Protein synthesis and protein phosphorylation during heat stress, recovery, and adaptation.

Incubating cells at elevated temperatures causes an inhibition of protein synthesis. Mild heat stress at 41-42 degrees C inhibits the fraction of active, polysomal ribosomes from greater than 60% (preheating) to less than 30%. A return to 37 degrees C leads to an increase in protein synthesis, termed "recovery." Continuous incubation at 41-42 degrees C also leads to a gradual restoration of protein synthesis (greater than 70% of ribosomes reactivated by 2-4 h), termed "adaptation". Protein synthesis inhibition and reactivation is prestressed, recovered cells that contain elevated levels of the heat stress proteins occur to the same extent and at the same rate as in "naive" cells. The adaptation response requires transcription of new RNA whereas recovery does not. A large number of phosphorylation changes are induced by severe heat stress and occur with kinetics similar to the inhibition of protein synthesis. These include phosphorylation of eukaryotic protein synthesis initiation factor (eIF)-2 alpha and dephosphorylation of eIF-4B and eIF-4Fp25 (eIF-4E). However, the extent to which the modification occurs is proportional to the severity of the stress, and, under mild (41-42 degrees C) heat stress conditions, these initiation factor phosphorylation changes do not occur. Similarly, under conditions of severe heat stress eIF-2 alpha and eIF-4B frequently recover to their prestress phosphorylation state before the recovery of protein synthesis. eIF-4E dephosphorylation likewise does not occur under mild heat stress conditions. Therefore, these changes in phosphorylation states, which are thought to be sufficient cause, are not necessary for the inhibition of protein synthesis observed.

Decreased expression of eukaryotic initiation factor 3f deregulates translation and apoptosis in tumor cells.

The eukaryotic initiation factor 3f (eIF3f) is the p47 subunit of the multi-subunit eIF3 complex. eIF3 plays an important role in translation initiation. In the present study, we investigate the biological function of eIF3f in translation and apoptosis in tumor cells. We demonstrated for the first time that eIF3f is downregulated in most human tumors using a cancer profiling array and confirmed by real-time reverse transcription PCR in melanoma and pancreatic cancer. Overexpression of eIF3f inhibits cell proliferation and induces apoptosis in melanoma and pancreatic cancer cells. Silencing of eIF3f protects melanoma cells from apoptosis. We further investigated the biological function of eIF3f. In vitro translation studies indicate that eIF3f is a negative regulator of translation and that the region between amino acids 170 and 248 of eIF3f is required for its translation regulatory function. Ectopic expression of eIF3f inhibits translation and overall cellular protein synthesis. Ribosome profile and ribosomal RNA (rRNA) fragmentation assays revealed that eIF3f reduces ribosomes, which may be associated with rRNA degradation. We propose that eIF3f may play a role in ribosome degradation during apoptosis. These data provide critical insights into the cellular function of eIF3f and in linking translation initiation and apoptosis.

Cellular titers and subcellular distributions of abundant polyadenylate-containing ribonucleic acid species during early development in the frog Xenopus laevis.

