Expression of eukaryotic translation initiation factors 4E and 2alpha is increased frequently in bronchioloalveolar but not in squamous cell carcinomas of the lung.

BACKGROUND: When resting cells are stimulated by growth factors, an increase in protein synthesis follows that depends in part on two key eukaryotic translation initiation factors, 4E and 2alpha (eIF-4E and eIF-2alpha, respectively). In the normal cell, expression and activity of both factors are increased transiently, whereas they become elevated constitutively in oncogene-transformed cultured cells, and overexpression of either initiation factor in rodent cells makes them tumorigenic. In this study, the authors investigated an association between the expression of these translation initiation factors and lung carcinogenesis. METHODS: The authors analyzed the expression of the protein synthesis initiation factors eIF-4E and eIF-2alpha by immunohistochemistry in bronchioloalveolar (BA) and squamous cell (SC) carcinomas of the lung. Western blot analysis was performed to validate the specificity of antibodies in detecting their cognate proteins. RESULTS: Both eIF-4E and eIF-2alpha were increased frequently in BA carcinomas, whereas only rarely did SC carcinomas demonstrate elevation of these translation initiation factors. An analysis of cyclin D1 expression did not show a strict correlation with the expression of eIF-4E and eIF-2alpha. CONCLUSIONS: Increased expression of either one or both translation initiation factors may facilitate accelerated growth and division of neoplastic cells in BA carcinoma of the lung. However, the current findings suggest a possibility that increased cell growth and proliferation in SC carcinoma may be achieved through a mechanism independent of increases in eIF-4E and eIF-2alpha expression.

Expression of translation initiation factors elF-4E and elF-2alpha and a potential physiologic role of continuous protein synthesis in human platelets.

It is generally believed that platelets do not have a functionally significant protein synthetic machinery. However, our analysis demonstrated that normal bone marrow megakaryocytes express high levels of translation initiation factors eIF-4E and eIF-2alpha and the expression of these protein synthesis initiation factors is continued in platelets (as determined by immunohistochemistry and Western blot analysis). Both eIF-4E and eIF-2alpha are key regulators of protein synthesis. The eIF-4E is a rate-limiting part of a multisubunit complex, eIF-4F, that binds to the 5' cap structure present in virtually all eukaryotic mRNAs, and carries out transfer of mRNAs to ribosomes for translation. Translation initiation factor eIF-2alpha is also a rate-limiting protein which associates with two other proteins to form an eIF-2 initiation factor complex responsible for the transfer of initiator methionyl-tRNA to the 40S ribosomal subunit. We confirm that expression of eIF-4E and eIF-2alpha is biologically relevant in that platelets continue protein synthesis, albeit at a 16 times lower rate than WBC (as determined by 35S-labeled amino acid incorporation, SDS-PAGE and scintillation counting). Finally, we determined that protein synthesis inhibitors (puromycin and emetine) attenuate the platelet aggregation response to a combination of ADP and epinephrine, but potentiate the response to collagen. Our data are consistent with the existence of different signal transducing pathways mediating the response to ADP/epinephrine and collagen. We suggest that the ADP/epinephrine response is positively affected by continuously synthesized proteins, while the response to collagen is modulated by continuously produced inhibitory proteins. Taken together, our results suggest that continuous protein synthesis is important for platelet function and its role in platelet physiology and pathophysiology deserves further study.

Expression of eukaryotic translation initiation factors 4E and 2alpha correlates with the progression of thyroid carcinoma.

Cell growth and proliferation depend on protein synthesis that is regulated, in part, by two eukaryotic translation initiation factors, eIF-4E and eIF-2alpha. These factors are transiently increased as normal cells respond to growth factors and are constitutively elevated in transformed cells. In cultured cells, eIF-4E facilitates cell cycle progression by increasing the expression of cell cycle promoting proteins including cyclin D1. Our previous study revealed elevated cyclin D1 expression in histologically more aggressive thyroid carcinomas as compared to conventional papillary carcinoma. We hypothesized that the increased cyclin D1 expression might correlate with increased eIF-4E expression. We, therefore studied the expression of eIF-4E by immunohistochemistry in 25 cases of conventional papillary carcinoma (CPC) and 28 cases of aggressive thyroid carcinomas (ATC), the latter included 11 tall cell/columnar cell variant of papillary carcinoma, 5 insular carcinomas, and 12 anaplastic carcinomas. We also analyzed the expression of eIF-2a in the same samples as this factor is usually regulated similarly to eIF-4E in cell culture models. Of the 25 CPC, 13 were eIF-4E positive (11 weakly and 2 strongly), and 19 were eIF-2a positive (14 weakly and 5 strongly). Conversely, of the 28 ATC, 25 were eIF-4E positive (4 weakly and 21 strongly), and 23 were eIF-2alpha positive (4 weakly and 19 strongly). There was a significantly increased expression of both eIF-4E (p < 0.001) and eIF-2alpha (p < 0.001) in ATC compared to CPC, suggesting that these translation initiation factors may play a role in the progression of thyroid cancer.

