Heat-Shock Response in Heat-Tolerant and Nontolerant Variants of Agrostis palustris Huds

The heat-shock response in heat-tolerant variants (SB) and non-tolerant variants (NSB) of creeping bentgrass (Agrostis palustris Huds.) was investigated. Both variants were derived from callus initiated from a single seed of the cultivar Penncross. SB and NSB synthesized heat-shock proteins (HSPs) of 97, 83, 70, 40, 25, and 18 kD. There were no major differences between SB and NSB in the time or temperature required to induce the heat-shock response. When the HSPs synthesized by SB and NSB were analyzed by two-dimensional gel electrophoresis, it was apparent that SB synthesized two to three additional members of the HSP27 family, which were smaller (25 kD) and more basic than those synthesized by NSB. Analysis of F1 progeny of NSB x SB indicated that 7 of the 20 progeny did not synthesize the additional HSP25 polypeptides. These progeny were significantly less heat tolerant than progeny that did synthesize the additional HSP25 polypeptides. The X2 test of independence (X2 = 22.45, P < 0.001) indicated that heat tolerance and the presence of the additional HSP25 polypeptides are linked traits.     

HSP70 mRNA translation in chicken reticulocytes is regulated at the level of elongation

During heat shock of chicken reticulocytes the synthesis of a single heat shock protein, HSP70, increases greater than 10-fold, while the level of HSP70 mRNA increases less than 2-fold during the same period. Comparison of the in vivo levels of HSP70 and beta-globin synthesis with their mRNA abundance reveals that the translation of HSP70 mRNA is repressed in normal reticulocytes and is activated upon heat shock. In its translationally repressed state HSP70 mRNA is functionally associated with polysomes based on sedimentation analysis of polysomes from untreated or puromycin-treated cells and by analysis of in vitro "run-off" translation products using isolated polysomes. Treatment of control and heat shocked cells with the initiation inhibitor pactamycin reveals that elongation of the HSP70 nascent peptide is not completely arrested, but is slower in control cells. Furthermore, the inefficient translation of HSP70 mRNA in vivo is not due to the lack of an essential translation factor; HSP70 mRNA is efficiently translated in chicken reticulocyte translation extracts as well as in heterologous rabbit reticulocyte extracts. Our results reveal that a major control point for HSP70 synthesis in reticulocytes is the elongation rate of the HSP70 nascent peptide.     

Heat shock gene expression in Xenopus laevis A6 cells in response to heat shock and sodium arsenite treatments

Continuous exposure of a Xenopus laevis kidney epithelial cell line, A6, to either heat shock (33 degrees C) or sodium arsenite (50 microM) resulted in transient but markedly different temporal patterns of heat-shock protein (HSP) synthesis and HSP 70 and 30 mRNA accumulation. Heat-shock-induced synthesis of HSPs was detectable within 1 h and reached maximum levels by 2-3 h. While sodium arsenite induced the synthesis of some HSPs within 1 h, maximal HSP synthesis did not occur until 12 h. The pattern of HSP 70 and 30 mRNA accumulation was similar to the response observed at the protein level. During recovery from heat shock, a coordinate decline in HSPs and HSP 70 and 30 mRNA was observed. During recovery from sodium arsenite, a similar phenomenon occurred during the initial stages. However, after 6 h of recovery, HSP 70 mRNA levels persisted in contrast to the declining HSP 30 mRNA levels. Two-dimensional polyacrylamide gel electrophoresis revealed the presence of 5 HSPs in the HSP 70 family, of which two were constitutive, and 16 different stress-inducible proteins in the HSP 30 family. In conclusion, heat shock and sodium arsenite induce a similar set of HSPs but maximum synthesis of the HSP is temporally separated by 12-24 h.     

