The Opposing Actions of Target of Rapamycin and AMP-Activated Protein Kinase in Cell Growth Control

Cell growth is a highly regulated, plastic process. Its control involves balancing positive regulation of anabolic processes with negative regulation of catabolic processes. Although target of rapamycin (TOR) is a major promoter of growth in response to nutrients and growth factors, AMP-activated protein kinase (AMPK) suppresses anabolic processes in response to energy stress. Both TOR and AMPK are conserved throughout eukaryotic evolution. Here, we review the fundamentally important roles of these two kinases in the regulation of cell growth with particular emphasis on their mutually antagonistic signaling.An efficient homeostatic response to maintain cellular energy despite a noncontinuous supply of nutrients is crucial for the survival of organisms. Cells have, therefore, evolved a host of molecular pathways to sense both intra- and extracellular nutrients and thereby quickly adapt their metabolism to changing conditions. The target of rapamycin (TOR) and AMP-activated protein kinase (AMPK) signaling pathways control growth and metabolism in a complementary manner with TOR promoting anabolic processes under nutrient- and energy-rich conditions, whereas AMPK promotes a catabolic response when cells are low on nutrients and energy. Both pathways are highly conserved from yeast to human. This review summarizes the cross talk between TOR and AMPK in different organisms.     

TOR信号调控真菌细胞的生长与代谢

TOR(target of rapamycin)是一类进化上保守的丝氨酸/苏氨酸(Ser/Thr)蛋白激酶,是真核细胞响应环境信号调控生长和代谢的关键因子。真菌TOR信号途径在营养、压力环境等刺激下,通过核糖体生物合成、营养物质摄入及代谢等过程调节维持胞内稳态。本文主要综述了酵母细胞TOR及TOR复合物的结构,以及近年来真菌TORC1蛋白在不同营养环境、压力等条件下对细胞生长与自噬、代谢以及胁迫生理响应等生命活动的调控机制进展及未来发展方向,为真菌TOR调控生长和代谢产物提供新思路。     

甜蜜的相遇——营养与激素信号协同调节植物生长的新机制

为应对持续不断的环境压力和逆境胁迫,植物需要整合内部和外部信息来调整自身的生长发育,以适应环境。其中,可溶性糖不仅是基础能量和营养代谢的必需分子,也是参与植物生长发育和应对胁迫的信号分子。然而,植物整合糖信号,平衡营养代谢和胁迫应答的分子机制尚不清楚。最近,福建农林大学熊延团队发现,居于植物营养感受通路中心地位的TOR...     

Discrete functions of rictor and raptor in cell growth regulation in Drosophila

The TOR signaling pathway regulates cell growth and metabolism in response to various nutrient signals by forming complexes with either rictor or raptor. To distinguish the physiological roles of the complexes formed by the two different TOR partners, we compared the in vivo functions of rictor and raptor in Drosophila. In rictor-null mutants, Akt-induced tissue hyperplasia was reduced and Akt-Ser-505 phosphorylation was decreased. Furthermore, FOXO-dependent apoptosis, which is inhibited by Akt, was augmented in the rictor-null background, indicating that rictor is essential for the Akt-FOXO signaling module. We found that neither S6K-dependent cell growth nor S6K-Thr-398 phosphorylation was affected in rictor-null mutants. However, the knockdown of another TOR binding partner, raptor, decreased S6K-Thr-398 phosphorylation and inhibited S6K-induced cell overgrowth. Collectively, our findings strongly support that the association of TOR with rictor or raptor plays pivotal roles in TOR-mediated cell apoptosis and growth control by differentially regulating Akt- and S6K-dependent signaling pathways, respectively.     

Autophagy in cellular growth control

Cell growth is regulated by two antagonistic processes: TOR signaling and autophagy. These processes integrate signals including growth factors, amino acids, and energy status to ensure that cell growth is appropriate to environmental conditions. Autophagy responds indirectly to the cellular milieu as a downstream inhibitory target of TOR signaling and is also directly controlled by nutrient availability, cellular energy status, and cell stress. The control of cell growth by TOR signaling and autophagy are relevant to disease, as altered regulation of either pathway results in tumorigenesis. Here we give an overview of how TOR signaling and autophagy integrate nutritional status to regulate cell growth, how these pathways are coordinately regulated, and how dysfunction of this regulation might result in tumorigenesis.     

