Hot topics in aging research: protein translation, 2009

In the last few years, links between regulation of mRNA translation and aging have been firmly established in invertebrate model organisms. This year, a possible relationship between mRNA translation and aging in mammals has been established with the report that rapamycin increases lifespan in mice. Other significant findings have connected translation control with other known longevity pathways and provided fodder for mechanistic hypotheses. Here, we summarize advances in this emerging field and raise questions for future studies.     

Protein translation, 2008

The important role that regulation of protein translation plays in determining longevity in invertebrate organisms became widely appreciated in 2007, with the publication of several papers discussed in last year's review. During 2008, several studies have further strengthened the idea that regulation of translation is one component of a highly evolutionarily conserved pathway that modifies longevity. Importantly, studies published this year also began to provide insights into specific mechanisms by which altered mRNA translation does (and in some cases does not) slow aging in invertebrate model organisms.     

Protein translation, 2007

Translation of RNA to protein is essential for life. It should perhaps not be surprising, therefore, that appropriate regulation of translation plays a key role in determining longevity. This Hot Topic article discusses papers published in the last year related to the importance of translation and its regulation by signaling through the target of rapamycin kinase, in modulating aging and age-associated diseases.     

Recent advances in vertebrate aging research 2009

Among the notable trends seen in this year’s highlights in mammalian aging research is an awakening of interest in the assessment of age‐related measures of mouse health in addition to the traditional focus on longevity. One finding of note is that overexpression of telomerase extended life and improved several indices of health in mice that had previously been genetically rendered cancer resistant. In another study, resveratrol supplementation led to amelioration of several degenerative conditions without affecting mouse lifespan. A primate dietary restriction (DR) study found that restriction led to major improvements in glucoregulatory status along with provocative but less striking effects on survival. Visceral fat removal in rats improved their survival, although not as dramatically as DR. An unexpected result showing the power of genetic background effects was that DR shortened the lifespan of long‐lived mice bearing Prop1^df, whereas a previous report in a different background had found DR to extend the lifespan of Prop1^df mice. Treatment with the mammalian target of rapamycin (mTOR) inhibitor, rapamycin, enhanced the survival of even elderly mice and improved their vaccine response. Genetic inhibition of a TOR target made female, but not male, mice live longer. This year saw the mTOR network firmly established as a major modulator of mammalian lifespan.     

drr‐2 encodes an eIF4H that acts downstream of TOR in diet‐restriction‐induced longevity of C. elegans

Dietary restriction (DR) results in a robust increase in lifespan while maintaining the physiology of much younger animals in a wide range of species. Here, we examine the role of drr‐2, a DR‐responsive gene recently identified, in determining the longevity of Caenorhabditis elegans. Inhibition of drr‐2 has been shown to increase longevity. However, the molecular mechanisms by which drr‐2 influences longevity remain unknown. We report here that drr‐2 encodes an ortholog of human eukaryotic translation initiation factor 4H (eIF4H), whose function is to mediate the initiation step of mRNA translation. The molecular function of DRR‐2 is validated by the association of DRR‐2 with polysomes and by the decreased rate of protein synthesis observed in drr‐2 knockdown animals. Previous studies have also suggested that DR might trigger a regulated reduction in drr‐2 expression to initiate its longevity response. By examining the effect of increasing drr‐2 expression on DR animals, we find that drr‐2 is essential for a large portion of the longevity response to DR. The nutrient‐sensing target of rapamycin (TOR) pathway has been shown to mediate the longevity effects of DR in C. elegans. Results from our genetic analyses suggest that eIF4H/DRR‐2 functions downstream of TOR, but in parallel to the S6K/PHA‐4 pathway to mediate the lifespan effects of DR. Together, our findings reveal an important role for eIF4H/drr‐2 in the TOR‐mediated longevity responses to DR.     

Expanding mTOR signaling

The mammalian target of rapamycin （mTOR） has drawn growth control and its involvement in human tumorigenesis much attention recently because of its essential role in cell Great endeavors have been made to elucidate the functions and regulation of mTOR in the past decade. The current prevailing view is that mTOR regulates many fundamental biological processes, such as cell growth and survival, by integrating both intracellular and extracellular signals, including growth factors, nutrients, energy levels, and cellular stress. The significance of roTOR has been highlighted most recently by the identification of mTOR-associated proteins. Amazingly, when bound to different proteins, mTOR forms distinctive complexes with very different physiological functions. These findings not only expand the roles that mTOR plays in cells but also further complicate the regulation network. Thus, it is now even more critical that we precisely understand the underlying molecular mechanisms in order to directly guide the development and usage of anti-cancer drugs targeting the mTOR signaling pathway. In this review, we will discuss different mTOR-associated proteins, the regulation of mTOR complexes, and the consequences of mTOR dysregulation under pathophysiological conditions.     

