Selective control of amino acid metabolism by the GCN2 eIF2 kinase pathway in Saccharomyces cerevisiae
© Zaborske et al; licensee BioMed Central Ltd. 2010
Received: 28 April 2010
Accepted: 4 August 2010
Published: 4 August 2010
When eukaryotic cells are deprived of amino acids, uncharged tRNAs accumulate and activate the conserved GCN2 protein kinase. Activated Gcn2p up-regulates the general amino acid control pathway through phosphorylation of the translational initiation factor eIF2. In Saccharomyces cerevisiae, Gcn2p is the only kinase that phosphorylates eIF2 to regulate translation through this mechanism. We addressed changes in yeast growth and tRNA aminoacylation, or charging, during amino acid depletion in the presence and absence of GCN2. tRNA charging was measured using a microarray technique which simultaneously measures all cytosolic tRNAs. A fully prototrophic strain, and its isogenic gcn2 Δ counterpart, were used to study depletion for each of the 20 amino acids, with a focus on Trp, Arg, His and Leu, which are metabolically distinct and together provide a good overview on amino acid metabolism.
While the wild-type strain had no observable phenotype upon depletion for any amino acid, the gcn2 Δ strain showed slow growth in media devoid of only Trp or Arg. Consistent with the growth phenotypes, profiles of genome-wide tRNA charging revealed significant decrease in cognate tRNA charging only in the gcn2 Δ strain upon depletion for Trp or Arg. In contrast, there was no change in tRNA charging during His and Leu depletion in either the wild-type or gcn2 Δ strains, consistent with the null effect on growth during loss of these amino acids. We determined that the growth phenotype of Trp depletion is derived from feedback inhibition of aromatic amino acid biosynthesis. By removing Phe and Tyr from the media in addition to Trp, regular growth was restored and tRNATrp charging no longer decreased. The growth phenotype of Arg depletion is derived from unbalanced nitrogen metabolism. By supplementing ornithine upon Arg depletion, both growth and tRNAArg charging were partially restored.
Under mild stress conditions the basal activity of Gcn2p is sufficient to allow for proper adaptation to amino acid depletion. This study highlights the importance of the GCN2 eIF2 kinase pathway for maintaining metabolic homeostasis, contributing to appropriate tRNA charging and growth adaptation in response to culture conditions deficient for the central amino acids, tryptophan and arginine.
Translational control is a fundamental step in the regulation of gene expression. An important mechanism for regulating eukaryotic translational initiation involves the phosphorylation of the α subunit of the initiation factor eIF2 in response to environmental stresses [1–3]. The eIF2 delivers initiator tRNA to the translation machinery, and phosphorylation of eIF2α (eIF2α-P) reduces it activity by blocking the eIF2-GDP to eIF2-GTP exchange required for each round of translation initiation. The resulting reduction in global translation conserves energy and allows for cells to reprogram gene expression to ameliorate stress damage. Coincident with this global repression of protein synthesis, eIF2α-P elicits preferential translation of selected mRNAs, including the yeast transcriptional activator GCN4 which directs transcription of genes involved in the synthesis of amino acids and the salvaging of nutrients (the so-called general amino acid control, GAAC) . In mammals, a related transcription activator, ATF4, is preferentially translated upon increasing eIF2α-P, contributing to the so-called integrated stress response [4–6].
In the yeast Saccharomyces cerevisiae, Gcn2p is the only known kinase for eIF2α phosphorylation . Activation of Gcn2p in response to amino acid starvation occurs by Gcn2p binding to an uncharged tRNA through its histidyl-tRNA-synthetase-like domain [1, 7–9]. Although uncharged tRNAHis is known to activate Gcn2p in vivo, other tRNAs can bind to this HisRS-like domain in vitro . We have shown recently that in vivo, activation of Gcn2p is coincident with enhanced levels of multiple uncharged tRNAs, and the actual uncharged tRNA activator can vary depending on the type of stress . This genome-wide method for measuring tRNA charging uses selective labeling of tRNAs with Cy3 or Cy5 and microarrays spotted with individual probes for each of the yeast tRNAs. Auxotrophic yeast strains were starved for the limiting amino acid, and the charging levels for both the cognate tRNA and some non-cognate tRNAs were decreased. These key results were confirmed by northern analyses, validating the method and the key findings. These results suggest that activation of Gcn2p occurs in response to a complex pattern of changes in tRNA charging upon starvation for amino acids.
