Figures
Abstract
Boron is an essential micronutrient for plants, and it is beneficial for animals. However, at high concentrations boron is toxic to cells although the mechanism of this toxicity is not known. Atr1 has recently been identified as a boron efflux pump whose expression is upregulated in response to boron treatment. Here, we found that the expression of ATR1 is associated with expression of genes involved in amino acid biosynthesis. These mechanisms are strictly controlled by the transcription factor Gcn4 in response to boron treatment. Further analyses have shown that boron impaired protein synthesis by promoting phosphorylation of eIF2α in a Gcn2 kinase dependent manner. The uncharged tRNA binding domain (HisRS) of Gcn2 is necessary for the phosphorylation of eIF2α in the presence of boron. We postulate that boron exerts its toxic effect through activation of the general amino acid control system and inhibition of protein synthesis. Since the general amino acid control pathway is conserved among eukaryotes, this mechanism of boron toxicity may be of general importance.
Citation: Uluisik I, Kaya A, Fomenko DE, Karakaya HC, Carlson BA, Gladyshev VN, et al. (2011) Boron Stress Activates the General Amino Acid Control Mechanism and Inhibits Protein Synthesis. PLoS ONE 6(11): e27772. https://doi.org/10.1371/journal.pone.0027772
Editor: Arthur J. Lustig, Tulane University Health Sciences Center, United States of America
Received: June 10, 2011; Accepted: October 25, 2011; Published: November 17, 2011
Copyright: © 2011 Uluisik et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by TUBITAK Grant No. 104T213, 110T917 and TUBA-GEBIP grant to (A.Koc). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Boron is required for plant growth and development, and adequate levels of boron are crucial for high crop yield [1], [2], [3]. It has been established that the primary role of boron is the cross linking of cell wall components, rhamnogalacturonan-II and pectin, in plants [4]. Boron also forms complexes with glycoproteins in membrane structures [5] and it has been hypothesized that it is required for stabilization of molecules with cis-diol groups [6]. Apart from these structural functions, boron can interact with transcription factors and plays roles in cell signaling [7] and quorum sensing [8], [9]. This element also has beneficial effects for animal growth and development. It stimulates embryogenesis in zebrafish and trout [10], [11] and reduces the risk for prostate and lung cancers in humans [12], [13].
Saccharomyces cerevisiae emerged as a useful model to identify and characterize boron tolerance genes [14], [15], [16], [17], [18], [19]. S. cerevisiae is boron tolerant and can tolerate boric acid levels of up to 80 mM [14], [15]. Recently, the ATR1 gene has been found to be a major boron tolerance gene [14]. Overexpression of ATR1 provides high resistance to boron and reduces the intracellular boron levels. Mutants lacking the ATR1 gene have been found to be sensitive to boron and have higher intracellular boron levels. Boron treatment has been shown to induce the ATR1 gene and many amino acid biosynthesis genes that are normally regulated by the Gcn4 transcription factor [14].
In the case of amino acid starvation, yeast induces amino acid biosynthesis genes which are known as general amino acid control (GAAC) [20], [21], [22]. The Gcn4 transcription factor is the master regulator of GAAC that governs the concerted induction of a large group of biosynthesis genes [20], [22]. Interestingly, the expression of GCN4 itself is regulated primarily at the translational level by four short open reading frames in its 5′-leader region [22], [23]. Activation of GAAC also triggers phosphorylation of the eukaryotic initiation factor–2 alpha (eIF2α) through the Gcn2 kinase and inhibits general translation [21], [24]. Activation of the Gcn2 kinase involves direct binding of uncharged tRNAs to the histidyl-tRNA synthetase domain of Gcn2 [21], [24], [25]. In yeast, eIF2α phosphorylation also leads to preferential translation of GCN4 mRNA, while inhibiting general translation [21], [24].
In this study, we demonstrate that boron is sensed via its disruption of amino acid metabolism and translation. We postulate that induction of GAAC in response to boron stress is toxic because of its inhibitory effects on translation. However, GAAC-dependent ATR1 activation is required for resistance to boron stress.
