor eIF-2 by a double-stranded RNA-activated protein kinase, DAI. In addition, the relative efficiency of translation of host cell and viral mRNA populations is regulated in the infected cell during the late phase such that viral mRNAs are selectively utilized. Three viral elements have been implicated in this process: the 5' leader present on most late viral mRNAs; the late protein, 100K; and VA RNA. This article reviews the mechanisms underlying these translational control phenomena.     

Characterization of a mutant pancreatic eIF-2alpha kinase, PEK, and co-localization with somatostatin in islet delta cells

Phosphorylation of eukaryotic translation initiation factor-2alpha (eIF-2alpha) is one of the key steps where protein synthesis is regulated in response to changes in environmental conditions. The phosphorylation is carried out in part by three distinct eIF-2alpha kinases including mammalian double-stranded RNA-dependent eIF-2alpha kinase (PKR) and heme-regulated inhibitor kinase (HRI), and yeast GCN2. We report the identification and characterization of a related kinase, PEK, which shares common features with other eIF-2alpha kinases including phosphorylation of eIF-2alpha in vitro. We show that human PEK is regulated by different mechanisms than PKR or HRI. In contrast to PKR or HRI, which are dependent on autophosphorylation for their kinase activity, a point mutation that replaced the conserved Lys-614 with an alanine completely abolished the eIF-2alpha kinase activity, whereas the mutant PEK was still autophosphorylated when expressed in Sf-9 cells. Northern blot analysis indicates that PEK mRNA was predominantly expressed in pancreas, though low expression was also present in several tissues. Consistent with the high levels of mRNA in pancreas, the PEK protein was only detected in human pancreatic islets, and the kinase co-localized with somatostatin, a pancreatic delta cell-specific hormone. Thus PEK is believed to play an important role in regulating protein synthesis in the pancreatic islet, especially in islet delta cells.     

The phosphorylation of eukaryotic initiation factor 2: a principle of translational control in mammalian cells

In eukaryotic cells, protein biosynthesis is controlled at the level of polypeptide chain initiation. During the initiation process, eukaryotic initiation factor 2 (eIF-2) catalyzes the binding of Met-tRNAf and GTP to the 40S ribosomal subunit. In a later step, eIF-2 is released from the ribosomal initiation complex, most likely as an eIF-2.GDP complex, and another initiation factor termed eIF-2B is necessary to recycle eIF-2 by displacing GDP by GTP. In rabbit reticulocytes, inhibition of protein synthesis is accompanied by the phosphorylation of the alpha-subunit of eIF-2, a process that does not render eIF-2 inactive, but prevents it from being recycled by eIF-2B. First described in rabbit reticulocytes as inhibitors of translation, two distinct eIF-2 alpha kinases are known: the haemin-controlled kinase (termed HCI) and the double-stranded RNA-activated kinase (termed DAI). eIF-2 alpha phosphorylation appears to be a reversible control mechanism since corresponding phosphatases have been described. Recent reports indicate a correlation between eIF-2 alpha phosphorylation and the inhibition of protein synthesis in several mammalian cell types under a range of physiological conditions. In this review, the physical and functional features of the known eIF-2 alpha kinases are described with respect to their role in mammalian cells and the mode of activation by cellular signals. Furthermore, the possible impact of the eIF-2/eIF-2B ratio and of the subcellular compartmentation of these factors (and the eIF-2 alpha kinases) on mammalian protein synthesis is discussed.     

Functional complementation by wheat eIF2alpha in the yeast GCN2-mediated pathway

Translational control by specific eIF2alpha phosphorylation on serine 51 has been characterized in all eukaryotes with the significant exception of plants. In order to evaluate the capability of plant eIF2alpha to functionally control translation, the wild type (51S) and a nonphosphorylatable mutant (51A) of wheat eIF2alpha were expressed in a yeast genetic system. Expression of either wheat protein did not handicap growth under conditions that repress the eIF2alpha phosphorylation pathway. However, under conditions that induce specific eIF2alpha phosphorylation only strains expressing wheat 51S were able to grow between 2 and 4 days. Growth was dependent upon activity of yeast eIF2alpha kinase GCN2 and resulted in the increased translation of GCN4. The association between plant eIF2alpha and yeast eIF2B is supported by their specific coimmunoprecipitation from transgenic yeast cells. These data support the similarity among eukaryotic translational initiation processes and strengthen the concept that plants may contain an eIF2alpha phosphorylation pathway.     