Thinking globally and acting locally with TOR

The target of rapamycin (TOR) pathway regulates ribosome biogenesis, protein synthesis, nutrient import, autophagy and cell cycle progression. After 30 years of concentrated attention, how TOR controls these processes is only now beginning to be understood. Recent advances have identified a wide array of TOR inputs, including amino acids, oxygen, ATP and growth factors, as well the regulatory proteins that facilitate their effects on TOR. Such proteins include AMPK, Rheb and the tumor suppressors LKB1, p53, and Tsc1/2. It has only recently been appreciated that TOR resides in two distinct signaling complexes with differing regulatory roles, only one of which is rapamycin-sensitive, thus opening a new avenue of inquiry into TOR function. Finally, TOR appears to regulate feeding behavior by facilitating communication between organ systems, and is thus implicated in the regulation of glucose and fat homeostasis, and possibly diabetes and obesity. TOR thus functions to coordinate growth-permitting inputs with growth-promoting outputs on both a cellular and an organismal level.     

Coordination of Ribosomal Protein and Ribosomal RNA Gene Expression in Response to TOR Signaling

Cells grow in response to nutrients or growth factors, whose presence is detected and communicated by elaborate signaling pathways. Protein kinases play crucial roles in processes such as cell cycle progression and gene expression, and misregulation of such pathways has been correlated with various diseased states. Signals intended to promote cell growth converge on ribosome biogenesis, as the ability to produce cellular proteins is intimately tied to cell growth. Part of the response to growth signals is therefore the coordinate expression of genes encoding ribosomal RNA (rRNA) and ribosomal proteins (RP). A key player in regulating cell growth is the Target of Rapamycin (TOR) kinase, one of the gatekeepers that prevent cell cycle progression from G1 to S under conditions of nutritional stress. TOR is structurally and functionally conserved in all eukaryotes. Under favorable growth conditions, TOR is active and cells maintain a robust rate of ribosome biogenesis, translation initiation and nutrient import. Under stress conditions, TOR signaling is suppressed, leading to cell cycle arrest, while the failure of TOR to respond appropriately to environmental or nutritional signals leads to uncontrolled cell growth. Emerging evidence from Saccharomyces cerevisiae indicates that High Mobility Group (HMGB) proteins, non-sequence-specific chromosomal proteins, participate in mediating responses to growth signals. As HMGB proteins are distinguished by their ability to alter DNA topology, they frequently function in the assembly of higher-order nucleoprotein complexes. We review here recent evidence, which suggests that HMGB proteins may function to coordinate TOR-dependent regulation of rRNA and RP gene expression.Key Words: Rapamycin, TORC1, HMO1, high mobility group, yeast, RP gene, rDNA.     

植物TOR激酶响应上游信号的研究进展

雷帕霉素靶蛋白(TOR)是真核生物中高度保守的丝氨酸/苏氨酸蛋白激酶, 能整合营养、能量、生长因子及环境信号, 协调细胞增殖、生长和代谢等过程, 是真核生物生长发育的核心调控因子。近年来, 随着相关研究系统的建立, 植物TOR的功能和机制研究取得了众多突破, 发现其进化上保守的生物学功能及植物中特有的信号通路。该文概述了TOR蛋白复合体的构成, 以及植物TOR响应糖、营养元素(氮、磷和硫)、激素及逆境胁迫信号来调控下游基因转录、蛋白翻译、代谢、细胞自噬和胁迫应答等生物学过程的分子机制, 并提出了植物TOR领域一些亟待解决的科学问题, 以期为全面揭示植物TOR的生物学功能提供参考。     

TOR inhibition primes immunity and pathogen resistance in tomato in a salicylic acid-dependent manner

All organisms need to sense and process information about the availability of nutrients, energy status, and environmental cues to determine the best time for growth and development. The conserved target of rapamycin (TOR) protein kinase has a central role in sensing and perceiving nutritional information. TOR connects environmental information about nutrient availability to developmental and metabolic processes to maintain cellular homeostasis. Under favourable energy conditions, TOR is activated and promotes anabolic processes such as cell division, while suppressing catabolic processes. Conversely, when nutrients are limited or environmental stresses are present, TOR is inactivated, and catabolic processes are promoted. Given the central role of TOR in regulating metabolism, several previous works have examined whether TOR is wired to plant defence. To date, the mechanisms by which TOR influences plant defence are not entirely clear. Here, we addressed this question by testing the effect of inhibiting TOR on immunity and pathogen resistance in tomato. Examining which hormonal defence pathways are influenced by TOR, we show that tomato immune responses and disease resistance to several pathogens increase on TOR inhibition, and that TOR inhibition-mediated resistance probably requires a functional salicylic acid, but not jasmonic acid, pathway. Our results support the notion that TOR is a master regulator of the development–defence switch in plants.     