Results
Transcriptional Regulation of ATR1: Roles of the Gcn4 Transcription Factor in Boron Stress Response
Recently, Atr1 has been identified as a membrane transporter with boron efflux function. Treating cells with boric acid causes a four-fold increase in ATR1 mRNA levels [14]. However, the factors that regulate ATR1 in response to boron stress are not known. Previously, transcription factors Yap1 and Gcn4 were suggested to play a role in the regulation of ATR1 [26]. Yap1 is a well known transcription factor that controls oxidative stress response genes and is likely to play a role in the activation of ATR1 [27]. Gcn4 is the major regulator of gene expression during amino acid starvation and also under conditions of nutrient limitation in yeast [21]. Knowing that boron stress also induces amino acid biosynthetic genes [14], we reasoned that the Gcn4 transcription factor should regulate ATR1 in response to boron treatment. To determine whether Yap1 or Gcn4 is required for ATR1 induction by boron, global gene expression patterns of Δyap1 and Δgcn4 mutants were analyzed after boron treatment using DNA microarrays. The absence of GCN4 prevented the activation of many transporters including ATR1 (Fig. 1A) and amino acid biosynthesis genes (Fig. 1B), whereas the absence of YAP1 had no effect on the expression of these genes. Thus, ATR1 and the genes under the control of GAAC, such as amino acid biosynthesis genes and transporters, appear to be regulated by the transcription factor Gcn4 during boron stress. Gcn4 requirement for ATR1 expression was also confirmed by a real time-PCR approach, in which ATR1 mRNA levels were almost similar in control and mutant untreated cells, but upon boron treatment Δgcn4 mutants failed to induce ATR1 transcription. However, deletion of YAP1 partially prevented ATR1 upregulation in response to boron (Fig. 1C).
To carry out microarray analyses, logarithmically growing wild type, Δgcn4 and Δyap1 mutant cells were split into two samples; one was treated with 20 mM boric acid for one hour while the other remained untreated. (A) Transporter genes that were upregulated or downregulated in response to boric acid treatment. (B) Amino acid biosynthesis genes that were upregulated and downregulated in response to boric acid treatment. Yeast Saccharomyces cerevisiae proteins annotation information from the yeast genome database (http://www.yeastgenome.org/) was used to identify transporters and other proteins. (C) Real time PCR analyses of ATR1 in wild type, Δgcn4 and Δyap1 cells in response to boron. Cells were treated or not with 50 mM boric acid for one hour and ATR1 expression was analyzed. Actin was used as the internal control. Bars represent the mean and SEM of triplicate assays.
Further processing of the data obtained by microarray analyses showed that boron treatment caused upregulation (≥2-fold) of 280 genes, and down regulation of 118 genes in wild type cells (Table S1, Table S2). However, many of the boron induced genes in wild type cells were not activated in Δgcn4 mutants (Table S3, Figure 1A and 1B). Thus Gcn4 transcription factor has a central role in mediating boron stress response in yeast cells.
Additionally, the microarray results showed that transcription of GCN4 was 1.5-fold increased (p-value 2.8xE-3) in wild type cells treated with 20 mM boric acid for one hour, but none of the activators (GCN1, GCN2, GCN3, GCN20) of GCN4 was upregulated (Table S1). The induction of internal GCN4 expression in response to boric acid treatment was further analyzed by real time PCR (Fig. 2A). This assay confirmed that GCN4 transcription is upregulated by boron and revealed that higher concentration of boron treatment (50 mM) causes a higher level of induction (5-fold). Since GCN4 is mainly controlled at the translational level [21], we also tested whether boron stress increases the amount of Gcn4 protein in cells. As seen in Fig. 2B, boron treatment leads to almost two-fold induction of a chromosomal GCN4-dependent LacZ reporter gene activity in wild type cells. Increased protein level of GCN4 was also shown by a western blotting approach using native GCN4 gene tagged by MYC epitope (Fig. 2C).
(A) Real time PCR analysis of GCN4 mRNA in wild type cells treated with 50 mM boric acid for one hour. Actin was used as the internal control. (B) Wild type cells were transformed with the p180 plasmid which had the GCN4-lacZ reporter gene with all four uORFs of GCN4. Transformants were grown to logarithmic phase in YNB-URA medium. The cultures were split into two; one half was treated with 50 mM boric acid for one hour, and the other half remained untreated. β-galactosidase activities were measured as explained in Materials and Methods. (C) Effect of boric acid treatment on Gcn4 protein levels determined by western blotting. Chromosomally tagged GCN4-MYC cells were grown to logarithmic phase, treated with indicated amounts of boric acid and harvested (900 µl, 0.5 OD600). Primary (anti-c-myc) and secondary antibodies (anti-rabbit IgG) were used in a dilution of 1:3000 and 1:10000 respectively. The blot was stripped and reprobed yeast phosphoglycerate kinase monoclonal antibody as an internal control (1:1500 dilutions) and its 1:10000 diluted secondary antibody was goat anti mouse IgG conjugated with horseradish peroxidase.