Regulation of heat-shock protein synthesis in chicken muscle culture during recovery from heat shock

Exposure of chick myotube cultures to a temperature (45 degrees C) higher than their normal growing temperature (37 degrees C) caused extensive synthesis of three major polypeptides of Mr = 25 000, 65 000 and 81 000 referred to as 'heat-shock polypeptides' (hsps). When these cells were allowed to recover from heat-shock treatment at 37 degrees C for 6-8 h, the rate of accumulation of isotope into the 65 000-Mr and 81 000-Mr hsps declined to levels comparable to those in control cultures maintained at 37 degrees C. However, incorporation of isotope in the 25 000-Mr hsp continued at an elevated rate for a longer period than the 65 000-Mr and 81 000-Mr hsps. When heat-shocked cells were allowed to recover at 37 degrees C in the presence of actinomycin D to block new mRNA synthesis, the hsp synthesis as measured by the incorporation of radioactive isotope in these polypeptides continued at levels comparable to those in heat-shocked cells prior to recovery. The block of recovery by actinomycin D was due to the presence of a greater amount of functional hsp mRNAs in the polysomes as compared to untreated controls. The role of competition between the mRNAs for hsps and normal cellular proteins for the translation machinery in regulating protein synthesis during the recovery from heat shock has been discussed.     

The Drosophila hsp70 message is rapidly degraded at normal temperatures and stabilized by heat shock

When heat-shocked Drosophila cells are returned to normal temperatures, heat-shock protein (HSP) synthesis is repressed and normal protein synthesis is restored. The repression of HSP70 synthesis is accompanied by the selective degradation of its mRNA. We have engineered cells to produce a modified hsp70 mRNA that behaves exactly as the wild-type message. That is, it is stable during heat shock but degraded during recovery when protein synthesis returns to normal. When this message, placed under the control of the metallothionein promoter, is induced at normal temperatures it is rapidly degraded, with a half life of 15-30 min. Apparently, the hsp70 message is inherently unstable. During heat-shock, degradation of the message is suspended; during recovery degradation is restored.     

Phosphorylation-dependent cellular localization and thermoprotective role of heat shock protein 25 in hippocampal progenitor cells

The present study examined phosphorylation-dependent cellular localization and the thermoprotective role of heat shock protein (HSP) 25 in hippocampal HiB5 cells. HSP25 was induced and phosphorylated by heat shock (at 43 degrees C for 3 h). HSP25, which was located in the cytoplasm in the normal condition, translocated into the nucleus after the heat shock. Transfection experiments with hsp27 mutants in which specific serine phosphorylation residues (Ser(78) and Ser(82)) were substituted with alanines or aspartic acids showed that phosphorylation of HSP27 is accompanied by its nuclear translocation. Phosphorylation of mitogen-activated protein kinases (MAPKs) such as p38 MAPK and ERK was markedly increased by the heat shock, and SB203580 (a p38 MAPK kinase inhibitor) and/or PD098059 (a MEK inhibitor) inhibited the phosphorylation of HSP25, indicating that p38 MAPK and ERK are upstream regulators of HSP25 phosphorylation in the heat shock condition. In the absence of heat shock, actin filament stability was not affected by SB203580 and/or PD098059. Heat shock caused disruption of the actin filament and cell death when phosphorylation of HSP25 was inhibited by SB203580 and/or PD098059. In addition, actin filament was more stable in Asp(78,82)-hsp27 (mimics the phosphorylated form) transfected HiB5 cells than in the normal and Ala(78,82)-hsp27 (nonphosphorylative form) transfected cells. In accordance with actin filament stability, the survival rate against the heat shock increased markedly in Asp(15,78,82)-hsp27 expressing HiB5 cells but decreased in Ala(15,78,82)-hsp27 expressing cells. These results support the idea that phosphorylation of HSP25 is critical for the maintenance of actin filament and enhancement of thermoresistance. Interestingly, HSP25 was dephosphorylated and returned to cytoplasm in a recovery time-dependent manner. This phenomenon was accompanied by an increment of apoptotic cell death as determined by nuclear and DNA fragmentation and fluorescence-activated cell sorter analysis. These results suggest that nuclear-translocated HSP25 might function to protect nuclear structure, thereby preventing apoptotic cell death.     

