Ribosome-binding Domain of Eukaryotic Initiation Factor-2 Kinase GCN2 Facilitates Translation Control*

Shuhao Zhu and Ronald C. WekDagger

From the Department of Biochemistry and Molecular Biology, Indiana University School of Medicine, Indianapolis, Indiana 46202-5122

    ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

A family of protein kinases regulate translation initiation in response to cellular stresses by phosphorylation of eukaryotic initiation factor-2 (eIF-2). One family member from yeast, GCN2, contains a region homologous to histidyl-tRNA synthetases juxtaposed to the kinase catalytic domain. It is thought that uncharged tRNA accumulating during amino acid starvation binds to the synthetase-related sequences and stimulates phosphorylation of the alpha  subunit of eIF-2. In this report, we define another domain in GCN2 that functions to target the kinase to ribosomes. A truncated version of GCN2 containing only amino acid residues 1467 to 1590 can independently associate with the translational machinery. Interestingly, this region of GCN2 shares sequence similarities with the core of the double-stranded RNA-binding domain (DRBD). Substitutions of the lysine residues conserved among DRBD sequences block association of GCN2 with ribosomes and impaired the ability of the kinase to stimulate translational control in response to amino acid limitation. Additionally, as found for other DRBD sequences, recombinant protein containing GCN2 residues 1467-1590 can bind double-stranded RNA in vitro, suggesting that interaction with rRNA mediates ribosome targeting. These results indicate that appropriate ribosome localization of the kinase is an obligate step in the mechanism leading to translational control by GCN2.

    INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Targeting of proteins to different compartments in the cell is an important mechanism regulating protein function. Proteins can associate with organelles, membranes, or components in the soluble fraction of the cell, providing proteins access to substrates or regulatory ligands. GCN2 is a member of a family of protein kinases that regulate translation by phosphorylation of eukaryotic translation initiation factor-2 (eIF-2)1 (1-4). Localization of GCN2 protein kinase to ribosomes appears to be a critical step leading to phosphorylation of eIF-2 in response to cellular stress.

Phosphorylation of eIF-2 is a well characterized mechanism regulating eukaryotic protein synthesis. The eIF-2 is a three-subunit protein that couples with Met-tRNAiMet and participates in ribosomal selection of the start codon (5). During this initiation process, GTP bound to eIF-2 is hydrolyzed to GDP. Phosphorylation of the alpha  subunit of eIF-2 at serine 51 impedes recycling of eIF-2-GDP to the active form, eIF-2-GTP. Currently, three protein kinases that phosphorylate this regulated site of eIF-2 have been characterized and their cDNAs cloned (1-3). Two of the proteins regulate protein synthesis in mammalian cells. The RNA-dependent protein kinase, PKR, participates in the antiviral defense mechanism mediated by interferon (6) and is also thought to function as a suppressor of cell proliferation and tumorigenesis (7-9), and the heme-regulated inhibitor kinase, HRI, is expressed predominately in reticulocytes and bone marrow and couples the synthesis of globin, the principal translation product in these tissues, to hemin availability (10). The third eIF-2 kinase, GCN2, functions in the general amino acid control pathway of yeast Saccharomyces cerevisiae. In response to starvation for any one of several different amino acids, GCN2 phosphorylation of eIF-2 stimulates the translation of GCN4 (2, 4, 11, 12). The GCN4 protein is a transcriptional activator of more than 30 genes involved in amino acid biosynthesis.

This report centers on the regulation of the GCN2 protein kinase. The kinase catalytic domain of GCN2 shares sequence and structural similarities with the PKR and HRI that are distinguishable from other eukaryotic protein kinases (2, 13, 14). Adjacent to the kinase catalytic domain, GCN2 contains a region homologous to histidyl-tRNA synthetase (HisRS) that binds uncharged tRNA (12, 15). It is proposed that different uncharged tRNAs, which accumulate during amino acid starvation conditions, can interact with the synthetase-related domain of GCN2, resulting in activation of the kinase and phosphorylation of eIF-2 (2, 4, 12, 15, 16).

Another domain that is important for regulation of GCN2 involves targeting of the kinase to ribosomes. Ramirez et al. (17) showed by several criteria that GCN2 was associated with ribosomes. GCN2 co-migrated with free 40 S and 60 S ribosomal subunits, 80 S particles, and polysomes separated by sucrose gradient centrifugation. When ribosomes were dissociated into 40 S and 60 S subunits by omitting MgCl2 from the extract preparation, GCN2 remained associated with 60 S ribosomal subunits (17). GCN2 was also complexed with ribosomal subunits after electrophoresis in a composite agarose-acrylamide gel under nondenaturing conditions. The related eIF-2 kinase, PKR, was also found to interact with the ribosomal machinery based on biochemical fractionation (3, 18-20) and immunofluorescent staining (21). Two regions in the amino terminus of PKR, designated dsRNA-binding domains (DRBDs), contain several basic amino acids in a predicted alpha -helical structure that are related to a family of RNA-binding proteins (22-25). In addition to regulating kinase activity by dsRNA, the DRBD sequences facilitate PKR association with ribosomes (20). PKR targeting to ribosomes is proposed to enhance in vivo phosphorylation of eIF-2 by providing the kinase access to this substrate.