In addition to the GAAC, cells use other mechanisms to regulate the activity of various metabolic pathways. For the aromatic amino acid biosynthetic super-pathway, the first step, biosynthesis of 3-deoxy-darabino-heptulosonate-7-phosphate, is under the control of both GCN4 and feedback inhibition of metabolites . While GCN4 can upregulate the expression of biosynthetic enzymes, the availability of Tyr and Phe can modulate the enzymatic activity of this step. To control arginine metabolism and the urea cycle, cells elicit transcriptional control by Gcn4p, along with monitoring the intracellular concentration of arginine, ornithine and citrulline to fine tune metabolic flux [12, 13]. In this study, we investigated the mechanisms by which yeast cells respond to individual amino acid depletion in a GCN2 dependent manner by monitoring cell growth and genome-wide tRNA charging levels. Our results reveal a complex relationship between cellular metabolism and GCN2 function.
GCN2-dependent recovery of cell growth upon amino acid depletion
GCN2-dependent tRNA charging effects upon amino acid depletion
Both tryptophan and arginine depletion are known to cause growth defects in gcn4 Δ and the growth rate analysis confirmed that our gcn2 Δ strain exhibited this phenotype as well ([15–17], Fig. 1). We chose to examine the changes in the tRNA charging profile upon depletion of four amino acids: Trp (Fig. 2A, B) and Arg (Fig. 2C), which showed significant growth defects in the gcn2 Δ cells, and Leu and His (Fig. 2D), which have extensive but distinct anabolic and catabolic pathways from Trp and Arg. The tRNA charging results showed a significant correlation to the growth profiles for each of these amino acids. Upon Trp depletion, the charging levels of tRNATrp were lowered by ~2-fold at 15 min for both strains. By 60 min, tRNATrp charging did not decrease further in the wild-type cells, but declined by 10-fold in the gcn2 Δ strain (Fig. 2A). This very large decrease of tRNATrp charging does not correlate with a significant change in the tRNATrp levels under the same condition (Fig. 2B). Aminoacylation of the initiator tRNAiMet was also selectively reduced in the gcn2 Δ strain in response to removal of Trp. It is unclear why Trp depletion leads to selective decrease in initiator tRNAiMet charging. However, reduced charging level of initiator tRNAiMet makes biologically sense because this would lead to decreasing the global level of translation and furthermore to up-regulation of GCN4 translation and enhanced GAAC . Upon Arg depletion, the charging levels of all four tRNAArg isoacceptors were reduced by ~2-fold at 15 min and ~10-fold at 60 min, but only in the gcn2 Δ strain. The charging of several non-cognate tRNAs, tRNAGlu and tRNAAsp and to a lesser extent tRNALys and tRNATyr, were also lowered in the gcn2 Δ strain upon Arg depletion in the medium. Therefore, in both cases of Trp and Arg depletion, the growth defect of the gcn2 Δ strain is accompanied by dramatic charging reductions in cognate tRNAs. The control experiments involving Leu and His depletion showed no appreciable decrease in the charging level of any tRNA in either wild-type or gcn2 Δ strains, consistent with the null effect of these two amino acid depletions on cell growth.
Cellular pathway linked to Trp sensitivity
This hypothesis posits that depleting all three aromatic amino acids simultaneously could restore growth in the gcn2 Δ cells; this was indeed observed (Fig. 4B). The tRNA charging profile after the simultaneous removal of three aromatic amino acids (Fig. 4C, D) showed that restoration of the growth phenotype in the gcn2 Δ strain is accompanied by the maintenance of high charging levels of tRNATrp at all times upon Trp/Phe/Tyr depletion, while charging for tRNAPhe and tRNATyr showed modest decrease. These results indicate that the requirement for GCN2 for growth and maintenance of tRNA charging in the SC medium limiting for Trp is both a consequence of the impaired GAAC and feedback inhibition regulating the carbon flux through the biosynthetic pathway for aromatic amino acids. Depletion of Trp alone retains Tyr and Phe in the SC medium which then can inhibit this combined synthesis pathway. Because Tyr and Phe are readily available in the SC medium depleted of Trp alone, cells should import sufficient amounts of Tyr and Phe to maintain the charging levels of tRNAPhe and tRNATyr.
