Browsing by Subject "GCN2"
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Item Activation of Gcn2 by Pharmacological Agents Designed to be Inhibitors(2023-01) Carlson, Kenneth Reed; Wek, Ronald C.; Georgiadis, Millie M.; Liu, Yunlong; Staschke, Kirk A.; Turchi, John J.The integrated stress response (ISR) is an important mechanism by which cells confer protection against environmental stresses. Central to the ISR is a collection of related protein kinases that monitor stress conditions, such as Gcn2 (EIF2AK4) that recognizes nutrient limitations, inducing phosphorylation of eukaryotic translation initiation factor 2 (eIF2). Gcn2 phosphorylation of eIF2 lowers bulk protein synthesis, conserving energy and nutrients, coincident with preferential translation of stressadaptive gene transcripts, such as that encoding the Atf4 transcriptional regulator. While Gcn2 is central for cell protection to nutrient stress and its depletion in humans leads to pulmonary disorders, Gcn2 can also contribute to the progression of cancers and facilitate neurological disorders during chronic stress. Consequently, specific ATP-competitive inhibitors of Gcn2 protein kinase have been developed. This thesis reports that one such Gcn2 inhibitor, Gcn2iB, can activate Gcn2, probes the mechanism by which this activation occurs, and compares the mechanism of Gcn2 activation by Gcn2iB to that of uncharged tRNA. In this study, Gcn2 activation was measured in cultured human cells by immunoblot and luciferase reporter assays making use of a genetic complementation assay to assess the contribution of various Gcn2 residues to its activation. Low concentrations of Gcn2iB increase Gcn2 phosphorylation of eIF2 and enhance Atf4 expression and activity. Of importance, Gcn2iB can activate Gcn2 mutants devoid of functional regulatory domains or with certain kinase domain substitutions derived fromGcn2-deficient human patients. Other ATP-competitive inhibitors can also activate Gcn2, although there are differences in their mechanisms of activation. These results provide a cautionary note about the pharmacodynamics of eIF2 kinase inhibitors in therapeutic applications. However, compounds designed to be kinase inhibitors that instead directly activate Gcn2, even loss of function variants, may provide tools to alleviate deficiencies in Gcn2 and other regulators of the ISR.Item Crystal structures of GCN2 protein kinase C-terminal domains suggest regulatory differences in yeast and mammals(ASBMB, 2014-04-09) He, Hongzhen; Singh, Isha; Wek, Sheree A.; Dey, Souvik; Baird, Thomas D.; Wek, Ronald C.; Georgiadis, Millie M.; Department of Biochemistry & Molecular Biology, IU School of MedicineIn response to amino acid starvation, GCN2 phosphorylation of eIF2 leads to repression of general translation and initiation of gene reprogramming that facilitates adaptation to nutrient stress. GCN2 is a multidomain protein with key regulatory domains that directly monitor uncharged tRNAs which accumulate during nutrient limitation, leading to activation of this eIF2 kinase and translational control. A critical feature of regulation of this stress response kinase is its C-terminal domain (CTD). Here, we present high resolution crystal structures of murine and yeast CTDs, which guide a functional analysis of the mammalian GCN2. Despite low sequence identity, both yeast and mammalian CTDs share a core subunit structure and an unusual interdigitated dimeric form, albeit with significant differences. Disruption of the dimeric form of murine CTD led to loss of translational control by GCN2, suggesting that dimerization is critical for function as is true for yeast GCN2. However, although both CTDs bind single- and double-stranded RNA, murine GCN2 does not appear to stably associate with the ribosome, whereas yeast GCN2 does. This finding suggests that there are key regulatory differences between yeast and mammalian CTDs, which is consistent with structural differencesItem Dietary Methionine Restriction Regulates Liver Protein Synthesis and Gene Expression Independently of Eukaryotic Initiation Factor 2 Phosphorylation in Mice(Oxford University Press, 2017-06) Pettit, Ashley P.; Jonsson, William O.; Bargoud, Albert R.; Mirek, Emily T.; Peelor, Frederick F., III; Wang, Yongping; Gettys, Thomas W.; Kimball, Scot R.; Miller, Benjamin F.; Hamilton, Karyn L.; Wek, Ronald C.; Anthony, Tracy G.; Biochemistry and Molecular Biology, School