Effects of mTORC1 inhibition on proteasome activity and levels

The mechanistic target of rapamycin (mTOR) regulates numerous extracellular and intracellular signals involved in the maintenan-ce of cellular homeostasis and cell growth. mTOR also functions as an endogenous inhibitor of autophagy. Under nutrient-rich conditions, mTOR complex 1 (mTORC1) phosphorylates the ULK1 complex, preventing its activation and subsequent autophagosome formation, while inhibition of mTORC1 using either rapamycin or nutrient deprivation induces autophagy. Autophagy and proteasomal proteolysis provide amino acids necessary for protein translation. Although the connection between mTORC1 and autophagy is well characterized, the association of mTORC1 inhibition with proteasome biogenesis and activity has not been fully elucidated yet. Proteasomes are long-lived cellular organelles. Their spatiotemporal rather than homeostatic regulation could be another adaptive cellular mechanism to respond to starvation. Here, we reviewed several published reports and the latest research from our group to examine the connection between mTORC1 and proteasome. We have also investigated and described the effect of mTORC1 inhibition on proteasome activity using purified proteasomes. Since mTORC1 inhibitors are currently evaluated as treatments for several human diseases, a better understanding of the link between mTORC1 activity and proteasome function is of utmost importance.     

Spatial regulation of the mTORC1 system in amino acids sensing pathway

The mammalian target of rapamycin (mTOR) is an evolutionarily conserved serine/threonine protein kinase that regulates numerous cellular processes including cell growth, proliferation, cell cycle, and autophagy. mTOR forms two different multi-protein complexes referred to as mTOR complex 1 (mTORC1) and mTORC2, and each complex exerts distinct functions exclusively. mTORC1 activity is sensitive to the selective inhibitor rapamycin, whereas mTORC2 is resistant. mTORC1 is regulated by many intra- and extra-cellular cues such as growth factors, nutrients, and energy-sensing signals, while mTORC2 senses ribosome maturation and growth factor signaling. This review focuses on current understandings by which mTORC1 pathway senses cellular nutrient availability for its activation.     

Lysosomal positioning coordinates cellular nutrient responses

mTOR (mammalian target of rapamycin) signalling and macroautophagy (henceforth autophagy) regulate numerous pathological and physiological processes, including cellular responses to altered nutrient levels. However, the mechanisms regulating mTOR and autophagy remain incompletely understood. Lysosomes are dynamic intracellular organelles intimately involved both in the activation of mTOR complex 1 (mTORC1) signalling and in degrading autophagic substrates. Here we report that lysosomal positioning coordinates anabolic and catabolic responses with changes in nutrient availability by orchestrating early plasma-membrane signalling events, mTORC1 signalling and autophagy. Activation of mTORC1 by nutrients correlates with its presence on peripheral lysosomes that are physically close to the upstream signalling modules, whereas starvation causes perinuclear clustering of lysosomes, driven by changes in intracellular pH. Lysosomal positioning regulates mTORC1 signalling, which in turn influences autophagosome formation. Lysosome positioning also influences autophagosome-lysosome fusion rates, and thus controls autophagic flux by acting at both the initiation and termination stages of the process. Our findings provide a physiological role for the dynamic state of lysosomal positioning in cells as a coordinator of mTORC1 signalling with autophagic flux.     

Amino acids activate mammalian target of rapamycin complex 2 (mTORC2) via PI3K/Akt signaling

The activity of mammalian target of rapamycin (mTOR) complexes regulates essential cellular processes, such as growth, proliferation, or survival. Nutrients such as amino acids are important regulators of mTOR complex 1 (mTORC1) activation, thus affecting cell growth, protein synthesis, and autophagy. Here, we show that amino acids may also activate mTOR complex 2 (mTORC2). This activation is mediated by the activity of class I PI3K and of Akt. Amino acids induced a rapid phosphorylation of Akt at Thr-308 and Ser-473. Whereas both phosphorylations were dependent on the presence of mTOR, only Akt phosphorylation at Ser-473 was dependent on the presence of rictor, a specific component of mTORC2. Kinase assays confirmed mTORC2 activation by amino acids. This signaling was functional, as demonstrated by the phosphorylation of Akt substrate FOXO3a. Interestingly, using different starvation conditions, amino acids can selectively activate mTORC1 or mTORC2. These findings identify a new signaling pathway used by amino acids underscoring the crucial importance of these nutrients in cell metabolism and offering new mechanistic insights.     