Regulation of global and specific mRNA translation by oral administration of branched-chain amino acids

The importance of branched-chain amino acids as nutrient regulators of protein synthesis in skeletal muscle was recognized more than 20 years ago. Of the branched-chain amino acids, leucine in particular was shown to play a central role in promoting muscle protein synthesis. However, it was only recently that the mechanism(s) involved in the stimulation of protein synthesis by leucine has begun to be defined. Studies performed in our laboratory during the past few years have revealed that oral administration of leucine to fasted rats enhances protein synthesis in association with increased phosphorylation of two proteins downstream of the protein kinase referred to as the mammalian target of rapamycin (mTOR). These proteins, eukaryotic initiation factor eIF4E binding protein (4E-BP)1 and ribosomal protein S6 kinase S6K1, control in part the step in translation initiation involving the binding of mRNA to the 40S ribosomal subunit. In theory the translation of all mRNAs can be regulated through such mechanisms, however, some mRNAs are more sensitive to the changes than others, resulting in modulation of gene expression through altered patterns of translation of specific mRNAs. Moreover, although a basal amount of plasma insulin is required for leucine to enhance signaling downstream of mTOR, the concentration observed in plasma of fasted rats is sufficient to observe maximal changes in phosphorylation of 4E-BP1 and S6K1.     

AMPK represses TOP mRNA translation but not global protein synthesis in liver

The AMP-activated protein kinase (AMPK) represses signaling through the mammalian target of rapamycin complex 1 (mTORC1). In muscle, repression of mTORC1 leads to a reduction in global protein synthesis. In contrast, repression of mTORC1 in the liver has no immediate effect on global protein synthesis. In the present study, signaling through mTORC1 and translation of specific mRNAs such as those bearing a 5′-terminal oligopyrimidine (TOP) tract and were examined in rat liver following activation of AMPK after treadmill running. Activation of AMPK repressed translation of the TOP mRNAs encoding rpS6, rpS8, and eEF1α. In contrast, neither global protein synthesis nor translation of mRNAs encoding GAPDH or β-actin was changed. Basal phosphorylation of the mTORC1 target 4E-BP1, but not S6K1 or rpS6, was reduced following activation of AMPK. Thus, in liver, AMPK activation repressed translation of TOP mRNAs through a mechanism distinct from downregulated phosphorylation of S6K1 or rpS6.     

哺乳动物雷帕霉素靶蛋白（mTOR）在不同发育阶段SD大鼠睾丸中的表达及作用

精子发生是男性生殖中的主要过程,精原细胞的不断分裂增殖又保证了精子发生的顺利进行。随着年龄的不断增长,男性精子的数量、质量出现下降趋势。mTOR信号转导通路在细胞增殖分化中发挥着中心调控作用,因此,mTOR信号通路可能在精子发生过程中有着重要的地位。为了探明mTOR信号通路与精子发生的关系,首先,通过SD大鼠睾丸组织切片的免疫组化,发现mTOR是在生精小管的精原细胞胞浆中表达;其次,采用FQ-PCR检测mTOR mRNA在SD大鼠睾丸中的表达。结果显示,80周龄组mTOR的转录与8周龄组相比差异显著。最后利用Western blot检测出mTOR蛋白的表达及其对下游靶蛋白P70S6K的磷酸化效率均随年龄的增长逐渐下降。同时,在用雷帕霉素处理8周龄SD大鼠中,发现精子数量减少,P70S6K磷酸化效率降低并伴随生精小管萎缩和空泡化。通过这些结果,可以看出mTOR信号转导通路可能在精子发生中发挥着重要作用。     

A phospho-proteomic screen identifies novel S6K1 and mTORC1 substrates revealing additional complexity in the signaling network regulating cell growth

S6K1, a critical downstream substrate of mTORC1, has been implicated in regulating protein synthesis and a variety of processes that impinge upon cell growth and proliferation. While the role of the cytoplasmic p70^S6K1 isoform in the regulation of translation has been intensively studied, the targets and function of the nuclear p85^S6K1 isoform remain unclear. Therefore, we carried out a phospho-proteomic screen to identify novel p85^S6K1 substrates. Four novel putative p85^S6K1 substrates, GRP75, CCTβ, PGK1 and RACK1, and two mTORC1 substrates, ANXA4 and PSMA6 were identified, with diverse roles in chaperone function, ribosome maturation, metabolism, vesicle trafficking and the proteasome, respectively. The chaperonin subunit CCTβ was further investigated and the site of phosphorylation mapped to serine 260, a site located in the chaperonin apical domain. Consistent with this domain being involved in folding substrate interactions, we found that phosphorylation of serine 260 modulates chaperonin folding activity.     