In this report, we describe the finding that GCN2 residues 1467-1590 can bind independently to ribosomes. This GCN2 domain contains a lysine-rich sequence with features similar to the core of the DRBDs. Alteration of these conserved lysine residues blocked both GCN2 interaction with ribosomes and stimulation of GCN4 expression in response to starvation for amino acids. As previously observed for the DRBDs, the lysine residues are essential for binding to dsRNA in vitro, suggesting that interaction with rRNA mediates ribosome targeting. This cellular localization may provide GCN2 access to its eIF-2 substrate or to regulatory ligands. Furthermore, these findings indicate that related RNA-binding sequences facilitates the in vivo activities of both GCN2 and PKR in response to cellular stresses.

    MATERIALS AND METHODS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Yeast Strains and Plasmid Constructions-- Yeast strains H1149 (MATalpha gcn2::LEU2 ino1 ura3-52 leu2-3, -112 HIS4-lacZ) (15) and H1816 (MATa ura3-52 leu2-3,-112 Delta gcn2 Delta sui2 GCN4-lacZ p1097 [SUI2, LEU2]) (11) were transformed with different alleles of GCN2 in the following low copy number URA3-based plasmids: GCN2 in p722 (26); gcn2-m2 in p299 (12); GCN2 in pC102-2 (27); and p560 (15) is a derivative of pC102-2 containing a unique SacI restriction site introduced into GCN2 after the codon for residue 1467. There were no detectable differences in the GCN2 phenotype between strains transformed with plasmids p722, pC102-2, or p560. Plasmid p630 (26) contains GCN2 inserted into the high copy number URA3 plasmid YEp24. Plasmids p332 (12) and p644 (26) are derivatives of p630 containing the gcn2-m2 and gcn2-K559R alleles, respectively. To construct the gcn2-605 mutation, three lysine residues in the carboxyl terminus of GCN2, at positions 1483, 1484, and 1487, were altered by polymerase chain reaction to CTG, ATA, and ATA encoding leucine, isoleucine, and isoleucine, respectively. The gcn2-605 mutation was introduced into plasmid p560 to generate the low copy number plasmid pSZ-6, and into high copy number plasmid p630 to generate pSZ-15.

To express the carboxyl-terminal portion of GCN2 in Escherichia coli we inserted a 0.7-kilobase SacI to SalI restriction fragment from p560 into a pET-15b derivative. The resulting plasmid, pSZ-3, encodes a polyhistidine amino-terminal sequence fused with GCN2 residues 1467-1590 downstream from the bacteriophage T7 promoter. Plasmid pSZ-5 is a similar construct that encodes the gcn2-605 mutations. To express this histidine-tagged portion of GCN2 in yeast strain WY294 (MATalpha ino1 ura3-52 leu2-3,-112 trp1 HIS4-lacZ) (28) or H1894 (MATa Delta gcn2 ura3-52 leu2-3,-112 trp1-Delta 63), polymerase chain reaction was used to insert the fusion gene into pYCDE2 (29). The resulting plasmid pSZ-31 expresses the truncated GCN2 sequences from the constitutively expressed ADC1 promoter. The kinase domain of GCN2 from residues 502 to 1054 were expressed in yeast using p408 as described previously (28).

Assay for GCN4-lacZ and His4-lacZ Enzyme Activity-- beta -Galactosidase activity was measured as described previously (30). For repressing conditions, saturated cultures were diluted 1:50 in the synthetic dextrose (SD) medium (31) supplemented with essential amino acids and cells were harvested after growth for 5 h at 30 °C. For starvation conditions, cells were grown for 2 h under repressing conditions, 10 mM 3-aminotriazole was added to the medium and the culture was incubated for an additional 5 h at 30 °C. Values reported here are the averages from three independent assays. beta -Galactosidase activities were expressed as nanomoles of o-nitrophenyl-beta -D-galactopyranoside hydrolyzed per min/mg of protein.

