Rat fibroblasts transfected with the human 70-kDa heat shock gene exhibit altered translation and eukaryotic initiation factor 2 alpha phosphorylation following heat shock.

Heat shock inhibits translation in a wide variety of cells. After heating, eukaryotic initiation factor 2-alpha (eIF-2 alpha) becomes phosphorylated which prevents the binding of Met-tRNA to the 40s ribosomal subunit inhibiting initiation of translation. Thermotolerant cells demonstrate resistance to inhibition of translation by additional heating suggesting that heat shock proteins may help to maintain translational integrity following thermal stress. Here we have examined the effects of increased intracellular levels of hsp70 protein on translation and eIF-2 alpha phosphorylation using rat fibroblasts stably transfected with a cloned human hsp70 gene. We observed a decrease in the rate of translational inhibition following heat shock in both hsp70-transfected and thermotolerant cells. Upon recovery at 37 degrees C, both hsp70-transfected and thermotolerant cells exhibit a faster rate of translational recovery. Utilizing slab gel isoelectric focusing coupled with immunoblotting we demonstrate that 45 degrees C heat shock leads to a rapid 4-5-fold increase in eIF-2 alpha phosphorylation, with little difference seen between control cells and hsp70-transfected cells. However, dephosphorylation of eIF-2 alpha occurs faster in the hsp70-transfected cells. These results suggest that hsp70 may play a role in facilitating the dephosphorylation of eIF-2 alpha as well as reversing the inhibition of translation following heat shock.

Translational control during heat shock.

Regulation of translation during heat shock of Drosophila and mammalian cells is reviewed. Protein synthesis is severely inhibited by elevated temperatures but synthesis of heat shock proteins (HSPs) is resistant to this inhibition. The primary site of regulation is polypeptide chain initiation. The activities of two initiation factors, eIF-2 and eIF-4F, are modulated during heat shock. A protein kinase which modulates eIF-2 activity appears to be associated with heat shock proteins (HSPs). Evidence is emerging that HSP70 acts as a heat sensor by detecting the presence of accumulating denatured proteins. In the rabbit reticulocyte lysate denatured proteins bind HSP70 releasing an eIF-2 kinase to shut down protein synthesis. It appears highly likely that a similar mechanism is acting in heat shocked cells. Cell-free protein synthesizing systems prepared from heat shocked cells are deficient in eIF-4F. Modulation of eIF-4F can explain in part the apparent preferential translation of HSP mRNAs.

Purification and characterization of eukaryotic initiation factor (eIF)-2 alpha kinases from Ehrlich ascites tumor cells.

A major mechanism of regulation of mammalian protein synthesis initiation is accomplished by the phosphorylation of the alpha subunit of eukaryotic initiation factor (eIF) 2. This modification inhibits the activity of another initiation factor, guanine nucleotide exchange factor, preventing conversion of eIF-2.GDP to eIF-2.GTP and hence binding of initiator tRNA and formation of ternary complex (eIF-2.GTP.Met-tRNAf). Inhibition of protein synthesis and phosphorylation of eIF-2 occurs in Ehrlich cells when they are amino acid- or serum-deprived or heat-shocked as well as in other nucleated cells under similar conditions. This paper describes the purification of two eIF-2 alpha kinases from Ehrlich cells. Unlike the two well characterized eIF-2 alpha kinases, HRI (heme-regulated inhibitor from reticulocytes) and P68 (double-stranded RNA-dependent kinase found in interferon-treated cells), the Ehrlich cell kinases do not appear to autophosphorylate. The two kinases chromatograph differently on DEAE-cellulose and Mono Q. Furthermore, their Michaelis constants (Km values) for ATP are different. Both kinases can inhibit purified guanine nucleotide exchange factor (GEF) from stimulating ternary complex formation. However, only one kinase inhibits reticulocyte lysate cell free protein synthesis. The other kinase co-purifies with a factor that suppresses inhibition of protein synthesis in reticulocyte lysates by eIF-2 alpha kinases. This suppressing activity is probably guanine nucleotide exchange factor.

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.