Screen for Chemical Modulators of Autophagy Reveals Novel Therapeutic Inhibitors of mTORC1 Signaling

Background

Mammalian target of rapamycin complex 1 (mTORC1) is a protein kinase that relays nutrient availability signals to control numerous cellular functions including autophagy, a process of cellular self-eating activated by nutrient depletion. Addressing the therapeutic potential of modulating mTORC1 signaling and autophagy in human disease requires active chemicals with pharmacologically desirable properties.

Methodology/Principal Findings

Using an automated cell-based assay, we screened a collection of >3,500 chemicals and identified three approved drugs (perhexiline, niclosamide, amiodarone) and one pharmacological reagent (rottlerin) capable of rapidly increasing autophagosome content. Biochemical assays showed that the four compounds stimulate autophagy and inhibit mTORC1 signaling in cells maintained in nutrient-rich conditions. The compounds did not inhibit mTORC2, which also contains mTOR as a catalytic subunit, suggesting that they do not inhibit mTOR catalytic activity but rather inhibit signaling to mTORC1. mTORC1 inhibition and autophagosome accumulation induced by perhexiline, niclosamide or rottlerin were rapidly reversed upon drug withdrawal whereas amiodarone inhibited mTORC1 essentially irreversibly. TSC2, a negative regulator of mTORC1, was required for inhibition of mTORC1 signaling by rottlerin but not for mTORC1 inhibition by perhexiline, niclosamide and amiodarone. Transient exposure of immortalized mouse embryo fibroblasts to these drugs was not toxic in nutrient-rich conditions but led to rapid cell death by apoptosis in starvation conditions, by a mechanism determined in large part by the tuberous sclerosis complex protein TSC2, an upstream regulator of mTORC1. By contrast, transient exposure to the mTORC1 inhibitor rapamycin caused essentially irreversible mTORC1 inhibition, sustained inhibition of cell growth and no selective cell killing in starvation.

Conclusion/Significance

The observation that drugs already approved for human use can reversibly inhibit mTORC1 and stimulate autophagy should greatly facilitate the preclinical and clinical testing of mTORC1 inhibition for indications such as tuberous sclerosis, diabetes, cardiovascular disease and cancer.     

Autoregulation of the Mechanistic Target of Rapamycin (mTOR) Complex 2 Integrity Is Controlled by an ATP-dependent Mechanism

Nutrients are essential for living organisms because they fuel biological processes in cells. Cells monitor nutrient abundance and coordinate a ratio of anabolic and catabolic reactions. Mechanistic target of rapamycin (mTOR) signaling is the essential nutrient-sensing pathway that controls anabolic processes in cells. The central component of this pathway is mTOR, a highly conserved and essential protein kinase that exists in two distinct functional complexes. The nutrient-sensitive mTOR complex 1 (mTORC1) controls cell growth and cell size by phosphorylation of the regulators of protein synthesis S6K1 and 4EBP1, whereas its second complex, mTORC2, regulates cell proliferation by functioning as the regulatory kinase of Akt and other members of the AGC kinase family. The regulation of mTORC2 remains poorly characterized. Our study shows that the cellular ATP balance controls a basal kinase activity of mTORC2 that maintains the integrity of mTORC2 and phosphorylation of Akt on the turn motif Thr-450 site. We found that mTOR stabilizes SIN1 by phosphorylation of its hydrophobic and conserved Ser-260 site to maintain the integrity of mTORC2. The optimal kinase activity of mTORC2 requires a concentration of ATP above 1.2 mm and makes this kinase complex highly sensitive to ATP depletion. We found that not amino acid but glucose deprivation of cells or acute ATP depletion prevented the mTOR-dependent phosphorylation of SIN1 on Ser-260 and Akt on Thr-450. In a low glucose medium, the cells carrying a substitution of SIN1 with its phosphomimetic mutant show an increased rate of cell proliferation related to a higher abundance of mTORC2 and phosphorylation of Akt. Thus, the homeostatic ATP sensor mTOR controls the integrity of mTORC2 and phosphorylation of Akt on the turn motif site.     