Cellular pathway linked to Arg sensitivity
Ornithine is only used as a metabolic precursor for citrulline and polyamine biosynthesis. It may be possible that supplementing media with citrulline and polyamines in the absence of arginine would recover growth in a manner similar to ornithine supplementation. However, no growth recovery was observed when citrulline and polyamines were added after arginine depletion (Fig. 5B). Increased concentrations of other nitrogen sources such as Glu and Gln upon Arg depletion also failed to rescue growth (data not shown). These results indicate that aside from Arg, ornithine is unique in this pathway in balancing nitrogen metabolism in the absence of GCN2.
The GAAC pathway is essential for regulating metabolism especially when cells are subjected to nutrient stresses. Previous work indicated that activation of Gcn2p in auxotrophic strains produces surprising tRNA charging profiles which can activate Gcn2p and consequently GAAC . In this work we focus on how Gcn2p is used to regulate metabolic flux in prototrophic cells.
While many stresses are known to activate Gcn2p, mild stresses of prototrophic S. cerevisiae, such as depleting a single amino acid from the growth media as done in this work do not require activation of Gcn2p under all conditions. One possible reason for this selective response to amino acid availability is that many metabolic pathways contain alternative regulators, in addition to GCN4 [23, 24]. For example, Chin et al.  showed that during the mild nutrient stress of leucine depletion, Leu3p can specially regulated the Leu biosynthetic pathway, and can sufficiently regulate the branched aromatic amino acid biosynthesis super-pathway independent of GCN4 up-regulation. Our results agree nicely with this previous study and furthermore, we observed no change in charging of any tRNA upon Leu depletion.
The first step of the aromatic amino acid biosynthetic super-pathway uses feedback inhibition in combination with GCN4 for regulation instead of using two separate transcription factors as in Leu biosynthesis. Our results confirm that improper regulation of this super-pathway causes growth and tRNA charging defects in gcn2 Δ cells subjected to tryptophan depletion. This may be explained by the gcn2 Δ strain lacking a non-GCN4 protein regulator of the first step of the aromatic amino acid biosynthetic pathway. Lack of Gcn2p mediated up-regulation of GCN4 ultimately results in an auxotroph-like phenotype. What would happen to the growth of gcn2 Δ strain if both Tyr and Phe are depleted? Addition of Tyr and Phe to a yeast strain in which the GCN2 pathway was genetically inactivated did not provide for growth, whereas the addition of Tyr alone or Phe alone did promote growth [15–17]. However, the addition of Trp alone in this yeast strain fully restored growth. These results suggest that as long as Trp is present, double depletion of Tyr and Phe would confer no effect on growth in gcn2 Δ strains.
Arginine metabolism is also regulated by feedback inhibition of metabolites and by the transcription factor Gcn4p. Unlike tryptophan biosynthesis, arginine metabolism is not strictly a linear pathway. Both arginine anabolism and catabolism are linked to the urea cycle. In the case of the urea cycle, cell uses the available arginine, ornithine, and citrulline to effect enzymatic activity in addition to Gcn4p to regulate metabolic flux [13, 26]. While we were unable to completely eliminate the growth defect in gcn2 Δ strains with supplements, partial growth restoration was possible in media containing high concentrations of ornithine. This result may be related to ornithine transport across cell membranes. Inefficient uptake from the media after arginine depletion could result in disrupted nitrogen flux. Another possibility is that ornithine, a known inhibitor of arginase activity in vitro , acts as an inhibitor of arginase which converts arginine to ornithine and releases urea as a byproduct. Therefore, it is possible that ornithine may accumulate in the cytosol and inhibit arginase. In this way, the presence of ornithine in the cytosol would reduce the conversion of arginine to ornithine, leaving more arginine available for translation.