To determine whether deletion of GCN4 or YAP1 renders cells boron sensitive, both mutants were inoculated to boron containing media and cell growth was followed. As seen in Fig. 3A, deletion of both of these genes sensitized cells to boron, suggesting that both Yap1 and Gcn4 might play roles in boron stress response.
(A) Overnight cultures of wild type and isogenic Δyap1, Δgcn4 yeast cells were first diluted to an OD600 of 0.2, 0.02, 0.002 and 0.0002, then 5 µl of each cell suspension were spotted onto YPD plates which contained different amounts of boric acid, as indicated. The cells were grown for 3 days at 30°C and photographed. (B) ATR1 mRNA expression levels of wild type cells containing empty pAG423GPD vector, pAG423GPD-YAP1 and pAG423GPD-GCN4 vectors, respectively. Actin was used as an internal control. These experiments were performed three times. (C) Boric acid tolerance level of the same cells. The transformants were grown to logarithmic phase in YNB-HIS media, serially diluted to OD600 of 0.2, 0.02, 0.002, and 0.0002 and 5 µl of cell suspension were spotted onto plates containing the indicated amounts of boric acid. The plates were incubated at 30°C for 5 days and photographed. (D) GCN4 mRNA expression levels in wild type cells overexpressing pAG423GPD and pAG423GPD-GCN4 vectors. (E) ATR1 mRNA levels in wild type and Δgcn4 mutant cells containing pAG423-YAP1 vector. Actin was used as an internal control.
It was previously shown that Gcn4 overexpression has toxic effects on yeast cell growth [28], [29]. We next overexpressed GCN4 in wild type cells from a high copy plasmid, to test whether or not its expression activates transcription of ATR1, and in this manner provides boron resistance or not. As seen in Fig. 3B, GCN4 overexpression in wild type cells neither increased the transcript level of ATR1 nor led to boron resistance (Fig. 3C), although the overall GCN4 level was notably elevated in wild type cells overexpressing GCN4 (Fig. 3D).
Even though deletion of YAP1 did not inhibit ATR1 expression in response to boron stress, overexpression of YAP1 from a plasmid stimulated the expression of ATR1 and provided increased boron resistance (Fig. 3B and 3C). Overexpression of GCN4 in Δgcn4 mutants showed effects similar to those in wild type cells (Fig. S1).
It was previously shown that Yap1 and Gcn4 bind to the same region of the ATR1 promoter and regulate transcription in response to DNA-damaging agent 4-NQO [26]. To test whether Gcn4 is required for Yap1-dependent expression of ATR1, we overexpressed YAP1 in Δgcn4 cells and observed a reduction in the level of ATR1 transcript compared to that in wild type cells, suggesting that Yap1 requires Gcn4 to induce ATR1 (Fig. 3E).
Overall, our gene expression analyses suggested that Gcn4 is required for ATR1 induction and that it serves as a physiologically relevant transcription factor in the response to boron treatment. However, Yap1 could also induce ATR1 and offer boron resistance when expressed ectopically.
Boron Inhibits Protein Synthesis
The activation of GAAC in response to boron stress prompted us to investigate the status of translation because Gcn2 kinase has a role in inhibiting protein synthesis upon activation [21]. Wild type cells were treated with 20 mM boric acid and labeled with radioactively labeled methionine for one hour. As shown in Fig. 4, boron-treated cells contained approximately 30% less 35S-labeled proteins than untreated cells (Fig. 4A, left panel) suggesting that boron inhibits protein synthesis. Translational status of boron-treated cells was further analyzed by the distribution of polysomes. Polysomes are clusters of ribosomes bound to an mRNA molecule that actively translates the message. They can be fractionated and quantified using sucrose density gradients. Cells that are grown in the absence of boron stress exhibit normal polysome profiles including peaks of 40S and 60S ribosomal subunits, 80S monosomes, and polysomes. After treatment with boric acid for one hour, we observed a dramatic shift from polysomal to monosomal states, suggesting that translation initiation collapses in the presence of boron (Fig. 4B). Inhibition of translation in response to certain stress conditions has been reported previously. For example, a recent study has shown that drugs generating oxidative stress as well as heavy metals stall initiation of translation in yeast [30].