AMPK and mTOR regulate autophagy through direct phosphorylation of Ulk1

Autophagy is a process by which components of the cell are degraded to maintain essential activity and viability in response to nutrient limitation. Extensive genetic studies have shown that the yeast ATG1 kinase has an essential role in autophagy induction. Furthermore, autophagy is promoted by AMP activated protein kinase (AMPK), which is a key energy sensor and regulates cellular metabolism to maintain energy homeostasis. Conversely, autophagy is inhibited by the mammalian target of rapamycin (mTOR), a central cell-growth regulator that integrates growth factor and nutrient signals. Here we demonstrate a molecular mechanism for regulation of the mammalian autophagy-initiating kinase Ulk1, a homologue of yeast ATG1. Under glucose starvation, AMPK promotes autophagy by directly activating Ulk1 through phosphorylation of Ser 317 and Ser 777. Under nutrient sufficiency, high mTOR activity prevents Ulk1 activation by phosphorylating Ulk1 Ser 757 and disrupting the interaction between Ulk1 and AMPK. This coordinated phosphorylation is important for Ulk1 in autophagy induction. Our study has revealed a signalling mechanism for Ulk1 regulation and autophagy induction in response to nutrient signalling.     

Active-Site Inhibitors of mTOR Target Rapamycin-Resistant Outputs of mTORC1 and mTORC2

The mammalian target of rapamycin (mTOR) regulates cell growth and survival by integrating nutrient and hormonal signals. These signaling functions are distributed between at least two distinct mTOR protein complexes: mTORC1 and mTORC2. mTORC1 is sensitive to the selective inhibitor rapamycin and activated by growth factor stimulation via the canonical phosphoinositide 3-kinase (PI3K)→Akt→mTOR pathway. Activated mTORC1 kinase up-regulates protein synthesis by phosphorylating key regulators of mRNA translation. By contrast, mTORC2 is resistant to rapamycin. Genetic studies have suggested that mTORC2 may phosphorylate Akt at S473, one of two phosphorylation sites required for Akt activation; this has been controversial, in part because RNA interference and gene knockouts produce distinct Akt phospho-isoforms. The central role of mTOR in controlling key cellular growth and survival pathways has sparked interest in discovering mTOR inhibitors that bind to the ATP site and therefore target both mTORC2 and mTORC1. We investigated mTOR signaling in cells and animals with two novel and specific mTOR kinase domain inhibitors (TORKinibs). Unlike rapamycin, these TORKinibs (PP242 and PP30) inhibit mTORC2, and we use them to show that pharmacological inhibition of mTOR blocks the phosphorylation of Akt at S473 and prevents its full activation. Furthermore, we show that TORKinibs inhibit proliferation of primary cells more completely than rapamycin. Surprisingly, we find that mTORC2 is not the basis for this enhanced activity, and we show that the TORKinib PP242 is a more effective mTORC1 inhibitor than rapamycin. Importantly, at the molecular level, PP242 inhibits cap-dependent translation under conditions in which rapamycin has no effect. Our findings identify new functional features of mTORC1 that are resistant to rapamycin but are effectively targeted by TORKinibs. These potent new pharmacological agents complement rapamycin in the study of mTOR and its role in normal physiology and human disease.     

