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。     

Signaling by Target of Rapamycin Proteins in Cell Growth Control

Target of rapamycin (TOR) proteins are members of the phosphatidylinositol kinase-related kinase (PIKK) family and are highly conserved from yeast to mammals. TOR proteins integrate signals from growth factors, nutrients, stress, and cellular energy levels to control cell growth. The ribosomal S6 kinase 1 (S6K) and eukaryotic initiation factor 4E binding protein 1(4EBP1) are two cellular targets of TOR kinase activity and are known to mediate TOR function in translational control in mammalian cells. However, the precise molecular mechanism of TOR regulation is not completely understood. One of the recent breakthrough studies in TOR signaling resulted in the identification of the tuberous sclerosis complex gene products, TSC1 and TSC2, as negative regulators for TOR signaling. Furthermore, the discovery that the small GTPase Rheb is a direct downstream target of TSC1-TSC2 and a positive regulator of the TOR function has significantly advanced our understanding of the molecular mechanism of TOR activation. Here we review the current understanding of the regulation of TOR signaling and discuss its function as a signaling nexus to control cell growth during normal development and tumorigenesis.     

The Target of Rapamycin Signaling Pathway Regulates mRNA Turnover in the Yeast Saccharomyces cerevisiae

The target of rapamycin (TOR) signaling pathway is an important mechanism by which cell growth is regulated by nutrient availability in eukaryotes. We provide evidence that the TOR signaling pathway controls mRNA turnover in Saccharomyces cerevisiae. During nutrient limitation (diauxic shift) or after treatment with rapamycin (a specific inhibitor of TOR), multiple mRNAs were destabilized, whereas the decay of other mRNAs was unaffected. Our findings suggest that the regulation of mRNA decay by the TOR pathway may play a significant role in controlling gene expression in response to nutrient depletion. The inhibition of the TOR pathway accelerated the major mRNA decay mechanism in yeast, the deadenylation-dependent decapping pathway. Of the destabilized mRNAs, two different responses to rapamycin were observed. Some mRNAs were destabilized rapidly, while others were affected only after prolonged exposure. Our data suggest that the mRNAs that respond rapidly are destabilized because they have short poly(A) tails prematurely either as a result of rapid deadenylation or reduced polyadenylation. In contrast, the mRNAs that respond slowly are destabilized by rapid decapping. In summary, the control of mRNA turnover by the TOR pathway is complex in that it specifically regulates the decay of some mRNAs and not others and that it appears to control decay by multiple mechanisms.     

Inhibition of Target of Rapamycin Signaling and Stress Activate Autophagy in Chlamydomonas reinhardtii