of MedicineBackground: The phosphorylation of eukaryotic initiation factor 2 (p-eIF2) during dietary amino acid insufficiency reduces protein synthesis and alters gene expression via the integrated stress response (ISR).Objective: We explored whether a Met-restricted (MR) diet activates the ISR to reduce body fat and regulate protein balance.Methods: Male and female mice aged 3-6 mo with either whole-body deletion of general control nonderepressible 2 (Gcn2) or liver-specific deletion of protein kinase R-like endoplasmic reticulum kinase (Perk) alongside wild-type or floxed control mice were fed an obesogenic diet sufficient in Met (0.86%) or an MR (0.12% Met) diet for ≤5 wk. Ala enrichment with deuterium was measured to calculate protein synthesis rates. The guanine nucleotide exchange factor activity of eIF2B was measured alongside p-eIF2 and hepatic mRNA expression levels at 2 d and 5 wk. Metabolic phenotyping was conducted at 4 wk, and body composition was measured throughout. Results were evaluated with the use of ANOVA (P < 0.05).Results: Feeding an MR diet for 2 d did not increase hepatic p-eIF2 or reduce eIF2B activity in wild-type or Gcn2-/- mice, yet many genes transcriptionally regulated by the ISR were altered in both strains in the same direction and amplitude. Feeding an MR diet for 5 wk increased p-eIF2 and reduced eIF2B activity in wild-type but not Gcn2-/- mice, yet ISR-regulated genes altered in both strains similarly. Furthermore, the MR diet reduced mixed and cytosolic but not mitochondrial protein synthesis in both the liver and skeletal muscle regardless of Gcn2 status. Despite the similarities between strains, the MR diet did not increase energy expenditure or reduce body fat in Gcn2-/- mice. Finally, feeding the MR diet to mice with Perk deleted in the liver increased hepatic p-eIF2 and altered body composition similar to floxed controls.Conclusions: Hepatic activation of the ISR resulting from an MR diet does not require p-eIF2. Gcn2 status influences body fat loss but not protein balance when Met is restricted.Item The effect of alternative splicing on key regulators of the integrated stress response(2016-08) Alzahrani, Mohammed; Wek, Ronald C.; Goebl, Mark G.; Mosley, Amber L.The protein kinase General control non-derepressible-2 (GCN2) is a key regulator of the Integrated stress response that responds to various stress signals, including nutritional deprivation. As a result of high levels of uncharged tRNAs during amino acid depletion, GCN2 phosphorylates serine-51 of the α subunit of eukaryotic initiation factor-2 (eIF2), a translation factor that delivers initiator tRNA to ribosomes. Phosphorylation of eIF2α inhibits general translation, which conserves energy and nutrients and facilitates reprogramming of gene expression for remediation of stress damage. Phosphorylation of eIF2α also directs preferential translation of specific transcription factors, such as ATF4. ATF4 reprograms gene expression to alleviate stress damage; however, under chronic stress, ATF4 directs the transcriptional expression of CHOP, which can trigger apoptosis. Because multiple stresses can induce eIF2α phosphorylation and translational control in mammals, this pathway is referred to as the Integrated stress response. GCN2 and CHOP are subject to alternative splicing that results in multiple transcripts that differ in the 5'-end of the gene transcripts. However, the effect of the different GCN2 and CHOP isoforms on their function and regulation have not been investigated. Our data suggests that GCN2 is alternatively spliced into five different transcripts and the beta isoform of GCN2 is most abundant. Also alternative splicing of CHOP creates two CHOP transcripts with different 5'-leaders encoding inhibitory upstream open reading frames that are critical for translational control of CHOP during stress. This study suggests that alternative splicing can play an integral role in the implementation and regulation of key factors in the Integrated stress response.Item Enhancing Leukemia Treatment: The Role of Combined Therapies Based on Amino Acid Starvation(MDPI, 2024-03-16) Chen, Can; Zhang, Ji; Pediatrics, School of MedicineCancer cells demand amino acids beyond their usage as "building blocks" for protein synthesis. As a result, targeting amino acid acquisition and utilization has emerged as a pivotal strategy in cancer treatment. In the setting of leukemia