Amino acid regulation of TOR complex 1

TOR complex 1 (TORC1), an oligomer of the mTOR (mammalian target of rapamycin) protein kinase, its substrate binding subunit raptor, and the polypeptide Lst8/GbetaL, controls cell growth in all eukaryotes in response to nutrient availability and in metazoans to insulin and growth factors, energy status, and stress conditions. This review focuses on the biochemical mechanisms that regulate mTORC1 kinase activity, with special emphasis on mTORC1 regulation by amino acids. The dominant positive regulator of mTORC1 is the GTP-charged form of the ras-like GTPase Rheb. Insulin, growth factors, and a variety of cellular stressors regulate mTORC1 by controlling Rheb GTP charging through modulating the activity of the tuberous sclerosis complex, the Rheb GTPase activating protein. In contrast, amino acids, especially leucine, regulate mTORC1 by controlling the ability of Rheb-GTP to activate mTORC1. Rheb binds directly to mTOR, an interaction that appears to be essential for mTORC1 activation. In addition, Rheb-GTP stimulates phospholipase D1 to generate phosphatidic acid, a positive effector of mTORC1 activation, and binds to the mTOR inhibitor FKBP38, to displace it from mTOR. The contribution of Rheb's regulation of PL-D1 and FKBP38 to mTORC1 activation, relative to Rheb's direct binding to mTOR, remains to be fully defined. The rag GTPases, functioning as obligatory heterodimers, are also required for amino acid regulation of mTORC1. As with amino acid deficiency, however, the inhibitory effect of rag depletion on mTORC1 can be overcome by Rheb overexpression, whereas Rheb depletion obviates rag's ability to activate mTORC1. The rag heterodimer interacts directly with mTORC1 and may direct mTORC1 to the Rheb-containing vesicular compartment in response to amino acid sufficiency, enabling Rheb-GTP activation of mTORC1. The type III phosphatidylinositol kinase also participates in amino acid-dependent mTORC1 activation, although the site of action of its product, 3'OH-phosphatidylinositol, in this process is unclear.     

mTORC1 inhibition increases neurotensin secretion and gene expression through activation of the MEK/ERK/c-Jun pathway in the human endocrine cell line BON

The mammalian target of rapamycin (mTOR) signaling exists in two complexes: mTORC1 and mTORC2. Neurotensin (NT), an intestinal hormone secreted by enteroendocrine (N) cells in the small bowel, has important physiological effects in the gastrointestinal tract. The human endocrine cell line BON abundantly expresses the NT gene and synthesizes and secretes NT in a manner analogous to that of N cells. Here, we demonstrate that the inhibition of mTORC1 by rapamycin (mTORC1 inhibitor), torin1 (both mTORC1 and mTORC2 inhibitor) or short hairpin RNA-mediated knockdown of mTOR, regulatory associated protein of mTOR (RAPTOR), and p70 S6 kinase (p70S6K) increased basal NT release via upregulating NT gene expression in BON cells. c-Jun activity was increased by rapamycin or torin1 or p70S6K knockdown. c-Jun overexpression dramatically increased NT promoter activity, which was blocked by PD98059, an mitogen-activated protein kinase kinase (MEK) inhibitor. Furthermore, overexpression of MEK1 or extracellular signal-regulated kinase 1 (ERK1) increased c-Jun expression and NT promoter activity. More importantly, PD98059 blocked rapamycin- or torin1-enhanced NT secretion. Consistently, rapamycin and torin1 also increased NT gene expression in Hep3B cells, a human hepatoma cell line that, similar to BON, expresses high levels of NT. Phosphorylation of c-Jun and ERK1/2 was also increased by rapamycin and torin1 in Hep3B cells. Finally, we showed activation of mTOR in BON cells treated with amino acids, high glucose, or serum and, concurrently, the attenuation of ERK1/2 and c-Jun phosphorylation and NT secretion. Together, mTORC1, as a nutrient sensor, negatively regulates NT secretion via the MEK/ERK/c-Jun signaling pathway. Our results identify a physiological link between mTORC1 and MEK/ERK signaling in controlling intestinal hormone gene expression and secretion.     

mTOR Ser-2481 Autophosphorylation Monitors mTORC-specific Catalytic Activity and Clarifies Rapamycin Mechanism of Action

