Regulation of mTOR and cell growth in response to energy stress by REDD1

The tuberous sclerosis tumor suppressors TSC1 and TSC2 regulate the mTOR pathway to control translation and cell growth in response to nutrient and growth factor stimuli. We have recently identified the stress response REDD1 gene as a mediator of tuberous sclerosis complex (TSC)-dependent mTOR regulation by hypoxia. Here, we demonstrate that REDD1 inhibits mTOR function to control cell growth in response to energy stress. Endogenous REDD1 is induced following energy stress, and REDD1-/- cells are highly defective in dephosphorylation of the key mTOR substrates S6K and 4E-BP1 following either ATP depletion or direct activation of the AMP-activated protein kinase (AMPK). REDD1 likely acts on the TSC1/2 complex, as regulation of mTOR substrate phosphorylation by REDD1 requires TSC2 and is blocked by overexpression of the TSC1/2 downstream target Rheb but is not blocked by inhibition of AMPK. Tetracycline-inducible expression of REDD1 triggers rapid dephosphorylation of S6K and 4E-BP1 and significantly decreases cellular size. Conversely, inhibition of endogenous REDD1 by short interfering RNA increases cell size in a rapamycin-sensitive manner, and REDD1-/- cells are defective in cell growth regulation following ATP depletion. These results define REDD1 as a critical transducer of the cellular response to energy depletion through the TSC-mTOR pathway.     

AMPK phosphorylation of raptor mediates a metabolic checkpoint

AMPK is a highly conserved sensor of cellular energy status that is activated under conditions of low intracellular ATP. AMPK responds to energy stress by suppressing cell growth and biosynthetic processes, in part through its inhibition of the rapamycin-sensitive mTOR (mTORC1) pathway. AMPK phosphorylation of the TSC2 tumor suppressor contributes to suppression of mTORC1; however, TSC2-deficient cells remain responsive to energy stress. Using a proteomic and bioinformatics approach, we sought to identify additional substrates of AMPK that mediate its effects on growth control. We report here that AMPK directly phosphorylates the mTOR binding partner raptor on two well-conserved serine residues, and this phosphorylation induces 14-3-3 binding to raptor. The phosphorylation of raptor by AMPK is required for the inhibition of mTORC1 and cell-cycle arrest induced by energy stress. These findings uncover a conserved effector of AMPK that mediates its role as a metabolic checkpoint coordinating cell growth with energy status.     

Energy depletion inhibits phosphatidylinositol 3-kinase/Akt signaling and induces apoptosis via AMP-activated protein kinase-dependent phosphorylation of IRS-1 at Ser-794

Energy depletion activates AMP-activated protein kinase (AMPK) and inhibits cell growth via TSC2-dependent suppression of mTORC1 signaling. Long term energy depletion also induces apoptosis by mechanisms that are not well understood to date. Here we show that AMPK, activated by energy depletion, inhibited cell survival by binding to and phosphorylating IRS-1 at Ser-794. Phosphorylation of IRS-1 at this site inhibited phosphatidylinositol 3-kinase/Akt signaling, suppressed the mitochondrial membrane potential, and promoted apoptosis. Of the treatments promoting energy depletion, glucose deprivation, hypoxia, and inhibition of ATP synthesis in the mitochondria stimulated phosphorylation of IRS-1 at Ser-794 via an LKB1/AMPK-dependent manner, whereas oxidative stress and 2-deoxyglucose stimulated phosphorylation at this site via a Ca2+/calmodulin-dependent protein kinase kinase beta/AMPK axis. These data define a novel pathway that cooperates with other adaptive mechanisms to formulate the cellular response to energy depletion.     

Akt activates the mammalian target of rapamycin by regulating cellular ATP level and AMPK activity