GCN2 Immunoblot and Immunoprecipitation Kinase Assay-- Immunoblots were carried out as described previously (26). Full-length GCN2 and gcn2-502-1054 were detected using rabbit polyclonal antiserum prepared against a TrpE-GCN2 fusion protein (15) and 125I-protein A. The polyhistidine tagged gcn2-1467-1590 was measured by immunoblot analysis using rabbit polyclonal antibody prepared against the carboxyl terminus of GCN2 and horseradish peroxidase-labeled secondary antibody. The gcn2-1467-1590 fusion protein, with a molecular weight of 16,000, was also detected using rabbit polyclonal antisera prepared against the polyhistidine tag encoded in pET-15b and was absent in strain WY294 containing the pYCDE2 vector alone. Relative amounts of GCN2 proteins were compared by measuring band intensities from autoradiographs of different length exposures using a Bio-Rad Model GS-670 Imaging Densitometer. GCN2 immunoprecipitation kinase assays were performed as described previously with the immunoprecipitation reactions carried out in the presence of 0.1% SDS, 1.0% Triton X-100, and 0.5% sodium deoxycholate (17, 26).

Ribosome Association-- Yeast strain H1149 was transformed with pC102-2, low copy number plasmid encoding GCN2; p630, high copy GCN2; p299, low copy gcn2-m2; p332, high copy gcn2-m2; pSZ-6, low copy gcn2-605; pSZ-15, high copy gcn2-605; or p644, high copy gcn2-K559R. No differences were detected in GCN2 ribosome association when the kinase was expressed from low copy or high copy number plasmids (17). The gcn2-1467-1590 protein was expressed using strain WY294 containing pSZ-31 and gcn2-502-1054 was expressed using H1816 containing p408 (28). Cells were grown under repressing conditions and 50 µg/ml cycloheximide was added to the culture 5 min before harvesting. Cells were collected by centrifugation and washed once with Breaking Solution (20 mM Tris-HCl, pH 7.9, 50 mM NaCl, 10 mM MgCl2, 1 mM dithiothreitol, 50 µg/ml cycloheximide, and 200 µg/ml heparin). Cells were resuspended in Breaking Solution in the presence of protease inhibitors (1 µM pepstatin, 1 µM leupeptin, 0.15 µM aprotinin, and 100 µM phenylmethylsulfonyl fluoride), lysed using glass beads, and clarified. Supernatant samples containing 20 A260 units were loaded onto a 5-47% sucrose gradient in Breaking Solution without heparin as described previously (17) and ultracentrifugation was performed using a Beckman rotor SW41 at 39,000 rpm for 3 h. Gradients were fractionated using an ISCO UA-6 absorbance monitor set at 254 nm and 0.5-ml aliquots were collected. Sucrose gradient analysis of the gcn2-1467-1590 fusion was also performed without cycloheximide and Mg2+ using a modified Breaking Solution (20 mM Tris-HCl, pH 7.9, 50 mM NaCl, 1 mM dithiothreitol, and 1 mM EDTA) in the presence or absence of 0.5 M KCl as described (17).

Expression of Recombinant Carboxyl-terminal GCN2 Protein-- E. coli strain BL21 (DE3) (F- ompT rB- mB- containing lysogen DE3) transformed with either expression plasmid pSZ-3 or pSZ-5 was grown at 30 °C in LB medium supplemented with 100 µg/ml ampicillin until mid-logarithmic phase and 0.5 mM isopropyl-1-thio-beta -D-galactopyranoside was added to the culture and incubated for an additional 3 h. The cell pellet was collected by centrifugation and washed once with a solution of 20 mM Tris-HCl, pH 7.9, and 500 mM NaCl. Cells were then resuspended in solution A (20 mM Tris-HCl, pH 7.9, 500 mM NaCl, 10% glycerol, and 1 mM phenylmethylsulfonyl fluoride) with 5 mM imidazole and lysed using a French press. Lysates were clarified by centrifugation at 39,000 × g and supernatant was loaded onto a column containing nickel chelation resin (Qiagen, Hilden, Germany) that binds to the polyhistidine tag of the fusion proteins. After washing the column with solution A containing 180 mM imidazole, gcn2-1467-1590 fusion proteins were eluted with 400 mM imidazole in solution A. The molecular weight of the gcn2-1467-1590 fusion protein was 16,000, in agreement with that predicted from the DNA sequence. This protein was absent from an identically prepared extract from BL21(DE3) transformed with vector pET-15b. Additionally, both GCN2 and gcn2-605 recombinant proteins were recognized by polyclonal antiserum prepared against the carboxyl terminus of GCN2.

dsRNA Binding Assay-- To measure binding of the gcn2-1467-1590 recombinant to dsRNA, we followed a procedure similar to that described by O'Malley et al. (32). Briefly, 5 µg of GCN2 or gcn2-605 recombinant protein were mixed with poly(I)·poly(C) bound to Sepharose 4B (Pharmacia Biotech) or Sepharose 4B alone in a 100-µl solution of binding buffer (20 mM HEPES, pH 7.5, 200 mM KCl, 10 mM MgCl2, and 0.5% Nonidet P-40). After incubating the binding mixtures for 30 min at room temperature, the beads were collected by brief centrifugation at 10,000 × g. Beads were washed three times in binding buffer and recombinant protein bound to the beads were eluted by added SDS sample buffer, followed by boiling for 5 min. Equal aliquots of each sample were analyzed by gel electrophoresis in a 15% SDS-polyacrylamide gel and the recombinant protein was visualized by staining the gel with Coomassie Blue.