Autophagy is a catabolic membrane-trafficking process whereby cells recycle cytosolic proteins and organelles under stress conditions or during development. This degradative process is mediated by autophagy-related (ATG) proteins that have been described in yeast, animals, and more recently in plants. In this study, we report the molecular characterization of autophagy in the unicellular green alga Chlamydomonas reinhardtii. We demonstrate that the ATG8 protein from Chlamydomonas (CrATG8) is functionally conserved and may be used as a molecular autophagy marker. Like yeast ATG8, CrATG8 is cleaved at the carboxyl-terminal conserved glycine and is associated with membranes in Chlamydomonas. Cell aging or different stresses such as nutrient limitation, oxidative stress, or the accumulation of misfolded proteins in the endoplasmic reticulum caused an increase in CrATG8 abundance as well as the detection of modified forms of this protein, both landmarks of autophagy activation. Furthermore, rapamycin-mediated inhibition of the Target of Rapamycin signaling pathway, a major regulator of autophagy in eukaryotes, results in identical effects on CrATG8 and a relocalization of this protein in Chlamydomonas cells similar to the one observed upon nutrient limitation. Thus, our findings indicate that Chlamydomonas cells may respond to stress conditions by inducing autophagy via Target of Rapamycin signaling modulation.Protein turnover is essential for the adaptation of cells to variable environmental conditions. Similar to other eukaryotes, plants have developed two distinct mechanisms to regulate protein degradation, a selective ubiquitin/26S proteasome pathway (Vierstra, 2009) and macroautophagy (hereafter referred to as autophagy), a nonselective membrane-trafficking process (Bassham, 2009). During autophagy, a large number of cytosolic components, including entire organelles, organelle fragments, and protein complexes, are enclosed in bulk within a double-membrane structure known as the autophagosome and delivered to the vacuole/lysosome for degradation to recycle needed nutrients or degrade toxic components (Xie and Klionsky, 2007; Nakatogawa et al., 2009). The autophagosomes appear to arise from isolation membranes usually observed in close proximity to the vacuole called the preautophagosomal structure (PAS). These membranes expand and fuse to encircle portions of the cytoplasm, generating an autophagosome that is targeted to the vacuole. The outer membrane of the autophagosome then fuses with the vacuole membrane, and the remaining vesicle, known as the autophagic body, is finally released to the vacuole for its degradation (Xie and Klionsky, 2007).The evolutionary conservation of autophagy among eukaryotes indicates that structural and regulatory components of this cellular process must be also conserved. Accordingly, a significant number of autophagy-related (ATG) genes that participate in autophagy regulation and autophagosome formation have been identified, initially through genetic approaches in yeast and subsequently in higher eukaryotes, including mammals, insects, protozoa, and plants (Bassham et al., 2006; Bassham, 2007; Meijer et al., 2007). In yeast, two protein conjugation systems composed of the ubiquitin-like proteins ATG8 and ATG12 and the three enzymes ATG3, ATG7, and ATG10 play an essential role in autophagosome formation and seem to be conserved through evolution (Geng and Klionsky, 2008). ATG8 becomes modified with the lipid molecule phosphatidylethanolamine (PE) by the consecutive action of the ATG7 and ATG3 enzymes in a process mechanistically similar to ubiquitination (Ichimura et al., 2000). Prior to this modification, ATG8 must be cleaved by the Cys protease ATG4 to expose a C-terminal Gly residue that is conjugated to PE (Kirisako et al., 2000; Kim et al., 2001). ATG12 becomes covalently attached to the ATG5 protein in a conjugation reaction that is catalyzed by ATG7 and ATG10 (Mizushima et al., 1998). ATG8-PE and ATG12-ATG5 conjugates localize to autophagy-related membranes and are required for the initiation and expansion of autophagosomal membrane and hemifusion of this membrane with the vacuolar membrane (Hanada et al., 2007; Nakatogawa et al., 2007, 2009; Fujita et al., 2008; Geng and Klionsky, 2008; Xie et al., 2008).Our understanding of the autophagy process has substantially increased with the development of specific markers for autophagy. In plants, two markers for autophagosomes have been described, the monodansylcadaverine dye and GFP-ATG8 fusion protein (Yoshimoto et al., 2004; Contento et al., 2005; Thompson et al., 2005). As in other species, binding of ATG8 to autophagosomes has been used to monitor autophagy in plants. In contrast to yeast, where a single ATG8 gene is present, plants appear to contain a small gene family with several ATG8 isoforms, suggesting that autophagy is more complex in these photosynthetic organisms. For example, Arabidopsis (Arabidopsis