The mammalian target of rapamycin (mTOR) Ser/Thr kinase signals in at least two multiprotein complexes distinguished by their different partners and sensitivities to rapamycin. Acute rapamycin inhibits signaling by mTOR complex 1 (mTORC1) but not mTOR complex 2 (mTORC2), which both promote cell growth, proliferation, and survival. Although mTORC2 regulation remains poorly defined, diverse cellular mitogens activate mTORC1 signaling in a manner that requires sufficient levels of amino acids and cellular energy. Before the identification of distinct mTOR complexes, mTOR was reported to autophosphorylate on Ser-2481 in vivo in a rapamycin- and amino acid-insensitive manner. These results suggested that modulation of mTOR intrinsic catalytic activity does not universally underlie mTOR regulation. Here we re-examine the regulation of mTOR Ser-2481 autophosphorylation (Ser(P)-2481) in vivo by studying mTORC-specific Ser(P)-2481 in mTORC1 and mTORC2, with a primary focus on mTORC1. In contrast to previous work, we find that acute rapamycin and amino acid withdrawal markedly attenuate mTORC1-associated mTOR Ser(P)-2481 in cycling cells. Although insulin stimulates both mTORC1- and mTORC2-associated mTOR Ser(P)-2481 in a phosphatidylinositol 3-kinase-dependent manner, rapamycin acutely inhibits insulin-stimulated mTOR Ser(P)-2481 in mTORC1 but not mTORC2. By interrogating diverse mTORC1 regulatory input, we find that without exception mTORC1-activating signals promote, whereas mTORC1-inhibitory signals decrease mTORC1-associated mTOR Ser(P)-2481. These data suggest that mTORC1- and likely mTORC2-associated mTOR Ser-2481 autophosphorylation directly monitors intrinsic mTORC-specific catalytic activity and reveal that rapamycin inhibits mTORC1 signaling in vivo by reducing mTORC1 catalytic activity.     

Intestinal cell kinase (ICK) promotes activation of mTOR complex 1 (mTORC1) through phosphorylation of Raptor Thr-908

Intestinal cell kinase (ICK), named after its cloning origin, the intestine, is actually a ubiquitously expressed and highly conserved serine/threonine protein kinase. Recently we reported that ICK supports cell proliferation and G(1) cell cycle progression. ICK deficiency significantly disrupted the mammalian target of rapamycin (mTOR) complex 1 (mTORC1) signaling events. However, the biological substrates that mediate the downstream signaling effects of ICK in proliferation and the molecular mechanisms by which ICK interacts with mTORC1 are not well defined. Our prior studies also provided biochemical evidence that ICK interacts with the mTOR/Raptor complex in cells and phosphorylates Raptor in vitro. In this report, we investigated whether and how ICK targets Raptor to regulate the activity of mTORC1. Using the ICK substrate consensus sequence [R-P-X-S/T-P/A/T/S], we identified a putative phosphorylation site, RPGT908T, for ICK in human Raptor. By mass spectrometry and a phospho-specific antibody, we showed that Raptor Thr-908 is a novel in vivo phosphorylation site. ICK is able to phosphorylate Raptor Thr-908 both in vitro and in vivo and when Raptor exists in protein complexes with or without mTOR. Although expression of the Raptor T908A mutant did not affect the mTORC1 integrity, it markedly impaired the mTORC1 activation by insulin or by overexpression of the small GTP-binding protein RheB under nutrient starvation. Our findings demonstrate an important role for ICK in modulating the activity of mTORC1 through phosphorylation of Raptor Thr-908 and thus implicate a potential signaling mechanism by which ICK regulates cell proliferation and division.     

Autophagy gets a brake: DAP1, a novel mTOR substrate,is activated to suppress the autophagic process

