Association of GCN1-GCN20 regulatory complex with the N-terminus of eIF2alpha kinase GCN2 is required for GCN2 activation

Stimulation of GCN4 mRNA translation due to phosphorylation of the alpha-subunit of initiation factor 2 (eIF2) by its specific kinase, GCN2, requires binding of uncharged tRNA to a histidyl-tRNA synthetase (HisRS)-like domain in GCN2. GCN2 function in vivo also requires GCN1 and GCN20, but it was unknown whether these latter proteins act directly to promote the stimulation of GCN2 by uncharged tRNA. We found that the GCN1-GCN20 complex physically interacts with GCN2, binding to the N-terminus of the protein. Overexpression of N-terminal GCN2 segments had a dominant-negative phenotype that correlated with their ability to interact with GCN1-GCN20 and impede association between GCN1 and native GCN2. Consistently, this Gcn(-) phenotype was suppressed by overexpressing GCN2, GCN1-GCN20 or tRNA(His). The requirement for GCN1 was also reduced by overexpressing tRNA(His) in a gcn1Delta strain. We conclude that binding of GCN1-GCN20 to GCN2 is required for its activation by uncharged tRNA. The homologous N-terminus of Drosophila GCN2 interacted with yeast GCN1-GCN20 and had a dominant Gcn(-) phenotype, suggesting evolutionary conservation of this interaction.     

IMPACT, a protein preferentially expressed in the mouse brain, binds GCN1 and inhibits GCN2 activation

Translational control directed by the eukaryotic translation initiation factor 2 alpha-subunit (eIF2alpha) kinase GCN2 is important for coordinating gene expression programs in response to nutritional deprivation. The GCN2 stress response, conserved from yeast to mammals, is critical for resistance to nutritional deficiencies and for the control of feeding behaviors in rodents. The mouse protein IMPACT has sequence similarities to the yeast YIH1 protein, an inhibitor of GCN2. YIH1 competes with GCN2 for binding to a positive regulator, GCN1. Here, we present evidence that IMPACT is the functional counterpart of YIH1. Overexpression of IMPACT in yeast lowered both basal and amino acid starvation-induced levels of phosphorylated eIF2alpha, as described for YIH1 (31). Overexpression of IMPACT in mouse embryonic fibroblasts inhibited phosphorylation of eIF2alpha by GCN2 under leucine starvation conditions, abolishing expression of its downstream target genes, ATF4 (CREB-2) and CHOP (GADD153). IMPACT bound to the minimal yeast GCN1 segment required for interaction with yeast GCN2 and YIH1 and to native mouse GCN1. At the protein level, IMPACT was detected mainly in the brain. IMPACT was found to be abundant in the majority of hypothalamic neurons. Scattered neurons expressing this protein at higher levels were detected in other regions such as the hippocampus and piriform cortex. The abundance of IMPACT correlated inversely with phosphorylated eIF2alpha levels in different brain areas. These results suggest that IMPACT ensures constant high levels of translation and low levels of ATF4 and CHOP in specific neuronal cells under amino acid starvation conditions.     

GCN20, a novel ATP binding cassette protein, and GCN1 reside in a complex that mediates activation of the eIF-2 alpha kinase GCN2 in amino acid-starved cells.

GCN2 is a protein kinase that phosphorylates the alpha-subunit of translation initiation factor 2 (eIF-2) and thereby stimulates translation of GCN4 mRNA in amino acid-starved cells. We isolated a null mutation in a previously unidentified gene, GCN20, that suppresses the growth-inhibitory effect of eIF-2 alpha hyperphosphorylation catalyzed by mutationally activated forms of GCN2. The deletion of GCN20 in otherwise wild-type strains impairs derepression of GCN4 translation and reduces the level of eIF-2 alpha phosphorylation in vivo, showing that GCN20 is a positive effector of GCN2 kinase function. In accordance with this conclusion, GCN20 was co-immunoprecipitated from cell extracts with GCN1, another factor required to activate GCN2, and the two proteins interacted in the yeast two-hybrid system. We conclude that GCN1 and GCN20 are components of a protein complex that couples the kinase activity of GCN2 to the availability of amino acids. GCN20 is a member of the ATP binding cassette (ABC) family of proteins and is closely related to ABC proteins identified in Caenorhabditis elegans, rice and humans, suggesting that the function of GCN20 may be conserved among diverse eukaryotic organisms.     