The distribution of cytoplasmic messenger ribonucleic acids (RNAs) in translationally active polysomes and inactive ribonucleoprotein particles changes during early development. Cellular levels and subcellular distributions have been determined for most messenger RNAs, but little is known about how individual sequences change. In this study, we used hybridization techniques with cloned sequences to measure the titers of 23 mitochondrial and non-mitochondrial polyadenylate-containing [poly(A)+]RNA species during early development in the frog Xenopus laevis. These RNA species were some of the most abundant cellular poly(A)+ RNA species in early embryos. The concentrations of most of the non-mitochondrial (cytoplasmic) RNAs remained constant in embryos during the first 10 h of development, although the concentrations of a few species increased. During neurulation, we detected several new poly(A)+ RNA sequences in polysomes, and with one possible exception the accumulation of these sequences was largely the result of new synthesis or de novo polyadenylation and not due to the recruitment of nonpolysomal (free ribonucleoprotein) poly(A)+ RNA. We measured the subcellular distributions of these RNA species in polysomes and free ribonucleoproteins during early development. In gastrulae, non-mitochondrial RNAs were distributed differentially between the two cell fractions; some RNA species were represented more in free ribonucleoproteins, and others were represented less. By the neurula stage this differential distribution in polysomes and free ribonucleoproteins was less pronounced, and we found species almost entirely in polysomes. Some poly(A)+ RNA species transcribed from the mitochondrial genome were localized within the mitochondria and were mapped to discrete fragments of the mitochondrial genome. Much of this poly(A)+ RNA was transcribed from the ribosomal locus. Nonribosomal mitochondrial poly(A)+ RNA species became enriched in polysome-like structures after fertilization, with time courses similar to the time course of mobilization of cytoplasmic poly(A)+ RNA.

Initiation factor protein modifications and inhibition of protein synthesis.

The protein covalent modification state of eucaryotic initiation factors eIF-2 and eIF-4B in HeLa cells was examined after they were exposed to a variety of conditions or treatments that regulate protein synthesis. A few factors (e.g., variant pH and sodium fluoride) altered the phosphorylation state of the initiation factor proteins, but the majority (hypertonic medium, ethanol, dimethyl sulfoxide sodium selenite, sodium azide, and colchicine) had no effect on either protein. While initiation factor phosphorylation may regulate protein synthesis in response to many physiological situations, other pathways can regulate protein synthesis under nonphysiological circumstances.

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.

The translation initiation factor eIF-4B contains an RNA-binding region that is distinct and independent from its ribonucleoprotein consensus sequence.

eIF-4B is a eukaryotic translation initiation factor that is required for the binding of ribosomes to mRNAs and the stimulation of the helicase activity of eIF-4A. It is an RNA-binding protein that contains a ribonucleoprotein consensus sequence (RNP-CS)/RNA recognition motif (RRM). We examined the effects of deletions and point mutations on the ability of eIF-4B to bind a random RNA, to cooperate with eIF-4A in RNA binding, and to enhance the helicase activity of eIF-4A. We report here that the RNP-CS/RRM alone is not sufficient for eIF-4B binding to RNA and that an RNA-binding region, located between amino acids 367 and 423, is the major contributor to RNA binding. Deletions which remove this region abolish the ability of eIF-4B to cooperate with eIF-4A in RNA binding and the ability to stimulate the helicase activity of eIF-4A. Point mutations in the RNP-CS/RRM had no effect on the ability of eIF-4B to cooperate with eIF-4A in RNA binding but significantly reduced the stimulation of eIF-4A helicase activity. Our results indicate that the carboxy-terminal RNA-binding region of eIF-4B is essential for eIF-4B function and is distinct from the RNP-CS/RRM.

Generation of a mutant form of protein synthesis initiation factor eIF-2 lacking the site of phosphorylation by eIF-2 kinases.

The phosphorylation of the alpha-subunit of initiation factor eIF-2 leads to an inhibition of protein synthesis in mammalian cells. We have performed site-directed mutagenesis on a cDNA encoding the alpha-subunit of human eIF-2 and have replaced the candidate sites of phosphorylation, Ser-48 and Ser-51, with alanines. The cDNAs were expressed in vitro by SP6 polymerase transcription and rabbit reticulocyte lysate translation, and the radiolabeled protein products were analyzed by high-resolution two-dimensional gel electrophoresis. The wild-type and Ser-48 mutant proteins became extensively phosphorylated by eIF-2 kinases present in the reticulocyte lysate, and when additional heme-controlled repressor or double-stranded RNA-activated kinase was present, phosphorylation of the proteins was enhanced. The Ser-51 mutant showed little covalent modification by the endogenous enzymes and showed no increase in the acidic variant with additional eIF-2 kinases, thereby suggesting that Ser-51 is the site of phosphorylation leading to repression of protein synthesis.