Circular Dichroism Spectrapolarimetry-- CD spectra were measured at 25 °C using a Jasco J-720 spectropolarimeter. Samples were prepared in 25 mM potassium phosphate buffer (pH 7.5). Three scans were averaged and the spectra were recorded with a 0.1-cm path length cuvette from 190 to 280 nm at a speed of 50 nm/min and with an increment of 1 nm. The mean residue ellipticities were calculated per amide bond. Secondary structure contents were estimated using the reference spectra of Yang et al. (33) and the SSE-338 program (Japan Spectroscopic Co., Tokyo, Japan).

    RESULTS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Carboxyl Terminus of GCN2 Functions as a Ribosome-binding Domain-- GCN2 interaction with ribosomes is proposed to facilitate stimulation of GCN4 translation in response to amino acid starvation. Ribosomal association appears to involve the carboxyl-terminal portion of GCN2 since deletion of this region reduced interaction of the kinase with ribosomes (17). To directly address whether the carboxyl terminus of GCN2 functions independently as a ribosome-binding domain, we expressed a polyhistidine fusion protein containing only GCN2 residues 1467-1590 in yeast strain WY294. Cell lysates were prepared as described under "Materials and Methods" and analyzed by sucrose gradient sedimentation. The distribution of the gcn2-1467-1590 in each gradient fraction was measured by immunoblot using polyclonal antiserum prepared against the carboxyl terminus of GCN2 (Fig. 1). The truncated GCN2 protein co-sedimented with ribosomes, with over 80% of gcn2-1467-1590 found in gradient fractions containing 60 S and 80 S particles and polysomes. Similar results were found when the truncated GCN2 protein was expressed in strain H1894 (Delta gcn2) indicating that the ribosomal association was independent of endogenous full-length GCN2. By comparison, the GCN2 kinase catalytic sequences from 502 to 1054 expressed in yeast migrated free of ribosomes when analyzed in a similar sucrose gradient (Fig. 1B).


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Fig. 1.   Carboxyl-terminal region of GCN2 functions as a ribosome-binding domain. Polyhistidine-tagged fusion proteins, containing GCN2 residues 1467-1590 or 502-1054, were expressed in yeast and cellular extracts and were analyzed by sucrose gradient sedimentation. In A and B, cycloheximide and MgCl2 were used in the extract preparation to arrest translation elongation and preserve polysomes during gradient analysis. In C and D, cycloheximide and Mg2+ were absent from the sucrose gradients, leading to 80 S ribosome dissociation into free 40 S and 60 S subunits. The sucrose gradient in D was supplemented with 0.5 M KCl to remove nonintegral ribosomal proteins. With the removal of nonintegral proteins, the free subunits migrated more slowly in the gradient and the arrows in D indicate the positions of 40 S and 60 S subunits in gradients analyzed in the absence of KCl. The top panels in each figure show the A254 profile of the gradient, with free 40 S and 60 S subunits, 80 S ribosomes, and polysomes indicated. The overlaid histogram shows the portion of gcn2-1467-1590 or gcn2-502-1054 protein found in each gradient fraction as measured by immunoblot analysis (bottom panels). Lane M in the immunoblot assay is the cellular lysate applied to the sucrose gradient. Sizes are indicated in kilodaltons to the left of each panel.

To further characterize the interaction of the carboxyl-terminal portion of GCN2 with ribosomes, we carried out sedimentation analysis in the absence of Mg2+, leading to the dissociation of ribosomes into free 40 S and 60 S particles. As previously observed for the full-length GCN2, we found that over 85% of the gcn2-1467-1590 protein comigrated with free 60 S subunits (Fig. 1C). When these samples were treated with 0.5 M KCl, the gcn2-1467-1590 protein was dissociated from the 60 S subunit. This dissociation in the presence of KCl was described previously for full-length GCN2 (17), indicating that GCN2 is not an integral ribosomal protein. These results taken together indicate that the amino acid residues from 1467 to 1590 directly target GCN2 kinase to ribosomes.