therapy, compelling examples of targeting amino acid metabolism exist at both pre-clinical and clinical stages. This review focuses on summarizing novel insights into the metabolism of glutamine, asparagine, arginine, and tryptophan in leukemias, and providing a comprehensive discussion of perturbing their metabolism to improve the therapeutic outcomes. Certain amino acids, such as glutamine, play a vital role in the energy metabolism of cancer cells and the maintenance of redox balance, while others, such as arginine and tryptophan, contribute significantly to the immune microenvironment. Therefore, assessing the efficacy of targeting amino acid metabolism requires comprehensive strategies. Combining traditional chemotherapeutics with novel strategies to perturb amino acid metabolism is another way to improve the outcome in leukemia patients via overcoming chemo-resistance or promoting immunotherapy. In this review, we also discuss several ongoing or complete clinical trials, in which targeting amino acid metabolism is combined with other chemotherapeutics in treating leukemia.Item The Essential Role of the Non-Essential Amino Acid Asparagine in Lymphoid Malignancies(2023-05) Srivastava, Sankalp; Zhang, Ji; Dong, X. Charlie; Mosley, Amber L.; Wek, Ronald C.Cancer cells display increased metabolic demands to support their proliferation and biosynthetic needs. It has been extensively shown in cancers, that amino acids have functions beyond the role of mRNA translation. The breadth of functions makes amino acid restriction an effective strategy for cancer therapy; hence an important line of research involves targeting amino acid acquisition and metabolism therapeutically. Currently, asparagine depletion via L-Asparaginase in acute lymphoblastic leukemia (ALL) remains the only clinically approved therapy to date. In the first project, we showed that ALL cells are auxotrophic for asparagine and rely on exogenous sources for this non-essential amino acid. However, sensitivity to L-Asparaginase therapy is mitigated by the expression of the enzyme asparagine synthetase (ASNS), involved in de novo asparagine biosynthesis. We showed that this adaptive response requires two essential steps; demethylation of the ASNS promoter and recruitment of activating transcription factor 4 (ATF4) to the promoter to drive ASNS transcription. Our follow-up study in ALL cells showed that asparagine bioavailability (through de novo biosynthesis or exogenous sources) is essential to maintain the expression of the critical oncogene c-MYC. c-MYC is a potent transcription factor and is dysregulated in over 60% of cancers, including hematopoietic malignancies. We showed that this regulation by asparagine is primarily at the translation level and c-MYC expression is rescued only when exogenous asparagine is available or when cells can undertake de novo biosynthesis. At the biochemical level, asparagine depletion also causes an induction of ATF4 mediated stress response and suppression of global translation mediated by decreased mammalian target of rapamycin complex 1 (mTORC1) activity. However, we found that neither inhibition of the stress response or rescuing global translation rescued c-MYC protein expression. We also extended this observation to c-MYC-driven lymphomas using cell lines and orthotopic in vivo models. We showed that genetic inhibition of ASNS or pharmacological inhibition of asparagine production can significantly limit c-MYC protein and tumor growth when environmental asparagine is limiting. Overall, our work shows an essential role for asparagine in lymphoid cancers and has expanded on the usage of L-Asparaginase to resistant leukemias and lymphomas.Item FGF21, not GCN2, influences bone morphology due to dietary protein restrictions(Elsevier, 2020- 06) McNulty, Margaret A.; Goupil, Brad A.; Albarado, Diana C.; Castaño-Martinez, Teresa; Ambrosi, Thomas H.; Puh, Spela; Schulz, Tim J.; Schürmann, Annette; Morrison, Christopher D.; Laeger, Thomas; Anatomy and Cell Biology, School of MedicineBackground Dietary protein restriction is emerging as an alternative approach to treat obesity and glucose intolerance because it markedly increases plasma fibroblast growth factor 21 (FGF21) concentrations. Similarly, dietary restriction of methionine is known to mimic metabolic effects of energy and protein restriction with FGF21 as a required mechanism. However, dietary protein has been shown to