Project description:The mammalian target of rapamycin complex 2 (mTORC2) contains the essential protein RICTOR and is activated by growth factors. mTORC2 in adipose tissue contributes to regulating glucose and lipid metabolism. In the perivascular adipose tissue (PVAT) mTORC2 ensures normal vascular reactivity by controlling expression of inflammatory molecules. To assess whether RICTOR/mTORC2 contributes to blood pressure regulation, we applied a radiotelemetry approach in control and Rictor knockout (RictoraP2KO) mice generated by using adipocyte protein-2 gene promoter-driven CRE recombinase to delete Rictor. 24 hour mean arterial pressure (MAP) was increased in RictoraP2KO mice, and the physiologic decline in MAP during the dark period impaired. In parallel, heart rate and locomotor activity were elevated during the dark period with a pattern similar to blood pressure changes. This phenotype was associated with mild cardiomyocyte hypertrophy, decreased cardiac natriuretic peptides (NPs) and NP receptor expression in adipocytes. Moreover, clock gene expression was dampened or phase-shifted in PVAT. No differences in clock gene expression were observed in the master clock suprachiasmatic nucleus (SCN), though Rictor gene expression was also lower in brain of RictoraP2KO mice. Thus, the present study underscores the importance of RICTOR/mTORC2 for interactions between vasculature, adipocytes and brain to tune physiological outcomes such as blood pressure and locomotion. Gene expression in PVAT of RictoraP2KO mice was compared to controls (Rictorfl/fl) mice.

Project description:Stimulating brown adipose tissue (BAT) activity represents a promising therapy for overcoming metabolic diseases. mTORC2 has been shown to be important for regulating BAT metabolism, yet its mechanism of activation is not known, nor are the identities of its downstream effectors. In this study, we apply proteomics to investigate the role of mTORC2 in brown adipocytes. To assess the role of mTORC2 in brown adipocytes, we compare wild-type controls to isogenic cells with an induced knockout of the mTORC2-specific subunit RICTOR (Rictor-iKO) by stimulating each with insulin for a 30 minute time course, and measuring the proteomes and phosphoproteomes. In Rictor-iKO cells, we identify decreases to the abundance of glycolytic and de novo lipogenesis enzymes, and increases to mitochondrial proteins as well as a set of proteins known to increase upon interferon stimulation, suggesting increased interferon-like signaling. We observe significant differences to basal phosphorylation including decreased phosphorylation of the lipid droplet protein perilipin-1 in Rictor-iKO cells and Rictor-null mouse BAT, suggesting that RICTOR could be involved with regulating basal lipolysis or droplet dynamics. And finally, we observe a general dampening of the insulin signaling response in Rictor-iKO cells. Some sites exhibit significant dependence on RICTOR, including an AKT substrate site on ATP citrate lyase, which could partially explain the previously-observed RICTOR dependence of de novo lipogenesis from glucose in BAT.

Project description:Obesity causes type 2 diabetes, cardiovascular diseases, NAFLD, and cancer, but all fat is not equal as subcutaneous white adipose tissue (SWAT) is more metabolically favorable than visceral fat. Here, we investigate mTORC2 function in SWAT growth by deleting its essential subunit Rictor in SWAT precursor cells and examining its effect on adipocyte differentiation and tissue development. We found that Rictor/mTORC2 is not required for SWAT preadipocyte differentiation per se; however, SWAT preadipocytes differentiating without Rictor cannot fully induce the lipid storage transcriptional program. In vivo, this results in smaller adipocytes, reduced SWAT size, lipid re-distribution to visceral and brown fat, and gender-distinct effects on systemic metabolic fitness. Mechanistically, mTORC2 promotes PPARg activity towards specific lipid metabolism genes independently of ChREBP, but in coordination, to set the lipid handling capacity of SWAT. Further exploring this pathway may uncover new strategies to stimulate lipid storage in more metabolically favorable SWAT.

Project description:The association between type 2 DM (T2DM) and susceptibility to tuberculosis (TB) is well recognized. Patients with DM have 2-3 fold increased susceptibility to TB, treatment is longer and the outcome is worse than in non-diabetic TB patients. Here, we report that aerosol infection with M. tuberculosis is followed by leukocyte infiltration and proliferation, and expression of inflammatory markers in adipose tissue of lean mice leading to disrupted lipid metabolism and the induction of adipocyte hypertrophy. RNA-sequencing (RNAseq) in whole pgWAT adipose tissue at 8 wk after aerosol challenge revealed an upregulation of genes that were associated with antigen presentation, Th1 and type-1 interferon response, indicated the induction of T cell activation. This was found to be due to activated mTORC2/Akt signaling. By depleting Rictor (mTORC2 subunit) in adipocytes we noticed the restoration of inflammation and cell hypertrophy. Our study suggests that TB-induced inflammation in the adipose tissue is associated with improved glucose tolerance and is mediated by mTORC2/Akt pathway.