thaliana) and maize (Zea mays) encode nine and five ATG8 genes, respectively (Doelling et al., 2002; Hanaoka et al., 2002; Ketelaar et al., 2004; Chung et al., 2009). However, despite the high complexity of the ATG8-conjugating system in plants, important findings have been recently reported on the molecular characterization of autophagy using ATG8 as an autophagy marker in these organisms. The use of specific markers for autophagy in plants has revealed that this process is active at a basal level under normal growth and is induced upon nitrogen- or carbon-limiting conditions as well as in response to oxidative stress (Yoshimoto et al., 2004; Thompson et al., 2005; Xiong et al., 2005, 2007; Chung et al., 2009). Reverse genetic approaches have also been applied to a number of Arabidopsis ATG genes using T-DNA insertional mutants or RNA interference in order to investigate the physiological roles of autophagy in plants. The initial characterization of autophagy-deficient plants demonstrated that the ATG system is not essential under nutrient-rich conditions. However, a detailed analysis of these mutants indicated that autophagy is required for the proper response of the plant to nutrient limitation or pathogen infection. Plants lacking the ATG4, ATG5, ATG7, ATG9, or ATG10 gene display premature leaf senescence and are hypersensitive to nitrogen or carbon limitation (Doelling et al., 2002; Hanaoka et al., 2002; Yoshimoto et al., 2004; Thompson et al., 2005; Phillips et al., 2008). Arabidopsis plants with reduced levels of ATG18, which is required for autophagosome formation, are more sensitive to methyl viologen treatment and accumulate high levels of oxidized proteins, demonstrating that autophagic processes participate in the response of the plant to oxidative stress (Xiong et al., 2005, 2007). Plants deficient in the autophagy genes ATG6/Beclin1, ATG3, ATG7, and ATG9 exhibit unrestricted hypersensitive response lesions in response to pathogen infection (Liu et al., 2005; Hofius et al., 2009). These findings implicate autophagy as a prosurvival mechanism to restrict programmed cell death associated with the pathogen-induced hypersensitive response in plants. Arabidopsis ATG6 has also been shown to mediate pollen germination in a manner independent of autophagy (Fujiki et al., 2007).As mentioned above, autophagy is triggered among other factors by a reduction in the availability of nutrients. This starvation signal is transmitted to the autophagic machinery by important regulatory factors, including the Ser/Thr kinases Target of Rapamycin (TOR), ATG1, and SNF1 and the phosphatidylinositol 3-kinase ATG6/Beclin1 (Diaz-Troya et al., 2008b; Bassham, 2009; Cebollero and Reggiori, 2009). TOR has been identified as a negative regulator of autophagy in yeast, mammals, and fruit flies (Diaz-Troya et al., 2008b). The pharmacological inhibition of TOR by rapamycin leads to autophagy activation through a mechanism that requires the activation of the ATG1 kinase (Kamada et al., 2000). It has been recently demonstrated in mammals and fruit flies that a rapamycin-sensitive TOR signaling complex termed TORC1 directly phosphorylates and inhibits the ATG1 kinase and its regulatory protein ATG13 (Chang and Neufeld, 2009; Hosokawa et al., 2009; Jung et al., 2009). These regulatory proteins are conserved in plants, although except for ATG6 (Liu et al., 2005), there is no direct evidence for regulation of autophagy by these signaling pathways.The unicellular green alga Chlamydomonas reinhardtii has been used as a model for the study of important cellular and metabolic processes in photosynthetic organisms (Harris, 2001). More recently, Chlamydomonas has also been proposed as a useful system for the characterization of the TOR signaling pathway in photosynthetic eukaryotes based on the finding that, unlike plants, Chlamydomonas cell growth is sensitive to rapamycin (Crespo et al., 2005; Diaz-Troya et al., 2008a). Treatment of Chlamydomonas cells with rapamycin results in a pronounced increase of vacuole size that resembles autophagy-like processes (Crespo et al., 2005). However, a role of TOR in autophagy regulation could not be demonstrated due to the absence of an autophagy marker in Chlamydomonas. Actually, no studies have been reported on any autophagy-related protein in green algae, despite the high conservation of ATG genes in Chlamydomonas (Diaz-Troya et al., 2008b).This study reports the molecular and cellular characterization of autophagy in the green alga Chlamydomonas. We demonstrate that the ATG8 protein from Chlamydomonas (CrATG8) may be used as a specific autophagy marker. Nutrient limitation and cell aging trigger an autophagic response that can be traced as an increase at the level of CrATG8, the detection of modified forms of CrATG8, and a change in the cellular localization of this protein. Furthermore, we demonstrate that autophagy is inhibited by a rapamycin-sensitive TOR cascade in Chlamydomonas.     