DRBD-related Sequences in the Carboxyl Terminus of GCN2 Are Required for Stimulation of the General Amino Acid Control Pathway-- Given that the DRBD sequences of PKR mediate association of this mammalian eIF-2 kinase with ribosomes (20), we examined whether there are sequence similarities between GCN2 residues 1467-1590 and the RNA-binding regions of PKR. Interestingly, residues 1479 to 1498 in GCN2 share sequence features similar to the core of the DRBD sequences found in PKR and other members of this RNA-binding family (Fig. 2). Although the structure of the RNA-binding regions in PKR have not yet been determined, the resolved structures of DRBD sequences from Staufen protein in Drosophila melanogaster and RNase III from E. coli show that this core region is alpha -helical (23, 34). The conserved lysine residues are located at the amino-terminal portion of the helix and are proposed to directly contact dsRNA (25, 35). Analysis of the GCN2 sequence also leads to a prediction of positively charged residues clustered in an alpha -helical secondary structure (Fig. 2).


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Fig. 2.   Carboxyl-terminal sequence of GCN2 shares sequence features with the DRBDs. Top, the box designated GCN2 represents the 1,590-amino acid-long sequence of the GCN2 protein kinase. GCN2 contains domains with homology to protein kinases and histidyl-tRNA synthetases (HisRS) (15). In the amino-terminal portion of GCN2 is an additional domain with sequences related to subdomains V1b to XI of eukaryotic protein kinases that is required for kinase function in vivo and in vitro (16, 26). Middle, alignment of the carboxyl terminus of GCN2 with different DRBD sequences. Amino acid residues with capital letters represent identities with proposed consensus sequences of the DRBDs (22-25). Numbers to the right of the sequences indicate the position of the last aligned residue in the indicated protein. Lysine residues at GCN2 positions 1483, 1484, and 1487 were altered to leucine, isoleucine, and isoleucine, respectively, in the gcn2-605 mutant allele. Dashes indicate a gap in the sequence. Bottom, helical wheel projection of GCN2 residues 1481 to 1498 predicted using the Garnier Plot program (54). Lysine residues in bold-capital letters are positions 1483, 1484, and 1487.

To determine the importance of this lysine-rich sequence of GCN2 in the stimulation of general control, we altered the three conserved lysine residues as shown in Fig. 2. The resulting mutant allele, termed gcn2-605, was introduced into the strain H1816 (Delta gcn2 GCN4-lacZ) on either a low copy or high copy number plasmid. The level of GCN4-LacZ enzyme activity was 5-fold higher in the strain H1816 expressing wild-type GCN2 in the presence of 3-aminotriazole, an inhibitor of histidine biosynthesis, than when these cells were grown under repressed or nonstarved conditions (Table I). In the absence of GCN2 function there was no increase in GCN4-LacZ enzyme activity in response to histidine starvation. The gcn2-605 mutant strain also showed very little increase in GCN4-LacZ enzyme activity during amino acid limiting conditions, even when the gcn2-605 allele was expressed from a high copy number plasmid. Consistent with the idea that the gcn2-605 protein is impaired for stimulation of the general control pathway, gcn2-605 strains also failed to grow on agar medium supplemented with 3-aminotriazole and showed no increase in the expression of HIS4-lacZ, a gene transcriptionally activated by GCN4, during starvation conditions. This reduction in gcn2-605 stimulation of the general amino acid control pathway is not due to instability of the mutant protein, as an immunoblot assay revealed steady-state levels of gcn2-605 protein to be comparable to wild-type GCN2 (Fig. 3). In fact, even when the gcn2-605 protein encoded on the high copy number plasmid was elevated 20-fold compared with the low copy number transformant, there was no measurable stimulation of the general control during amino acid starvation.

                              
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Table I
DRBD-related sequences in GCN2 are essential for stimulation of GCN4-LacZ and HIS4-LacZ enzyme activities in response to starvation for amino acids
beta -Galactosidase enzyme activity was assayed in extracts prepared from transformants of H1816 (Delta gcn2 GCN4-LacZ) and H1149 (Delta gcn2 HIS4-LacZ) containing the indicated GCN2 alleles. R, repressed or non-starved growth conditions; D, derepressed growth conditions imposed by the addition of 3-AT to the culture medium. Each GCN2 allele was encoded on a URA3-based plasmid as follows: GCN2 encoded in pC102-2; Delta gcn2 is vector YCp50; gcn2-605 encoded on low copy number plasmid PSZ-6 and high copy-number plasmid pSZ-15. Results shown are averages of three independent assays, and the individual measurements deviated from the average values shown here by 20% or less. Growth of H1149 transformants on 3-aminotriazole (3-AT) agar plates is a measure of stimulation of HIS3 expression in response to histidine limiting growth conditions. Symbols: +, confluent growth of replica-plated patches of cells after 2 days at 30 °C; nondiscernable growth under the same conditions.