The serine/threonine kinase Akt is an upstream positive regulator of the mammalian target of rapamycin (mTOR). However, the mechanism by which Akt activates mTOR is not fully understood. The known pathway by which Akt activates mTOR is via direct phosphorylation and inhibition of tuberous sclerosis complex 2 (TSC2), which is a negative regulator of mTOR. Here we establish an additional pathway by which Akt inhibits TSC2 and activates mTOR. We provide for the first time genetic evidence that Akt regulates intracellular ATP level and demonstrate that Akt is a negative regulator of the AMP-activated protein kinase (AMPK), which is an activator of TSC2. We show that in Akt1/Akt2 DKO cells AMP/ATP ratio is markedly elevated with concomitant increase in AMPK activity, whereas in cells expressing activated Akt there is a dramatic decrease in AMP/ATP ratio and a decline in AMPK activity. Currently, the Akt-mediated phosphorylation of TSC2 and the inhibition of AMPK-mediated phosphorylation of TSC2 are viewed as two separate pathways, which activate mTOR. Our results demonstrate that Akt lies upstream of these two pathways and induces full inhibition of TSC2 and activation of mTOR both through direct phosphorylation and by inhibition of AMPK-mediated phosphorylation of TSC2. We propose that the activation of mTOR by Akt-mediated cellular energy and inhibition of AMPK is the predominant pathway by which Akt activates mTOR in vivo.     

New roles for the LKB1-->AMPK pathway

The AMP-activated protein kinase (AMPK) is a sensor of cellular energy that is conserved throughout eukaryotes. It is activated by rising AMP, signifying falling energy status caused by starvation for a carbon source or other stress. Binding of AMP to the regulatory gamma subunit triggers phosphorylation of the catalytic alpha subunit by the upstream kinase LKB1, and the activated kinase switches on ATP-generating catabolic pathways while switching off ATP-requiring processes. AMPK inhibits the TOR (target of rapamycin) pathway by phosphorylating TSC2, thus inhibiting cell growth during times of stress. AMPK is also a target for adipokines that regulate energy balance at the whole-body level.     

Hypoxia-induced energy stress regulates mRNA translation and cell growth

Oxygen (O2) deprivation, or hypoxia, has profound effects on cell metabolism and growth. Cells can adapt to low O2 in part through activation of hypoxia-inducible factor (HIF). We report here that hypoxia inhibits mRNA translation by suppressing multiple key regulators, including eIF2alpha, eEF2, and the mammalian target of rapamycin (mTOR) effectors 4EBP1, p70S6K, and rpS6, independent of HIF. Hypoxia results in energy starvation and activation of the AMPK/TSC2/Rheb/mTOR pathway. Hypoxic AMP-activated protein kinase (AMPK) activation also leads to eEF2 inhibition. Moreover, hypoxic effects on cellular bioenergetics and mTOR inhibition increase over time. Mutation of the TSC2 tumor suppressor gene confers a growth advantage to cells by repressing hypoxic mTOR inhibition and hypoxia-induced G1 arrest. Together, eIF2alpha, eEF2, and mTOR inhibition represent important HIF-independent mechanisms of energy conservation that promote survival under low O2 conditions.     

Differential localization of ATM is correlated with activation of distinct downstream signaling pathways

ATM, the gene mutated in the genetic disease ataxia telangiectasia (AT), is a well-known protein involved in the DNA double-strand break response, where it plays an important role in sensing damage and signaling to DNA repair machinery and cell cycle checkpoints. However, a number of recent papers, including ours have found that ATM also plays important roles outside of the nucleus, which may explain some of the phenotypic features seen in AT patients. Our research into mechanisms of TSC2 regulation helped uncover a pathway upstream of TSC2 that is regulated by cytoplasmic ATM in response to ROS initiated by ATM activation of LKB1 and AMPK. We found that TSC2 activation results in mTORC1 repression and subsequent induction of autophagy. Elucidation of this stress response pathway provides a molecular mechanism for ATM signaling in the cytoplasm, and lays the groundwork for further studies on how ATM activity is regulated beyond DNA damage in different cellular compartments.     

Regulation of Torpor in the Gray Mouse Lemur:Transcriptional and Translational Controls and Role of AMPK Signaling

The gray mouse lemur (Microcebus murinus) is one of few primate species that is able to enter daily torpor or prolonged hibernation in response to environmental stresses. With an emerg-ing significance...     

The function study on the interaction between Grb2 and AMPK

Growth factor receptor-bound protein 2 (Grb2) is an extensively studied adaptor protein involved in cell signaling. Grb2 is a highly flexible protein composed of a single SH2 domain flanked by two SH3 domains. The evolutionarily conserved serine/threonine kinase, AMP-activated protein kinase (AMPK), functions as a cellular fuel gauge that regulates metabolic pathways in glucose and fatty acid metabolism and protein synthesis. AMPK regulates the activation of TSC2 by phosphorylating TSC2. Here we report for the first time on the interaction of Grb2 with AMPK. SH2 domain of Grb2 and KIS domain of AMPK are both required for the combination of Grb2 and AMPK. Furthermore, Grb2 function as a factor which mediates phosphorylation of AMPK at Thr172, and potentially involves in metabolism pathways and AMPK-TSC2-mTOR cell growth pathway through regulating the activation of AMPK.     