be required for normal bone growth, though there is conflicting evidence as to the influence of dietary protein restriction on bone remodeling. The purpose of the current study was to evaluate the effect of dietary protein and methionine restriction on bone in lean and obese mice, and clarify whether FGF21 and general control nonderepressible 2 (GCN2) kinase, that are part of a novel endocrine pathway implicated in the detection of protein restriction, influence the effect of dietary protein restriction on bone. Methods Adult wild-type (WT) or Fgf21 KO mice were fed a normal protein (18 kcal%; CON) or low protein (4 kcal%; LP) diet for 2 or 27 weeks. In addition, adult WT or Gcn2 KO mice were fed a CON or LP diet for 27 weeks. Young New Zealand obese (NZO) mice were placed on high-fat diets that provided protein at control (16 kcal%; CON), low levels (4 kcal%) in a high-carbohydrate (LP/HC) or high-fat (LP/HF) regimen, or on high-fat diets (protein, 16 kcal%) that provided methionine at control (0.86%; CON-MR) or low levels (0.17%; MR) for up to 9 weeks. Long bones from the hind limbs of these mice were collected and evaluated with micro-computed tomography (μCT) for changes in trabecular and cortical architecture and mass. Results In WT mice the 27-week LP diet significantly reduced cortical bone, and this effect was enhanced by deletion of Fgf21 but not Gcn2. This decrease in bone did not appear after 2 weeks on the LP diet. In addition, Fgf21 KO mice had significantly less bone than their WT counterparts. In obese NZO mice dietary protein and methionine restriction altered bone architecture. The changes were mediated by FGF21 due to methionine restriction in the presence of cystine, which did not increase plasma FGF21 levels and did not affect bone architecture. Conclusions This study provides direct evidence of a reduction in bone following long-term dietary protein restriction in a mouse model, effects that appear to be mediated by FGF21.Item GCN2 eIF2 Kinase Promotes Prostate Cancer by Maintaining Amino Acid Homeostasis(2024-04) Cordova E., Ricardo A.; Wek, Ronald C.; Staschke, Kirk A.; Pili, Roberto; Mosley, Amber L.; Elmendorf, Jeffrey S.; Zhang, JiActivation of the integrated stress response (ISR) contributes to the progression of many cancers, including prostate cancer (PCa). The ISR features a family of protein kinases that phosphorylate the eukaryotic translation initiation factor 2 (eIF2) during different stress conditions, repressing global protein synthesis. In parallel, eIF2 phosphorylation also enhances the translation of select gene transcripts, such as ATF4, which directs the transcription of ISR-target genes critical for stress adaptation. We reported that the eIF2 kinase GCN2 is a critical driver of the ISR in PCa and is crucial to maintaining amino acid (AA) homeostasis. GCN2 is activated in PCa due to AA limitation, resulting in increased expression of key AA transporters which providing nutrient import to fuel protein synthesis and metabolism that drive prostate tumor cell proliferation. Inhibition of GCN2 results in lowered expression of AA transporters, leading to severe depletion of intracellular AA and reduced proliferation in PCa. We identified purine biosynthesis as a key metabolic pathway dependent on GCN2. Inhibition of GCN2 and the accompanying depletion of AAs decreases purine levels in PCa cells, ultimately resulting in reduced ribosome biogenesis leading to the activation of a p53-dependent cell cycle checkpoint, termed the Impaired Ribosome Biogenesis Checkpoint (IRBC). Interestingly, induction of p53 promotes survival of PCa following GCN2 inhibition by halting cell cycle progression and reprogramming metabolism to restore metabolic homeostasis. We found that reductions in select AAs that impact nucleotide pools activate GCN2 and p53 in parallel, and that cooperation of these stress pathways is critical for maintaining AA and purine pools. Of importance, deletion of p53 sensitizes PCa cells to GCN2 inhibition suggesting that loss of p53 creates a dependency for GCN2. Of importance, we demonstrate that a small molecule inhibitor of GCN2 showed robust in vivo efficacy in androgen-sensitive and castrationresistant mouse models of PCa, supporting its therapeutic potential for the treatment of PCa.Item Human keratinocytes utilize the integrated stress response to adapt to environmental stress(2017-06) Collier, Ann E.; Spandau, Dan