The heat-shock response in Drosophila KC 161 cells. mRNA competition is the main explanation for reduction of normal protein synthesis

The effect of heat shock on protein synthesis in the Drosophila melanogaster KC 161 tissue culture cell line was examined with a view to investigating the mechanism underlying the acute reduction in normal cellular protein synthesis typical of heat-shocked Drosophila cells. However, at 36-37 degrees C, the optimum temperature for induction of the 70-kDa heat-shock protein, this cell line did not show such a response. The synthesis of a very limited number of proteins was abruptly turned off following heat shock in the presence or absence of actinomycin, but the rate of synthesis of the majority of normal cellular proteins declined slowly over a three-hour period. Incubation of heat-shocked cells in hypertonic media increased the relative proportion of protein synthesis directed towards heat-shock proteins (as opposed to normal cellular proteins). Incubation with low concentrations of cycloheximide had the converse effect and resulted in a preferential increase in the size of polysomes translating normal cellular mRNAs, greater than the increase in size of polysomes synthesising heat-shock proteins. Heat shock also resulted in some mRNAs being almost completely displaced from polysomes into the postribosomal supernatant. These observations suggest that competition between normal cellular mRNAs and increasing amounts of heat-shock mRNAs with a higher affinity for the translation machinery was the main explanation for the gradual reduction in the synthesis of normal cellular proteins, although a slight reduction in overall translation initiation rates cannot be excluded as a subsidiary cause. The results demonstrate that the acute reduction in normal cellular protein synthesis seen in other Drosophila cell lines is not an integral and necessary feature of the heat-shock response in this organism, which makes it unlikely that the mechanism of this acute shut-off is intimately connected with the mechanism of induction of heat-shock mRNAs.     

Preferential translation of heat shock mRNAs in HeLa cells deficient in protein synthesis initiation factors eIF-4E and eIF-4 gamma.

Expression of antisense RNA against eukaryotic translation initiation factor 4E (eIF-4E) in HeLa cells causes a reduction in the levels of both eIF-4E and eIF-4 gamma (p220) and a concomitant decrease in the rates of both cell growth and protein synthesis (De Benedetti, A., Joshi-Barve, S., Rinker-Schaffer, C., and Rhoads, R. E. (1991) Mol. Cell Biol. 11, 5435-5445). The synthesis of most proteins in the antisense RNA-expressing cells (AS cells) is decreased, but certain proteins continue to be synthesized. In the present study, we identified many of these as stress-inducible or heat shock proteins (HSPs). By mobilities on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by reactivity with monoclonal antibodies generated against human HSPs, four of these were shown to be HSP 90, HSP 70, HSP 65, and HSP 27. The steady-state levels of HSP 90, 70, and 27 were elevated in relation to total protein in AS cells. Pulse labeling and immunoprecipitation indicated that HSP 90 and HSP 70 were synthesized more rapidly in AS cells than in control cells. The accelerated synthesis of HSPs in the AS cells was not due, however, to increased mRNA levels; the levels of HSP 90 and 70 mRNAs either remained the same or decreased after induction of antisense RNA expression. Actin mRNA, a typical cellular mRNA, was found on high polysomes in control cells but shifted to smaller polysomes in AS cells, as expected from the general decrease in translational initiation caused by eIF-4E and eIF-4 gamma depletion. HSP 90 and 70 mRNAs showed the opposite behavior; they were associated with small polysomes in control cells but shifted to higher polysomes in AS cells. These results demonstrate that HSP mRNAs have little or no requirement in vivo for the cap-recognition machinery and suggest that these mRNAs may utilize an alternative, cap-independent mechanism of translational initiation.     

Enhanced constitutive expression of the 27-kDa heat shock proteins in heat-resistant variants from Chinese hamster cells

Four heat-resistant variants were isolated after treatment of Chinese hamster lung cells with the mutagen ethyl methane sulfonate, followed by a single-step selection procedure consisting in a severe hyperthermic treatment of 4 h at 44 degrees C. The isolated clones had a stable resistant phenotype for at least 150 generations during which they showed a 5,000-fold increased survival to a 4-h treatment at 44 degrees C when compared to wild-type cells. Comparative two-dimensional electrophoretic analyses of proteins revealed that, like induced thermotolerant wild-type cells (i.e., cells induced to a transient physiological state of thermotolerance by a sublethal heat conditioning treatment administered 18 h before), the heat-resistant variants had, at normal temperature, an increased content of a heat-shock protein with Mr of 27,000 (HSP27). In three of the four heat-resistant variants, the increased content of HSP27 was correlated with a two-fold increase in the constitutive level of the mRNA encoding HSP27. Chinese hamster HSP27 is composed of three species that differ in their relative isoelectric point, among which the two most acidic forms are phosphoproteins. In both the heat-resistant variant and wild-type cells, heat shock induces a rapid enhancement of the phosphorylation of HSP27: maximal phosphorylation occurs within 10 min upon changing the incubation temperature from 35 degrees to 44 degrees C. A concomitant shift in silver-staining intensity is rapidly detectable between the three isoforms, which seems to indicate that the two phosphorylated species represent post-translational modifications of the more basic species. It is concluded that most likely the enhanced expression of HSP27 is linked to the resistant phenotype of the variants. The study provides supporting evidence that both the content and phosphorylation status of HSP27 are determining factors in the ability of cells to survive hyperthermic treatments.     