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Fig. 3.   Immunoblot analysis of GCN2 protein. Protein extracts were prepared from strain H1149 (Delta gcn2) transformed with different plasmid-borne GCN2 alleles as described under "Materials and Methods." Equal amounts of protein extracts were separated by 7.5% SDS-PAGE, transferred to nitrocellulose paper and GCN2 protein was measured using antiserum prepared against a TrpE-GCN2 fusion protein. Lanes are designated by wild-type GCN2 or mutant gcn2-605 protein expressed from low copy number (L.C.) or high copy number (H.C.) plasmids. The steady-state levels of gcn2-605 and GCN2 proteins expressed from low copy number plasmids differed by less than 20% as judged by densitometry. Comparison of high copy levels of GCN2 indicate that gcn2-605 protein is 60% of wild-type kinase. The lane designated Delta gcn2 is strain H1149 transformed with vector YEp24.

Association between GCN2 and Ribosomes Requires the DRBD-related Sequences-- Alterations in the conserved lysine residues in the DRBD-related region of GCN2 blocked the ability of the kinase to stimulate GCN4 translation in response to histidine starvation. To determine whether this lysine-rich sequence is required for GCN2 association with ribosomes, we prepared cellular extracts from yeast strain H1149 encoding gcn2-605 or other mutant alleles of GCN2 and fractionated the lysates by centrifugation using sucrose gradients. In an earlier study, Ramirez et al. (17) measured GCN2 protein in each gradient fraction by immunoprecipitating GCN2 and assaying for autophosphorylation activity by incubation of the immune complex in the presence of [gamma -32P]ATP. This kinase assay which uses polyclonal antisera prepared against the GCN2 kinase domain was more sensitive than immunoblot assays and when compared in parallel experiments was found to be an accurate measure of steady-state protein levels. Consistent with this earlier study, we found wild-type GCN2 kinase associated with free 40 S, 60 S, and 80 S particles and polysomes. We observed a similar pattern of GCN2 distribution in the sucrose gradient when we fractionated a cellular extract prepared from yeast cells expressing the kinase from a high copy number plasmid and measured GCN2 protein by immunoblot analysis (data not shown).

To address whether the gcn2-605 mutant protein was altered for ribosomal association, a gcn2-605 strain lysate was fractionated by sucrose gradient sedimentation, followed by the immunoprecipitation kinase assay (Fig. 4). We observed that the autophosphorylation level of the mutant protein in the immunoprecipitation kinase assays was near that of wild-type GCN2 (Fig. 4, data not shown). The gcn2-605 protein was found near the top of the sucrose gradient, in fractions free of ribosomes. In a parallel experiment, lysate prepared from cells expressing the mutant kinase from a high copy number plasmid was analyzed by sucrose gradient centrifugation, followed by immunoblot analysis. Even when gcn2-605 protein levels were elevated in the cell we found the mutant kinase in the top portion of the gradient in fractions containing no ribosomes (data not shown).


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Fig. 4.   DRBD-related sequences facilitate association of GCN2 with ribosomes. Cellular extracts were prepared from strain H1149 (Delta gcn2) containing different plasmid-borne GCN2 alleles and analyzed by sucrose gradient centrifugation. The top panel shows the A254 profile of a representative gradient analyzing the GCN2 extract. Free 40 S, 60 S, and 80 S particles and polysomes are indicated. GCN2, gcn2-m2, or gcn2-605 proteins in each gradient sample was measured using the immunoprecipitation kinase assay. Kinase mutant protein, gcn2-K559R, was measured by immunoblot analysis. Marker, M, indicates analysis of pregradient extract sample.

Two additional mutant versions of GCN2 were next analyzed to determine whether the function of other domains of the kinase were essential for targeting to the translation machinery. First, we fractionated extracts prepared from cells expressing the mutant gcn2-K559R protein that contains a substitution of the conserved lysine in the ATP-binding sequence in the kinase catalytic domain, rendering it catalytically impaired (26). Immunoblot analysis of the gcn2-K559R protein in the gradient fractions revealed a similar profile to that determined for wild-type GCN2 (Fig. 4). Second, we analyzed a GCN2 mutant protein containing substitutions in the conserved Tyr and invariant Arg at positions 1050 and 1051, respectively, in the motif 2 sequence of the synthetase-related domain. Previously, this gcn2-m2 protein was shown to be blocked in its ability to stimulate GCN4 expression in response to amino acid limitation and was greatly reduced for binding in vitro to uncharged tRNA compared with wild-type GCN2 (12). Fractionation of the gcn2-m2 protein in the sucrose gradient revealed a ribosomal profile for the mutant protein similar to that determined for the wild-type GCN2 protein. Taken together with the ribosomal association of the kinase defective-gcn2-K559R protein, we conclude that binding of uncharged tRNA to the HisRS-related domain or subsequent activation of the kinase catalytic activity is not a prerequisite for ribosomal association of GCN2.