The 39-kilodalton subunit of eukaryotic translation initiation factor 3 is essential for the complex's integrity and for cell viability in Saccharomyces cerevisiae.

Eukaryotic translation initiation factor 3 (eIF3) in the yeast Saccharomyces cerevisiae comprises about eight polypeptides and plays a central role in the binding of methionyl-tRNAi and mRNA to the 40S ribosomal subunit. The fourth largest subunit, eIF3-p39, was gel purified, and a 12-amino-acid tryptic peptide was sequenced, enabling the cloning of the TIF34 gene. TIF34 encodes a 38,753-Da protein that corresponds to eIF3-p39 in size and antigenicity. Disruption of TIF34 is lethal, and depletion of eIF3-p39 by glucose repression of TIF34 expressed from a GAL promoter results in cessation of cell growth. As eIF3-p39 levels fall, polysomes become smaller, indicating a role for eIF3-p39 in the initiation phase of protein synthesis. Unexpectedly, depletion results in degradation of all of the subunit proteins of eIF3 at a rate much faster than the normal turnover rates of these proteins. eIF3-p39 has 46% sequence identity with the p36 subunit of human eIF3. Both proteins are members of the WD-repeat family of proteins, possessing five to seven repeat elements. Taken together, the results indicate that eIF3-p39 plays an important, although not necessarily direct, role in the initiation phase of protein synthesis and suggest that it may be required for the assembly and maintenance of the eIF3 complex in eukaryotic cells.

SUI1/p16 is required for the activity of eukaryotic translation initiation factor 3 in Saccharomyces cerevisiae.

A genetic reversion analysis at the HIS4 locus in Saccharomyces cerevisiae has identified SUI1 as a component of the translation initiation complex which plays an important role in ribosomal recognition of the initiator codon. SUI1 is an essential protein of 12.3 kDa that is required in vivo for the initiation of protein synthesis. Here we present evidence that SUI1 is identical to the smallest subunit, p16, of eukaryotic translation initiation factor 3 (eIF-3) in S. cerevisiae. SUI1 and eIF3-p16 comigrate upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis and cross-react with anti-SUI1 and anti-eIF3 antisera. Anti-SUI1 antisera immunoprecipitate all of the subunits of eIF3, whereas antisera against the eIF3 complex and the individual PRT1 and GCD10 subunits of eIF3 immunoprecipitate SUI1. Finally, the N-terminal amino acid sequence of a truncated form of eIF3-p16 matches the sequence of SUI1. eIF3 isolated from a sui1(ts) strain at 37 degrees C lacks SUI1 and fails to exhibit eIF3 activity in the in vitro assay for methionyl-puromycin synthesis. A free form of SUI1 separate from the eIF3 complex is found in S. cerevisiae but lacks activity in the in vitro assay. The results, together with prior genetic experiments, indicate that SUI1 is essential for eIF3 activity and functions as part of eIF3 and in concert with eIF2 to promote eIF2-GTP-Met-tRNAi ternary complex recognition of the initiator codon.

Localization of cap-binding protein in subcellular fractions of HeLa cells.

The 26,000-M(r) cap-binding protein was analyzed by a cross-linking assay in cell fractions from uninfected and poliovirus-infected HeLa cells. Cap-binding protein was found in the postribosomal supernatant (S-200) and in the ribosomal salt wash. The cap-binding protein in the S-200 had a sedimentation coefficient of 5 to 7S and lacked the ability to restore translation in extracts of poliovirus-infected cells.

The phosphorylation state of eucaryotic initiation factor 2 alters translational efficiency of specific mRNAs.

