Maithili Navaratnarajah

Rag GTPases and AMPK/TSC2/Rheb mediate the differential regulation of mTORC1 signaling in response to alcohol and leucine

Leucine (Leu) and insulin both stimulate muscle protein synthesis, albeit at least in part via separate signaling pathways. While alcohol (EtOH) suppresses insulin-stimulated protein synthesis in cultured myocytes, its ability to disrupt Leu signaling and Rag GTPase activity has not been determined. Likewise, little is known regarding the interaction of EtOH and Leu on the AMPK/TSC2/Rheb pathway. Treatment of myocytes with EtOH (100 mM) decreased protein synthesis, whereas Leu (2 mM) increased synthesis. In combination, EtOH suppressed the anabolic effect of Leu. The effects of EtOH and Leu were associated with coordinate changes in the phosphorylation state of mTOR, raptor, and their downstream targets 4EBP1 and S6K1. As such, EtOH suppressed the ability of Leu to activate these signaling components. The Rag signaling pathway was activated by Leu but suppressed by EtOH, as evidenced by changes in the interaction of Rag proteins with mTOR and raptor. Overexpression of constitutively active (ca)RagA and caRagC increased mTORC1 activity, as determined by increased S6K1 phosphorylation. Furthermore, the caRagA-caRagC heterodimer blocked the inhibitory effect of EtOH. EtOH and Leu produced differential effects on AMPK signaling. EtOH enhanced AMPK activity, resulting in increased TSC2 (S1387) and eEF2 phosphorylation, whereas Leu had the opposite effect. EtOH also decreased the interaction of Rheb with mTOR, and this was prevented by Leu. Collectively, our results indicate that EtOH inhibits the anabolic effects that Leu has on protein synthesis and mTORC1 activity by modulating both Rag GTPase function and AMPK/TSC2/Rheb signaling.

Alcohol-Induced Modulation of Rictor and mTORC2 Activity in C2C12 Myoblasts

BACKGROUND The mammalian target of rapamycin (mTOR) kinase controls cell growth, proliferation, and metabolism through 2 distinct multiprotein complexes, mTORC1 and mTORC2. We reported that alcohol (EtOH) inhibits mTORC1 activity and protein synthesis in C2C12 myoblasts. However, the role that mTORC2 plays in this process has not been elucidated. In this study, we investigated whether mTORC2 functions as part of a feedback regulator in response to EtOH, acting to maintain the balance between the functions of Akt, mTORC2, and mTORC1. METHODS C2C12 myoblasts were incubated with EtOH for 18 to 24 hours. Levels of various mTORC2 proteins and mRNA were assessed by immunoblotting and real-time PCR, respectively, while protein-protein interactions were determined by immunoprecipitation and immunoblotting. An in vitro mTORC2 kinase activity assay was performed using Akt as a substrate. The rate of protein synthesis was determined by (35) S-methionine/cysteine incorporation into cellular protein. RESULTS EtOH (100 mM) increased the protein and mRNA levels of the mTORC2 components rictor, mSin1, proline-rich repeat protein 5, and Deptor. There was also an increased association of these proteins with mTOR. EtOH increased the in vitro kinase activity of mTORC2, and this was correlated with decreased binding of rictor with 14-3-3 and Deptor. Reduced rictor phosphorylation at T1135 by EtOH was most likely due to decreased S6K1 activity. Knockdown of rictor elevated mTORC1 activity, as indicated by increased S6K1 phosphorylation and protein synthesis. Likewise, there were decreased amounts and/or phosphorylation levels of various mTORC1 and mTORC2 components including raptor, proline-rich Akt substrate 40 kDa, mSin1, Deptor, and GβL. Activated PP2A was associated with decreased Akt and eukaryotic elongation factor 2 phosphorylation. Collectively, our results provide evidence of a homeostatic balance between the 2 mTOR complexes following EtOH treatments in myoblasts. CONCLUSIONS   EtOH increased the activity of mTORC2 by elevating levels of various components and their interaction with mTOR. Decreased rictor phosphorylation at T1135 acts as mTORC1-dependent feedback mechanisms, functioning in addition to the insulin receptor substrate-I/PI3K signaling pathway to regulate protein synthesis.

Adamts1 mediates ethanol-induced alterations in collagen and elastin via a FoxO1-sestrin3-AMPK signaling cascade in myocytes.