Heat shock impairs the interaction of cap-binding protein complex with 5' mRNA cap.

Cell-free protein synthesizing systems prepared from heat-shocked Ehrlich cells retain the inhibition of translation that is seen at the cellular level. Recently, we showed that a highly purified cap-binding protein complex composed of the p220 and p28 subunits of eukaryotic initiation factor 4F, in a 1:1 molar ratio, restores protein synthesis in these cell-free translation systems (Lamphear, B.J., and Panniers, R. (1990) J. Biol. Chem. 265, 5333-5336). Here we have estimated the amount of cap-binding complex in cell extracts that can restore protein synthesis in heat-shocked cells. We find reduced restoring activity in heat-shocked cell extracts. Further, less cap-binding complex can be purified by 7-methyl-guanosine triphosphate Sepharose affinity chromatography from heat-shocked cell extracts, and we conclude that heat shock impairs the binding of complex to 5' mRNA cap. We have ruled out proteolysis and competitive inhibitors as mediators of this impairment. However we cannot distinguish between two possible explanations: (i) reduced association of p220 with p28 or (ii) a non-competitive inhibitor blocks complex binding to cap. We have also examined the affect of heat shock on the phosphorylation state of two forms of p28, p220.p28 complex and p28 free of p220. Both forms have reduced levels of phosphorylation during heat shock. The significance of these changes is discussed.

Inhibition of protein synthesis by antagonists of calmodulin in Ehrlich ascites tumor cells.

Several recent publications indicate that Ca2+ is required for protein synthesis in mammalian cells, including the Ehrlich ascites tumor cell. The present communication examines whether the effects of Ca2+ might be mediated through calmodulin or a related protein. Four calmodulin antagonists belonging to different chemical categories were used to provide evidence of calmodulin involvement. Three of the antagonists inhibited protein synthesis in intact cells; 50% inhibitory concentrations were 10 microM calmidazolium, 12 microM N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W7) and 17.5 microM trifluoperazine (TFP). Initiation was preferentially inhibited as indicated by an increase in the 80S monomers accompanied by a significant disaggregation of polyribosomes. All the antagonists also inhibited protein synthesis initiation in the cell-free protein-synthesizing system; 50% inhibitory concentrations for compound 48/80, calmidazolium, TFP, and W7 were 10 microM, 125 microM, 300 microM and 500 microM, respectively. A weak analogue of W7 inhibited only 20% at 1000 microM. Inhibition in the cell-free system was reversed by the addition of exogenous calmodulin in all four cases. The levels of 43S complexes were significantly elevated with all four antagonists, indicating a block in the utilization of 43S complexes. The similarity of the effects of four distinct classes of antagonists and their ready reversal by exogenous calmodulin leads us to suggest that there may be a role for calmodulin or a very similar calcium-binding protein in protein synthesis.

The alpha subunit of eucaryotic initiation factor 2 is phosphorylated in mengovirus-infected mouse L cells.

Infection of mouse L cells with mengovirus resulted in the activation of a protein kinase (PK) that selectively phosphorylated the small, 38,000-molecular-weight alpha subunit of eucaryotic initiation factor 2 (eIF-2) in vitro. The mengovirus-activated kinase was detected in vitro approximately 3 h after virus adsorption. The ratio of phosphorylated to unphosphorylated eIF-2 also increased in vivo between 3 and 7 h after adsorption. The virus-activated kinase fractionated with the ribosomal pellet and had a high affinity for DEAE-cellulose and Mono Q ion-exchange columns. Gel electrophoresis of the kinase activity eluting from the Mono Q column and silver staining of the gel revealed only one protein band with a molecular mass of 70 kilodaltons. The optimal assay conditions for the mengovirus-activated kinase paralleled those of the double-stranded RNA-activated PK (dsRNA-PK). Lysates from infected cells contained elements capable of activating partially purified dsRNA-PK. These elements were identified as double-stranded RNA by their sensitivity to double-stranded RNase. The phosphorylation of the alpha subunit of eIF-2 coincided with the synthesis of dsRNA in infected cells, suggesting that the mengovirus-activated kinase is the dsRNA-PK. The phosphorylation of the alpha subunit of eIF-2 correlated with the global inhibition of protein synthesis that occurs at late times after infection.