(A) Radiogram (left panel) showing incorporation of radioactive methionine into newly synthesized proteins. Coomassie staining of the same gel is shown in the right panel as a loading control. (B) Boron treatment decreases the abundance of polysomes. Wild type cells were grown to logarithmic phase and then treated with 50 and 100 mM of boric acid or left untreated. The cell lysates were analyzed by sucrose density gradient centrifugation. The absorbance profiles at 254 nm show 40S, 60S, 80S and polysome fractions, as indicated.
Boron Stress Induces Gcn2-dependent Phosphorylation of eIF2α
The protein kinase Gcn2 can be activated by a variety of conditions and it is the only known kinase in yeast that can phosphorylate eIF2α, which is responsible for carrying methionyl initiator tRNA (Met-tRNAiMet) to the 40S ribosomal subunit during the initiation stage of translation. Phosphorylation of eIF2α at serine 51 prevents GTP exchange by eIF2B and precludes the formation of a ternary complex for translation initiation, thus blocking protein synthesis. To determine whether the inhibition of protein synthesis in response to boron stress is dependent on the phosphorylation of eIF2α by Gcn2 kinase, wild type and Δgcn2 cells were treated with boron and the samples were subjected to western blotting analyses using an antibody which specifically recognizes the phosphorylated form of Ser51 in eIF2α. As seen in Fig. 5A, eIF2α is phosphorylated in wild type cells upon boron treatment, but not in Δgcn2 mutants. Thus, boron leads to phosphorylation of eIF2α in a Gcn2-dependent manner.
(A) Wild type and Δgcn2 cells were grown to logarithmic phase in YPD medium; the cultures were split and treated with 25 mM or 50 mM boric acid for one hour or left untreated. The levels of eIF2α phosphorylation at Ser51 were measured by western blot analysis using an antibody against phospho Ser51 on eIF2α. The membrane was stripped and reprobed with antibodies against yeast phosphoglycerate kinase (Pgk) antibody as an internal control. (B) Effect of boric acid on eIF2α phosphorylation depends on uncharged tRNA binding to an intact HisRS-like domain in Gcn2. The Δgcn2 transformants carrying plasmids for an empty vector (p-only), GCN2 with S577A substitution (p-GCN2-S577A), GCN2 without HisRS domain (p-GCN2-m2), GCN2 without HisRS domain and with S577A substitution (p-GCN2-S577A-m2), and intact GCN2 (p-GCN2) were grown to logarithmic phase in YNB-URA medium and split in half; one of which was treated with 50 mM boric acid for one hour while the other was left untreated. Western blot analyses were performed with cell extracts using an antibody against eIF2α phosphorylated on Ser51. The membrane was stripped and reprobed with antibodies against yeast phosphoglycerate kinase (Pgk) as an internal control.
Apart from its kinase domain, Gcn2 contains a region similar to histidyl-tRNA synthetase (HisRS) which regulates Gcn2 kinase activity by monitoring uncharged tRNA levels in cells [25], [31]. Gcn2 activity can also be regulated by dephosphorylation of Ser577 [21]. To investigate whether Gcn2 activation is the result of uncharged tRNA binding or dephosphorylation of Ser577 in response to boron stress, we transformed Δgcn2 mutants with plasmids containing intact and mutated forms of the GCN2 gene (GCN2 without m2 domain [32], GCN2 with S577A substitution [33], or a combination of both). The ability of transformants to phosphorylate eIF2α was investigated in boron-treated cells. As seen in Fig. 5B, eIF2α phoshorylation was unaffected by S577A substitution. However, mutation in the HisRS domain of Gcn2 (GCN2-m2), which abolishes uncharged tRNA binding to Gcn2, prevents eIF2α phosphorylation. Thus, the HisRS-like region is responsible for induction of Gcn2 kinase activity and this finding confirms that boron induces the uncharged tRNA signaling pathway.