Translational regulation of cyclin D1 by 15-deoxy-delta(12,14)-prostaglandin J(2).

The D-group cyclins play a key role in the progression of cells through the G(1) phase of the cell cycle. Treatment of MCF-7 breast cancer cells with the cyclopentenone prostaglandin 15-deoxy-Delta(12,14)-PGJ(2) (15d-PGJ(2)) results in rapid down-regulation of cyclin D1 protein expression and growth arrest in the G(0)/G(1) phase of the cell cycle. 15d-PGJ(2) also down-regulates the expression of cyclin D1 mRNA; however, this effect is delayed relative to the effect on cyclin D1 protein levels, suggesting that the regulation of cyclin D1 occurs at least partly at the level of translation or protein turnover. Treatment of MCF-7 cells with 15d-PGJ(2) leads to a rapid increase in the phosphorylation of protein synthesis initiation factor eukaryotic initiation factor 2alpha (eIF-2alpha) and a shift of cyclin D1 mRNA from the polysome-associated to free mRNA fraction, indicating that 15d-PGJ(2) inhibits the initiation of cyclin D1 mRNA translation. The selective rapid decrease in cyclin D1 protein accumulation is facilitated by its rapid turnover (t(1/2) = 34 min) after inhibition of cyclin D1 protein synthesis. The half-life of cyclin D1 protein is not significantly altered in cells treated with 15d-PGJ(2). Treatment of cells with 15d-PGJ(2) results in strong induction of heat shock protein 70 (HSP70) gene expression, suggesting that 15d-PGJ(2) might activate protein kinase R (PKR), an eIF-2alpha kinase shown previously to be responsive to agents that induce stress. 15d-PGJ(2) strongly stimulates eIF-2alpha phosphorylation and down-regulates cyclin D1 expression in a cell line derived from wild-type mouse embryo fibroblasts but has an attenuated effect in PKR-null cells, providing evidence that PKR is involved in mediating the effect of 15d-PGJ(2) on eIF-2alpha phosphorylation and cyclin D1 expression. In summary, treatment of MCF-7 cells with 15d-PGJ(2) results in increased phosphorylation of eIF-2alpha and inhibition of cyclin D1 mRNA translation initiation. At later time points, repression of cyclin D1 mRNA expression may also contribute to the decrease in cyclin D1 protein.     

Mutations in the GCD7 subunit of yeast guanine nucleotide exchange factor eIF-2B overcome the inhibitory effects of phosphorylated eIF-2 on translation initiation.

Phosphorylation of the alpha subunit of eukaryotic translation initiation factor 2 (eIF-2 alpha) impairs translation initiation by inhibiting the guanine nucleotide exchange factor for eIF-2, known as eIF-2B. In Saccharomyces cerevisiae, phosphorylation of eIF-2 alpha by the protein kinase GCN2 specifically stimulates translation of GCN4 mRNA in addition to reducing general protein synthesis. We isolated mutations in several unlinked genes that suppress the growth-inhibitory effect of eIF-2 alpha phosphorylation catalyzed by mutationally activated forms of GCN2. These suppressor mutations, affecting eIF-2 alpha and the essential subunits of eIF-2B encoded by GCD7 and GCD2, do not reduce the level of eIF-2 alpha phosphorylation in cells expressing the activated GCN2c kinase. Four GCD7 suppressors were shown to reduce the derepression of GCN4 translation in cells containing wild-type GCN2 under starvation conditions or in GCN2c strains. A fifth GCD7 allele, constructed in vitro by combining two of the GCD7 suppressors mutations, completely impaired the derepression of GCN4 translation, a phenotype characteristic of deletions in GCN1, GCN2, or GCN3. This double GCD7 mutation also completely suppressed the lethal effect of expressing the mammalian eIF-2 alpha kinase dsRNA-PK in yeast cells, showing that the translational machinery had been rendered completely insensitive to phosphorylated eIF-2. None of the GCD7 mutations had any detrimental effect on cell growth under nonstarvation conditions, suggesting that recycling of eIF-2 occurs efficiently in the suppressor strains. We propose that GCD7 and GCD2 play important roles in the regulatory interaction between eIF-2 and eIF-2B and that the suppressor mutations we isolated in these genes decrease the susceptibility of eIF-2B to the inhibitory effects of phosphorylated eIF-2 without impairing the essential catalytic function of eIF-2B in translation initiation.     