AMPK/mTOR信号通路的研究进展

mTOR是细胞生长和增殖的中枢调控因子。mTOR形成2个不同的复合物mTORC1和mTORC2。mTORC1受多种信号调节,如生长因子、氨基酸和细胞能量,同时,mTORC1调节许多重要的细胞过程,包括翻译、转录和自噬。AMPK作为一种关键的生理能量传感器,是细胞和有机体能量平衡的主要调节因子,协调多种代谢途径,平衡能量的供应和需求,最终调节细胞和器官的生长。能量代谢平衡调控是由多个与之相关的信号通路所介导,其中AMPK/mTOR信号通路在细胞内共同构成一个合成代谢和分解代谢过程的开关。此外,AMPK/mTOR信号通路还是一个自噬的重要调控途径。本文着重于目前对AMPK和mTOR信号传导之间关系的了解,讨论了AMPK/mTOR在细胞和有机体能量稳态中的作用。     

Activation of AMP-activated protein kinase inhibits protein synthesis associated with hypertrophy in the cardiac myocyte

A necessary mediator of cardiac myocyte enlargement is protein synthesis, which is controlled at the levels of both translation initiation and elongation. Eukaryotic elongation factor-2 (eEF2) mediates the translocation step of peptide-chain elongation and is inhibited through phosphorylation by eEF2 kinase. In addition, p70S6 kinase can regulate protein synthesis by phosphorylating eEF2 kinase or via phosphorylation of ribosomal protein S6. We have recently shown that eEF2 kinase is also controlled by phosphorylation by AMP-activated protein kinase (AMPK), a key regulator of cellular energy homeostasis. Moreover, the mammalian target of rapamycin has also been shown to be inhibited, indirectly, by AMPK, thus leading to the inhibition of p70S6 kinase. Although AMPK activation has been shown to modulate protein synthesis, it is unknown whether AMPK could also be a regulator of cardiac hypertrophic growth. Therefore, we investigated the role of AMPK activation in regulating protein synthesis during both phenylephrine- and Akt-induced cardiac hypertrophy. Metformin and 5-aminoimidazole-4-carboxamide 1-beta-D-ribofuranoside were used to activate AMPK in neonatal rat cardiac myocytes. Activation of AMPK significantly decreased protein synthesis induced by phenylephrine treatment or by expression of constitutively active Akt. Activation of AMPK also resulted in decreased p70S6 kinase phosphorylation and increased phosphorylation of eEF2, suggesting that inhibition of protein synthesis involves the eEF2 kinase/eEF2 axis and/or the p70S6 kinase pathway. Together, our data suggest that the inhibition of protein synthesis by pharmacological activation of AMPK may be a key regulatory mechanism by which hypertrophic growth can be controlled.     

Regulation of AMP-activated protein kinase by multisite phosphorylation in response to agents that elevate cellular cAMP

The AMP-activated protein kinase (AMPK) and cAMP signaling systems are both key regulators of cellular metabolism. In this study, we show that AMPK activity is attenuated in response to cAMP-elevating agents through modulation of at least two of its alpha subunit phosphorylation sites, viz. alpha-Thr(172) and alpha1-Ser(485)/alpha2-Ser(491), in the clonal beta-cell line INS-1 as well as in mouse embryonic fibroblasts and COS cells. Forskolin, isobutylmethylxanthine, and the glucose-dependent insulinotropic peptide inhibited AMPK activity and reduced phosphorylation of the activation loop alpha-Thr(172) via inhibition of calcium/calmodulin-dependent protein kinase kinase-alpha and -beta, but not LKB1. These agents also enhanced phosphorylation of alpha-Ser(485/491) by the cAMP-dependent protein kinase. AMPK alpha-Ser(485/491) phosphorylation was necessary but not sufficient for inhibition of AMPK activity in response to forskolin/isobutylmethylxanthine. We show that AMPK alpha-Ser(485/491) can be a site for autophosphorylation, which may play a role in limiting AMPK activation in response to energy depletion or other regulators. Thus, our findings not only demonstrate cross-talk between the cAMP/cAMP-dependent protein kinase and AMPK signaling modules, but also describe a novel mechanism by which multisite phosphorylation of AMPK contributes to regulation of its enzyme activity.     