The Constitutive Heat Shock Protein-70 Is Required for Optimal Expression of Myelin Basic Protein During Differentiation of Oligodendrocytes

To further elucidate the role of the constitutive heat shock protein-70 (HSC70) as a chaperone for the synthesis of myelin basic protein (MBP), HSC70 content was decreased in oligodendrocyte precursor cells prior to MBP expression either by transfection with an antisense oligonucleotide specific for HSC70, or by exposure to low levels of quercetin, a bioflavonoid known to decrease synthesis of HSC70. As these cells underwent differentiation in vitro, antisense treatment decreased HSC70 levels to 66% of controls. At the same time, a sharp induction resulted in the stress-inducible heat shock protein-70 (HSP70). Levels of two other stress proteins increased as well, namely, the 25-kDa heat shock protein (HSP25) and the 78-kDa glucose regulated protein (GRP78). MBP synthesis proceeded over a normal time course, but at only 50% of control values. As HSC70 content returned to normal, MBP synthesis was also restored to normal levels. Quercetin reduced the expression of HSC70 to an even greater extent than transfection, and prevented the induction of HSP70. In contrast to antisense-treated cells, MBP synthesis was essentially blocked in quercetin-treated cells even though levels of HSP25 and GRP78 increased. Taken together, these observations (a) indicate that HSP70 partially compensates for decreased chaperoning of nascent MBP by HSC70 (HSC70 and HSP70 are closely related and perform similar functions); (b) preclude the involvement of HSP25 and GRP78 in MBP synthesis; and (c) emphasize the requirement of HSC70 for optimal synthesis of MBP.     

The cytoplasmic pH, ATP content and total protein synthesis rate during heat-shock protein inducing treatments in yeast

In S. cerevisiae the induction of heat-shock protein (HSP) synthesis is accompanied by a decrease in the cytoplasmic and vacuolar pH as determined by means of [31P]NMR spectroscopy. The relationship of HSP synthesis and acidification of the cytoplasmic pH is dose-dependent under a variety of treatments (temperature increases (23-32 degrees C), addition of 2,4-dinitrophenol (greater than 1 mM), sodium arsenite (greater than 3.75 X 10(-5) M) or sodium cyanide (greater than 10 mM]. Changes in the intracellular pH occur within 5 min after treatment, attain a maximum within 30 min and are subsequently stable. HSPs 98, 85 and 70 show maximum synthesis rates 1-2 h after a 40 degrees C heat shock. The synthesis rates then decline. HSPs 56, 44 and 33 reveal a smaller and slower increase and almost no decrease in the synthesis rate within 4 h at 40 degrees C. The similar dose dependencies of HSP synthesis and cytoplasmic pH. as well as the immediate response of the pH, can also be demonstrated in the mitochondrial mutant of S. cerevisiae (Q0). This result indicates that the heat-shock response is mainly independent of intact oxidative phosphorylation. No correlation was observed between HSP synthesis rate and total intracellular ATP content.     

Translational regulation of the synthesis of a major heat shock protein in HeLa cells

The synthesis of a major heat shock protein (HSP 70) was measured in HeLa cells incubated at 42.5 degrees C and then transferred to 37 degrees C or 30 degrees C. After 90 min, synthesis of HSP 70 decreased by 54 and 85%, respectively, whereas HSP 70 mRNA was reduced at most by 20%. Therefore, the reduced synthesis of HSP 70 could not be accounted for by mRNA turnover. HSP 70 was associated with large polyribosomes (6-10 ribosomes) in cells kept at 42.5 degrees C, but with medium or small polyribosomes in cells transferred to 37 degrees C or 30 degrees C (5-6 or 2-3 ribosomes, respectively). Addition of puromycin to these cells resulted in the release of all ribosomes from HSP 70 mRNA, indicating that they were translationally active. The regulation of HSP 70 synthesis was investigated in cell-free systems prepared from heat-shocked or control cells and incubated at 30 degrees C and 42 degrees C. After 5 min at 42 degrees C, the cell-free system from heat-shocked cells synthesized protein at 3 times the rate of the control cell-free system. This difference was in large part due to synthesis of HSP 70. Addition of HSP mRNA to the control cell-free system stimulated protein synthesis at 42 degrees C, but not at 30 degrees C. These findings suggest that translation of HSP 70 mRNA is specifically promoted at high temperature and repressed during recovery from heat shock by regulatory mechanisms active at the level of initiation.     