Expression of the eukaryotic translation initiation factors 4E and 2alpha in non-Hodgkin's lymphomas.

Transition of cells from quiescence to proliferation requires an increase in the rate of protein synthesis, which is regulated in part by two key translation initiation factors, 4E and 2alpha. The expression and activity of both factors are increased transiently when normal resting cells are stimulated to proliferate. They are constitutively elevated in oncogene transformed cultured cells, and overexpression of either initiation factor in rodent cells makes them tumorigenic. In this study we investigate an association between the expression of translation initiation factors and lymphomagenesis. We have analyzed the expression of the protein synthesis initiation factors 4E and 2alpha by immunohistochemistry in reactive lymph nodes and several types of non-Hodgkin's lymphoma representing a wide range of clinical behaviors based on the Revised European-American Lymphoma behavioral classification. The study included 7 benign lymph nodes with follicular hyperplasia, 26 indolent lymphomas (6 marginal zone lymphomas, 7 small lymphocytic lymphomas, and 13 follicular lymphomas, grades 1 and 2), 16 moderately aggressive lymphomas (8 mantle cell lymphomas and 8 follicular lymphomas, grade 3), 24 aggressive lymphomas (14 large-B-cell lymphomas and 10 anaplastic large-cell lymphomas), and 15 highly aggressive lymphomas (7 lymphoblastic lymphomas and 8 Burkitt's lymphomas). Strong expression of initiation factors 4E and 2alpha was demonstrated in the germinal centers of reactive follicles. Minimal or no expression was seen in the mantle zones and surrounding paracortices, indicating that high expression of initiation factors 4E and 2alpha is associated with the active proliferation of lymphocytes. Most cases of aggressive and highly aggressive lymphomas showed strong expression of initiation factors 4E and 2alpha, in contrast to the cases of indolent and moderately aggressive lymphoma, in which their expression was intermediate between the germinal centers and the mantles of reactive follicles. A positive correlation was found between the expression of both initiation factors 4E and 2alpha and the Revised European-American Lymphoma behavior classification (P < 0.05). Thus, constitutively increased expression of initiation factors 4E and 2alpha may play an important role in the development of lymphomas and is correlated with their biological aggressiveness.

Upregulation of protein synthesis initiation factor eIF-4E is an early event during colon carcinogenesis.

A general increase in protein synthesis and a specific increase in the synthesis of growth-promoting proteins are necessary for mitogenesis. Regulation of protein synthesis, as well as preferential translation of some mRNAs coding for growth promoting proteins (e.g. cyclin D1), involves the essential protein synthesis initiation factor eIF-4E. This factor is induced by various oncoproteins, and, when overexpressed, it can transform cultured cells. In this report we explore the roles of eIF-4E in human neoplastic disorders of the colon and in the regulation of general and specific protein synthesis. We find that eIF-4E is increased in colon adenomas and carcinomas, and this increase is accompanied in most but not all cases by elevation of cyclin D1 levels. While general protein synthesis is increased by eIF-4E overexpression in cultured cells, only a small proportion of proteins is preferentially upregulated by eIF-4E, as revealed by two-dimensional gel electrophoresis. These results are consistent with the view that eIF-4E plays a role in carcinogenesis by increasing general protein synthesis and by preferentially upregulating a subset of putative growth promoting proteins. Our results, taken together with the recent findings that c-myc transcription is negatively regulated by APC and our earlier data on transcriptional activation of eIF-4E expression by c-Myc suggest that eIF-4E is a downstream target of the APC/beta-catenin/Tcf-4 pathway, and is strongly involved in colon tumorigenesis.