A variety of stressors including alcohol (EtOH) are known to induce collagen production and fibrotic diseases. Matrix metalloproteinases (MMP) play an important role in regulating fibrosis, but little is known regarding the relationship between EtOH and MMPs. In addition, the signaling cascades involved in this process have not been elucidated. We have identified the MMP Adamts1 as a target of EtOH regulation. To characterize the function of Adamts1, we examined EtOH‐induced alterations in collagen I and elastin protein levels in C2C12 myocytes. Incubation of myocytes with 100 mM EtOH decreased elastin and increased collagen content, respectively, and these changes were associated with increased O‐GLcNAc modification of Adamts1. Conversely, silencing of Adamts1 by siRNA blocked the adverse effects of EtOH on collagen and elastin levels. Similar results were obtained after treatment with a pharmacological inhibitor of MMP. Changes in collagen were due, at least in part, to a decreased interaction of Adamts1 with its endogenous inhibitor TIMP3. The AMPK inhibitor compound C blocked the EtOH‐induced stimulation of collagen and O‐GLcNAc Adamts1 protein. Changes in AMPK appear linked to FoxO1, since inhibition of FoxO1 blocked the effects of EtOH on AMPK phosphorylation and O‐GLcNAc levels. These FoxO‐dependent modifications were associated with an upregulation of the FoxO1 transcription target sestrin 3, as well as increased binding of sestrin 3 with AMPK. Collectively, these data indicate that EtOH regulates the collagen I and elastin content in an Adamts1‐dependent manner in myocytes. Furthermore, Adamts1 appears to be controlled by the FoxO1‐sestrin 3‐AMPK signaling cascade. J. Cell. Biochem. 116: 91–101, 2015.

Disruption of genes encoding eIF4E binding proteins-1 and -2 does not alter basal or sepsis-induced changes in skeletal muscle protein synthesis in male or female mice.

Sepsis decreases skeletal muscle protein synthesis in part by impairing mTOR activity and the subsequent phosphorylation of 4E-BP1 and S6K1 thereby controlling translation initiation; however, the relative importance of changes in these two downstream substrates is unknown. The role of 4E-BP1 (and -BP2) in regulating muscle protein synthesis was assessed in wild-type (WT) and 4E-BP1/BP2 double knockout (DKO) male mice under basal conditions and in response to sepsis. At 12 months of age, body weight, lean body mass and energy expenditure did not differ between WT and DKO mice. Moreover, in vivo rates of protein synthesis in gastrocnemius, heart and liver did not differ between DKO and WT mice. Sepsis decreased skeletal muscle protein synthesis and S6K1 phosphorylation in WT and DKO male mice to a similar extent. Sepsis only decreased 4E-BP1 phosphorylation in WT mice as no 4E-BP1/BP2 protein was detected in muscle from DKO mice. Sepsis decreased the binding of eIF4G to eIF4E in WT mice; however, eIF4E•eIF4G binding was not altered in DKO mice under either basal or septic conditions. A comparable sepsis-induced increase in eIF4B phosphorylation was seen in both WT and DKO mice. eEF2 phosphorylation was similarly increased in muscle from WT septic mice and both control and septic DKO mice, compared to WT control values. The sepsis-induced increase in muscle MuRF1 and atrogin-1 (markers of proteolysis) as well as TNFα and IL-6 (inflammatory cytokines) mRNA was greater in DKO than WT mice. The sepsis-induced decrease in myocardial and hepatic protein synthesis did not differ between WT and DKO mice. These data suggest overall basal protein balance and synthesis is maintained in muscle of mice lacking both 4E-BP1/BP2 and that sepsis-induced changes in mTOR signaling may be mediated by a down-stream mechanism independent of 4E-BP1 phosphorylation and eIF4E•eIF4G binding.