F.; Wek, Ronald C.; Travers, Jeffrey B.; Turchi, John J.; Turner, Matthew J.Human skin, consisting of the outer epidermis and inner dermis, serves as a barrier that protects the body from an onslaught of environmental stresses. Keratinocytes in the stratified epidermis undergo sequential differentiation that consists of multiple layers of cells differing in structure and function. Therefore, keratinocytes must not only combat environmental stress, but need to undergo massive changes in gene expression and morphology to form a proper barrier. One mode by which cells cope with stress and differentiation is through phosphorylation of the α subunit of eukaryotic initiation factor 2 (eIF2α-P), which causes global inhibition of protein synthesis coincident with preferential translation of select gene transcripts. Translational repression allows stressed cells to conserve energy and prioritize pro-survival processes to alleviate stress damage. Since eIF2α kinases are each activated by distinct types of stress, this pathway is referred to as the Integrated Stress Response (ISR). We sought to identify the roles of the ISR in the keratinocyte response to the stresses associated with differentiation and ultraviolet B (UVB) irradiation. In this thesis, we show that both general and gene-specific translational control in the ISR are activated following differentiation or UVB irradiation of human keratinocytes. ISR deficiency through genetic modifications or pharmacological interventions caused severe divergence from the appropriate keratinocyte response to differentiation or UVB. Differentiation genes were selectively translated by eIF2α-P, and inhibition of the ISR diminished their induction during differentiation. Furthermore, loss of the eIF2α kinase GCN2 (EIF2AK4) adversely affected the ability of keratinocytes to stratify in three dimensional cultures. Our analysis also revealed a non-canonical ISR response following UVB irradiation, in which downstream factors ATF4 (CREB2) and CHOP (DDIT3/GADD153) were poorly expressed due to repressed transcription, despite preferential translation in response to eIF2α-P. The ISR was cytoprotective during UVB and we found that eIF2α-P was required for a UVB induced G1 arrest, cell fate determination, and DNA repair via a mechanism involving translational control of human CDKN1A (p21 protein) transcript variant 4 mRNA. Collectively, this thesis describes novel roles for the ISR in keratinocyte differentiation and response to UVB, emphasizing the utility of targeting translational control in skin disease therapy.Item Integration of general amino acid control and TOR regulatory pathways in yeast(2010-05) Staschke, Kirk Alan; Wek, Ronald C.; Edenberg, Howard J.; Roach, Peter J.; Bard, MartinTwo important nutrient sensing and regulatory pathways, the general amino acid control (GAAC) and the target of rapamycin (TOR), participate in the control of yeast growth and metabolism in response to changes in nutrient availability. Starvation for amino acids activates the GAAC through Gcn2p phosphorylation of the translation initiation factor eIF2 and preferential translation of GCN4, a transcription activator. TOR senses nitrogen availability and regulates transcription factors, such as Gln3p. We used microarray analyses to address the integration of the GAAC and TOR pathways in directing the yeast transcriptome during amino acid starvation and rapamycin treatment. We found that the GAAC is a major effector of the TOR pathway, with Gcn4p and Gln3p each inducing a similar number of genes during rapamycin treatment. While Gcn4p activates a common core of 57 genes, the GAAC directs significant variations in the transcriptome during different stresses. In addition to inducing amino acid biosynthetic genes, Gcn4p activates genes required for assimilation of secondary nitrogen sources, such as -amino-butyric acid (GABA). Gcn2p activation upon shifting to secondary nitrogen sources is suggested to occur by means of a dual mechanism. First, Gcn2p is induced by the release of TOR repression through a mechanism involving Sit4p protein phosphatase. Second, this eIF2 kinase is activated by select uncharged tRNAs, which were shown to accumulate during the shift to GABA medium. This study highlights the mechanisms by which the GAAC and TOR pathways are integrated to recognize changing nitrogen availability and direct the transcriptome for optimal growth adaptation.