Phosphorylation of the alpha subunit of the eucaryotic translation initiation factor (eIF-2 alpha) by the double-stranded RNA-activated inhibitor (DAI) kinase correlates with inhibition of translation initiation. The importance of eIF-2 alpha phosphorylation in regulating translation was studied by expression of specific mutants of eIF-2 alpha in COS-1 cells. DNA transfection of certain plasmids could activate DAI kinase and result in poor translation of plasmid-derived mRNAs. In these cases, translation of the plasmid-derived mRNAs was improved by the presence of DAI kinase inhibitors or by the presence of a nonphosphorylatable mutant (serine to alanine) of eIF-2 alpha. The improved translation mediated by expression of the nonphosphorylatable eIF-2 alpha mutant was specific to plasmid-derived mRNA and did not affect global mRNA translation. Expression of a serine-to-aspartic acid mutant eIF-2 alpha, created to mimic the phosphorylated serine, inhibited translation of the mRNAs derived from the transfected plasmid. These results substantiate the hypothesis that DAI kinase activation reduces translation initiation through phosphorylation of eIF-2 alpha and reinforce the importance of phosphorylation of eIF-2 alpha as a way to control initiation of translation in intact cells.

Translation initiation factor 5A and its hypusine modification are essential for cell viability in the yeast Saccharomyces cerevisiae.

Translation intitiation factor eIF-5A (previously named eIF-4D) is a highly conserved protein that promotes formation of the first peptide bond. One of its lysine residues is modified by spermidine to form hypusine, a posttranslational modification unique to eIF-5A. To elucidate the function of eIF-5A and determine the role of its hypusine modification, the cDNA encoding human eIF-5A was used as a probe to identify and clone the corresponding genes from the yeast Saccharomyces cerevisiae. Two genes named TIF51A and TIF51B were cloned and sequenced. The two yeast proteins are closely related, sharing 90% sequence identity, and each is ca. 63% identical to the human protein. The purified protein expressed from the TIF51A gene substitutes for HeLa eIF-5A in the mammalian methionyl-puromycin synthesis assay. Strains lacking the A form of eIF-5A, constructed by disruption of TIF51A with LEU2, grow slowly, whereas strains lacking the B form, in which HIS3 was used to disrupt TIF51B, show no growth rate phenotype. However, strains with both TIF51A and TIF51B disrupted are not viable, indicating that eIF-5a is essential for cell growth in yeast cells. Northern (RNA) blot analysis shows two mRNA species, a larger mRNA (0.9 kb) transcribed from TIF51A and a smaller mRNA (0.8 kb) encoded by TIF51B. Under the aerobic growth conditions of this study, the 0.8-kb TIF51B transcript is not detected in the wild-type strain and is expressed only when TIF51A is disrupted. The TIF51A gene was altered by site-directed mutagenesis at the site of hypusination by changing the Lys codon to that for Arg, thereby producing a stable protein that retains the positive charge but is not modified to the hypusine derivative. The plasmid shuffle technique was used to replace the wild-type gene with the mutant form, resulting in failure of the yeast cells to grow. This result indicates that hypusine very likely is required for the vital in vivo function of eIF-5A and suggests a precise, essential role for the polyamine spermidine in cell metabolism.

The role of mammalian initiation factor eIF-4D and its hypusine modification in translation.

Initiation factor eIF-4D functions late in the initiation pathway, apparently during formation of the first peptide bond. The factor is post-translationally modified at a specific lysine residue by reaction with spermidine and subsequent hydroxylation to form hypusine. A precursor form lacking hypusine is inactive in the assay for methionyl-puromycin synthesis, but activity is restored following in vitro modification to deoxyhypusine, thereby suggesting that the modification is essential for function. Since formylated methionyl-tRNA is less dependent on eIF-4D in the puromycin assay, we postulate that eIF-4D and its hypusine modification may stabilize charged Met-tRNA binding to the peptidyl transferase center of the 60S ribosomal subunit. Analysis of eIF-4D genes in yeast indicate that eIF-4D and its hypusine modification are essential for cell growth.

Feedback regulation of rRNA synthesis in Escherichia coli. Requirement for initiation factor IF2.