Translational control of programmed cell death: eukaryotic translation initiation factor 4E blocks apoptosis in growth-factor-restricted fibroblasts with physiologically expressed or deregulated Myc.

There is increasing evidence that cell cycle transit is potentially lethal, with survival depending on the activation of metabolic pathways which block apoptosis. However, the identities of those pathways coupling cell cycle transit to survival remain undefined. Here we show that the eukaryotic translation initiation factor 4E (eIF4E) can mediate both proliferative and survival signaling. Overexpression of eIF4E completely substituted for serum or individual growth factors in preserving the viability of established NIH 3T3 fibroblasts. An eIF4E mutant (Ser-53 changed to Ala) defective in mediating its growth-factor-regulated functions was also defective in its survival signaling. Survival signaling by enforced expression of eIF4E did not result from autocrine release of survival factors, nor did it lead to increased expression of the apoptosis antagonists Bcl-2 and Bcl-XL. In addition, the execution apparatus of the apoptotic response in eIF4E-overexpressing cells was found to be intact. Increased expression of eIF4E was sufficient to inhibit apoptosis in serum-restricted primary fibroblasts with enforced expression of Myc. In contrast, activation of Ha-Ras, which is required for eIF4E proliferative signaling, did not suppress Myc-induced apoptosis. These data suggest that the eIF4E-activated pathways leading to survival and cell cycle progression are distinct. This dual signaling of proliferation and survival might be the basis for the potency of eIF4E as an inducer of neoplastic transformation.

Upregulated expression of the genes encoding translation initiation factors eIF-4E and eIF-2alpha in transformed cells.

Increased protein synthesis is necessary for the transition of cells from quiescence to proliferation. It is shown in this paper that the induction of expression of the translation initiation factor eIF-4E in normal cells requires serum growth factors, while this requirement is abrogated in tumor cells analyzed in this study. Further, the expression of eIF-4E and eIF-2alpha is increased in c-myc, v-src, and v-abl-transformed cells. It is demonstrated that an increase in c-myc function leads to elevated expression of eIF-4E and eIF-2alpha, increases in net protein synthesis and cell proliferation. It may be suggested that constitutive activation of translational machinery may be one common mechanism by which various oncogenes exert their transforming function.

Deregulation of protein synthesis as a mechanism of neoplastic transformation.

Early research on the cell cycle revealed correlations between protein accumulation and cell proliferation. In this review, I describe the data showing that abnormality of cell growth and tumor development are dependent upon oncogene-induced increases in the levels and activity of factors that determine the rate of protein synthesis. It is proposed that the establishment of a vicious circle, namely oncoproteins-->increase in translation-->oncoproteins, is a major biological mechanism that fuels neoplastic growth. The constitutively high rates of protein synthesis and accumulation of proteins, including those necessary for DNA replication and mitosis, would drive cells to excessive proliferation.

Transient inhibition of protein synthesis induces expression of proto-oncogenes and stimulates resting cells to enter the cell cycle.

There is evidence that resting cells are able to produce molecules with antiproliferative activity, some of which behave as short-lived repressor proteins. We suggest that transient inhibition of protein synthesis in resting cells would lead to a decrease in the levels of these negative growth regulators and might, therefore, promote mitogenic responses. We report that treatment of resting (serum-deprived) NIH 3T3 cells with cyclocheximide (CH) or puromycin induces expression of c-fos, c-jun and c-myc proto-oncogenes in a manner similar to that of platelet-derived growth factor (PDGF). Actinomycin D (Act D) abrogates the induction of proto-oncogene expression. Transient inhibition of protein synthesis by CH or puromycin also induces the resting NIH 3T3 and C3H 1OT1/2 cells to enter the cell cycle. Inhibition of new RNA or protein synthesis abolishes the proliferative response. These findings show that control mechanisms at both transcriptional and translational levels are operative in the resting cells treated with protein synthesis inhibitors. Cell fusion experiments with resting and serum-stimulated NIH 3T3 cells revealed that brief pre-incubation of resting cells with either PDGF, CH or puromycin abrogates their ability to suppress the onset of DNA synthesis in the nuclei of stimulated cells in heterodikaryons. However, the abrogative effect of PDGF disappeared in the presence of Act D, whereas the effects of protein synthesis inhibitors did not, indicating their independence of the induction of transcription. The data suggest that the observed effects of protein synthesis inhibitors are connected with elimination of some short-lived negative growth regulators, since a brief translational arrest is sufficient for the resumption of DNA synthesis in the nuclei of stimulated cells blocked by resting cells in heterodikaryons.