Mammalian Target of Rapamycin (mTOR) Signaling Network in Skeletal Myogenesis

Mammalian (or mechanistic) target of rapamycin (mTOR) regulates a wide range of cellular and developmental processes by coordinating signaling responses to mitogens, nutrients, and various stresses. Over the last decade, mTOR has emerged as a master regulator of skeletal myogenesis, controlling multiple stages of the myofiber formation process. In this minireview, we present an emerging view of the signaling network underlying mTOR regulation of myogenesis, which contrasts with the well established mechanisms in the regulation of cell and muscle growth. Current questions for future studies are also highlighted.     

高等植物赤霉素代谢及其信号转导通路

赤霉素是一类重要的植物激素,对植物的生长发育,如种子的萌发、茎的延展、叶片的生长、休眠芽的萌发以及植物的花和种子的发育等生理具有重要的调控作用。从1926年被发现至今,阐明了赤霉素代谢机理及调控机制,明确了赤霉素在植物体内的信号转导途径。本文综述了赤霉素的生物合成途径及其平衡的调节;赤霉素受体GID1、DELLA蛋白在赤霉素信号转导途径中的作用及相关研究;泛素介导的DELLA蛋白降解在赤霉素信号转导中的研究进展。     

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.     

雷帕霉素靶在小鼠受精卵早期发育中的作用研究

哺乳动物雷帕霉素靶(mTOR)是细胞生长的中心调控因子,应用RT-PCR、免疫印迹、放射性同位素体外测定酶活性等方法,研究mTOR在小鼠受精卵第一次有丝分裂过程中在卵中的表达、活性变化以及对卵裂的影响.研究发现mTOR在小鼠卵母细胞和受精卵中都有表达,在mRNA水平,mTOR从G2期开始降解,在蛋白水平,则各期没有明显变化;mTOR的激酶活性在受精后明显升高,并且在整个1-细胞期保持较高活性;mTOR的特异性抑制剂雷帕霉素能抑制卵裂,并且能抑制成熟促进因子MPF的调节亚基cyclin B的表达,从而抑制了MPF的活性.结果表明mTOR可能通过促进MPF的激活而促进小鼠受精卵的分裂.     

膨胀素在植物生长发育中的作用

膨胀素是一类具有非水解活性的细胞壁松弛蛋白,参与植物生长发育过程中细胞壁的修饰。大多数植物中都发现有膨胀素基因家族成员存在,其功能涉及植物生长发育的各个方面,包括营养生长、形态发生、受精授粉、果实成熟等,并表现出高度的组织、器官和细胞特异性。本文综述膨胀素在种子萌发、叶的发育、根茎生长、花的发育等生长发育过程中的作用。     

类脂对植物生长和发育的作用

简述了类脂在植物生长和发育中的作用,特别是类脂中脂肪酸的饱和度对植物生长发育的影响,植物固醇对植物的表型和在低温下的生长、胚胎的发育以及可育性中的作用.     

Methylglyoxal Activates the Target of Rapamycin Complex 2-Protein Kinase C Signaling Pathway in Saccharomyces cerevisiae

Methylglyoxal is a typical 2-oxoaldehyde derived from glycolysis. We show here that methylglyoxal activates the Pkc1-Mpk1 mitogen-activated protein (MAP) kinase cascade in a target of rapamycin complex 2 (TORC2)-dependent manner in the budding yeast Saccharomyces cerevisiae. We demonstrate that TORC2 phosphorylates Pkc1 at Thr¹¹²⁵ and Ser¹¹⁴³. Methylglyoxal enhanced the phosphorylation of Pkc1 at Ser¹¹⁴³, which transmitted the signal to the downstream Mpk1 MAP kinase cascade. We found that the phosphorylation status of Pkc1^T1125 affected the phosphorylation of Pkc1 at Ser¹¹⁴³, in addition to its protein levels. Methylglyoxal activated mammalian TORC2 signaling, which, in turn, phosphorylated Akt at Ser⁴⁷³. Our results suggest that methylglyoxal is a conserved initiator of TORC2 signaling among eukaryotes.     

Role of Slit/Robo Signaling pathway in Bone Metabolism

Slit/Robo signals were initially found to play an essential role in nerve development as axonal guidance molecules. In recent years, with in-depth study, the role of Slit/Robo in other life activities, such as tumor development, angiogenesis, cell migration, and bone homeostasis, has gradually been revealed. Bone is an organ with an active metabolism. Bone resorption and bone formation are closely related through precise spatiotemporal coordination. There is much evidence that slit, as a new bone coupling factor, can regulate bone formation and resorption. For example, Slit3 can promote bone formation and inhibit bone resorption through Robo receptors, which has excellent therapeutic potential in metabolic bone diseases. Although the conclusions of some studies are contradictory, they all affirm the vital role of Slit/Robo signaling in regulating bone metabolism. This paper reviews the research progress of Slit/Robo signaling in bone metabolism, briefly discusses the contradictions in the existing research, and puts forward the research direction of Slit/Robo in the field of bone metabolism in the future.