Inhibition Of Global Protein Synthesis Research Articles

Hypoxic Regulation of Id-1 and Activation of the Unfolded Protein Response Are Aberrant in Neuroblastoma

The Id proteins play an important role in proliferation, differentiation and tumorigenesis. Many tumors are hypoxic, but it is unknown if expression of Id proteins is regulated in hypoxic cells. Here we show that Id-1 is down-regulated in multiple primary, immortalized, and neoplastic hypoxic cell lines, and the transcriptional repressor ATF-3 is both necessary and sufficient for this hypoxia-induced repression of Id-1. Hypoxic up-regulation of ATF-3 is due in part to activation of the unfolded protein response, a cellular stress response. Remarkably, we observe that the unfolded protein response is de-regulated in all neuroblastoma cell lines tested. Indeed, in the absence of ATF-3 the hypoxia-induced transcription factor HIF-1 up-regulates Id-1 in hypoxic neuroblastoma cells. Hypoxic neuroblastoma cells diminish expression of some neuronal differentiation markers, and forced expression of ATF-3 in hypoxic neuroblastoma cells represses Id-1 and prevents the loss of these markers. The divergent regulation of Id proteins in distinct hypoxic cells may explain some of the varied effects hypoxia has on cellular differentiation and proliferation.

Global Translational Responses to Oxidative Stress Impact upon Multiple Levels of Protein Synthesis

Global inhibition of protein synthesis is a common response to stress conditions. We have analyzed the regulation of protein synthesis in response to oxidative stress induced by exposure to H(2)O(2) in the yeast Saccharomyces cerevisiae. Our data show that H(2)O(2) causes an inhibition of translation initiation dependent on the Gcn2 protein kinase, which phosphorylates the alpha-subunit of eukaryotic initiation factor-2. Additionally, our data indicate that translation is regulated in a Gcn2-independent manner because protein synthesis was still inhibited in response to H(2)O(2) in a gcn2 mutant. Polysome analysis indicated that H(2)O(2) causes a slower rate of ribosomal runoff, consistent with an inhibitory effect on translation elongation or termination. Furthermore, analysis of ribosomal transit times indicated that oxidative stress increases the average mRNA transit time, confirming a post-initiation inhibition of translation. Using microarray analysis of polysome- and monosome-associated mRNA pools, we demonstrate that certain mRNAs, including mRNAs encoding stress protective molecules, increase in association with ribosomes following H(2)O(2) stress. For some candidate mRNAs, we show that a low concentration of H(2)O(2) results in increased protein production. In contrast, a high concentration of H(2)O(2) promotes polyribosome association but does not necessarily lead to increased protein production. We suggest that these mRNAs may represent an mRNA store that could become rapidly activated following relief of the stress condition. In summary, oxidative stress elicits complex translational reprogramming that is fundamental for adaptation to the stress.

Initiating morphological changes associated with long‐term facilitation in Aplysia is independent of transcription or translation in the cell body

In Aplysia, the growth of axonal arbor and the formation of new presynaptic varicosities are thought to contribute to long-term facilitation (LTF) produced by serotonin (5-HT). While it is known that there is a requirement for both transcription and translation in LTF and in the accompanying morphological changes, the mechanisms mediating the initiation and maintenance of these changes are poorly understood. We used long-term labeling of the presynaptic sensory neuron to carry out repeated imaging of axonal morphology, coupled with electrophysiology, to further elucidate the macromolecular requirements of this process. Robust synaptic facilitation, axonal growth, and the formation of axonal varicosities were elicited by 5-HT even when transcription was blocked with actinomycin. Increases in synaptic efficacy and varicosity number were detected 12 h after exposure to 5-HT but did not persist to 24 h. Even when sensory neuron cell bodies were removed, eliminating the contributions of both somal transcription and translation, 5-HT elicited these transient morphological and electrophysiological responses. New sensory varicosities contacting the postsynaptic neuron were filled with the neuropeptide sensorin. Under all conditions, global inhibition of protein synthesis completely blocked the formation of new axonal branches and varicosities. These results demonstrate that neither transcription nor somal translation is required to initiate the axonal growth that often accompanies long-term synaptic plasticity-protein synthesis in the axon is sufficient. Macromolecular synthesis in the cell body is, however, required to maintain the enlarged arbor.