Boron inhibits aminoacylation of tRNAs
To determine whether boron inhibits the aminoacylation of tRNAs, we aminoacylated total calf liver tRNA with either 3H-serine or 3H-phenylalanine in the presence of various concentrations of neutralized boric acid. We found that boric acid inhibits both tRNASer and tRNAPhe formation if there is more than 50 mM boric acid in the reaction (Fig. S2). Thus, boron interferes with aminoacylation steps of the tRNAs and causes uncharged tRNA stress.
Discussion
The essentiality of boron for plant growth is predominantly due to its presence in cell walls as a structural component of the rhamnogalacturonan II complex [4]. There has been no convincing evidence that boron toxicity is exerted through disruption of any process for which boron is required, notably via its role in cell walls. We recently suggested a potential link between translational control and boron toxicity in yeast based on the observation that mutants which show boron resistance were all lacking genes that play a role in uridine base modifications at the wobble position of tRNAs during translation [19]. Here, we found that the transcriptional activation of ATR1 is mediated by the transcription factor Gcn4 in response to boron treatment. Further analyses have shown that boron activates the Gcn2 kinase, and leads to phosphorylation of eIF2α and inhibition of protein synthesis. The uncharged tRNA binding site (HisRS domain) of the Gcn2 kinase is required for Gcn2 to phosphorylate eIF2α. The requirement for HisRS-like domain (uncharged tRNA binding region) to phosphorylate eIF2α suggests that the Gcn2 kinase activity is stimulated by uncharged tRNAs. Eventhough, boron impairs the acylation of tRNAs, the mechanism by which boric acid interferes with tRNA acylation should be further investigated. Boric acid is a relatively unreactive compound, however, it can form ester bonds with several metabolites with multiple hydroxyl groups in the cis-configuration [6], [34]. Among such metabolites, one of the most important moieties is the ribose sugar found in ribonucleotides. It is likely that boric acid can bind to RNA species and interfere with the acylation reaction of tRNAs. In opposition to this, a recent study has shown that oxidative stress leads to degradation of tRNAs, mediated by Rny1 nuclease and induction of the Gcn2 kinase [35], [36]. We argue against this possibility since yeast cells lacking the RNY1 gene still show a wild type level of eIF2α phosphorylation in response to boron treatment (data not shown).
It is also unclear how boron induces the transcription of Gcn4. Many stress and signaling pathways converge on the Gcn4 transcription factor and there are more than a dozen transcription factor binding sites in the GCN4 promoter region [37]. Thus, further studies are required to identify upstream players in the boron stress response pathway.
Our results suggest a role for GAAC in boron stress response. It is known that several other stress conditions also activate GAAC. Among these stressors, transcriptional response to hydrogen peroxide [30], 3-AT and rapamycin [38] have also been analyzed in Δgcn4 cells and their datasets are publicly available. In order to understand whether the cellular response to boron stress is mediated via a unique or a common mechanism, we compared our microarray data to those of hydrogen peroxide, 3-AT and rapamycin treated cells. We also compared expression profiles of Δgcn4 mutants exposed to boron and other stress conditions to determine how Gcn4-dependent boron regulon differs from other regulons. We observed that the transcriptional response of wild type cells to boron and other stress conditions is quite different (Fig. S3). The major gene clusters, up- or down-regulated in response to boron treatment, did not show similarity to the patterns observed for 3-AT, rapamycin or hydrogen peroxide treatments. However, it is clear that the expression profiles of 3-AT and rapamycin treated cells share some common patterns. The expression profiles of Δgcn4 mutants exposed to boron and other stressors are also different (Fig. S3). This data clearly shows that the Gcn4-dependent boron regulon is different from those of other stress conditions and that boron stress has specific effects on the transcriptome.
Recently, it was shown that amino acid starvation in response to 3-AT treatment leads to repression of genes encoding ribosomal proteins via the transcription factor Gcn4 [39]. Our results showed that boron treatment does not change the expression pattern of most of the ribosomal protein genes, and that Gcn4 has no roles in regulating either RPL or RPS genes in response to boron stress (Table S1).
Overall, our results suggest that the general amino acid control pathway contributes to boron toxicity and transcriptional regulation of ATR1 in response to boron stress. In this respect, we propose a model, wherein Gcn2 is activated by boron in an uncharged tRNA binding domain-dependent manner, activates Gcn4 and inhibits protein synthesis. Upon activation, Gcn4 induces the transcription of its boron specific target genes, ATR1, and many genes under the control of GAAC. Since the Gcn4-specific boron regulon shows differences with the activation of Gcn4 by other stress conditions, we speculate that there are other transcription factors that are involved in boron stress specific gene induction.
