mTOR signalling: the molecular interface connecting metabolic stress, aging and cardiovascular diseases.

The continuing increase in the prevalence of obesity and metabolic disorders such as type-II diabetes and an accelerating aging population globally will remain the major contributors to cardiovascular mortality and morbidity in the 21st century. It is well known that aging is highly associated with metabolic and cardiovascular diseases. Growing evidence also shows that obesity and metabolic diseases accelerate aging process. Studies in experimental animal models demonstrate similarity of metabolic and cardiovascular phenotypes in metabolic diseases and old age, e.g. insulin resistance, oxidative stress, chronic low grade inflammation, cardiac hypertrophy, cardiac fibrosis, and heart failure, as well as vascular dysfunctions. Despite intensive research, the molecular mechanisms linking metabolic stress, aging, and ultimately cardiovascular diseases are still elusive. Although the mammalian target of rapamycin (mTOR) signalling is a well known regulator of metabolism and lifespan in model organisms, its central role in linking metabolic stress, aging and cardiovascular diseases is recently emerging. In this article, we review the evidence supporting the role of mTOR signalling as a molecular interface connecting metabolic stress, aging and cardiovascular diseases. The therapeutic potentials of targeting mTOR signalling to protect against metabolic and age-associated cardiovascular diseases are discussed.

Parallel and independent regulation of interleukin-3 mRNA turnover by phosphatidylinositol 3-kinase and p38 mitogen-activated protein kinase.

AU-rich elements (ARE) present in the 3' untranslated regions of many cytokines and immediate-early genes are responsible for targeting the transcripts for rapid decay. We present evidence from cotransfection experiments in NIH 3T3 cells that two signaling pathways, one involving phosphatidylinositol 3-kinase (PI3-K), and one involving the p38 mitogen-activated protein kinase (MAPK), lead to stabilization of interleukin-3 mRNA in parallel. Stabilization mediated by either of the two pathways was antagonized by tristetraprolin (TTP), an AU-binding protein known to promote constitutive decay of ARE-containing transcripts. Remarkably, the stabilizing AU-binding protein HuR, in collaboration with p38 MAPK but not with PI3-K, could overcome the destabilizing effect of TTP. These data argue that the stabilizing kinases PI3-K and p38 MAPK do not act through direct inactivation of TTP but via activating pathway-specific stabilizing AU-binding proteins. Our data suggest an integrated model of mRNA turnover control, where stabilizing (HuR) and destabilizing (TTP) AU-binding proteins compete and where the former are under the positive control of independent phosphokinase signaling pathways.

Somatic mRNA turnover mutants implicate tristetraprolin in the interleukin-3 mRNA degradation pathway.

Control of mRNA stability is critical for expression of short-lived transcripts from cytokines and proto-oncogenes. Regulation involves an AU-rich element (ARE) in the 3' untranslated region (3'UTR) and cognate trans-acting factors thought to promote either degradation or stabilization of the mRNA. In this study we present a novel approach using somatic cell genetics designed to identify regulators of interleukin-3 (IL-3) mRNA turnover. Mutant cell lines were generated from diploid HT1080 cells transfected with a reporter construct containing green fluorescent protein (GFP) linked to the IL-3 3'UTR. GFP was expressed at low levels due to rapid decay of the mRNA. Following chemical mutagenesis and selection of GFP-overexpressing cells, we could isolate three mutant clones (slowA, slowB, and slowC) with a specific, trans-acting defect in IL-3 mRNA degradation, while the stability of IL-2 and tumor necrosis factor alpha reporter transcripts was not affected. Somatic cell fusion experiments revealed that the mutants are genetically recessive and form two complementation groups. Expression of the tristetraprolin gene in both groups led to reversion of the mutant phenotype, thereby linking this gene to the IL-3 mRNA degradation pathway. The genetic approach described here should allow identification of the defective functions by gene transfer and is also applicable to the study of other mRNA turnover pathways.

c-jun N-terminal kinase is involved in AUUUA-mediated interleukin-3 mRNA turnover in mast cells.

Whereas signalling pathways involved in transcriptional control have been studied extensively, the pathways regulating mRNA turnover remain poorly understood. We are interested in the role of mRNA stability in cell activation and oncogenesis using PB-3c mast cells as a model system. In these cells the short-lived interleukin-3 (IL-3) mRNA is stabilized by ionomycin treatment and following oncogenesis. To identify the signalling pathways involved in these mechanisms, we analysed the effect of different kinase inhibitors. SB202190 and wortmannin were shown to antagonize ionomycin-induced IL-3 mRNA stabilization in PB-3c cells in the presence of actinomycin D, and this effect coincided with their ability to inhibit c-jun N-terminal kinase (JNK) activation by ionomycin. Moreover, transfection of activated MEKK1 amplified ionomycin-induced IL-3 mRNA expression at the post-transcriptional level, and a dominant-negative mutant of JNK counteracted mRNA stabilization by ionomycin. Taken together, these data indicate that JNK is involved in the regulation of IL-3 mRNA turnover in mast cells. In addition, transfection experiments revealed that the cis-acting AU-rich element in the 3' untranslated region of IL-3 mRNA is necessary and sufficient to confer JNK-dependent mRNA stabilization in response to cell activation.

Rapamycin destabilizes interleukin-3 mRNA in autocrine tumor cells by a mechanism requiring an intact 3' untranslated region.