Methionine restriction selectively targets thymidylate synthase in prostate cancer cells

Tumor cells are more sensitive to methionine restriction than normal tissues, a phenomenon known as methionine auxotrophy. Previous studies showed that 5-fluorouracil and methionine restriction act synergistically against a variety of tumors. The purpose of the current studies was to determine the molecular mechanism(s) underlying this synergy. 5-Fluorouracil is known to inhibit thymidylate synthase (TS), a key enzyme that transfers a methyl group from 5,10-methylene-tetrahydrofolate to dUMP during nucleotide biosynthesis. We found that methionine restriction reduced 5,10-methylene-tetrahydrofolate levels by 75% and selectively inhibited TS activity in PC-3 human prostate cancer cells within 24 hr, whereas it did not in normal prostate epithelial cells. The observed fall in TS activity was accompanied by a commensurate reduction in TS protein levels as determined by western blot analysis. In contrast, 5-fluorouracil inhibited TS activity by >90% but increased TS protein levels. This increase was abrogated by methionine restriction. Surprisingly, methionine restriction increased 3 H -leucine incorporation in PC-3 cells over the first 24 hr, suggesting that reduction of TS levels was not simply due to global protein synthesis inhibition. Methionine restriction also significantly reduced the ratio of dUMP to dTTP in PC-3 cells, creating an imbalanced nucleotide pool. These results suggest that synergy between methionine restriction and 5-fluorouracil is attributable to multiple factors, including depletion of reduced folates, selective inhibition of TS, and creation of an imbalanced nucleotide pool. Dietary and/or enzymatic methionine restriction combined with 5-fluoruracil has great promise as a novel treatment for advanced cancer.

Regulation of elongation factor-2 kinase by pH.

Elongation factor-2 kinase (eEF-2K) is a Ca(2+)/calmodulin-dependent protein kinase that phosphorylates and inactivates eEF-2 and that can regulate the rate of protein synthesis at the elongation stage. Here we report that a slight decrease in pH, within the range observed in vivo, leads to a dramatic activation of eEF-2K. The activity of eEF-2K in mouse liver extracts, as well as the activity of purified recombinant human eEF-2K, is low at pH 7.2-7.4 and is increased by severalfold when the pH drops to 6.6-6.8. eEF-2K requires calmodulin for activity at neutral as well as acidic pH. Kinetic studies demonstrate that the pH does not affect the K(M) for ATP or eEF-2 and activation of eEF-2K at acidic pH is due to an increase in V(max). To analyze the potential role of eEF-2K in regulating protein synthesis by pH, we constructed a mouse fibroblast cell line that expresses eEF-2K in a tetracycline-regulated manner. Overexpression of eEF-2K led to a decreased rate of protein synthesis at acidic pH, but not at neutral pH. Our results suggest that pH-dependent activation of eEF-2K may play a role in the global inhibition of protein synthesis during tissue acidosis, which accompanies such processes as hypoxia and ischemia.

Sequence‐selective DNA binding drugs mithramycin A and chromomycin A3 are potent inhibitors of neuronal apoptosis induced by oxidative stress and DNA damage in cortical neurons

Global inhibitors of RNA or protein synthesis such as actinomycin D or cycloheximide abrogate neuronal apoptosis induced by numerous pathological stimuli in vitro and in vivo. The clinical application of actinomycin D or cycloheximide to human neurological disease has been limited by the toxicities of these agents. To overcome these toxicities, strategies must be developed to inhibit selectively the expression of deleterious proapoptotic proteins, while leaving the expression of antiapoptotic, proregeneration, and other critical homeostatic proteins unperturbed. Mithramycin A (trade name Plicamycin) is an aureolic acid antibiotic that has been used in humans to treat hypercalcemia and several types of cancers. This class of agents is believed to act, in part, by selectively inhibiting gene expression by displacing transcriptional activators that bind to G-C-rich regions of promoters. Here we demonstrate that mithramycin A and its structural analog chromomycin A3 are potent inhibitors of neuronal apoptosis induced by glutathione depletion-induced oxidative stress or the DNA-damaging agent camptothecin. We correlate the protective effects of mithramycin A with its ability to inhibit enhanced DNA binding of the transcription factors Sp1 and Sp3 to their cognate "G-C" box induced by oxidative stress or DNA damage. The protective effects of mithramycin A cannot be attributed to global inhibition of protein synthesis. Together, these results suggest that mithramycin A and its structural analogs may be effective agents for the treatment of neurological diseases associated with aberrant activation of apoptosis and highlight the potential use of sequence-selective DNA-binding drugs as neurological therapeutics.