It has been shown that the transcription of rRNA in Escherichia coli is feedback-regulated by its own transcription products through a negative feedback loop which appears to require the assembly of rRNA into complete ribosomes. In order to examine whether the feedback loop involves the ribosomes' main function, translation, we have constructed a strain in which the chromosomal copy of infB, encoding IF2, was placed under lac promoter/operator control, and the effects of limitation of translation initiation factor IF2 on the regulation were examined. By varying the concentration of a lac operon inducer, isopropyl thiogalactoside (IPTG), it was possible to vary the cellular concentration of IF2. Under the growth conditions used, decreasing the concentration of IF2 about twofold affected the growth rate only slightly, but further deprivation of IF2 resulted in a significant decrease in growth rate, an increase in RNA content and a large accumulation of non-translating ribosomes. These accumulated ribosomes were apparently unable to cause feedback regulation of rRNA synthesis in the absence of sufficient IF2. When a higher concentration of IPTG was added to these IF2-deficient cells, a rapid increase in the IF2 level and a significant decrease in the rate of RNA accumulation were observed before the new steady-state growth was attained. These results indicate that IF2 apparently is necessary for feedback regulation of stable RNA and imply that ribosomes must enter translation for feedback regulation to occur.

Isolation and characterization of the promoter and flanking regions of the gene encoding the human protein-synthesis-initiation factor 2 alpha.

The promoter region of the gene (eIF-2 alpha) for eukaryotic initiation factor 2 alpha (eIF-2 alpha) was isolated from a human genomic library and its structure was determined by restriction mapping and nucleotide (nt) sequence analysis. The promoter region and twelve in vivo transcriptional start points (tsp) have been identified by endonuclease S1 mapping and their location confirmed by primer-extension analysis, using RNA isolated from human cells. The untranslated leader is 102 to 140 nt long depending upon the tsp, and the 5' region of the mRNA has the potential for forming stable stem-loop structures. The nt sequence of the regions upstream and downstream from the tsp contains neither a 'TATA box' nor a 'CAAT box', but does contain several direct and inverted repeats, as well as palindromic sequences near the tsp. In addition, multiple consensus binding sites for a wide variety of regulatory proteins are present throughout upstream and downstream tsp-flanking regions.

Mutations in the NKXD consensus element indicate that GTP binds to the gamma-subunit of translation initiation factor eIF2.

Initiation factor eIF2 binds GTP and promotes the binding of methionyl-tRNA to ribosomes. Biochemical and sequence evidence suggests that the GTP might bind to either the beta- or gamma-subunit of eIF2. Mutations were made in the NKXD consensus elements found in both subunits and individual mutant forms were overexpressed in transiently transfected COS-1 cells. The effect on the translational efficiency of a reporter mRNA for dihydrofolate reductase was monitored. Mutations in the gamma-subunit cause severe repression of protein synthesis, whereas those in the beta-subunit are only mildly inhibitory. The results support the view that GTP binds exclusively to the gamma-subunit.

Poliovirus 2A proteinase cleaves directly the eIF-4G subunit of eIF-4F complex.

The initiation of translation on eukaryotic mRNA is governed by the concerted action of polypeptides of the eIF-4F complex. One of these polypeptides, eIF-4G, is proteolytically inactivated upon infection with several members of the Picornaviridae family. This cleavage occurs by the action of virus-encoded proteinases: 2Apro (entero- and rhinovirus) or Lpro (aphthovirus). An indirect mode of eIF-4G cleavage through the activation of a second cellular proteinase has been proposed in the case of poliovirus. Although cleavage of eIF4G by rhino- and coxsackievirus 2Apro has been achieved directly in vitro, a similar activity has not been documented to date for poliovirus 2Apro. We report here that a recombinant form of poliovirus 2Apro fused to maltose binding protein (MBP) directly cleaves human eIF-4G from a highly purified eIF-4F complex. Efficient cleavage of eIF-4G requires magnesium ions. The presence of other initiation factors such as eIF-3, eIF-4A or eIF-4B mimics in part the stimulatory effect of magnesium ions and probably stabilizes the cleavage products of eIF-4G generated by 2Apro. These results suggest that efficient cleavage of eIF4G by MBP-2Apro requires a proper conformation of this factor. Finally, MBP-2Apro protein cleaves an eIF-4G-derived synthetic peptide at the same site as rhino- and coxsackievirus 2Apro (R485-G486).