Synthesis of characteristic proteins in nutrient-depleted cell suspension cultures of parsley

Cell suspension cultures of parsley (Petroselinum crispum) exhibited an altered pattern of protein synthesis after transfer from complete growth medium to water or medium containing no macronutrients. Similar changes occurred when cultures were grown in the original medium until the nutrients were depleted. The effect was reversible upon transfer to fresh medium and was not observed during regular subculturing of the cells. While total protein synthesis decreased sharply after nutrient depletion, the synthesis of a few characteristic proteins (starvation-related proteins, STPs) increased strongly. The protein labeled at highest rates with [³⁵S]methionine in vivo (STP 62) had an apparent molecular weight of about 62000 and a pI of about 6.3. Although its increased rate of synthesis was therefore easily detected by labeling in vivo, translation of mRNA in vitro did not give comparable results. Thus, regulatory control may be exerted mainly at the level of translation. Synthesis of STP ceased rapidly when heat shock (37° C) was applied under conditions of nutrient depletion, whereas heat-shock proteins were strongly induced.Abbreviations HSP heat-shock protein - STP starvation-related protein     

Cellular localization of HSP23 during Drosophila development and following subsequent heat shock

The low-molecular-weight heat-shock protein HSP23 is synthesized in the absence of heat shock during Drosophila development. Here, I present a quantitative analysis of this phenomenon and describe the cellular localization of this protein during normal development and after a subsequent heat shock. HSP23 is first detected in the late third instar larvae and continues to accumulate reaching a maximum level in late pupae. In a 1-week-old adult, HSP23 can no longer be detected. Following lysis of whole pupae, HSP23 is found in the soluble lysate fraction in a form which sediments between 10 and 20 S. Exposure of larvae, pupae, and the adult fly to heat stress (37 degrees C) results in an increased amount of HSP23 which, however, is recovered in an insoluble particulate form following insect lysis. During recovery from heat shock, HSP23 is again found in the soluble 10- to 20-S lysate fraction. In pupae which are exposed to a severe heat stress (41 degrees C) HSP23 remains in the pellet fraction after the heat stress and no pupae are able to emerge as adult flies. However, when pupae are first exposed to a mild heat-shock treatment prior to the 41 degrees C stress, the thermotolerance process is induced and HSP23 is again rapidly found in the soluble lysate fraction during the recovery from heat shock. These observations suggest a possible correlation between the survival of pupae after heat shock and the recovery of HSP23 in the soluble lysate fraction as 10- to 20-S structures after the heat shock.     

hsp80 of Neurospora crassa: cDNA cloning, gene mapping, and studies of mRNA accumulation under stress.

Using mRNA isolated from Neurospora crassa mycelium, grown for 14 h at normal growth temperature of 28 degrees C, and heat shocked for 1 h at 48 degrees C, a cDNA library was prepared in the expression vector lambda gt11. Following immunoscreening of this library with a polyclonal antiserum raised against a 80-kilodalton heat-shock protein (HSP80), cDNA clones containing 1.1- and 1.4-kilobase inserts were selected. Analysis of the partial nucleotide sequence and the deduced amino acid sequence of the cDNA clones revealed a remarkable extent of homology with other eukaryotic stress-90 family proteins; 85% identity of the amino acid sequence with that of yeast HSP90(82) was seen. The C-terminal end of the sequence contained the MEEVD motif, characteristic of eukaryotic stress proteins with a predominantly cytosolic localization. The gene for N. crassa HSP80 was mapped to the right arm of linkage group V, using restriction fragment length polymorphism mapping. Its expression during heat shock and recovery was monitored by probing Northern blots of RNA isolated from mycelium grown under various stress conditions.     