mTOR/S6K1信号通路与胰岛素抵抗的关系及有氧运动对其影响的研究

目的:通过研究高脂饮食和有氧运动对胰岛素抵抗(IR)小鼠骨骼肌雷帕霉素靶蛋白/核糖体S6激酶1(mTOR/S6K1)通路的影响,试图为运动防治IR提供理论依据。方法:8周C57BL/6小鼠随机分为正常饮食组和高脂饮食组,每组各20只,高脂饮食组喂养8周后建立IR模型。随后将正常饮食组再次随机分为正常饮食安静组(NC)和正常饮食运动组(NE);高脂饮食组也随机分为高脂饮食安静组(HC)和高脂饮食运动组(HE)。各运动组进行为期6周、75%VO2max强度跑台训练,每天1次,每次60min,每周5次。实验结束后采用OGTT检测葡萄糖耐量,组织学检测胰岛形态变化,ELISA法检测血清空腹胰岛素水平,Northern blot、Western blot检测骨骼肌中mTOR和S6K1 mRNA和蛋白及其磷酸化蛋白pS6K1-Thr389的表达。结果:与NC组相比,HC组小鼠体重、空腹血清胰岛素值和胰岛β细胞团面积百分比均呈显著增加,且OGTT曲线显示糖耐量明显受损,然而6周有氧运动后以上各指标呈显著性降低,葡萄糖耐量也得到明显改善;且骨骼肌中mTOR、S6K1、pS6K1-Thr389 mRNA和蛋白表达均明显降低。结论:mTOR/S6K1信号通路与高脂饮食诱导IR的发生密切相关,有氧运动明显增加了机体组织对胰岛素的敏感性,推测有氧运动可能通过抑制mTOR/S6K1信号通路,增加IR小鼠骨骼肌的能量代谢从而改善IR。     

mRNA transport,translation, and decay in adult mammalian central nervous system axons

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Repression of protein translation and mTOR signaling by proteasome inhibitor in colon cancer cells

Protein homeostasis relies on a balance between protein synthesis and protein degradation. The ubiquitin-proteasome system is a major catabolic pathway for protein degradation. In this respect, proteasome inhibition has been used therapeutically for the treatment of cancer. Whether inhibition of protein degradation by proteasome inhibitor can repress protein translation via a negative feedback mechanism, however, is unknown. In this study, proteasome inhibitor MG-132 lowered the proliferation of colon cancer cells HT-29 and SW1116. In this connection, MG-132 reduced the phosphorylation of mammalian target of rapamycin (mTOR) at Ser2448 and Ser2481 and the phosphorylation of its downstream targets 4E-BP1 and p70/p85 S6 kinases. Further analysis revealed that MG-132 inhibited protein translation as evidenced by the reductions of ³⁵S-methionine incorporation and polysomes/80S ratio. Knockdown of raptor, a structural component of mTOR complex 1, mimicked the anti-proliferative effect of MG-132. To conclude, we demonstrate that the inhibition of protein degradation by proteasome inhibitor represses mTOR signaling and protein translation in colon cancer cells.     

Identification and characterization of a constitutively T-loop phosphorylated and active recombinant S6K1: expression, purification, and enzymatic studies in a high capacity non-radioactive TR-FRET Lance assay

The p70 S6 ribosomal protein kinase 1 (S6K) is a substrate and effector of the mammalian target of rapamycin (mTOR). The mTOR/S6K pathway is implicated in cancer and metabolic disorders. To study the molecular regulation of S6K and identify specific inhibitors, availability of active recombinant S6K and robust enzyme assays are critically needed. To date, however, expression of active recombinant S6K has not been feasible as S6K activation requires a cascade of phosphorylation events. We have compared several engineered S6K enzymes. Expression of the Flag-S6KDeltaCT(T389E) in HEK293 cells resulted in a highly active S6K that was constitutively phosphorylated on T229 in the activation-loop (T-loop). The active enzyme was readily purified in large scale by anti-Flag affinity chromatography achieving a high purity. We developed a high capacity homogeneous time-resolved fluorescence resonance energy transfer. Lance assay for measurement of substrate phosphorylation and analysis of kinetic parameters. The Michaelis constant (Km) values of S6K for ATP and the Biotin-S6 substrate peptide were determined to be 21.4+/-0.29 and 0.9+/-0.48 microM, respectively. The Lance assay was further validated with a diverse panel of literature inhibitors, in which the PKC inhibitors staurosporine, Ro-318220, and the PKA inhibitor Balanol potently inhibited S6K. Dose-response and inhibition mechanism by these inhibitors were also studied. Our data provide a new simplified strategy to achieve rapid production of active S6K and demonstrate utility of the Lance assay for S6K enzyme screen in searching for specific inhibitors.     