Sequence‐selective DNA binding drugs mithramycin A and chromomycin A3 are potent inhibitors of neuronal apoptosis induced by oxidative stress and DNA damage in cortical neurons

Global inhibitors of RNA or protein synthesis such as actinomycin D or cycloheximide abrogate neuronal apoptosis induced by numerous pathological stimuli in vitro and in vivo. The clinical application of actinomycin D or cycloheximide to human neurological disease has been limited by the toxicities of these agents. To overcome these toxicities, strategies must be developed to inhibit selectively the expression of deleterious proapoptotic proteins, while leaving the expression of antiapoptotic, proregeneration, and other critical homeostatic proteins unperturbed. Mithramycin A (trade name Plicamycin) is an aureolic acid antibiotic that has been used in humans to treat hypercalcemia and several types of cancers. This class of agents is believed to act, in part, by selectively inhibiting gene expression by displacing transcriptional activators that bind to G-C-rich regions of promoters. Here we demonstrate that mithramycin A and its structural analog chromomycin A3 are potent inhibitors of neuronal apoptosis induced by glutathione depletion-induced oxidative stress or the DNA-damaging agent camptothecin. We correlate the protective effects of mithramycin A with its ability to inhibit enhanced DNA binding of the transcription factors Sp1 and Sp3 to their cognate “G-C” box induced by oxidative stress or DNA damage. The protective effects of mithramycin A cannot be attributed to global inhibition of protein synthesis. Together, these results suggest that mithramycin A and its structural analogs may be effective agents for the treatment of neurological diseases associated with aberrant activation of apoptosis and highlight the potential use of sequence-selective DNA-binding drugs as neurological therapeutics. Ann Neurol 2001;49:345–354

Regulation of prostate cancer cell division by glucose.

Previous studies have shown that rapid cell proliferation is associated with elevated glucose consumption. However, those studies did not establish whether glucose is required for prostate cancer cell proliferation or define the molecular mechanisms by which glucose regulates cell division. We addressed these issues by studying two metastatic human prostate cancer cell lines: DU145, which is androgen independent and highly proliferative; and LNCaP, which is androgen dependent and relatively slow growing. We found that proliferation of DU145 cells was significantly inhibited by reduction of glucose in the medium to 0.5 g/L, which is half the physiologic concentration, whereas LNCaP cells grew at control rates even in the presence of only 0.05 g/L glucose. Glucose deprivation of DU145 cells caused a 90% reduction in DNA synthesis; a 10-20-fold reduction in cyclins D and E and CDK4 levels; and cell cycle arrest in G0-G1. However, glucose deprivation did not cause global inhibition of protein synthesis, since mutant p53 levels increased in glucose-deprived DU145 cells. This observed increase in mutant p53 levels was not associated with a rise in p21 levels. Glucose deprivation of DU145 cells also led to apparent dephosphorylation of mutant retinoblastoma (RB) protein. We conclude that: 1) high levels of glucose consumption are required for rapid proliferation of androgen-independent prostate cancer cells, 2) glucose may not be required for slow growth of androgen-dependent prostate cancer cells, and 3) glucose promotes passage of cells through early G1 by increasing the expression of several key cell cycle regulatory proteins that normally inhibit RB function.

Disturbances of calcium homeostasis within the endoplasmic reticulum may contribute to the development of ischemic-cell damage

It is widely accepted that disturbances of calcium homeostasis play a key role in the development of cell damage produced by transient cerebral ischemia. It is believed that the sharp increase in cytosolic calcium activity during ischemia activates a cascade of calcium-dependent metabolic processes which ultimately destroy the integrity of the cell. However, it has never been taken into account that ischemic cell damage may, at least in part, be caused by a disturbance of calcium homeostasis within the endoplasmic reticulum after transient cerebral ischemia. In fact, depletion of the endoplasmic reticulum from calcium induces metabolic changes resembling, in many respects, those produced by transient cerebral ischemia: it causes an inhibition of the activity of the eucaryotic initiation factor eIF-2α (by phosphorylation), a disaggregation of polyribosomes and thus an inhibition of global protein synthesis, and an increased expression of certain genes such as transcription factors (c- fos and c- jun) and the glucose-related protein grp78. Finally, a depletion of calcium in the endoplasmic reticulum induces tissue damage within the brain and triggers apoptosis in neuronal and non-neuronal cells. It is therefore concluded that cell damage induced by transient ischemia may, at least in part, be caused by a disturbance of calcium homeostasis within the endoplasmic reticulum.

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.