Modulation of tRNA(iMet), eIF-2, and eIF-2B expression shows that GCN4 translation is inversely coupled to the level of eIF-2.GTP.Met-tRNA(iMet) ternary complexes.

To understand how phosphorylation of eukaryotic translation initiation factor (eIF)-2 alpha in Saccharomyces cerevisiae stimulates GCN4 mRNA translation while at the same time inhibiting general translation initiation, we examined the effects of altering the gene dosage of initiator tRNA(Met), eIF-2, and the guanine nucleotide exchange factor for eIF-2, eIF-2B. Overexpression of all three subunits of eIF-2 or all five subunits of eIF-2B suppressed the effects of eIF-2 alpha hyperphosphorylation on both GCN4-specific and general translation initiation. Consistent with eIF-2 functioning in translation as part of a ternary complex composed of eIF-2, GTP, and Met-tRNA(iMet), reduced gene dosage of initiator tRNA(Met) mimicked phosphorylation of eIF-2 alpha and stimulated GCN4 translation. In addition, overexpression of a combination of eIF-2 and tRNA(iMet) suppressed the growth-inhibitory effects of eIF-2 hyperphosphorylation more effectively than an increase in the level of either component of the ternary complex alone. These results provide in vivo evidence that phosphorylation of eIF-2 alpha reduces the activities of both eIF-2 and eIF-2B and that the eIF-2.GTP. Met-tRNA(iMet) ternary complex is the principal component limiting translation in cells when eIF-2 alpha is phosphorylated on serine 51. Analysis of eIF-2 alpha phosphorylation in the eIF-2-overexpressing strain also provides in vivo evidence that phosphorylated eIF-2 acts as a competitive inhibitor of eIF-2B rather than forming an excessively stable inactive complex. Finally, our results demonstrate that the concentration of eIF-2-GTP. Met-tRNA(iMet) ternary complexes is the cardinal parameter determining the site of reinitiation on GCN4 mRNA and support the idea that reinitiation at GCN4 is inversely related to the concentration of ternary complexes in the cell.     

Inhibition of translation in cells infected with a poliovirus 2Apro mutant correlates with phosphorylation of the alpha subunit of eucaryotic initiation factor 2.

A poliovirus type 2 Lansing mutant was constructed by inserting 6 base pairs into the 2Apro region of an infectious cDNA clone, resulting in the addition of a leucine and threonine into the polypeptide sequence. The resulting small-plaque mutant, 2A-2, had a reduced viral yield in HeLa cells and synthesized viral proteins inefficiently. Infection with the mutant did not lead to specific inhibition of host cell protein synthesis early in infection, and this defect was attributed to a failure to induce cleavage of the cap-binding complex protein p220. At late times after infection with the mutant virus, both cellular and viral protein syntheses were severely inhibited. To explain this global inhibition of protein synthesis, the phosphorylation state of the alpha subunit of eucaryotic initiation factor 2 (eIF-2 alpha) was examined. eIF-2 alpha was phosphorylated in both R2-2A-2- and wild-type-virus-infected cells, indicating that poliovirus does not encode a function that blocks phosphorylation of eIF-2 alpha. The kinetics and extent of eIF-2 alpha phosphorylation correlated with the production of double-stranded RNA in infected cells, suggesting that eIF-2 alpha is phosphorylated by P1/eIF-2 alpha kinase. When HeLa cells were infected with R2-2A-2 in the presence of 2-aminopurine, a protein kinase inhibitor, much higher virus titers were produced, cleavage of p220 occurred, and host cell protein synthesis was specifically inhibited. Since phosphorylation of eIF-2 alpha was not inhibited by 2-aminopurine, we propose that 2-aminopurine rescues the ability of R2-2A-2 to induce cleavage of p220 by inhibition of a second as yet unidentified kinase.     

Multicopy tRNA genes functionally suppress mutations in yeast eIF-2 alpha kinase GCN2: evidence for separate pathways coupling GCN4 expression to unchanged tRNA.