The Carboxyl Terminus of GCN2 Can Bind dsRNA and Contains an alpha -Helical Structure-- Given the well characterized affinity of the DRBD regions of PKR for dsRNA, we wanted to address directly whether the carboxyl-terminal domain of GCN2 shared this binding property. We overexpressed in E. coli a recombinant protein containing the GCN2 sequence from residues 1467 to 1590 fused to an amino-terminal sequence containing six contiguous histidine residues. Nickel chelation resin was used to purify the recombinant fusion protein, and in parallel, we overexpressed and purified a similar fusion protein containing the gcn2-605 residue substitutions. Both proteins were purified to apparent homogeneity as judged by Coomassie staining of an SDS-polyacrylamide gel after electrophoretic analysis (Fig. 5). Purified GCN2 or gcn2-605 recombinant protein were mixed in a buffer solution containing poly(I)·poly(C) bound to Sepharose or to Sepharose alone. After incubating the samples, beads were collected by a brief centrifugation and washed. Equal aliquots of proteins bound to beads were analyzed by SDS-PAGE and visualized by staining with Coomassie Blue (Fig. 5). Recombinant protein containing the carboxyl-terminal domain from wild-type GCN2 was found to bind dsRNA, whereas no association was found with Sepharose alone. The recombinant gcn2-605 protein had no affinity for dsRNA. We conclude that the ribosomal targeting domain of GCN2 can bind dsRNA.


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Fig. 5.   Lysine residues in DRBD-related sequences of GCN2 are required for binding to dsRNA. Purified recombinant protein containing amino acid residues 1467-1590 from wild-type GCN2 or gcn2-605 were mixed with poly(I)·poly(C) bound Sepharose or with Sepharose alone. Bound recombinant proteins were analyzed by SDS-PAGE and visualized by staining the gel with Coomassie Blue. Lanes 1-3 are recombinant proteins containing residues 1467 to 1590 from wild-type GCN2, and lanes 4-6 contain the carboxyl-terminal portion of gcn2-605 protein. Lanes 1 and 4 are purified recombinant proteins (Total); lanes 2 and 5 are recombinant proteins bound to Sepharose; and lanes 3 and 6 are recombinant proteins bound to poly(I)·poly(C) linked with Sepharose (dsRNA-Sepharose). M, protein standards with sizes in kilodaltons shown to the left.

To learn more about the secondary structure properties of the carboxyl-terminal region of GCN2, we measured the circular dichroism spectrum of the recombinant GCN2 protein (Fig. 6). The spectrum contains a broad negative trough of ellipticity with minimum near 208 and 222 nm and positive ellipticity at 192-193 nm. This spectrum is characteristic of helix-containing proteins and analysis of the secondary structure indicated a 45% alpha -helical content (see "Materials and Methods"). The gcn2-605 recombinant protein showed a similar spectrum suggesting that these residue substitutions did not disrupt the secondary structure of the GCN2 protein. To assess whether the polyhistidine tag contributed to the helical properties, we utilized a thrombin proteolytic cleavage site located between the amino-terminal polyhistidine and GCN2 sequences to remove the tag from the recombinant protein. After purification of the cleaved version of the recombinant protein, the CD spectrum was shown to be similar to that determined in Fig. 6, indicating that the polyhistidine tag did not contribute to the determination of helical content.


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Fig. 6.   Circular dichroism spectrum of purified recombinant proteins containing GCN2 carboxyl terminus. A CD spectrum was analyzed for recombinant protein containing residues 1467 to 1590 from wild-type GCN2 (solid line) and gcn2-605 (dotted line).

    DISCUSSION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

GCN2 is a multidomain protein kinase that regulates GCN4 translation initiation in response to amino acid starvation. In this report, we observed that the carboxyl terminus of GCN2 from residues 1467 to 1590 directly facilitate targeting of the kinase to the translation machinery. Interestingly, comparison of this region of GCN2 with DRBD sequences that facilitate ribosome interaction of a related eIF-2 kinase, PKR, revealed a lysine-rich sequence in GCN2 with features similar to the core of this RNA-binding domain. Substitutions of lysine residues conserved among DRBDs block association of GCN2 with ribosomes and impaired the ability of the kinase to stimulate the general control pathway in response to amino acid limitation. These results suggest that appropriate localization of GCN2 to the translational machinery is an obligate step in the mechanism leading to kinase phosphorylation of eIF-2.

