Project description:The mechanistic target of rapamycin (mTOR) is often referred to as a master regulator of the cellular metabolism that can integrate the growth factor and nutrient signaling. Fasting suppresses hepatic mTORC1 activity via the activity of the tuberous sclerosis complex (TSC), a negative regulator of mTORC1, to suppress anabolic metabolism. The loss of TSC1 in the liver locks the liver in a constitutively anabolic state even during fasting, which was suggested to regulate peroxisome proliferator-activated receptor alpha (PPARα) signaling and ketogenesis, but the molecular determinants of this regulation are unknown. Here, we examined if the activation of the mTORC1 complex in mice by the liver-specific deletion of TSC1 (TSC1L-/-) is sufficient to suppress PPARα signaling and therefore ketogenesis in the fasted state. We found that the activation of mTORC1 in the fasted state is not sufficient to repress PPARα-responsive genes or ketogenesis. Furthermore, we examined whether the activation of the anabolic program mediated by mTORC1 complex activation in the fasted state could suppress the robust catabolic programming and enhanced PPARα transcriptional response of mice with a liver-specific defect in mitochondrial long-chain fatty acid oxidation using carnitine palmitoyltransferase 2 (Cpt2L-/-) mice. We generated Cpt2L-/-; Tsc1L-/- double-KO mice and showed that the activation of mTORC1 by deletion of TSC1 could not suppress the catabolic PPARα-mediated phenotype of Cpt2L-/- mice. These data demonstrate that the activation of mTORC1 by the deletion of TSC1 is not sufficient to suppress a PPARα transcriptional program or ketogenesis after fasting.

Project description:The mesencephalic astrocyte-derived neurotrophic factor (MANF) has been recently identified as a neurotrophic factor, but its role in hepatic fibrosis is unknown. Here, we found that MANF was upregulated in the fibrotic liver tissues of the patients with chronic liver diseases and of mice treated with CCl4. MANF deficiency in either hepatocytes or hepatic mono-macrophages, particularly in hepatic mono-macrophages, clearly exacerbated hepatic fibrosis. Myeloid-specific MANF knockout increased the population of hepatic Ly6Chigh macrophages and promoted HSCs activation. Furthermore, MANF-sufficient macrophages (from WT mice) transfusion ameliorated CCl4-induced hepatic fibrosis in myeloid cells-specific MANF knockout (MKO) mice. Mechanistically, MANF interacted with S100A8 to competitively block S100A8/A9 heterodimer formation and inhibited S100A8/A9-mediated TLR4-NF-κB signal activation. Pharmacologically, systemic administration of recombinant human MANF significantly alleviated CCl4-induced hepatic fibrosis in both WT and hepatocytes-specific MANF knockout (HKO) mice. This study reveals a mechanism by which MANF targets S100A8/A9-TLR4 as a "brake" on the upstream of NF-κB pathway, which exerts an impact on macrophage differentiation and shed light on hepatic fibrosis treatment.

Project description:By breeding TRAMP mice with S100A9 knock-out (S100A9(-/-)) animals and scoring the appearance of palpable tumors we observed a delayed tumor growth in animals devoid of S100A9 expression. CD11b(+) S100A9 expressing cells were not observed in normal prostate tissue from control C57BL/6 mice but were readily detected in TRAMP prostate tumors. Also, S100A9 expression was observed in association with CD68(+) macrophages in biopsies from human prostate tumors. Delayed growth of TRAMP tumors was also observed in mice lacking the S100A9 ligand TLR4. In the EL-4 lymphoma model tumor growth inhibition was observed in S100A9(-/-) and TLR4(-/-), but not in RAGE(-/-) animals lacking an alternative S100A9 receptor. When expression of immune-regulating genes was analyzed using RT-PCR the only common change observed in mice lacking S100A9 and TLR4 was a down-regulation of TGFβ expression in splenic CD11b(+) cells. Lastly, treatment of mice with a small molecule (ABR-215050) that inhibits S100A9 binding to TLR4 inhibited EL4 tumor growth. Thus, S100A9 and TLR4 appear to be involved in promoting tumor growth in two different tumor models and pharmacological inhibition of S100A9-TLR4 interactions is a novel and promising target for anti-tumor therapies.