Cap binding protein complex that restores protein synthesis in heat-shocked Ehrlich cell lysates contains highly phosphorylated eIF-4E.

Cell-free protein-synthesizing systems derived from Ehrlich ascites tumor cells that have been exposed to elevated temperatures retain the inhibition of translation that is seen at the cellular level. A multisubunit cap binding protein complex able to restore protein synthesis in these cell free systems was purified from Ehrlich ascites tumor cells via affinity chromatography using m7GTP-Sepharose and fast protein liquid chromatography on Mono Q. The purified complex contains an Mr 220,000 polypeptide (p220) and an Mr 28,000 polypeptide (p28), both of which are components of eukaryotic initiation factor 4F (eIF-4F). p28 is identical to eIF-4E. Restoring activity was relatively free of the Mr 46,000 polypeptide (p46) that is the third component of eIF-4F and does not appear to be dependent on its presence. p28 associated in a complex with p220 is 85% phosphorylated; however, the majority of p28 is not associated with p220, and this free form is only about 50% phosphorylated. The correlation between association of p28 with p220 and high levels of p28 phosphorylation suggests a possible role for phosphorylation in association of p220 with p28.

Mechanism of inhibition of polypeptide chain initiation in calcium-depleted Ehrlich ascites tumor cells.

Protein synthesis in Ehrlich ascites tumor cells is inhibited when cellular calcium is depleted by the addition of EGTA to the growth medium. This inhibition is at the level of polypeptide chain initiation as evidenced by a disaggregation of polyribosomes accompanied by a significant elevation in 80-S monomers. To identify direct effects of calcium on the protein synthesis apparatus we have developed a calcium-dependent, cell-free protein-synthesizing system from the Ehrlich cells by using 1,2-bis(O-aminophenoxy)-ethane-N,N,N',N'-tetraacetic acid (BAPTA), a recently developed chelator with a high (greater than 10(5)) selectivity for calcium (pKa = 6.97) over magnesium (pKa = 1.77). BAPTA inhibits protein synthesis by 70% at 1 mM and 90% at 2 mM. This effect was reversed by calcium but not by other cations tested. The levels of 43-S complexes (i.e., 40-S subunits containing bound methionyl-tRNAf.eIF-2.GTP) were significantly lower in the calcium-deprived incubations, indicating either inhibition of the rate of formation or decreased stability of 43-S complexes. Analysis of 43-S complexes on CsCl gradients showed that in BAPTA-treated lysates, 40-S subunits containing eIF-3, completely disappeared and the residual methionyl-tRNA-containing complexes were bound to 40-S subunits lacking eIF-3. Our results demonstrate a direct involvement of Ca2+ in protein synthesis and we have localized the effect of calcium deprivation to decreased binding of eIF-2 and eIF-3 to 40-S subunits.

Physiological stresses inhibit guanine-nucleotide-exchange factor in Ehrlich cells.