We analyzed the effect of rapamycin on autocrine mast cell tumor lines with abnormally stable interleukin-3 (IL-3) transcripts due to a defect in mRNA degradation. Rapamycin inhibited IL-3 mRNA expression specifically, while transcripts of IL-4 and IL-6 were not affected. As indicated by the use of the transcriptional inhibitor actinomycin D or by reporter constructs, inhibition was posttranscriptional and resulted from destabilization of the mRNA. Transcripts from transgenes lacking the AU-rich 3' untranslated region were refractory to drug-induced degradation, suggesting that these 3' sequences contain the target of the rapamycin effect. Rapamycin did not promote IL-3 mRNA degradation in cells of a tumor variant lacking expression of FKBP12, the binding protein of rapamycin. Experiments with wortmannin indicated that rapamycin does not act via p70S6 kinase. FK-506, another ligand of FKBP12 affecting the phosphatase calcineurin, did not antagonize but shared the effect of rapamycin. Our data fit a model whereby both FKBP12 and calcineurin target an unknown regulator of IL-3 mRNA turnover.

Activation and phosphorylation of a pleckstrin homology domain containing protein kinase (RAC-PK/PKB) promoted by serum and protein phosphatase inhibitors.

Treatment of quiescent Swiss 3T3 fibroblasts with serum, or with the phosphatase inhibitors okadaic acid and vanadate, induced a 2- to 11-fold activation of the serine/ threonine RAC protein kinase (RAC-PK). Kinase activation was accompanied by decreased mobility of RAC-PK on SDS/PAGE such that three electrophoretic species (a to c) of the kinase were detected by immunoblot analysis, indicative of differentially phosphorylated forms. Addition of vanadate to arrested cells increased the RAC-PK phosphorylation level 3-to 4-fold. Unstimulated RAC-PK was phosphorylated predominantly on serine, whereas the activated kinase was phosphorylated on both serine and threonine residues. Treatment of RAC-PK in vitro with protein phosphatase 2A led to kinase inactivation and an increase in electrophoretic mobility. Deletion of the N-terminal region containing the pleckstrin homology domain did not affect RAC-PK activation by okadaic acid, but it reduced vanadate-stimulated activity and also blocked the serum-induced activation. Deletion of the serine/threonine rich C-terminal region impaired both RAC-PKalpha basal and vanadate-stimulated activity. Studies using a kinase-deficient mutant indicated that autophosphorylation is not involved in RAC-PKalpha activation. Stimulation of RAC-PK activity and electrophoretic mobility changes induced by serum were sensitive to wortmannin. Taken together the results suggest that RAC-PK is a component of a signaling pathway regulated by phosphatidylinositol (PI) 3-kinase, whose action is required for RAC-PK activation by phosphorylation.

4E-BP1 phosphorylation is mediated by the FRAP-p70s6k pathway and is independent of mitogen-activated protein kinase.

It has previously been argued that the repressor of protein synthesis initiation factor 4E, 4E-BP1, is a direct in vivo target of p42mapk. However, the immunosuppressant rapamycin blocks serum-induced 4E-BP1 phosphorylation and, in parallel, p70s6k activation, with no apparent effect on p42mapk activation. Consistent with this finding, the kinetics of serum-induced 4E-BP1 phosphorylation closely follow those of p70s6k activation rather than those of p42mapk. More striking, insulin, which does not induce p42mapk activation in human 293 cells or Swiss mouse 3T3 cells, induces 4E-BP1 phosphorylation and p70s6k activation in both cell types. Anisomycin, which, like insulin, does not activate p42mapk, promotes a small parallel increase in 4E-BP1 phosphorylation and p70s6k activation. The insulin effect on 4E-BP1 phosphorylation and p70s6k activation in both cell types is blocked by SQ20006, wortmannin, and rapamycin. These three inhibitors have no effect on p42mapk activation induced by phorbol 12-tetradecanoate 13-acetate, though wortmannin partially suppresses both the p70s6k response and the 4E-BP1 response. Finally, in porcine aortic endothelial cells stably transfected with either the wild-type platelet-derived growth factor receptor or a mutant receptor bearing the double point mutation 740F/751F, p42mapk activation in response to platelet-derived growth factor is unimpaired, but increased 4E-BP1 phosphorylation is ablated, as previously reported for p70s6k. The data presented here demonstrate that 4E-BP1 phosphorylation is mediated by the FRAP-p70s6k pathway and is independent of mitogen-activated protein kinase.

Activation of p70/p85 S6 kinase by a pathway independent of p21ras.

The enzymes p70s6k and p85s6k are two isoforms of the same kinase and are important in mitogenesis. Both isoforms are activated by a complex phosphorylation event and lie on a common signalling pathway, distinct from that of the p42mapk/p44mapk kinases. Activation of p42mapk/p44mapk is triggered by sequential activation of the GDP-GTP exchange factor Sos, the GTP-binding protein p21ras, and protein kinases p74raf and p47mek (refs 7-10). As p21ras transformed cells have increased S6 phosphorylation, we tested whether the p70s6k/p85s6k signalling pathway bifurcates between p21ras and p42mapk/p44mapk. We found that mutants of p74raf and p21ras blocked activation of epitope-tagged p44mapk but not epitope-tagged p70s6k. Moreover, in cells expressing human platelet-derived growth factor receptors lacking the kinase-insert domain, the growth factor activates p21ras but not p70s6k/p85s6k. The critical autophosphorylation site for p70s6k/p85s6k activation within this domain is a tyrosine at residue 751. Our results show that the p70s6k/p85s6k signalling pathway is independent of p21ras, that it bifurcates from the p21ras pathway at the receptor, and that it is initiated by autophosphorylation at a specific site.