Project description:we examined if the activation of the anabolic program mediated by the activation of the mTorc1 complex in the fasted state could suppress the robust catabolic programing and enhanced Pparα transcriptional of mice with a liver specific defect in mitochondrial long chain fatty acid oxidation (Cpt2L-/- mice). We found that the activation of mTorc1 in the fasted state was not sufficient to repress Pparα responsive genes or ketogenesis.

Project description:Long non-coding RNAs (lncRNAs) play vital roles in diabetic nephropathy (DN). This research aimed to study the potential role and underlying molecular mechanisms of long non-coding RNA MEG3 in DN. We found that MEG3 was upregulated in DN in vivo and in vitro and could enhance cell fibrosis and inflammatory response in DN. MEG3 functioned as an endogenous sponge for miR-181a in mesangial cells (MCs) via direct targeting and in an Ago2-dependent manner. MiR-181a inhibition promoted MC fibrosis and inflammatory response. In addition, Egr-1 was confirmed as a target gene of miR-181a. Further investigations verified that MEG3 promotes fibrosis and inflammatory response via the miR-181a/Egr-1/TLR4 axis in vitro and in vivo. These results provide new insights into the regulation between MEG3 and the miR-181a/Egr-1/TLR4 signaling pathway during DN progression.

Project description:We examined in 20-week-old Zucker diabetic fatty (ZDF) rats whether restoration of hepatic glucokinase (GK) expression would alter hepatic glucose flux and improve hyperglycemia.ZDF rats were treated at various doses with an adenovirus that directs the expression of rat liver GK (AdvCMV-GKL) dose dependently, and various metabolic parameters were compared with those of nondiabetic lean littermates (ZCL rats) before and during a hyperglycemic clamp. Viral infection per se did not affect hepatic GK activity, since expression of a catalytically inactive form of GK did not alter endogenous hepatic GK activity.ZDF rats compared with ZCL rats have lower hepatic GK activity (11.6 +/- 1.9 vs. 32.5 +/- 3.2 mU/mg protein), marked hyperglycemia (23.9 +/- 1.2 vs. 7.4 +/- 0.3 mmol/l), higher endogenous glucose production (80 +/- 3 vs. 38 +/- 3 micromol x kg(-1) x min(-1)), increased glucose-6-phosphatase flux (150 +/- 11 vs. 58 +/- 8 micromol x kg(-1) x min(-1)), and during a hyperglycemic clamp, a failure to suppress endogenous glucose production (80 +/- 7 vs. -7 +/- 4 micromol x kg(-1) x min(-1)) and promote glucose incorporation into glycogen (15 +/- 5 vs. 43 +/- 3 micromol/g liver). Treatment of ZDF rats with different doses of AdvCMV-GKL, which restored hepatic GK activity to one to two times that of ZCL rats, normalized plasma glucose levels and endogenous glucose production. During a hyperglycemic clamp, glucose production was suppressed and glucose incorporation into glycogen was normal.Alteration of hepatic GK activity in ZDF rats has profound effects on plasma glucose and hepatic glucose flux.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:The mechanistic target of rapamycin complex 1 (mTORC1) controls cellular anabolism in response to nutrient sufficiency and growth factor signaling, and genetic and pharmacological inhibition of mTORC1 extends longevity across eukaryotes. Up to date, mouse models to analyze the mechanisms of aging governed by mTORC1 has been limited by detrimental pleiotropic consequences of genetically-increased mTORC1 activity in mice. RragcS74N/+, RragcS74C/+ and RragcT89N/+ knock-in mice endogenously express active mutant variants of RagC, a GTPase that signaling nutrient sufficiency to mTORC1. Rragcmutant/+ mice show an only moderate increase in nutrient signaling to mTORC1, and after one year of life exhibit multiple features of a premature aging phenotype that include prominent senescence in peripheral organs, parenchymal expression of inflammatory and chemo-attractant molecules, increased myeloid inflammation and extensive features of inflammaging. In vivo transplantation and ex vivo functional experiments with bone marrow-derived cells show that myeloid cells are abnormally activated by parenchymal signals evoked from Rragcmut/+ organs, to where myeloid cells extravasate to inflict additional inflammatory damage. Therapeutic suppression of myeloid inflammation in old Rragcmut/+ attenuates features of premature aging and extends longevity. We provide the first genetic link of elevated nutrient – mTORC1 activity and premature aging in mammals, and provide support for a two-component model in which increased nutrient signaling drives parenchymal damage and myeloid inflammation precipitates organ deterioration and accelerated aging.