Growth factor-independent expression of the gene encoding eukaryotic translation initiation factor 4E in transformed cell lines.

Activation of protein synthesis is necessary for the transition of cells from quiescence to proliferation, while withdrawal of growth factors leads to decrease in protein synthesis and transition of normal cells into the resting period. It is shown in this paper that serum growth factors are required for activation of expression of gene encoding translation initiation factor 4E (eIF-4E) in non-transformed NIH 3T3 and Rat-1 fibroblasts but this requirement is lost in C6 glioblastoma, A431 carcinoma and N-myc transformed Rat-1 cells. These data raise the possibility that neoplastic transformation leads to growth factor-independent expression of eIF-4E, thus facilitating continuous growth and replication of transformed cells.

Eukaryotic translation initiation factor 4E regulates expression of cyclin D1 at transcriptional and post-transcriptional levels.

Regulation of the cell cycle is orchestrated by cyclins and cyclin-dependent kinases. We have demonstrated previously that overexpression of eukaryotic translation initiation factor 4E (eIF-4E) in NIH 3T3 cells growing in 10% fetal calf serum leads to highly elevated levels of cyclin D1 protein without significant increase in cyclin D1 mRNA levels, suggesting that a post-transcriptional mechanism is involved. (Rosenwald, I. B., Lazaris-Karatzas, A., Sonenberg, N., and Schmidt, E. V. (1993) Mol. Cell. Biol. 13, 7358-7363). In the present research, we did not find any significant effect of eIF-4E on polysomal distribution of cyclin D1 mRNA. However, the total amount of cyclin D1 mRNA associated with polysomes was significantly increased by eIF-4E overexpression. Further, we determined that the levels of both cyclin D1 protein and mRNA are increased in serum-deprived cells overexpressing eIF-4E. Nuclear run-on experiments demonstrated that the rate of the cyclin D1 transcription is not down-regulated in serum-deprived cells overexpressing eIF-4E. Thus, elevated levels of eIF-4E may lead to increased transcription of the cyclin D1 gene, and this effect becomes visible when serum deprivation down-regulates the rate of cyclin D1 mRNA synthesis in control cells. However, artificial overexpression of cyclin D1 mRNA in serum-deprived cells in the absence of eIF-4E overexpression did not cause the elevation of cyclin D1 protein, and this overexpressed cyclin D1 mRNA accumulated in the nucleus, suggesting that one post-transcriptional role of eIF-4E is to transport cyclin D1 mRNA from the nucleus to cytoplasmic polysomes.

Elevated levels of cyclin D1 protein in response to increased expression of eukaryotic initiation factor 4E.

Cyclin D1 is a G1-specific cyclin that has been linked to lymphoid, parathyroid, and breast tumors. Recent studies suggested that high protein levels of cyclin D1 are not always produced when cyclin D1 mRNA is overexpressed in transfected cells, suggesting that posttranscriptional events may be important in cyclin D1 regulation. The mRNA cap-binding protein (eukaryotic initiation factor 4E [eIF-4E]) is a potential regulatory of several posttranscriptional events, and it can itself induce neoplastic transformation. Consequently, we examined eIF-4E as a potential regulator of cyclin D1. Overexpression of cyclin D1 mRNA in NIH 3T3 cells did not increase cyclin D1 protein. In contrast, overexpression of eIF-4E markedly increased the amount of cyclin D1 protein in NIH 3T3 cells. This increase was specific to cyclin D1 in comparison with the retinoblastoma gene product, c-Myc, actin, and eukaryotic initiation factor 2 alpha. We also examined cyclin D1 protein in cells expressing an estrogen receptor-Myc fusion protein because we previously found that eIF-4E increases after induction of c-myc function. In these cells, increased levels of eIF-4E protein were closely followed by increases in levels of cyclin D1 protein, but the level of cyclin D1 mRNA was not increased. We conclude that increases in cyclin D1 levels may result from increased expression of eIF-4E, and this regulation may be one determinant of cyclin D1 levels in the cell.

Increased expression of eukaryotic translation initiation factors eIF-4E and eIF-2 alpha in response to growth induction by c-myc.