GCN2 is a protein kinase that stimulates translation of GCN4 mRNA in amino acid-starved cells by phosphorylating the alpha subunit of translation initiation factor 2 (eIL-2). We isolated multicopy plasmids that overcome the defective derepression of GCN4 and its target genes caused by the leaky mutation gcn2-507. One class of plasmids contained tRNA(His) genes and conferred efficient suppression only when cells were starved for histidine; these plasmids suppressed a gcn2 deletion much less efficiently than they suppressed gcn2-507. This finding indicates that the reduction in GCN4 expression caused by gcn2-507 can be overcome by elevating tRNA(His) expression under conditions in which the excess tRNA cannot be fully aminoacylated. The second class of suppressor plasmids all carried the same gene encoding a mutant form of tRNA(Val) (AAC) with an A-to-G transition at the 3' encoded nucleotide, a mutation shown previously to reduce aminoacylation of tRNA(Val) in vitro. In contrast to the wild-type tRNA(His) genes, the mutant tRNA(Val) gene efficiently suppressed a gcn2 deletion, and this suppression was independent of the phosphorylation site on eIF-2 alpha (Ser-51). Overexpression of the mutant tRNA(Val) did, however, stimulate GCN4 expression at the translational level. We propose that the multicopy mutant tRNA(Val) construct leads to an accumulation of uncharged tRNA(Val) that derepresses GCN4 translation through a pathway that does not involve GCN2 or eIF-2 alpha phosphorylation. This GCN2-independent pathway was also stimulated to a lesser extent by the multicopy tRNA(His) constructs in histidine-deprived cells. Because the mutant tRNA(Val) exacerbated the slow-growth phenotype associated with eIF-2 alpha hyperphosphorylation by an activated GCN2c kinase, we suggest that the GCN2-independent derepression mechanism involves down-regulation of eIF-2 activity.     

Evidence for a second phosphorylation site on eIF-2 alpha from rabbit reticulocytes

Ser 51 in the NH2-terminal sequence of the alpha-subunit of eukaryotic peptide initiation factor 2 (eIF-2) has been identified as a second phosphorylation site for the heme-controlled eIF-2 alpha kinase from rabbit reticulocytes. Increased phosphorylation of this serine relative to the previously described phosphorylation site (Ser 48) is observed when the kinase reaction is carried out in the presence of the alpha-subunit of spectrin. A synthetic peptide corresponding to eIF-2 alpha (41-54) is phosphorylated only in Ser 51 by the eIF-2 alpha kinase.     

Phosphorylation of translation initiation factor eIF-4E is induced in a ras-dependent manner during nerve growth factor-mediated PC12 cell differentiation.

Translation initiation factor eIF-4E, which binds to the 5' cap structure of eukaryotic mRNAs, is believed to play an important role in the control of cell growth. Consistent with this, overexpression of eIF-4E in fibroblasts results in their malignant transformation. The activity of eIF-4E is thought to be regulated by phosphorylation on a single serine residue (Ser-53). Treatment of rat pheochromocytoma (PC12) cells with nerve growth factor (NGF) strongly curtails their growth and causes their differentiation into cells that resemble sympathetic neurons. The present study shows that eIF-4E is rapidly phosphorylated in PC12 cells upon NGF treatment, resulting in a significant increase in the steady-state levels of the phosphorylated protein. In contrast, epidermal growth factor, a factor which elicits a weak mitogenic response in PC12 cells, did not significantly enhance eIF-4E phosphorylation. We also show that although the mitogen and tumor promoter, phorbol 12-myristate-13-acetate, is able to induce phosphorylation of eIF-4E in PC12 cells, the NGF-mediated increase is primarily a protein kinase C-independent response. The NGF-induced enhancement of eIF-4E phosphorylation is abrogated in PC12 cells expressing a dominant inhibitory ras mutant (Ser-17 replaced by Asn), indicating that eIF-4E phosphorylation is dependent on a ras signalling pathway. As phosphorylation of eIF-4E effects translation initiation, these results suggest that NGF-mediated and ras-dependent eIF-4E phosphorylation may play a role in switching the pattern of gene expression during the differentiation of PC12 cells.