Translational regulation in response to stress in Saccharomyces cerevisiae (original) (raw)
Related papers
Adaptation to stress in yeast: to translate or not?
Biochemical Society Transactions, 2012
For most eukaryotic organisms, including Saccharomyces cerevisiae, the rapid inhibition of protein synthesis forms part of a response to stress. In order to balance the changing conditions, precise stress-specific alterations to the cell's proteome are required. Therefore, in the background of a global down-regulation in protein synthesis, specific proteins are induced. Given the level of plasticity required to enable stress-specific alterations of this kind, it is surprising that the mechanisms of translational regulation are not more diverse. In the present review, we summarize the impact of stress on translation initiation, highlighting both the similarities and distinctions between various stress responses. Finally, we speculate as to how yeast cells generate stress-responsive programmes of protein production when regulation is focused on the same steps in the translation pathway.
Genome biology, 2012
Gene expression is controlled globally and at multiple levels in response to environmental stress, but the relationships among these dynamic regulatory changes are not clear. Here we analyzed global regulation during different stress conditions in fission yeast, Schizosaccharomyces pombe, combining dynamic genome-wide data on mRNA, translation, and protein profiles. We observed a strong overall concordance between changes in mRNAs and co-directional changes in translation, for both induced and repressed genes, in response to three conditions: oxidative stress, heat shock, and DNA damage. However, approximately 200 genes each under oxidative and heat stress conditions showed discordant regulation with respect to mRNA and translation profiles, with genes and patterns of regulation being stress-specific. For oxidative stress, we also measured dynamic profiles for 2,147 proteins, comprising 43% of the proteome. The mRNAs induced during oxidative stress strongly correlated with increased...
Gene regulation during stress response transcription in Saccharomyces Cerevisiae
2013
DYNAMIC TRANSCRIPTOME ANALYSIS MEASURES RATES OF MRNA SYNTHESIS AND DECAY IN YEAST To obtain rates of mRNA synthesis and decay in yeast, we established dynamic transcriptome analysis (DTA). DTA combines non-perturbing metabolic RNA labeling with dynamic kinetic modeling. DTA reveals that most mRNA synthesis rates are around several transcripts per cell and cell cycle, and most mRNA half-lives range around a median of 11 min. DTA can monitor the cellular response to osmotic stress with higher sensitivity and temporal resolution than standard transcriptomics. In contrast to monotonically increasing total mRNA levels, DTA reveals three phases of the stress response. During the initial shock phase, mRNA synthesis and decay rates decrease globally, resulting in mRNA storage. During the subsequent induction phase, both rates increase for a subset of genes, resulting in production and rapid removal of stress-responsive mRNAs. During the recovery phase, decay rates are largely restored, whe...
Specific and global regulation of mRNA stability during osmotic stress in Saccharomyces cerevisiae
RNA, 2009
Hyperosmotic stress yields reprogramming of gene expression in Saccharomyces cerevisiae cells. Most of this response is orchestrated by Hog1, a stress-activated, mitogen-activated protein kinase (MAPK) homologous to human p38. We investigated, on a genomic scale, the contribution of changes in transcription rates and mRNA stabilities to the modulation of mRNA amounts during the response to osmotic stress in wild-type and hog1 mutant cells. Mild osmotic shock induces a broad mRNA destabilization; however, osmo-mRNAs are up-regulated by increasing both transcription rates and mRNA half-lives. In contrast, mild or severe osmotic stress in hog1 mutants, or severe osmotic stress in wild-type cells, yields global mRNA stabilization and sequestration of mRNAs into P-bodies. After adaptation, the absence of Hog1 affects the kinetics of P-bodies disassembly and the return of mRNAs to translation. Our results indicate that regulation of mRNA turnover contributes to coordinate gene expression upon osmotic stress, and that there are both specific and global controls of mRNA stability depending on the strength of the osmotic stress.