Stress-induced activation of the AMP-activated protein kinase in the freeze-tolerant frog Rana sylvatica

Survival in the frozen state depends on biochemical adaptations that deal with multiple stresses on cells including long-term ischaemia and tissue dehydration. We investigated whether the AMP-activated protein kinase (AMPK) could play a regulatory role in the metabolic re-sculpting that occurs during freezing. AMPK activity and the phosphorylation state of translation factors were measured in liver and skeletal muscle of wood frogs (Rana sylvatica) subjected to anoxia, dehydration, freezing, and thawing after freezing. AMPK activity was increased 2-fold in livers of frozen frogs compared with the controls whereas in skeletal muscle, AMPK activity increased 2.5-, 4.5- and 3-fold in dehydrated, frozen and frozen/thawed animals, respectively. Immunoblotting with phospho-specific antibodies revealed an increase in the phosphorylation state of eukaryotic elongation factor-2 at the inactivating Thr56 site in livers from frozen frogs and in skeletal muscles of anoxic frogs. No change in phosphorylation state of eukaryotic initiation factor-2alpha at the inactivating Ser51 site was seen in the tissues under any of the stress conditions. Surprisingly, ribosomal protein S6 phosphorylation was increased 2-fold in livers from frozen frogs and 10-fold in skeletal muscle from frozen/thawed animals. However, no change in translation capacity was detected in cell-free translation assays with skeletal muscle extracts under any of the experimental conditions. The changes in phosphorylation state of translation factors are discussed in relation to the control of protein synthesis and stress-induced AMPK activation.     

mTOR coordinates protein synthesis,mitochondrial activity and proliferation

Protein synthesis is one of the most energy consuming processes in the cell. The mammalian/mechanistic target of rapamycin (mTOR) is a serine/threonine kinase that integrates a multitude of extracellular signals and intracellular cues to drive growth and proliferation. mTOR activity is altered in numerous pathological conditions, including metabolic syndrome and cancer. In addition to its well-established role in regulating mRNA translation, emerging studies indicate that mTOR modulates mitochondrial functions. In mammals, mTOR coordinates energy consumption by the mRNA translation machinery and mitochondrial energy production by stimulating synthesis of nucleus-encoded mitochondria-related proteins including TFAM, mitochondrial ribosomal proteins and components of complexes I and V. In this review, we highlight findings that link mTOR, mRNA translation and mitochondrial functions.     

Specific interaction between S6K1 and CoA synthase: a potential link between the mTOR/S6K pathway, CoA biosynthesis and energy metabolism

Ribosomal protein S6 kinase (S6K) is a key regulator of cell size and growth. It is regulated via phosphoinositide 3-kinases (PI3K) and the mammalian target of rapamycin (mTOR) signaling pathways. We demonstrate for the first time that CoA synthase associates specifically with S6K1. The association was observed between native and transiently overexpressed proteins in vivo, as well as by BIAcore analysis in vitro. The sites of interaction were mapped to the C-terminal regions of both CoA synthase and S6K1. In vitro studies indicated that the interaction does not affect their enzymatic activities and that CoA synthase is not a substrate for S6 kinase. This study uncovers a potential link between mTor/S6K signaling pathway and energy metabolism through CoA and its thioester derivatives, but its physiological relevance should be further elucidated.     

mTOR coordinates protein synthesis,mitochondrial activity and proliferation

Protein synthesis is one of the most energy consuming processes in the cell. The mammalian/mechanistic target of rapamycin (mTOR) is a serine/threonine kinase that integrates a multitude of extracellular signals and intracellular cues to drive growth and proliferation. mTOR activity is altered in numerous pathological conditions, including metabolic syndrome and cancer. In addition to its well-established role in regulating mRNA translation, emerging studies indicate that mTOR modulates mitochondrial functions. In mammals, mTOR coordinates energy consumption by the mRNA translation machinery and mitochondrial energy production by stimulating synthesis of nucleus-encoded mitochondria-related proteins including TFAM, mitochondrial ribosomal proteins and components of complexes I and V. In this review, we highlight findings that link mTOR, mRNA translation and mitochondrial functions.     

Structural basis of translation termination,rescue, and recycling in mammalian mitochondria

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