Materials and Methods
Yeast Growth, Media and Transformation
WT strain BY4741 (MATa his3 leu2 met15 ura3) and its isogenic deletion mutants were obtained from the yeast deletion library (Invitrogen). Cells were grown in either YEPD (2% glucose, 1% yeast extract, 2% peptone and 2% agar for solid media) or YNB (yeast nitrogen base) media supplemented with required amino acids and bases. Yeast transformations were performed using the LiAc method [40].
DNA Microarray Analysis
BY4741 wild type, Δyap1, Δgcn4 mutant cells were grown to an optical density of 0.2–0.3 at 600 nm in 200 ml YPD medium, with or without 20 mM boric acid treatment for 1 hour. Cells were then harvested by centrifugation. Total RNA was isolated using the Ambion RiboPure™-Yeast Kit. The Agilent Two-Color Low RNA Input Linear Amplification Kit was used to generate fluorescently labeled cRNA for two-color microarray hybridizations. Fluorescently labeled cRNA molecules were purified from the reaction mixture using the Qiagen RNeasy mini kit. The resulting cRNA samples (825 ng each) were mixed with Agilent Hi-RPM hybridization buffer. Microarray hybridizations were performed using Agilent SureHyb hybridization chambers. The hybridization chambers were loaded onto a rotisserie in an Agilent Hybridization oven and were incubated at 65°C for 17 hours with a rotational speed of 10 rpm. Following incubation, the microarray slides were washed for 1 min each in Gene Expression wash buffer 1 (6×SSPE, 0.005% N-lauroylsarcosine, at room temperature) and Gene Expression Wash Buffer 2 (0.06×SSPE, 0.005% N-lauroylsarcosine, at 31°C) for 1 min each. The microarray slides were briefly dipped in a solution of acetonitrile, dried and scanned in an Agilent Technologies G2505B microarray scanner at 5 µm resolution. Microarray data is MIAME compliant; the raw data has been deposited in the GEO database (Accession number GSE29887).
Western Blot Analyses
Wild type, and the isogenic Δgcn2 and GCN4-MYC strains were grown to mid-log phase in either YPD or selective YNB-Ura media, with or without boron treatment and equal numbers of cells were harvested by centrifugation for each strain. Cell extracts were resuspended in sample buffer (0.06 M Tris-HCl, pH 6.8, 10% (v/v) glycerol, 2% (w/v) SDS, 5% (v/v) 2-mercaptoethanol, 0.0025% (w/v) bromophenol blue) and heated at 95°C for 5 min. Samples were separated in 5–15% SDS-PAGE and electrotransferred to a PVDF (Sigma) membrane. Primary antibodies against phospho (Ser51) specific eIF2α were acquired from USBiological and anti-c-myc antibody used for detection of GCN4-MYC was from Sigma. The blots were stripped and reprobed with monoclonal antibodies specific for yeast phosphoglycerate kinase (Invitrogen) as an internal control. As secondary antibodies, anti-rabbit IgG conjugated to horseradish peroxidase (Sigma) or goat anti mouse IgG conjugated to horseradish peroxidase (Sigma) were used. The membranes were treated with enhanced chemiluminescence system (Bio-Rad) and visualized using the VersaDoc Imaging System (Bio-Rad).
Metabolic Labeling
BY4741 yeast cells were grown in 200 ml of YNB medium to OD600 = 0.5, split to 100 ml aliquots, and one aliquot was treated with 20 mM of boric acid. After 1 hour of incubation, both aliquots were metabolically labeled with 0.5 mCi of EXPRE35S35S Protein Labeling Mix (Perkin-Elmer) for 30 min. Cells were harvested by centrifugation, washed three times with PBS buffer and disrupted with glass beads for 10 min in PBS buffer. The resulting cellular lysates were normalized according to protein concentration and 10 µg of each lysate was subjected to SDS-PAGE. Resolved proteins were transferred onto PVDF membrane. 35S-labeled proteins were visualized with a Storm PhosphorImager system (Molecular Dynamics). ImageQuant package was used to quantify the autoradiogram data.