In mammalian and Drosophila cells, heat stress strongly reduces general protein translation while activating cap-independent translation mechanisms to promote the expression of stress-response proteins. In contrast, in Saccharomyces cerevisiae general translation is only mildly and transiently reduced by heat stress and cap-independent translation mechanisms have not been correlated with the heat stress response. Recently we have identified direct target genes of the heat shock transcription factor (HSF), including genes encoding proteins thought to be important for general translation. One gene activated by HSF during heat stress encodes the enhancer of decapping protein, Edc2, previously shown to enhance mRNA decapping under conditions when the decapping machinery is limited. In this report we show that strains lacking Edc2, as well as the paralogous protein Edc1, are compromised for growth under persistent heat stress. This growth deficiency can be rescued by expression of a mutant Edc1 protein deficient in mRNA decapping indicative of a decapping independent function during heat stress. Yeast strains lacking Edc1 and Edc2 are also sensitive to the pharmacological inhibitor of translation paromomycin and exposure to heat stress and paromomycin functions synergistically to reduce yeast viability, suggesting that in the absence of Edc1 and Edc2 translation is compromised under heat stress conditions. Strains lacking Edc1 and Edc2 have significantly reduced rates of protein translation during growth under heat stress conditions, but not under normal growth conditions. We propose that Edc1 and the stress responsive isoform Edc2 play important roles in protein translation during stress.
Loss of Translational Control in Yeast Compromised for the Major mRNA Decay Pathway
Molecular and Cellular Biology, 2004
The cytoplasmic fate of mRNAs is dictated by the relative activities of the intimately connected mRNA decay and translation initiation pathways. In this study, we have found that yeast strains compromised for stages downstream of deadenylation in the major mRNA decay pathway are incapable of inhibiting global translation initiation in response to stress. In the past, the paradigm of the eIF2␣ kinase-dependent amino acid starvation pathway in yeast has been used to evaluate this highly conserved stress response in all eukaryotic cells. Using a similar approach we have found that even though the mRNA decay mutants maintain high levels of general translation, they exhibit many of the hallmarks of amino acid starvation, including increased eIF2␣ phosphorylation and activated GCN4 mRNA translation. Therefore, these mutants appear translationally oblivious to decreased ternary complex abundance, and we propose that this is due to higher rates of mRNA recruitment to the 40S ribosomal subunit.
Eukaryotic Cell, 2005
The stress-activated protein kinase (SAPK) pathway plays a central role in coordinating gene expression in response to diverse environmental stress stimuli. We examined the role of this pathway in the translational response to stress in Schizosaccharomyces pombe. Exposing wild-type cells to osmotic stress (KCl) resulted in a rapid but transient reduction in protein synthesis. Protein synthesis was further reduced in mutants disrupting the SAPK pathway, including the mitogen-activated protein kinase Wis1 or the mitogen-activated protein kinase Spc1/Sty1, suggesting a role for these stress response factors in this translational control.
Global Translational Responses to Oxidative Stress Impact upon Multiple Levels of Protein Synthesis
Journal of Biological Chemistry, 2006
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 ␣-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.
The role of PKA in the translational response to heat stress in Saccharomyces cerevisiae
PloS one, 2017
Cellular responses to stress stem from a variety of different mechanisms, including translation arrest and relocation of the translationally repressed mRNAs to ribonucleoprotein particles like stress granules (SGs) and processing bodies (PBs). Here, we examine the role of PKA in the S. cerevisiae heat shock response. Under mild heat stress Tpk3 aggregates and promotes aggregation of eIF4G, Pab1 and eIF4E, whereas severe heat stress leads to the formation of PBs and SGs that contain both Tpk2 and Tpk3 and a larger 48S translation initiation complex. Deletion of TPK2 or TPK3 impacts upon the translational response to heat stress of several mRNAs including CYC1, HSP42, HSP30 and ENO2. TPK2 deletion leads to a robust translational arrest, an increase in SGs/PBs aggregation and translational hypersensitivity to heat stress, whereas TPK3 deletion represses SGs/PBs formation, translational arrest and response for the analyzed mRNAs. Therefore, this work provides evidence indicating that Tp...