Autophagy, a highly regulated catabolic process, is controlled by the action of positive and negative regulators. While many of the positive mediators of autophagy have been identified, very little is known about negative regulators that might counterbalance the process. We recently identified death-associated protein 1 (DAP1) as a suppressor of autophagy and as a novel direct substrate of mammalian target of rapamycin (mTOR). We found that DAP1 is functionally silent in cells growing under rich nutrient supplies through mTOR-dependent inhibitory phosphorylation on two sites, which were mapped to Ser3 and Ser51. During amino acid starvation, mTOR activity is turned off resulting in a rapid reduction in the phosphorylation of DAP1. This caused the conversion of the protein into a suppressor of autophagy, thus providing a buffering mechanism that counterbalances the autophagic flux and prevents its overactivation under conditions of nutrient deprivation. Based on these studies we propose the “gas and brake” concept in which mTOR, the main sensor that regulates autophagy in response to amino acid deprivation, also controls the activity of a specific balancing brake to prevent the overactivation of autophagy.Key words: DAP1, mTOR, autophagy, amino acid starvation, phosphorylationIn recent years, many of the genes controlling and executing the autophagic process have been identified. Most of these genes act as positive mediators of the various steps of the process, including the ULK1 complex, which regulates the induction step, the Vps34-Beclin 1 complex that participates in the vesicle nucleation step and two ubiquitin-like pathways, the Atg12-Atg5 and the LC3-phosphatidylethanolamine (PE) conjugation steps, which play a central role in the vesicle elongation process. To date, only a few negative regulators of autophagy have been identified, including mTOR and the anti-apoptotic Bcl-2 family members. mTOR Ser/Thr kinase is a central suppressor of autophagy acting at the initiating regulatory steps of the process. Many signaling pathways act to inhibit mTOR activity, thus relieving its inhibitory effects on autophagy. The anti-apoptotic Bcl-2 and Bcl-X_L proteins, on the other hand, act at the nucleation step, by directly binding to Beclin 1''s BH3 domain, thus reducing the activation of Vps34 and subsequent autophagy. This inhibition can be relieved through dissociation of the complex, following either JNK-1 mediated phosphorylation of Bcl-2 or DAP kinase-mediated phosphorylation of the BH3 domain of Beclin 1.DAP1 is a small (∼15 kDa), ubiquitously expressed protein, rich in prolines and lacking known functional motifs. DAP1 was isolated more than a decade ago in our laboratory using a functional approach to gene cloning aimed at identifying novel mediators of IFNγ-induced cell death in mammalian cell cultures. Until recently, very little was known about the cellular and molecular functions of DAP1, mainly due to the lack of homology to other known proteins and the lack of functional motifs that could indicate a possible cellular function and studies in mammalian systems were missing.Recently, we discovered that DAP1 is another negative regulator of autophagy; yet, interestingly, its suppressive activity is selectively turned on during the autophagic process. Moreover, we found that DAP1 suppressive activity is tightly linked to the status of mTOR kinase activity. Under nutrient-rich culture conditions, DAP1 is phosphorylated by mTOR on two sites, Ser3 and Ser51, resulting in its inactivation. In response to nutrient deprivation, mTOR is inhibited and DAP1 undergoes rapid dephosphorylation. By knocking down the endogenous DAP1 and introducing either the phosphomimetic or the nonphosphorylatible DAP1 mutants, we found that the dephosphorylation leads to activation of the autophagic suppressive function of DAP1, whereas the phophorylated form is inactive. These results led to a “gas and brake” model, in which at the same time that autophagy is induced, some brakes such as DAP1 are also activated to provide a buffering mechanism that counterbalances the autophagic flux and prevents its overactivation under nutrient-deprivation conditions (Fig. 1). Notably, balancing autophagy is extremely important, since deregulated or excessive autophagy has been implicated in the pathogenesis of diverse diseases, such as certain types of neuronal degeneration and cancer and also in cellular aging.Open in a separate windowFigure 1“Gas and brake” model. During nutrient-rich conditions, active mTORC1 phosphorylates and inactivates the components of the ULK1 complex, ULK1 and Atg13, thus preventing the induction of autophagy. DAP1 is also inactivated simultaneously by mTORC1-mediated phosphorylation on Ser3 and Ser51. In addition, mTORC1 phosphorylates and activates p70S6K and 4E-BP1, which mediate the protein translation and cell growth activities of mTOR. Upon nutrient starvation, mTORC1 activity is attenuated, leading to dephosphorylation and activation of ULK1. ULK1, in turn, undergoes autophosphorylation and phosphorylates Atg13 and FIP200 resulting in ULK1 complex activation and induction of autophagy. On the other hand, activation of DAP1 by dephosphorylation, results in suppression of autophagy, thus inserting a brake into the process of autophagy. Note that the inactive proteins/complexes are faded out.The current challenge is to identify the molecular basis of the suppressive functions of DAP1 on autophagy. We have recently shown that DAP1 knockdown enhances LC3 lipidation and autophagosome accumulation both during amino acid starvation and rapamycin treatment. In addition, preliminary data indicate that the knockdown of DAP1 has no effect on mTOR complex 1 (mTORC1) activity in cells, at least during the first hours of starvation. Accordingly, DAP1 may function between the mTORC1 and the LC3 conjugation systems. The potential targets may fall into one of the multiprotein complexes functioning downstream of mTOR such as the ULK1 complex, the Vps34-Beclin 1 complex and more. Future studies will be performed to identify the molecular mechanism by which DAP1 suppresses autophagy. The lack of known functional motifs in the DAP1 protein sequence suggests that this small proline-rich protein may function as an adaptor blocking autophagy by binding to critical protein partners that still await identification.Although autophagy is primarily a protective process for the cell, it can also play a role in cell death. In response to prolonged starvation, autophagy can act either as a cell survival mechanism or be recruited as a cell death executer. In the future it would be interesting to examine whether the autophagy enhancement resulting from DAP1 knockdown contributes to increased cell death in our system or even may convert the survival properties of autophagy into death induction. This will fit the “gas and brake” model, in which autophagy, which is initially recruited as a cell survival mechanism, is converted into cell death machinery when a certain threshold is crossed due to the loss of the “brake” by the knockdown of DAP1.To date, very little is known about the putative mechanisms that restrict the intensity of the autophagic flux to maintain the continuous benefits of this process under stress. Therefore, the ability of DAP1 to counterbalance and buffer the process in a manner that is tightly linked to the status of a central player in autophagy (i.e., mTOR) is an important discovery in this field and provides a target for future drug design.     