Polysome Profiling
Density gradient centrifugation system was used in order to separate total RNA based on the molecular weight. In brief, 5% and 70% sucrose solutions [RiboLock™ RNase inhibitor (Fermentas), 100 mM NaCl, 10 mM MgCl2, 20 mM HEPES] were prepared and thereafter sucrose gradients were prepared by using ISCO systems. BY4741 cells were grown to an optical density of 0.7–0.9 at 600 nm in 30 ml YPD medium. These cells were either exposed to 50 mM or 100 mM boric acid for 1 hour or not exposed. They were harvested by centrifugation, washed twice with distilled water, and frozen at −80°C. Then, yeast cells were homogenized in 5 ml lysis buffer [100 mM NaCl, 10 mM MgCl2, 20 mM HEPES, 40 u/µl RiboLock™ RNase inhibitor (Fermentas), 1% Triton-X 100, 1% sodium deoxycolate (NaDOC), 10 mg/ml cycloheximide (Sigma)] by vortexing with glass beads for 10 min. After ten minutes of incubation on ice, homogenates were centrifuged for 10 min at 12,000 g and 4°C. The supernatants were transferred to 5%–70% (w/v) sucrose gradients and sedimented for 2.5 h, at 27,000 rpm, 4°C, in an SW28 rotor using a Beckman Coulter Optima™ L-XP Ultracentrifuge System. Forty fractions were collected from the top of the gradient by using an ISCO Tris pump while monitoring absorbance at 254 nm with an ISCO UA-6 monitor. The RNP populations were grouped according to their sedimentation rates: mRNP, 40S, monosomes and polyribosome fractions.
Boron Tolerance Assays
YPD (2% glucose, 2% peptone, 1% yeast extract and 2% agar) or YNB (2% glucose, 0.67% yeast nitrogen base without amino acids and 2% agar) agar plates with different concentrations of boric acid were prepared. Overnight cultures were diluted to an optical density of 0.2 at 600 nm and then serially diluted to 0.02, 0.002, and 0,002. A 5 µl aliquot of each dilution was spotted on plates and incubated for 3 days at 30°C.
RNA Isolation and Real Time PCR Analyses
Total RNA was isolated from boron-treated and untreated samples using an RNA isolation kit (Invitrogen). Genomic DNA traces were removed by DNAse treatment (Fermentas). Complementary DNA (cDNA) from total mRNA was obtained using the First Strand cDNA Synthesis Kit (Fermentas). The cDNA was used as a template for amplifying a 186 bp fragment for the ATR1 gene, a 155 bp fragment for the GCN4 gene and a 103 bp fragment for the internal control ACT1 gene. Triplicate real-time PCR analyses were performed with the IQ5 real-time PCR system (Bio-Rad) using Fermentas MaximaTM SYBR Green qPCR Master Mix (2X). The primers used for the amplification of ATR1 were ATR1F (5′-ACGCGTATAGCATAGCCGCTTTCA-3′) and ATR1B (5′-TGTAAGCCTGGTTCCAACCCGATA-3′); the primers used for the amplification of GCN4 were GCN4F (5′-ATCCAATGGGTTTCTCACCA-3′) and GCN4B (5′- CGAAGGGGTATCCTGTTTGA-3′); and those used for the amplification of ACT1 were ACT1F (5′-ACGTTCCAGCCTTCTACGTTTCCA-3′) and ACT1B (5′-ACGTGAGTAACACCATCACCGGAA-3′). The conditions of PCR amplification for ATR1 were as follows: 40 cycles at 94°C for 30 s, 58°C for 30 s and 72 °C for 30 s, and for GCN4: 40 cycles at 94°C for 30 s, 56°C for 30 s, and 72°C for 30 s.