Previously, we have shown that phosphorylation of the eukaryotic initiation factor eIF-2 alpha increases under several physiological stresses in which protein synthesis is inhibited in Ehrlich ascites tumor cells. As phosphorylated eIF-2 [eIF-2(alpha P)] is a potent inhibitor of guanine nucleotide exchange factor (GEF), it seemed likely that it was responsible for the inhibition. We have assayed GEF activity levels in extracts prepared from Ehrlich cells exposed to three such stresses, namely heat shock, serum deprivation and glutamine deprivation. Activity was estimated by the ability of GEF to enhance the release of [alpha-32P]GDP from purified eIF-2 [a modification of the reticulocyte lysate assay of Matts, R. L. & London, I. M. (1984) J. Biol. Chem. 259, 6708]. GEF activity was reduced from control values in extracts of heat-shocked cells and serum-deprived cells, concomitant with increased eIF-2 alpha phosphorylation. Inhibition of GEF activity in heat-shocked and serum-deprived cells was reversed to control levels by increasing the concentration of purified eIF-2.GDP added as substrate in the GEF assay. Since we have shown elsewhere that eIF-2(alpha P).GDP inhibits GEF by competition with eIF-2.GDP, the complete reversal of inhibition of GEF activity in heat-shocked and serum-deprived cells indicates that inhibition is due solely to phosphorylation of eIF-2 alpha. In glutamine-deprived cells phosphorylation of eIF-2 alpha was increased modestly and GEF activity was reduced but GEF activity could not be fully reversed by addition of eIF-2.GDP, suggesting that GEF may also be regulated in other ways. There are greater amounts of GEF relative to eIF-2 in Ehrlich cells (approximately 50%) compared with rabbit reticulocytes (approximately 20%). This explains the efficient rates of protein synthesis in control Ehrlich cells even though they have 30% of their eIF-2 phosphorylated which is enough to inhibit GEF and initiation in reticulocytes completely but only enough to trap approximately 60% of the GEF in Ehrlich cells.

The effect of Mg2+ and guanine nucleotide exchange factor on the binding of guanine nucleotides to eukaryotic initiation factor 2.

A major site of regulation of polypeptide chain initiation is the binding of Met-tRNA to 40 S ribosomal subunits which is mediated by eukaryotic initiation factor 2 (eIF-2). The formation of ternary complex, eIF-2.GTP.Met-tRNA, is potently inhibited by GDP. Measurement of the parameters for guanine nucleotide binding to eIF-2 is critical to understanding the control of protein synthesis by fluctuations in cellular energy levels. We have compared the dissociation constants (Kd) of eIF-2.GDP and eIF-2.GTP and find that GDP has a 400-fold higher affinity for GDP than GTP. The Kd for GDP is almost an order of magnitude less than has been reported previously. The difference between the Kd values for the two nucleotides is the result of a faster rate constant for GTP release, the rate constants for binding being approximately equal. This combination of rate constants and low levels of contaminating GDP in preparations of GTP can explain the apparently unstable nature of eIF-2.GTP observed by others. Mg2+ stabilizes binary complexes slowing the rates of release of nucleotide from both eIF-2.GDP and eIF-2.GTP. The competition between GTP and GDP for binding to eIF-2.guanine nucleotide exchange factor complex has been measured. A 10-fold higher GTP concentration than GDP is required to reduce [32P] GDP binding to eIF-2.guanine nucleotide exchange factor complex by 50%. The relevance of this competition to the regulation of protein synthesis by energy levels is discussed.

The catalytic mechanism of guanine nucleotide exchange factor action and competitive inhibition by phosphorylated eukaryotic initiation factor 2.

Guanine nucleotide exchange factor (GEF) is a multisubunit protein involved in the initiation of translation. Although numerous models have been proposed for its mechanism of action, none have been definitive. An assay dependent on GEF activity was developed using highly purified eukaryotic initiation factor 2 (eIF-2) and GEF from Ehrlich cells. GEF was considered in terms of an enzyme whose catalytic function was the exchange of eIF-2-bound [alpha-32P]GDP for unlabeled nucleotide. The turnover number of GEF at 37 degrees C, calculated on the basis of enzyme kinetic methods is 0.027 s, which is consistent with in vivo rates of protein synthesis. Moreover, kinetic data support an enzyme-substituted mechanism as the mode of GEF function. This mechanism proposes the existence of a GEF.eIF-2.GDP complex and excludes the possibility of two guanine nucleotide binding sites on eIF-2. An analogous mechanism has been recently reported for elongation factor Ts, suggesting the importance of this mechanism to protein synthesis. The mechanism of inhibition of GEF function by eIF-2 alpha phosphorylation has also been investigated. It has been generally assumed that the mechanism by which eIF-2(P) traps GEF is an excessively stable complex, from which GEF is released very slowly. Data presented here, however, reveal that eIF-2(P).GDP is a competitive inhibitor of GEF (rather than an irreversible inhibitor) competing with eIF-2.GDP for binding to GEF. Even though the eIF-2(P).GDP.GEF complex dissociates too rapidly to measure, GEF is trapped because it has at least 150-fold greater affinity for eIF-2(P).GDP than for eIF-2.GDP. The implications of competitive inhibition with respect to the mechanism of reversal of inhibition by an eIF-2(P) phosphatase are discussed.