Human cytomegalovirus infection maintains mTOR activity and its perinuclear localization during amino acid deprivation

The mammalian target of rapamycin (mTOR) kinase is present in 2 functionally distinct complexes, mTOR complex 1 (mTORC1) and complex 2 (mTORC2). Active mTORC1 mediates phosphorylation of eIF4E-binding protein (4E-BP) and p70 S6 kinase (S6K), which is important for maintaining translation. During human cytomegalovirus (HCMV) infection, cellular stress responses are activated that normally inhibit mTORC1; however, previous data show that HCMV infection circumvents stress responses and maintains mTOR kinase activity. Amino acid deprivation is a stress response that normally inhibits mTORC1 activity. Amino acids can signal to mTORC1 through the Rag proteins, which promote the colocalization of mTORC1 with its activator Rheb-GTP in a perinuclear region, thereby inducing 4E-BP and S6K phosphorylation. As expected, our results show that amino acid depletion in mock-infected cells caused loss of mTORC1 activity and loss of the perinuclear localization; however, there was no loss of activity or perinuclear localization in HCMV-infected cells where the perinuclear localization of Rheb-GTP and mTOR coincided with the perinuclear assembly compartment (AC). This suggested that HCMV infection bypasses normal Rag-dependent amino acid signaling. This was demonstrated by short hairpin RNA (shRNA) depletion of Rag proteins, which had little effect on mTORC1 activity in infected cells but inhibited activity in mock-infected cells. Our data show that HCMV maintains mTORC1 activity in an amino acid- and Rag-independent manner through the colocalization of mTOR and Rheb-GTP, which occurs in association with the formation of the AC, thus bypassing inhibition that may result from lowered amino acid levels.     

Impaired autophagy due to constitutive mTOR activation sensitizes TSC2-null cells to cell death under stress

It has been well documented that cells deficient in either TSC1 or TSC2 are highly sensitive to various cell death stimuli. In this study, we utilized the TSC2 (-/-) mouse embryonic fibroblasts (MEFs) to study the involvement of autophagy in the enhanced susceptibility of TSC2-null cells to cell death. We first confirmed that both TSC1-null and TSC2-null MEFs are more sensitive to apoptosis in response to amino acid starvation (EBSS) and hypoxia. Second, we found that both the basal and inducible autophagy in TSC2 (-/-) MEFs is impaired, mainly due to constitutive activation of mTORC1. Third, suppression of autophagy by chloroquine and Atg7 knockdown sensitizes TSC2 (+/+) cells, but not TSC2 (-/-) cells, to EBSS-induced cell death. Conversely, the inhibition of mTORC1 by raptor knockdown and rapamycin activates autophagy and subsequently rescues TSC2 (-/-) cells. Finally, in starved cells, nutrient supplementations (insulin-like growth factor-1 (IGF-1) and leucine) enhanced cell death in TSC2 (-/-) cells, but reduced cell death in TSC2 (+/+) cells. Taken together, these data indicate that constitutive activation of mTORC1 in TSC2 (-/-) cells leads to suppression of autophagy and enhanced susceptibility to stress-mediated cell death. Our findings thus provide new insights into the complex relationships among mTOR, autophagy and cell death, and support the possible autophagy-targeted intervention strategies for the treatment of TSC-related pathologies.     