The aging stress response

Aging is the outcome of a balance between damage and repair. The rate of aging and the appearance of age-related pathology are modulated by stress response and repair pathways that gradually decline, including the proteostasis and DNA damage repair networks and mitochondrial respiratory metabolism. Highly conserved insulin/IGF-1, TOR, and sirtuin signaling pathways in turn control these critical cellular responses. The coordinated action of these signaling pathways maintains cellular and organismal homeostasis in the face of external perturbations, such as changes in nutrient availability, temperature, and oxygen level, as well as internal perturbations, such as protein misfolding and DNA damage. Studies in model organisms suggest that changes in signaling can augment these critical stress response systems, increasing life span and reducing age-related pathology. The systems biology of stress response signaling thus provides a new approach to the understanding and potential treatment of age-related diseases.     

An emerging role for TOR signaling in mammalian tissue and stem cell physiology

The mammalian target of rapamycin (mTOR) is a kinase that responds to a myriad of signals, ranging from nutrient availability and energy status, to cellular stressors, oxygen sensors and growth factors. The finely tuned response of mTOR to these stimuli results in alterations to cell metabolism and cell growth. Recent studies of conditional knockouts of mTOR pathway components in mice have affirmed the role of mTOR signaling in energy balance, both at the cell and whole organism levels. Such studies have also highlighted a role for mTOR in stem cell homeostasis and lifespan determination. Here, we discuss the molecular mechanisms of TOR signaling and review recent in vitro and in vivo studies of mTOR tissue-specific activities in mammals.     

The TSC/Rheb/TOR Signaling Pathway in Fission Yeast and Mammalian Cells: Temperature Sensitive and Constitutive Active Mutants of TOR

The TSC/Rheb/TOR signaling pathway plays important roles in growth and cell cycle regulation. The main player TOR belongs to the PI3K-related protein kinase family. Recent studies utilizing fission yeast Tor2 have led to the identification of a number of amino acid changes that lead to inactivation as well as activation of TOR kinase. Also, constitutive active mutations in its upstream regulator, Rheb, have been identified. Isolation and characterization of temperature sensitive Tor2 mutants have established that this kinase functions as a key switch that determines cell fate between growth and sexual development. Introduction of Tor2 activating mutations into mTOR conferred nutrient independent activation of mTOR. Interestingly, these studies point to regions of TOR kinase important for its function.     

Drosophila Melted modulates FOXO and TOR activity

The insulin/PI3K signaling pathway controls both tissue growth and metabolism. Here, we identify Melted as a new modulator of this pathway in Drosophila. Melted interacts with both Tsc1 and FOXO and can recruit these proteins to the cell membrane. We provide evidence that in the melted mutant, TOR activity is reduced and FOXO is activated. The melted mutant condition mimics the effects of nutrient deprivation in a normal animal, producing an animal with 40% less fat than normal.     

Plant TOR signaling components

Cell growth is a process that needs to be tightly regulated. Cells must be able to sense environmental factors like nutrient abundance, the energy level or stress signals and coordinate growth accordingly. The Target Of Rapamycin (TOR) pathway is a major controller of growth-related processes in all eukaryotes. If environmental conditions are favorable, the TOR pathway promotes cell and organ growth and restrains catabolic processes like autophagy. Rapamycin is a specific inhibitor of the TOR kinase and acts as a potent inhibitor of TOR signaling. As a consequence, interfering with TOR signaling has a strong impact on plant development. This review summarizes the progress in the understanding of the biological significance and the functional analysis of the TOR pathway in plants.     

雌激素影响物质和能量代谢的中枢机制

雌激素与糖尿病的发生和发展有密切关系。新近研究表明,雌激素受体(estrogen receptor,ER)对物质代谢和能量平衡具有重要调节作用。雌激素可由核内ER介导,通过基因组机制,或膜上ER通过磷脂酰肌醇3-激酶/蛋白激酶B及胞外信号调节激酶信号转导通路,调节下丘脑神经元摄食和厌食神经肽的表达。下丘脑ERα基因沉默小鼠表现出典型的代谢综合征症状,提示中枢ERα能够影响外周能量代谢。进一步研究发现,中枢ERα和胰岛素以及瘦素信号转导通路存在交互作用。因此,阐明中枢ER调控能量代谢的机制,可为临床防治雌激素紊乱导致的糖和能量代谢异常提供新的思路。