Nuclear Factor-κB Mediates the Inhibitory Effects of Tumor Necrosis Factor-α on Growth Hormone-Inducible Gene Expression in Liver

TNF inhibits serine protease inhibitor 2.1 (Spi 2.1) and IGF-I gene expression by GH in CWSV-1 hepatocytes. The current study describes construction of a GH-inducible IGF-I promoter construct and investigates mechanisms by which TNF and nuclear factor-kappaB (NFkappaB) inhibit GH-inducible gene expression. CWSV-1 cells were transfected with GH-inducible Spi 2.1 or IGF-I promoter luciferase constructs, incubated with TNF signaling inhibitors (fumonisin B1 for sphingomyelinase and SP600125 for c-Jun N-terminal kinase), treated with or without TNF, and then stimulated with recombinant human GH. The 5- to 6-fold induction of Spi 2.1 and IGF-I promoter activity by GH was inhibited by TNF. Neither fumonisin B1 nor SP600125 prevented the inhibitory effects of TNF on GH-inducible promoter activity. Dominant-negative inhibitor-kappaBalpha (IkappaBalpha) expression vectors (IkappaBalphaS/A or IkappaBalphaTrunc), p65 and p50 expression vectors, and p65 deletion constructs were used to investigate the NFkappaB pathway. IkappaBalphaS/A and IkappaBalphaTrunc ameliorated the inhibitory effects of TNF on GH-inducible Spi 2.1 and IGF-I promoter activity. Cotransfection of CWSV-1 cells with expression vectors for p65 alone or p50 and p65 together inhibited GH-inducible Spi 2.1 and IGF-I promoter activity. Cotransfection with a C-terminal p65 deletion (1-450) enhanced GH-inducible promoter activity, whereas the N-terminal deletion (31-551) was inhibitory for IGF-I but not Spi 2.1. Cycloheximide did not antagonize the inhibitory effects of TNF on GH-inducible IGF-I expression. We conclude the inhibitory effects of TNF on GH-inducible promoter activity are mediated by NFkappaB, especially p65, by a mechanism that does not require protein synthesis.

Skeletal muscle catabolism in trinitrobenzene sulfonic acid-induced murine colitis

The present study determined whether the muscle atrophy produced by colitis is associated with altered rates of muscle protein synthesis or degradation, as well as the potential role of the local (eg, muscle) insulin-like growth factor (IGF) system and muscle-specific ubiquitin E3 ligases atrogin-1 and MuRF1 in mediating altered muscle protein balance. Colitis was induced in C57BL/6 mice by intrarectal administration of trinitrobenzene sulfonic acid (TNBS), and blood and tissues were collected on day 10. Mice with inflammatory bowel disease demonstrated reduced skeletal muscle mass and protein content, whereas colonic segment weight and gross damage score were both increased in mice with colitis, compared with time-matched control values. There was no change in muscle protein synthesis in mice with inflammatory bowel disease; but there was an increased protein breakdown (45%), proteasome activity (85%), and messenger RNA (mRNA) expression for atrogin-1 and MuRF1 (200%-300%) in muscle. These changes were associated with a reduction in liver (but not muscle) IGF-I mRNA as well as a reduction in both total and free IGF-I in the blood. Colitis decreased the hepatic content of IGF binding protein (IGFBP)-3 mRNA by 40% and increased IGFBP-1 mRNA by 100%. In contrast, colitis did alter IGFBP mRNAs in muscle. The tumor necrosis factor-α, interleukin-6, and nitric oxide synthase 2 mRNA content of both liver and skeletal muscle was increased in TNBS-treated mice; and plasma tumor necrosis factor-α and interleukin-6 concentrations were also elevated. These data suggest that TNBS-induced colitis is independent of a change in muscle protein synthesis but dependent on stimulation of protein degradation via increased expression of muscle-specific atrogenes, which may be mediated in part by the reduction in circulating concentration of IGF-I and the concomitant increase in inflammatory mediators observed in the blood and muscle per se.

Nuclear Factor ??B Mediates the Inhibitory Effects of Interleukin-1 on Growth Hormone-Inducible Gene Expression