AICAR induces phosphorylation of AMPK in an ATM-dependent, LKB1-independent manner

AMPK is an AMP-activated protein kinase that plays an important role in regulating cellular energy homeostasis. Metabolic stress, such as heat shock and glucose starvation, causes an energy deficiency in the cell and leads to elevated levels of intracellular AMP. This results in the phosphorylation and activation of AMPK. LKB1, a tumor suppressor, has been identified as an upstream kinase of AMPK. We found that in response to treatment with 5-aminoimidazole-4-carboxamide-1-β-4-ribofuranoside (AICAR), the LKB1 deficient cancer cell line, HeLa, exhibited AMPK-α phosphorylation. This indicates the existence of an LKB1-independent AMPK-α phosphorylation pathway. ATM is a protein that is deficient in the disease ataxia telangiectasia (A-T). We measured the activation of AMPK by AICAR in the normal mouse embryo fibroblast cell line, A29, and the mouse cell line lacking the ATM protein, A38. In A38 cells, the level of AICAR-induced AMPK-α phosphorylation was significantly lower than that found in A29 cells. Furthermore, phosphorylation of AMPK in HeLa and A29 cells was inhibited by an ATM specific inhibitor, KU-55933. Our results demonstrate that AICAR treatment could lead to phosphorylation of AMPK in an ATM-dependent and LKB1-independent manner. Thus, ATM may function as a potential AMPK kinase in response to AICAR treatment.     

Cryptotanshinone induces G1 cell cycle arrest and autophagic cell death by activating the AMP-activated protein kinase signal pathway in HepG2 hepatoma

AMP-activated protein kinase (AMPK) performs a pivotal function in energy homeostasis via the monitoring of intracellular energy status. Once activated under the various metabolic stress conditions, AMPK regulates a multitude of metabolic pathways to balance cellular energy. In addition, AMPK also induces cell cycle arrest or apoptosis through several tumor suppressors including LKB1, TSC2, and p53. LKB1 is a direct upstream kinase of AMPK, while TSC2 and p53 are direct substrates of AMPK. Therefore, it is expected that activators of AMPK signal pathway might be useful for treatment or prevention of cancer. In the present study, we report that cryptotanshinone, a natural compound isolated from Salvia miltiorrhiza, robustly activated AMPK signaling pathway, including LKB1, p53, TSC2, thereby leading to suppression of mTORC1 in a number of LKB1-expressing cancer cells including HepG2 human hepatoma, but not in LKB1-deficient cancer cells. Cryptotanshinone induced HepG2 cell cycle arrest at the G1 phase in an AMPK-dependent manner, and a portion of cells underwent apoptosis as a result of long-term treatment. It also induced autophagic HepG2 cell death in an AMPK-dependent manner. Cryptotanshinone significantly attenuated tumor growth in an HCT116 cancer xenograft in vivo model, with a substantial activation of AMPK signal pathways. Collectively, we demonstrate for the first time that cryptotanshinone harbors the therapeutic potential for the treatment of cancer through AMPK activation.     

Inactivation of Rheb by PRAK-mediated phosphorylation is essential for energy-depletion-induced suppression of mTORC1

Cell growth can be suppressed by stressful environments, but the role of stress pathways in this process is largely unknown. Here we show that a cascade of p38β mitogen-activated protein kinase (MAPK) and p38-regulated/activated kinase (PRAK) plays a role in energy-starvation-induced suppression of mammalian target of rapamycin (mTOR), and that energy starvation activates the p38β-PRAK cascade. Depletion of p38β or PRAK diminishes the suppression of mTOR complex 1 (mTORC1) and reduction of cell size induced by energy starvation. We show that p38β-PRAK operates independently of the known mTORC1 inactivation pathways--phosphorylation of tuberous sclerosis protein 2 (TSC2) and Raptor by AMP-activated protein kinase (AMPK)--and surprisingly, that PRAK directly regulates Ras homologue enriched in brain (Rheb), a key component of the mTORC1 pathway, by phosphorylation. Phosphorylation of Rheb at Ser 130 by PRAK impairs the nucleotide-binding ability of Rheb and inhibits Rheb-mediated mTORC1 activation. The direct regulation of Rheb by PRAK integrates a stress pathway with the mTORC1 pathway in response to energy depletion.