Phosphorylation of eukaryotic initiation factor 2 during physiological stresses which affect protein synthesis.

Phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF-2) is a major mechanism regulating protein synthesis in rabbit reticulocytes. To determine whether phosphorylation of eIF-2 alpha is a likely regulatory mechanism in the Ehrlich cell, we have measured the percent of cellular eIF-2 alpha which is phosphorylated in cells exposed to heat shock, 2-deoxyglucose, or amino acid deprivation, conditions which rapidly decrease the concentration of 40 S initiation complexes and inhibit protein synthesis. eIF-2 alpha and eIf-2 alpha (P) were separated by isoelectric focusing and were detected by immunoblotting with a monoclonal antibody we developed for this purpose. Under the above three inhibitory conditions, phosphorylation of eIF-2 alpha increased rapidly, and this increase correlated in time with the rapid inhibition of protein synthesis. In heat-shocked cells which were returned to 37 degrees C, both phosphorylation and protein synthesis remained unchanged for 10 min and then returned toward control values slowly and in parallel. The close temporal correspondence between changes in protein synthesis and phosphorylation supports an important regulatory role for phosphorylation in protein synthesis. An increase of 25-35 percentage points, to 50-60% phosphorylation from control levels of 20-30% phosphorylation, correlated with an 80-100% inhibition of protein synthesis. This steep curve of inhibition is consistent with a mechanism in which eIF-2 alpha (P) saturates and inhibits the guanine-nucleotide exchange factor.

Regulation of polypeptide chain initiation in Chinese hamster ovary cells with a temperature-sensitive leucyl-tRNA synthetase. Changes in phosphorylation of initiation factor eIF-2 and in the activity of the guanine nucleotide exchange factor GEF.

When cultures of the temperature-sensitive Chinese hamster ovary cell mutant tsH1 are shifted from 34 degrees C (permissive temperature) to 39.5 degrees C (nonpermissive temperature), protein synthesis is inhibited by more than 80%. This is due principally to a block in activity of polypeptide chain initiation factor eIF-2. In this paper we show that there is impairment of the ability of the guanine nucleotide exchange factor (GEF) to displace GDP from eIF-2 X GDP complexes in extracts from cells incubated at the nonpermissive temperature. Addition of GEF or of high concentrations of eIF-2 stimulates protein synthesis to the level observed in control cell extracts, suggesting that GEF is rate-limiting for eIF-2 activity and overall protein synthesis at the nonpermissive temperature. Analysis of eIF-2 by two-dimensional gel electrophoresis and immunoblotting reveals an increase in the proportion of the alpha subunit in the phosphorylated form from 5.5 +/- 2.4% to 17.2 +/- 3.9% on shifting tsH1 cells from 34 to 39.5 degrees C. No such effect is seen in wild-type cells, which do not exhibit temperature-sensitive protein synthetic activity. Since the primary lesion in tsH1 cells is in their leucyl-tRNA synthetase, these results suggest a role for eIF-2 phosphorylation and GEF activity in coupling the rate of polypeptide chain initiation to the activity of the chain elongation machinery.

Mechanism of inhibition of polypeptide chain initiation in heat-shocked Ehrlich cells involves reduction of eukaryotic initiation factor 4F activity.