Novel compounds for the modulation of mTOR and autophagy to treat neurodegenerative diseases

Most neurodegenerative diseases show a disruption of autophagic function and display abnormal accumulation of toxic protein aggregates that promotes cellular stress and death. Therefore, induction of autophagy has been proposed as a reasonable strategy to help neurons clear abnormal protein aggregates and survive. The kinase mammalian target of rapamycin (mTOR) is a major regulator of the autophagic process and is regulated by starvation, growth factors, and cellular stressors. The phosphoinositide 3-kinase (PI3K)/ protein kinase B (Akt) pathway, which promotes cellular survival, is the main modulator upstream of mTOR, and alterations in this pathway are common in neurodegenerative diseases, e.g. Alzheimer’s disease (AD) and Parkinson’s disease (PD). In the present work we revised mammalian target of rapamycin complex 1 (mTORC1) pathway and mTORC2 as a complementary an important element in mTORC1 signaling. In addition, we revised the extracellular signal regulated kinase (ERK) pathway, which has become relevant in the regulation of the autophagic process and cellular survival through mTORC2 signaling. Finally, we summarize novel compounds that promote autophagy and neuronal protection in the last five years.     

Amino Acid-Dependent mTORC1 Regulation by the Lysosomal Membrane Protein SLC38A9

The serine/threonine kinase mTORC1 regulates cellular homeostasis in response to many cues, such as nutrient status and energy level. Amino acids induce mTORC1 activation on lysosomes via the small Rag GTPases and the Ragulator complex, thereby controlling protein translation and cell growth. Here, we identify the human 11-pass transmembrane protein SLC38A9 as a novel component of the Rag-Ragulator complex. SLC38A9 localizes with Rag-Ragulator complex components on lysosomes and associates with Rag GTPases in an amino acid-sensitive and nucleotide binding state-dependent manner. Depletion of SLC38A9 inhibits mTORC1 activity in the presence of amino acids and in response to amino acid replenishment following starvation. Conversely, SLC38A9 overexpression causes RHEB (Ras homolog enriched in brain) GTPase-dependent hyperactivation of mTORC1 and partly sustains mTORC1 activity upon amino acid deprivation. Intriguingly, during amino acid starvation mTOR is retained at the lysosome upon SLC38A9 depletion but fails to be activated. Together, the findings of our study reveal SLC38A9 as a Rag-Ragulator complex member transducing amino acid availability to mTORC1 activity.     

Phosphorylation of Raptor by p38beta participates in arsenite-induced mammalian target of rapamycin complex 1 (mTORC1) activation

Cell growth is influenced by environmental stress. Mammalian target of rapamycin (mTOR), the central regulator of cell growth, can be positively or negatively regulated by various stresses through different mechanisms. The p38 MAP kinase pathway is essential in cellular stress responses. Activation of MK2, a downstream kinase of p38α, enhances mTOR complex 1 (mTORC1) activity by preventing TSC2 from inhibiting mTOR activation. The p38β-PRAK cascade targets Rheb to inhibit mTORC1 activity upon glucose depletion. Here we show the activation of p38β participates in activation of mTOR complex 1 (mTORC1) induced by arsenite but not insulin, nutrients, anisomycin, or H(2)O(2). Arsenite treatment of cells activates p38β and induces interaction between p38β and Raptor, a regulatory component of mTORC1, resulting in phosphorylation of Raptor on Ser(863) and Ser(771). The phosphorylation of Raptor on these sites enhances mTORC1 activity, and contributes largely to arsenite-induced mTORC1 activation. Our results shown here and in previous work demonstrate that the p38 pathway can regulate different components of the mTORC1 pathway, and that p38β can target different substrates to either positively or negatively regulate mTORC1 activation when a cell encounters different environmental stresses.