BACKGROUND Hepatic expression of growth hormone (GH)-inducible genes serine protease inhibitor (Spi 2.1) and insulin-like growth factor (IGF)-I are inhibited by interleukin (IL)-1. The current study examines the role of the nuclear factor kappaB (NFkappaB) pathway and suppressor of cytokine signaling (SOCS)-3 expression as potential mechanisms for IL-1-mediated GH resistance. METHODS CWSV-1 hepatocytes were cotransfected with Spi 2.1 or IGF-1 promoter luciferase constructs and empty pCMV4 vector or dominant negative inhibitor-kappaBalpha (IkappaBalpha)S/A construct. Cells were treated with or without IL-1 and then stimulated with or without recombinant human GH. Cell extracts were assayed for luciferase activity and protein, normalized and expressed as fold-induction. CWSV-1 cells transfected with pCMV4 or IkappaBalphaS/A were treated with or without IL-1 then SOCS-3 mRNA was measured. Finally, CWSV-1 cells were cotransfected with a SOCS-3 promoter construct with or without pCMV4 or IkappaBalphaS/A and then stimulated with or without IL-1 to investigate SOCS-3 promoter activity. RESULTS CWSV-1 cells cotransfected with pCMV4 demonstrated a three- to fivefold induction of Spi 2.1 or IGF-1 promoter activity after GH stimulation that was almost completely inhibited by IL-1. Cotransfection with IkappaBalphaS/A increased GH-inducible Spi 2.1 and IGF-1 promoter activity, but the inhibitory effects of IL-1 on both promoters were attenuated by cotransfection with IkappaBalphaS/A. IL-1 stimulated SOCS-3 mRNA expression and promoter activity. Cotransfection with IkappaBalphaS/A increased IL-1-inducible SOCS-3 promoter activity, but not SOCS-3 mRNA or protein. CONCLUSIONS Signaling via the NFkappaB pathway is responsible for the inhibitory effects of IL-1 on GH-inducible gene expression by a mechanism that does not seem to involve increased SOCS-3 expression.

Suppression of p16 increases nucleotide synthesis via mTORC1

Reprogrammed metabolism and cell cycle dysregulation are two cancer hallmarks. p16 is a cell cycle inhibitor and tumor suppressor that is upregulated during oncogene-induced senescence (OIS). Loss of p16 allows for uninhibited cell cycle progression, bypass of OIS, and tumorigenesis. Whether p16 loss affects pro-tumorigenic metabolism is unclear. We report that suppression of p16 plays a central role in reprogramming metabolism by increasing nucleotide synthesis. This occurred via Ataxia Telangiectasia and Rad3-Related Protein (ATR) activation of mTORC1 signaling, which mediated increased translation of the mRNA encoding ribose-5-phosphate isomerase A (RPIA), a pentose phosphate pathway enzyme. p16 loss correlated with activation of the ATR-mTORC1-RPIA axis in multiple cancer types. Suppression of RPIA inhibited proliferation of cancer cells only with low p16 by inducing senescence both in vitro and in vivo. These data reveal the molecular basis whereby p16 loss modulates pro-tumorigenic metabolism through mTORC1-mediated upregulation of nucleotide synthesis and reveals a metabolic vulnerability of p16-low cancer cells. Highlights Suppression of p16 activates the ATR-mTORC1 signaling axis to increase nucleotide synthesis Low p16 expression increases sensitivity to mTORC1 inhibition mTORC1 increases translation of the mRNA encoding the pentose phosphate pathway enzyme ribose-5-phosphate isomerase A (RPIA) RPIA suppression induces senescence only in cancer cells with low p16Summary Reprogrammed metabolism and cell cycle dysregulation are two cancer hallmarks. p16 is a cell cycle inhibitor and tumor suppressor that is upregulated during oncogene-induced senescence (OIS). Loss of p16 allows for uninhibited cell cycle progression, bypass of OIS, and tumorigenesis. Whether p16 loss affects pro-tumorigenic metabolism is unclear. We report that suppression of p16 plays a central role in reprogramming metabolism by increasing nucleotide synthesis. This occurred via activation of mTORC1 signaling, which directly mediated increased translation of the mRNA encoding ribose-5-phosphate isomerase A (RPIA), a pentose phosphate pathway enzyme. p16 loss correlated with activation of the mTORC1-RPIA axis in multiple cancer types. Suppression of RPIA inhibited proliferation only in p16-low cells by inducing senescence both in vitro and in vivo. These data reveal the molecular basis whereby p16 loss modulates pro-tumorigenic metabolism through mTORC1-mediated upregulation of nucleotide synthesis and reveals a metabolic vulnerability of p16-null cancer cells. Highlights mTORC1 is activated by p16 knockdown to increase nucleotide synthesis and bypass senescence mTORC1 directly increases translation RPIA to increase ribose-5-phosphate Activation of mTORC1 pathway downstream of p16 suppression is independent of RB RPIA suppression induces senescence only in cells and tumors with low p16