Although activation of c-myc is a critical step in the development of lymphomas and other tumors, its normal function(s) in cell growth remain obscure because few myc-regulated genes are known. myc expression normally increases in response to mitogens and peaks in G1 when additional protein synthesis is required for cell-cycle progression. Protein synthesis is controlled by the availability of translation initiation factors, including the mRNA cap binding protein (eIF-4E) and the alpha subunit of the eIF-2 complex that binds the initiator Met-tRNA. Consequently we examined eIF-4E and eIF-2 alpha for evidence of regulation by c-myc. Expression of eIF-4E and eIF-2 alpha correlated with c-myc expression in fibroblasts after growth stimulation. In addition, expression of eIF-4E and eIF-2 alpha was increased in myc-transformed rat embryo fibroblasts but was not increased in ras-transformed cells. Transcription rates of eIF-4E and eIF-2 alpha mRNAs were regulated by c-myc in cells expressing an estrogen receptor-Myc fusion protein. Finally, electrophoretic mobility-shift assays identified a sequence element in the eIF-2 alpha promoter, TCCGCAT-GCGCG, which was specifically retarded by extracts of myc-expressing cells. c-myc is thought to deregulate the growth of cancer cells by activating transcription, suggesting that specific genes regulated by c-myc should also function as oncogenes. In previous studies these translation initiation factors could induce neoplastic growth because overexpression of eIF-4E-transformed cells and inhibition of a suppressor of eIF-2 alpha (eIF-2 alpha kinase) also caused malignant transformation. Our studies suggest that one important biological function of c-myc may be to increase cell growth by increasing expression of eIF-4E and eIF-2 alpha.

Protein synthesis inhibitors, like growth factors, may render resting 3T3 cells competent for DNA synthesis: a radioautographic and cell fusion study.

Serum-deprived (0.1-0.2%) resting NIH 3T3 mouse fibroblasts pre-incubated with cycloheximide (7.5 micrograms/ml), or puromycin (10 micrograms/ml), were fused with stimulated cells taken 10 h after changing the medium to one containing 10% serum, and DNA synthesis was investigated in the nuclei of monokaryons, homodikaryons and heterodikaryons using radioautography with the double-labelling technique. Pre-incubation of resting cells with inhibitors of protein synthesis for 1-4 h abolished their ability to suppress DNA synthesis in stimulated nuclei in heterokaryons. Three hours after the removal of cycloheximide from the medium, the resting cells acquired once again the inhibitory capacity for entry of stimulated nuclei into the S period. This inhibitory influence disappeared also in the case of post-fusion cycloheximide application as well as following an 8-12 h pre-treatment of resting cells with actinomycin D (1 microgram/ml) prior to fusion. Pre-incubation of resting cells for 12 h with PDGF (1 u/ml-1) followed by an 8-48 h incubation in serum-free medium stimulated the onset of DNA synthesis. A brief exposure (45 min) of resting cells to cycloheximide (7.5 micrograms/ml), or puromycin (7.5 micrograms/ml), exerted a similar effect, inducing by itself the entry of cells into the S period. The results support the assumption that acquirement, by resting cells, of competence for DNA replication includes as a necessary step the down-regulation of intracellular growth inhibitors whose formation depends on protein synthesis.

Lysosomal inhibitors stimulate resting NIH 3T3 cells to proliferate.

Lysosomal inhibitors (amino acid methyl esters) and platelet-derived growth factor stimulate resting NIH 3T3 cells to enter the S period. Incubation of cells in medium containing lysosomal inhibitors causes an increase in protein accumulation and does not disrupt lysosomes. The results indicate that proliferative homeostasis depends partially on the metabolic status of the cell and that catabolic processes activated in resting cells negatively influence prereplicative reactions.

Growth factors and endogenous control of cell proliferation.

Incubation of resting (serum-deprived) NIH 3T3 mouse fibroblasts for 12 hours with PDGF1) stimulates the onset of DNA synthesis. A brief exposure (45 minutes) of resting cells to inhibitors of protein synthesis (cycloheximide or puromycin) exerts similar effect inducing by itself the entry of cells into the S period. Incubation with EGF1) following pretreatment with either PDGF or protein synthesis inhibitors does not enhance the number of cells synthesizing DNA. The results support the assumption that the acquirement, by resting cells, of competence for DNA replication includes, as a necessary step, the down-regulation of intracellular growth inhibitors whose formation depends on protein synthesis.