Analysis of the control of citrulline synthesis in isolated rat-liver mitochondria

Irradiation of chicken muscle cells with ultraviolet light (254 nm) to cross-link RNA and protein moieties was used to examine the polypeptide complements of cytoplasmic mRNA-protein complexes (mRNP). The polypeptides of translationally active mRNP complexes released from polysomes were compared to the repressed nonpolysomal cytoplasmic (free) mRNP complexes. In general, all of the polypeptides present in free mRNPs were also found in the polysomal mRNPs. In contrast to polysomal mRNPS, polypeptides of Mr 28 000, 32 000, 46 000, 65 000 and 150 000 were either absent or present in relatively smaller quantities in free mRNP complexes. On the other hand, the relative proportion of polypeptides of Mr 130 000 and 43 000 was higher in free mRNPs than in polysomal mRNP complexes. To examine the role of cytoplasmic mRNP complexes in protein synthesis or mRNA metabolism, the changes in these complexes were studied following (a) inhibition of mRNA synthesis and (b) heat-shock treatment to alter the pattern of protein synthesis. Actinomycin D was used to inhibit mRNA synthesis in chick myotubes. The possibility of newly synthesized polypeptides of cytoplasmic mRNP complexes being assembled into these complexes in the absence of mRNA synthesis was examined. These studies showed that the polypeptides of both free and polysomal mRNP complexes can bind to pre-existing mRNAs, therefore suggesting that polypeptides of mRNP complexes can be exchanged with a pool of RNA-binding proteins. In free mRNP complexes, this exchange of polypeptides is significantly slower than in the polysomal mRNP complexes. Heat-shock treatment of chicken myotubes induces the synthesis of three polypeptides of Mr = 81 000, 65 000 and 25 000 (heat-shock polypeptides). Whether this altered pattern of protein synthesis following heat-shock treatment could affect the polypeptide composition of translationally active polysomal mRNPs was examined. The results of these studies show that, compared to normal cells, more newly synthesized polypeptides were assembled into polysomal mRNPs following heat-shock treatment. A [35S]methionine-labeled polypeptide of Mr = 80 000 was detected in mRNPs of heat-shocked cells, but not of normal cells. This polypeptide was, however, detected by AgNO3 staining of the unlabeled polypeptide of mRNP complexes of normal cells. These results, therefore, suggest that the assembly of newly synthesized 80 000-Mr polypeptide to polysomal mRNPs was enhanced following induction of new heat-shock mRNAs. The results of these studies reported here have been discussed in relation to the concept that free mRNP complexes are inefficiently translated in vivo.(ABSTRACT TRUNCATED AT 400 WORDS)     

Roles of YB-1 under arsenite-induced stress: Translational activation of HSP70 mRNA and control of the number of stress granules

Background

When cells become stressed, they form stress granules (SGs) and show an increase of the molecular chaperone HSP70. The translational regulator YB-1 is a component of SGs, but it is unclear whether it contributes to the translational induction of HSP70 mRNA. Here we examined the roles of YB-1 in SG assembly and translational regulation of HSP70 mRNA under arsenite-induced stress.

Method

Using arsenite-treated NG108-15 cells, we examined whether YB-1 was included in SGs with GluR2 mRNA, a target of YB-1, and investigated the interaction of YB-1 with HSP70 mRNA and its effect on translation of the mRNA. We also investigated the distribution of these mRNAs to SGs or polysomes, and evaluated the role of YB-1 in SG assembly.

Results

Arsenite treatment reduced the translation level of GluR2 mRNA; concomitantly, YB-1-bound HSP70 mRNA was increased and its translation was induced. Sucrose gradient analysis revealed that the distribution of GluR2 mRNA was shifted from heavy-sedimenting to much lighter fractions, and also to SG-containing non-polysomal fractions. Conversely, HSP70 mRNA was shifted from the non-polysomal to polysome fractions. YB-1 depletion abrogated the arsenite-responsive activation of HSP70 synthesis, but SGs harboring both mRNAs were still assembled. The number of SGs was increased by YB-1 depletion and decreased by its overexpression.

Conclusion

In arsenite-treated cells, YB-1 mediates the translational activation of HSP70 mRNA and also controls the number of SGs through inhibition of their assembly.

General significance

Under stress conditions, YB-1 exerts simultaneous but opposing actions on the regulation of translation via SGs and polysomes.