Separate domains in GCN1 for binding protein kinase GCN2 and ribosomes are required for GCN2 activation in amino acid-starved cells

GCN2 stimulates GCN4 translation in amino acid-starved cells by phosphorylating the alpha-subunit of translation initiation factor 2. GCN2 function in vivo requires the GCN1/GCN20 complex, which binds to the N-terminal domain of GCN2. A C-terminal segment of GCN1 (residues 2052-2428) was found to be necessary and sufficient for binding GCN2 in vivo and in vitro. Overexpression of this fragment in wild-type cells impaired association of GCN2 with native GCN1 and had a dominant Gcn(-) phenotype, dependent on Arg2259 in the GCN1 fragment. Substitution of Arg2259 with Ala in full-length GCN1 abolished complex formation with native GCN2 and destroyed GCN1 regulatory function. Consistently, the Gcn(-) phenotype of gcn1-R2259A, but not that of gcn1Delta, was suppressed by overexpressing GCN2. These findings prove that GCN2 binding to the C-terminal domain of GCN1, dependent on Arg2259, is required for high level GCN2 function in vivo. GCN1 expression conferred sensitivity to paromomycin in a manner dependent on its ribosome binding domain, supporting the idea that GCN1 binds near the ribosomal acceptor site to promote GCN2 activation by uncharged tRNA.     

The metabolic sensor GCN2 branches out

GCN2 is a sensor of amino acid deprivation that triggers a repression of global protein synthesis while simultaneously inducing translation of specific proteins. In this issue of Cell Metabolism, Guo and Cavener (2007) present a much broader role for GCN2 in controlling lipid homeostasis in response to amino acid deprivation.     

GCN2 whets the appetite for amino acids

In response to amino acid starvation, the kinase GCN2 in yeast activates amino acid biosynthesis. Two recent studies (Maurin et al., 2005; Hao et al., 2005) reveal that GCN2 in the brain of mice restricts intake of diets lacking essential amino acids.     

Conserved intermolecular salt bridge required for activation of protein kinases PKR, GCN2, and PERK

The protein kinases PKR, GCN2, and PERK phosphorylate translation initiation factor eIF2alpha to regulate general and genespecific protein synthesis under various cellular stress conditions. Recent x-ray crystallographic structures of PKR and GCN2 revealed distinct dimeric configurations of the kinase domains. Whereas PKR kinase domains dimerized in a back-to-back and parallel orientation, the GCN2 kinase domains displayed an antiparallel orientation. The dimerization interfaces on PKR and GCN2 were localized to overlapping surfaces on the N-terminal lobes of the kinase domains but utilized different intermolecular contacts. A key feature of the PKR dimerization interface is a salt bridge interaction between Arg(262) from one protomer and Asp(266) from the second protomer. Interestingly, these two residues are conserved in all eIF2alpha kinases, although in the GCN2 structure, the two residues are too remote to interact. To test the importance of this potential salt bridge interaction in PKR, GCN2, and PERK, the residues constituting the salt bridge were mutated either independently or together to residues with the opposite charge. Single mutations of the Asp (or Glu) and Arg residues blocked kinase function both in yeast cells and in vitro. However, for all three kinases, the double mutation designed to restore the salt bridge interaction with opposite polarity resulted in a functional kinase. Thus, the salt bridge interaction and dimer interface observed in the PKR structure is critical for the activity of all three eIF2alpha kinases. These results are consistent with the notion that the PKR structure represents the active state of the eIF2alpha kinase domain, whereas the GCN2 structure may represent an inactive state of the kinase.