Cloning of YAP1 and GCN4 Genes
Wild type alleles of YAP1 and GCN4 were amplified using High Fidelity Enzyme (Fermentas) from yeast genomic DNA using the following primers: YAP1F (5′GGGGACAAGTTTGTACAAAAAAGCAGGCTCTTAAACCATGAGTGTGTCT-3′) and YAP1B (5′GGGGACCACACTTTGTACAAGAAAGCTGGGTGTTCCCGCTTTAGTTCATAT-3′) for YAP1, and GCN4F (5′GGGGACAAGTTTGTACAAAAAAGCAGGCTAATGTCCGAATATCAGCCAA-3′) and GCN4B (5′GGGGACCACTTTGTACAAGAAAGCTGGGTATGAAATCAGCGTTCGCCAA-3′) for GCN4. The amplified fragments were first cloned into the pDONR vector using 2 µl BP ClonaseTM II enzyme (Invitrogen) with an overnight incubation at 25°C and then moved to LR clonase reaction. This reaction was performed with 2 µl of isolated entry clones, 1.5 µl pAG423GPD expression vector, 3 µl TE buffer and 2 µl LR ClonaseTM II enzyme mixture (Invitrogen). Isolated plasmids were verified by sequence analyses, and then yeast cells were transformed with the empty vector or with a gene expression construct, and selected for histidine prototrophy. Plasmids with Gcn2 (p4384, flag epitope-tagged form of GCN2; p4055, nonphosphorylatable S577-Alanine mutation; p4056, substitutions in the m2 motif of the HisRS-like domain; p4057, with substitutions both in the m2 motif and the S577A motif) were obtained from Alan Hinnebusch (NIH).
β-galactosidase activity assays
Wild type cells were transformed with the p180 plasmid which carries the GCN4-lacZ gene [41]. Overnight cultures of wild type cells in 25 ml of YNB-URA were diluted to 0.1 at OD600. After 2 hours incubation, cultures were split into two flasks with or without 50 mM boric acid. After 1 hour growth in the presence of boron, 100 µl of cell solution, at an optical density between 0.2 and 0.6 at 600 nm, was taken and homogenized in 400 µl of Z-buffer [60 mM Na2HPO4, 40 mM NaH2PO4, 10 mM KCl, 1 mM MgSO4, 50 mM β-mercaptoethanol and 0.2% N-lauryl sarcosine]. After 30 min preincubation at 30°C, 150 µl of Z-buffer with 4 mg/ml, ONPG (o-nitrophenyl-β-D-galactopyranoside) (FlukaBioChemika) was added to the suspensions and the resulting solutions were incubated at 30°C for one hour. The reaction was stopped by adding 400 µl 1.5 M Na2CO3. After centrifugation for 1 min, supernatants were taken and their absorbance assayed at 420 nm [42]. The obtained absorbance values were normalized according to the OD values of cells.
Aminoacylation of tRNAs in boric acid
Total calf liver tRNA (Sigma) was aminoacylated under limiting tRNA conditions with either 3H-serine (Moravek Biochemicals, specific activity 20 Ci/mmol) or 3H-phenylalanine (GE Healthcare, specific activity 123 Ci/mmol) and 19 unlabelled amino acids in the presence of rabbit reticulocyte synthetases as described [43] and various concentrations of boric acid (Sigma).
Supporting Information
Figure S1.
Growth rates of cells transfromed with GCN4 or YAP1 plasmids.
https://doi.org/10.1371/journal.pone.0027772.s001
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Figure S2.
Inhibition of aminoacylation of tRNAs by boric acid.
https://doi.org/10.1371/journal.pone.0027772.s002
(TIF)
Figure S3.
Gcn4 regulates different sets of genes in response to various stress conditions. Comparison of genomic expression profiles in response to boric acid, rapamycin, 3-AT and H2O2 in wild type and gcn4Δ cells using publicly available datasets [38].
https://doi.org/10.1371/journal.pone.0027772.s003
(TIF)
Table S1.
Gene expression profiles of WT, gcn4- and yap1- cells in response to 20 mM boric (1 h treatment).
https://doi.org/10.1371/journal.pone.0027772.s004
(XLS)
Table S2.
Genes whose expression changed more than 2-fold in response to boron stress in wild type cells.
https://doi.org/10.1371/journal.pone.0027772.s005
(XLS)
Table S3.
Genes whose expression changed more than 2-fold in gcn4Δ cells in response to boron.
https://doi.org/10.1371/journal.pone.0027772.s006
(XLS)
Acknowledgments
We thank Alan Hinnebusch (NIH) for providing GCN2 plasmids, Bunyamin Akgul and Ozge Tuncel (Izmir Institute of Technology, Turkey) for their help with polysome analyses and Biotechnology Center (Izmir Institute of Technology) for their help in instruments.
Author Contributions
Conceived and designed the experiments: A.Koc DF HK. Performed the experiments: IU A.Kaya DF BC A.Koc. Analyzed the data: A.Koc DF VG. Wrote the paper: A.Koc IU DF VG HK.
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