Project description:The mechanistic target of rapamycin complex 1 (mTORC1) controls cellular anabolism in response to nutrient sufficiency and growth factor signaling, and genetic and pharmacological inhibition of mTORC1 extends longevity across eukaryotes. Up to date, mouse models to analyze the mechanisms of aging governed by mTORC1 has been limited by detrimental pleiotropic consequences of genetically-increased mTORC1 activity in mice. RragcS74N/+, RragcS74C/+ and RragcT89N/+ knock-in mice endogenously express active mutant variants of RagC, a GTPase that signaling nutrient sufficiency to mTORC1. Rragcmutant/+ mice show an only moderate increase in nutrient signaling to mTORC1, and after one year of life exhibit multiple features of a premature aging phenotype that include prominent senescence in peripheral organs, parenchymal expression of inflammatory and chemo-attractant molecules, increased myeloid inflammation and extensive features of inflammaging. In vivo transplantation and ex vivo functional experiments with bone marrow-derived cells show that myeloid cells are abnormally activated by parenchymal signals evoked from Rragcmut/+ organs, to where myeloid cells extravasate to inflict additional inflammatory damage. Therapeutic suppression of myeloid inflammation in old Rragcmut/+ attenuates features of premature aging and extends longevity. We provide the first genetic link of elevated nutrient – mTORC1 activity and premature aging in mammals, and provide support for a two-component model in which increased nutrient signaling drives parenchymal damage and myeloid inflammation precipitates organ deterioration and accelerated aging.

Project description:The mechanistic target of rapamycin complex 1 (mTORC1) controls cellular anabolism in response to nutrient sufficiency and growth factor signaling, and genetic and pharmacological inhibition of mTORC1 extends longevity across eukaryotes. Up to date, mouse models to analyze the mechanisms of aging governed by mTORC1 has been limited by detrimental pleiotropic consequences of genetically-increased mTORC1 activity in mice. RragcS74N/+, RragcS74C/+ and RragcT89N/+ knock-in mice endogenously express active mutant variants of RagC, a GTPase that signaling nutrient sufficiency to mTORC1. Rragcmutant/+ mice show an only moderate increase in nutrient signaling to mTORC1, and after one year of life exhibit multiple features of a premature aging phenotype that include prominent senescence in peripheral organs, parenchymal expression of inflammatory and chemo-attractant molecules, increased myeloid inflammation and extensive features of inflammaging. In vivo transplantation and ex vivo functional experiments with bone marrow-derived cells show that myeloid cells are abnormally activated by parenchymal signals evoked from Rragcmut/+ organs, to where myeloid cells extravasate to inflict additional inflammatory damage. Therapeutic suppression of myeloid inflammation in old Rragcmut/+ attenuates features of premature aging and extends longevity. We provide the first genetic link of elevated nutrient – mTORC1 activity and premature aging in mammals, and provide support for a two-component model in which increased nutrient signaling drives parenchymal damage and myeloid inflammation precipitates organ deterioration and accelerated aging.