Expression of initiation factor genes in mammalian cells.

This review focuses on how cells establish the levels of initiation factors, within the broader context of determining levels of the translational machinery. Most initiation factor polypeptides are moderately abundant proteins with concentrations approaching those of ribosomes. eIF4A and eIF5A are more abundant than ribosomes, whereas eIF4F alpha and eIF2B are considerably less abundant than the other factors. The cloning of cDNAs generates hybridization probes for monitoring the levels and activities of factor mRNAs, and the cloning of their genes is just beginning to provide insight into promoter structures and regulation. Initiation factor gene expression appears to be coordinately regulated in many cases, and preferential synthesis is seen in mitogen-activated T-cells. The gene for eIF2 alpha has been best characterized, and mechanisms that provide for the coordinated synthesis of eIF2 subunits are emerging. Recombinant DNA methods also allow investigators to manipulate the levels of expression of specific factor genes by overexpression or antisense repression. Such approaches provide a means to investigate in vivo the mechanisms of action of the initiation factors and their roles in regulating translation rates.

Depletion and deletion analyses of eucaryotic translation initiation factor 1A in Saccharomyces cerevisiae.

Translation initiation factor eIF1A is a highly conserved, small, acidic protein that is required for cell growth in yeast. Biochemical studies in vitro implicate eIF1A in dissociating ribosomes, promoting methionyl-tRNA(i) binding to 40S ribosomal subunits, scanning of mRNAs and recognizing the AUG initiation codon. To elucidate the pleiotropic functions of eIF1A in vivo, the factor was depleted by placing its gene behind the repressible GAL1 promoter. After Saccharomyces cerevisiae cells were shifted to glucose medium, depletion of eIF1A was seen after 3-4 generations, corresponding with cessation of cell growth. Polysome profiles of the depleted strain showed ribosome run-off from mRNAs, indicating that eIF1A is involved in the initiation phase of translation. A decrease in free 40S ribosomes and an apparent increase in free 60S ribosomes were attributed to the formation of 40S subunit dimers. The result suggests that one of the functions of eIF1A is to prevent formation of 40S dimers. Mutant forms of eIF1A lacking either the positively charged N-terminal region or the negatively charged C-terminal region were constructed and tested for their ability to confer cell growth as the sole source of eIF1A. Either deletion supports cell growth, albeit at a slower rate, and causes a reduction in polysomes, although eIF1A lacking the N-terminal region is more deleterious. Therefore the charged terminal regions contribute to, but are not absolutely essential for, eIF1A function.

A fractionated reticulocyte lysate retains high efficiency for protein synthesis.

The rabbit reticulocyte lysate is a highly efficient system for protein synthesis in vitro, and therefore has been used frequently in studies of translational control. However, when the lysate is fractionated into ribosomes and soluble proteins by centrifugation, there is a severe loss of activity, thereby making the system less suitable for identifying components involved in translational control. We have devised a new method of cell fractionation which employs rapid (20-min) centrifugation to pellet ribosomes. The post-ribosomal supernatant (S-100), high salt-washed ribosomes, and the high salt wash are all required in the reconstituted protein synthesis assay, and greater than 70% of the activity of the unfractionated lysate is attained. Proteins in the high salt wash have been further fractionated by ammonium sulfate precipitation, and the assay system has been used to measure the activities of eIF-4B and eIF-4F. This highly active fractionated lysate system should be useful in measuring the specific activities of translational components and may be appropriate for detecting changes due to covalent modifications such as phosphorylation.