We also observed decreased charging levels of specific tRNAs that are not cognate to the depleted amino acid, e.g. initiator tRNAiMet upon Trp depletion or tRNAAsp and tRNAGlu upon Arg depletion. In the genetic background used here (gcn2 Δ), a possible cause of these changes in tRNA charging is derived from regulated expression levels in their cognate aminoacyl-tRNA synthetases prior to amino acid depletion. Transcription of at least one aminoacyl-tRNA synthetase is known to be up-regulated by GCN4 . Hence, the extremely low level of GCN4 protein in the gcn2 Δ strain (Fig. 1C) could reduce the expression of certain tRNA synthetases, thereby predisposes these cells to become hypersensitive to metabolic fluxes upon amino acid depletion.
In summary, this work examines growth and genome-wide tRNA charging response in wild type and gcn2 Δ cells subjected to mild nutritional stress. Although eIF2 phosphorylation was thought to control translation upon the depletion of any amino acid, we found that this conserved mechanism of translational control is particularly sensitive to the availability of just two amino acids, Trp and Arg. This GCN2 dependent response to the limitation of Trp and Arg is due to synthesis of Trp and degradation of Arg. Our results show unexpected complexity of cellular metabolism and tRNA charging, and indicate that some metabolic pathways are particularly sensitive to translational control.
Cell strains and growth
The S. cerevisiae strains used in this study were derived from EG328-1A (MAT α ura3-52 leu2 trp1) [29, 30]. Strain EG328-1A was transformed with DNA fragments containing the LEU2, TRP1, or URA3 genes, generating a prototrophic strain, WY798 (MAT α URA3 LEU2 TRP1). An isogenic strainWY799 (MAT α gcn2::URA3 LEU2 TRP1) contains a deletion in the GCN2 gene. Cells were grown overnight in filter sterilized synthetic complete (SC) media containing 2% dextrose, 0.5% ammonium sulfate, and all amino acids . To screen for growth in media with selected amino acids, cells were grown overnight to saturation (A600 ~ 6-7) in SC media containing all amino acids. Cells were collected by centrifugation, and then resuspended in SC media lacking only the specified amino acid to A600 of ~0.1. Cells were grown in 96 well plates at 30°C with constant shaking. For flask growth an overnight culture of cells was diluted down to A600 of 0.1 and grown in SC media until an A600 of 0.4-0.5. Cells were pelleted and then resuspended in SC media lacking only the specified amino acid and growth was monitored for up to 24 h.
GCN4-lacZ reporter assay
WY523 and WY525 (gcn2Δ) cells were derived from strain EG328-1A transformed with plasmid p180, encoding GCN4-lacZ with the full complement of upstream ORFs . Cells were grown overnight in SC media containing all amino acids. Cells were diluted down to A600 ~ 0.1, then grown to A600 ~ 0.4-0.5 at which point they were spun down and resuspended in media lacking the specified amino acid. 35 ml cells were taken at designated time points and lysed using beads in 0.4 ml of 100 mM Tris-HCl pH 8, 20% glycerol, 1 mM β -mercaptoethanol and 100 μM PMSF. Lysate was clarified with a 10 min spin at 18,600 RFC. 20 μl of extract was combined with 980 μl of reaction buffer (100 mM Sodium Phosphate, pH 7.5, 10 mM KCl, 2 mM MgSO4, 4.5 mM β-mercaptoethanol). 200 μl of o-nitrophenyl-β-D-galactopyranoside solution (4 mg/ml) was added and the reaction was allowed to proceed for 20 and 60 min at 28°C. Reaction was quenched by adding 0.5 ml of 1 M Na2CO3 and absorbance was taken at 420 nm.
Genome-wide tRNA charging profile by microarrays
Isolation, genome-wide profiling of charged tRNA was carried out as previously described  and in a Method video article . The microarray data has been deposited in Geo data base (accession number GSE22452).
Genome-wide tRNA abundance profile by microarrays
List of abbreviations
general amino acid control.
This work was supported in part by an exploratory grant from Ajinomoto Inc., Japan (to TP), by National Institutes of Health Grant R01GM49164 (to RCW), and by the NIH Training Grant T32GM007183-33 (to JZ). We thank Dr. Alan Hinnebusch for helpful discussions and suggesting the triple amino acid depletion experiment.
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