Effect of Endotoxin-induced Cell Injury on 70-kD Heat Shock Proteins in Bovine Lung Endothelial Cells

Heat shock proteins (HSPs) have been remarkably conserved throughout evolution. It has been assumed that induction of HSPs remains a stereotypic response to injury, important for survival of eukaryotic cells during euthermic injury. However, there are few studies of this phenomenon in endothelial cells, and none in pulmonary endothelial cells. We studied the induction of synthesis of 70-kD proteins in bovine pulmonary artery endothelial cells (BPAECs) in response to heat shock and to euthermic injury induced by bacterial endotoxin. First, in response to heat, BPAECs showed rapid and reversible heat-induced synthesis of 70-kD proteins, readily detectable by one-dimensional SDS-PAGE of [35S]methionine-labeled BPAECs. Heat shock at 42 degrees C for 3 h or 43 degrees C for 2 h suppressed total protein synthesis by 30% (P less than 0.001) but an increased rate of synthesis of 70-kD protein continued, representing an increasing fraction of total protein synthesis. Heat-induced synthesis of 70-kD protein returned to baseline levels 8 h after heat shock. Northern analysis showed that mRNA for a protein homologous to a conserved amino acid sequence in the family of species-homologous 70-kD heat shock proteins (HSP 70) was induced by a 15-min incubation at 42 degrees C and remained detectably increased for 6 h. We next assessed whether euthermic injury by bacterial endotoxin (LPS) generated a similar response. LPS was cytotoxic by BPAECs as assessed morphologically, by release of 51Cr from prelabeled cells, and by a significant suppression of total protein synthesis (range, 35 to 70%; P less than 0.001). Despite cytotoxicity, LPS did not induce 70-kD protein at a level that could be detected by SDS-PAGE, and no increase in mRNA for HSP 70 was detected by Northern analysis. LPS-injured BPAECs remained "competent" to induce both 70-kD proteins and mRNA for HSP 70 in response to heat shock. We conclude that at least quantitatively, induction of HSP 70 by BPAECs is not a stereotypic response to injury but rather is at least relatively injury-specific. However, competence to induce HSP 70 appears to be extremely resilient: it is retained in dysfunctional BPAECs in the face of profound inhibition of global protein synthesis, suggesting an important homeostatic role.

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.

Regulation of protein synthesis in root, shoot and embryonic tissues of germinating barley during salinity stress

Abstract Protein synthesis during seed germination, a stage vulnerable to salinity stress, was investigated. The responses of barley genotypes, CM72 (California Mariout 72) and Prato, toward salinity were different during seed germination. Germination of CM72 was unaffected up to 0.34 kmol m−3 (2%) NaCl, but that of Prato was reduced 30% by 0.17 kmol m 3 NaCl and 75% by 0.34 kmol m−3 NaCl. Therefore, the former genotype is relatively more salt‐tolerant than the latter. Protein synthesis in roots, shoots, and embryos was investigated in these two genotypes before and after salinity stress. The uptake of S‐methionine and its incorporation into protein were significantly reduced by salinity in both genotypes. The inhibition of global protein synthesis was significant in roots and shoots. Proteins from different tissues were resolved by single and two dimensional gels. The steady‐state protein levels were maintained remarkably well during salinity stress in roots and shoots. Likewise, proteins in germinating embryos were stable except for a 42‐kilodalton protein unique to the salt tolerant genotype which was apparently degraded during salinity stress. Salinity, around 0.34 kmol m−3 NaCl, induced both quantitative and qualitative changes in the expression of some proteins labelled in vivo. The quantitative changes included repression or enhancement of synthesis of selected groups of proteins. Around 8% of the nearly 400 resolved proteins in a tissue was affected this way. Some of the proteins in this category were specific to each genotype. About 1 % of the total showed qualitative changes; these proteins were expressed only during salinity stress. In roots, two proteins (28, 41.7 kilodaltons) were detected in CM72 and five (28, 45, 60.5, 76.5, 82.5 kilodaltons) in Prato; only the 28‐kilodalton protein was common to both genotypes. In shoots, four proteins (45, 60.5, 76.5, 82.5 kilodaltons) were found only in Prato and these were similar to those induced in roots. The four new proteins (32, 37.5, 89, 92 kilodaltons) in germinating embryos were apparently induced only in CM72; these were distinctly different from those detected in developed roots and shoots. The unique protein changes induced by salinity stress during germination (this study) and seedling growth studies reported earlier (Ramagopal, 1987b) are apparently different. The findings demonstrate that ontogeny plays an important role in the expression of tissue‐specific proteins during salinity stress in the salt tolerant and sensitive barley genotypes.