Almost all living organisms studied respond to elevated temperature with a marked inhibition of overall protein synthesis but increased synthesis of a specific set of proteins, the so-called heat-shock proteins. We have prepared a cell-free protein synthesizing system (lysate) from heat-shocked Ehrlich ascites tumor cells that reflects the inhibition of protein synthesis in intact cells at elevated temperatures. We have isolated and partially purified a stimulator of the heat-shocked cell lysate from Ehrlich cells. Through four purification steps, the stimulator is chromatographically identical to eukaryotic initiation factor 4F (eIF-4F), an initiation factor which specifically binds mRNA cap structure. Therefore, we have tested the effects of highly purified reticulocyte eIF-4F on the heat-shocked cell lysate. Protein synthesis is strongly stimulated by addition of highly purified eIF-4F. Synthesis in the heat-shocked lysate is more inhibited at high (70 mM) KCl concentrations, than at lower concentrations, and stimulation by eIF-4F is correspondingly greater at higher KCl concentrations, so that the rate of protein synthesis is returned to control (non-heat-shocked lysate) levels at all KCl concentrations. Furthermore, at 70 mM KCl, in heat-shocked lysates, synthesis of the 68-kDa heat-shock protein is much less inhibited than synthesis of the bulk of non-heat-shock proteins, and eIF-4F stimulates synthesis of 68-kDa protein to a much lesser extent than non-heat-shock proteins. Thus, addition of purified eIF-4F reverses the effects of elevated temperatures on Ehrlich cells that are reflected in lysates. Therefore, we propose that the inhibition of translation in heat-shocked Ehrlich cells is the result of inactivation of eIF-4F function.

Mechanism of inhibition of polypeptide chain initiation in heat-shocked Ehrlich ascites tumour cells.

The rate of polypeptide synthesis is inhibited by 80% in Ehrlich cells incubated at 43 degrees C compared to those at 37 degrees C. The regulatory site of translation resides at polypeptide chain initiation. Polypeptide synthesis does not recover at the higher temperature; however, the inhibition is reversed by returning the cells to 37 degrees C. Neither new RNA synthesis or protein synthesis is required for recovery at 37 degrees C, eliminating degradation of mRNA and irreversible denaturation of a protein essential for polypeptide chain initiation. The concentration of 40-S initiation complexes was found to be reduced markedly in heat-shocked cells compared to controls. This was confirmed in the cell-free protein-synthesizing systems prepared from heat-shocked and control cells. Reversible alteration in the activity of components affecting eIF2 function is, therefore, a likely mechanism of regulation in heat-shocked Ehrlich cells. In extracts from heat-shocked cells, Met-tRNA synthetase activity was unaltered compared to control extracts.

A GDP/GTP exchange factor essential for eukaryotic initiation factor 2 cycling in Ehrlich ascites tumor cells and its regulation by eukaryotic initiation factor 2 phosphorylation.

Formation of the ternary complex Met-tRNAi X eukaryotic initiation factor (eIF) 2 X GTP from eIF-2 X GDP requires exchange of GDP for GTP. However, at physiological Mg2+ concentrations, GDP is released from eIF-2 exceedingly slowly (Clemens, M.J., Pain, V.M., Wong, S.T., and Henshaw, E.C. (1982) Nature (Lond.) 296, 93-95). However, GDP is released rapidly from impure eIF-2 preparations, indicating the presence of a GDP/GTP exchange factor. We have now purified this factor from Ehrlich cells and refer to it as GEF. CM-Sephadex chromatography of ribosomal salt wash separated two peaks of eIF-2 activity. GEF was found in association with eIF-2 in the first peak and co-purified with eIF-2 under low salt conditions. It was separated from eIF-2 in high salt buffers and further purified on hydroxylapatite and phosphocellulose. Gel electrophoresis of our purest preparations showed major bands at 85, 67, 52, 37, 27, and 21 kDa. Purified GEF increased the rate of exchange of [32P] GDP for unlabeled GDP 25-fold but did not function with phosphorylated eIF-2 (alpha subunit). The factor also stimulated markedly the rate of ternary complex formation using eIF-2 X GDP as substrate with GTP and Met-tRNAi but not using phosphorylated eIF-2 X GDP as substrate. eIF-2 is released from the 80 S initiation complex with hydrolysis of GTP. If eIF-2 X GDP is actually the complex released, then GEF is absolutely required for eIF-2 to cycle and it is therefore a new eukaryotic initiation factor. Furthermore, the inability of GEF to utilize eIF-2 (alpha P) X GDP explains how phosphorylation of eIF-2 can inhibit polypeptide chain initiation.