Role of Ribosome Binding in Stimulating GCN2 Phosphorylation of eIF-2alpha in Response to Amino Acid Starvation Conditions-- Three mutant alleles of GCN2 were examined for their effects on association of the kinase to ribosomes. While the gcn2-605 protein, containing substitutions in the DRBD-related sequence, was not associated with ribosomes, the kinase-defective gcn2-K559R protein showed a pattern of ribosome interaction similar to wild-type GCN2 (Fig. 4). GCN2 interaction with uncharged tRNA also does not appear to be a prerequisite step leading to ribosome association, since the gcn2-m2 mutant protein, containing substitutions in the HisRS-related domain that greatly reduce binding of uncharged tRNA in vitro (12), co-fractionates with ribosomes in the sucrose gradient (Fig. 4). These results suggest that the DRBD-related sequence of GCN2 interacts with ribosomes independent of autophosphorylation of GCN2 or stimulation of kinase activity by uncharged tRNA that accumulates during amino acid starvation conditions.

What role does association with ribosomes play in the process leading to GCN2 phosphorylation of eIF-2alpha ? Targeting to ribosomes could provide GCN2 access to its substrate eIF-2. During initiation of translation, eIF-2 is associated with ribosomal subunits, providing ribosome-associated GCN2 proximity to its substrate (5, 17). A second possible role of ribosome association in the regulation of GCN2 kinase is that it provides a vehicle for GCN2 to monitor the levels of uncharged tRNA in the cell. GCN2 interaction with ribosomes may be adjacent to the aminoacyl (A) site, with the HisRS-related domain monitoring uncharged tRNA that enters and is released from this site during the elongation of step in protein synthesis. The proximity of GCN2 in the ribosome would be similar to that of the RelA protein of E. coli. In this example, the ppGpp synthetase activity of RelA is thought to be stimulated by uncharged tRNA that binds the A site during amino acid starvation conditions (36). This model implies that the uncharged tRNA levels in the cell can be more efficiently monitored by GCN2 when the kinase is associated with ribosomes compared with the kinase being dispersed throughout the cytoplasmic solution.

In support of the idea that a ribosomal context facilitates monitoring of uncharged tRNA levels, Deutscher and colleagues (37-39) proposed that there is cellular channeling process for delivery and release of tRNA to the translation apparatus. During this channeling, tRNAs are directly transferred from aminoacyl-tRNA synthetases to the elongation factors to the ribosomes without being freely soluble in the cytoplasmic fluid. After deacylation during the translation process, tRNAs reassociate with their cognate aminoacyl tRNA synthetases to repeat the cycle. Perhaps, during conditions of amino acid limitation, uncharged tRNAs whose levels are elevated, enter and are released from the A site with increased frequency by this channeling process. The ribosome localization of GCN2 would provide the kinase access to one of the channeling steps, allowing the synthetase-related domain of GCN2 to monitor the levels of uncharged tRNAs. Ancillary factors such as GCN1 and GCN20 (40, 41), that form a heterocomplex associated with ribosomes and are required for high levels of GCN2 phosphorylation of eIF-2 during histidine limitation, may function to direct uncharged tRNAs from the A site to the HisRS-related domain of GCN2 (42).

General Role of DRBD Sequences in Targeting Proteins to Ribosomes-- Over 20 different proteins have been identified that contain DRBD sequences (24). Many of these proteins have been characterized only by genomic sequencing projects and the role of DRBDs in facilitating their physiological functions are currently unclear. We have shown that DRBD-related sequences mediate association of the eIF-2 kinases, GCN2 and PKR, with ribosomes. Recently, another DRBD-containing protein, X1rbpa, that is the Xenopus homolog of TAR-RNA-binding protein, was also found to associate with ribosomes (43). Another likely example is the protein encoded by the YML3 gene from S. cerevisiae (44, 45) that contains a single DRBD and is associated with the large ribosomal subunit in mitochondria. The specific ribosomal locations that can accommodate by different DRBD sequences appear to be variable, with ribosomal dissociation experiments indicating that GCN2 and PKR are localized to 60 S and 40 S ribosomal subunits, respectively. These different ribosomal binding sites suggest that DRBD sequences bind to unique double-stranded regions in rRNA. Amino acid residue differences between the DRBDs would be expected to mediate this specificity for different RNA sequences and structures. Additionally, the fact that many proteins contain multiple DRBD sequences suggests that multiple RNA-binding elements may contribute to the affinity for unique ribosomal sites.

    ACKNOWLEDGEMENTS

We thank Peter Roach and Anna DePaoli-Roach for their comments on this manuscript, Eric Long for his assistance with the circular dichroism studies, and Minerva Garcia-Barrio and Alan Hinnebusch for GCN2 antiserum.

    FOOTNOTES

* This work was supported in part by United States Public Health Service Grant GM49164 from the National Institutes of Health.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed. Tel.: 317-274-0549; Fax: 317-274-4686; E-mail: ron_wek{at}iucc.iupui.edu.

1 The abbreviations used are: eIF-2, eukaryotic initiation factor-2; ds, double-stranded; DRBD, double-stranded RNA-binding domain; PAGE, polyacrylamide gel electrophoresis.

    REFERENCES
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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