Project description:Recent work using mouse models has revealed that mTORC2, which unlike mTORC1 is not acutely sensitive to rapamycin, plays a key role in the regulation of organismal physiology. The substrates and pathways regulated by mTORC2 are at present relatively unknown Using a mouse model with a targeted deletion of hepatic RICTOR, we investigated the loss of mTORC2 on the murine liver transcriptome Rictor floxed (RKO) and control mice (n=4 per group) were fasted overnight, refed for 3 hr, then sacrificed. Livers were removed, rinsed in PBS, and flash frozen in liquid nitrogen. RNA was extracted and hybridized to Affymetrix Genechip Mouse Gene 1.0 ST arrays

Project description:We provide evidence that IFN-induced Stat-activation is defective in cells with targeted disruption of the Rictor gene, whose protein product is a key element of mTOR complex 2 (mTORC2). Our studies show that transient or stable knockdown of Rictor leads to decreased expression of several IFN-inducible genes that mediate important biological functions, including antiproliferative and pro-apoptotic responses. Rictor+/+ and Rictor-/- MEFs were treated with 2500 U/ml of mouse IFNα for 24 hours

Project description:Although inflammation plays critical roles in the development of atherosclerosis, its regulatory mechanisms remain incompletely understood. Perivascular adipose tissue (PVAT) has been reported to undergo inflammatory changes in response to vascular injury. Here, we showed that vascular injury induced the beiging (brown adipose tissue-like phenotype change) of PVAT, which fine-tunes inflammatory response and thus vascular remodeling as a protective mechanism. In a mouse model of endovascular injury, macrophages accumulated in PVAT, causing beiging phenotype change. Inhibition of PVAT beiging by genetically silencing PRDM16, a key regulator to beiging, exacerbated inflammation and vascular remodeling following injury. Conversely, activation of PVAT beiging attenuated inflammation and pathological vascular remodeling. Single-cell RNA sequencing revealed that beige adipocytes abundantly expressed neuregulin 4 (Nrg4) which critically regulated alternative macrophage activation. Importantly, significant beiging was observed in the diseased aortic PVAT in patients with acute aortic dissection. Taken together, vascular injury induced the beiging of adjacent PVAT with macrophage accumulation, where NRG4 secreted from the beige PVAT facilitated alternative activation of macrophages, leading to the resolution of vascular inflammation. Our study demonstrated the pivotal roles of PVAT in vascular inflammation and remodeling and will open a new avenue for treating atherosclerosis.

Project description:Thoracic perivascular adipose tissue (PVAT) is a unique adipose depot that likely influences vascular function and susceptibility to pathogenesis in obesity and metabolic syndrome. Surprisingly, PVAT has been reported to share characteristics of both brown and white adipose, but a detailed direct comparison to interscapular brown adipose tissue (BAT) has not been performed. Here we show by full genome DNA microarray analysis that global gene expression profiles of PVAT are virtually identical to BAT, with equally high expression of Ucp-1, Cidea and other genes known to be uniquely or very highly expressed in BAT. PVAT and BAT also displayed nearly identical phenotypes upon immunohistochemical analysis, and electron microscopy confirmed that PVAT contained multilocular lipid droplets and abundant mitochondria. Compared to white adipose tissue (WAT), PVAT and BAT from C57BL/6 mice fed a high fat diet for 13 weeks had markedly lower expression of immune cell-enriched mRNAs, suggesting resistance to obesity-induced inflammation. Indeed, staining of BAT and PVAT for macrophage markers (F4/80, CD68) in obese mice showed virtually no macrophage infiltration, and FACS analysis of BAT confirmed the presence of very few CD11b+/CD11c+ macrophages in BAT (1.0%) in comparison to WAT (31%). In summary, murine PVAT from the thoracic aorta is virtually identical to interscapular BAT, is resistant to diet-induced macrophage infiltration, and thus may play an important role in protecting the vascular bed from thermal and inflammatory stress. 8-week-old male C57BL6/J mice were fed a normal (ND) or high fat diet (HFD) (Research Diets 12451, 45 kcal% fat) for 13 weeks. Mice were then euthanized and four different adipose depots were harvested for RNA analysis: perivascular fat from the lesser curvature of the aortic arch (PVAT), interscapular brown adipose (BAT), inguinal adipose tissue (SAT), and epididymal adipose tissue (VAT). 250 ng total RNA pooled from two mice was used for cDNA synthesis; 3 biological replicates per tissue and diet were performed for a total of 24 hybridizations.

Project description:Primary glioblastoma, representing over 90% of adult glioblastoma, develop rapidly without preexisting lower-grade glioma. We have generated a mouse model of primary glioblastoma driven by a single p53 mutation. These p53-mutant gliomas lose the syntenic region of human chromosome 10q, which is mapped to mouse chr19 and chr7. Loss of mouse chr19, containing Pten, activates PI3K/Akt signaling. Rictor/mTORC2 deletion inhibits Akt signaling, causing a significant delay in p53-mutant driven glioma formation. Unexpectedly, Rictor/mTORC2 loss promotes p53-mutant driven medulloblastomas with unique features of pediatric SHH medulloblastoma. Mechanistically, Rictor/mTORC2 loss inhibits the generation of glioma precursor cells from neural stem/progenitor cells in the adult brain, while causing a delay in differentiation of granule cell precursors in the developing brain, a cell-of-origin of SHH medulloblastoma.

Project description:Brown adipose tissue can expend large amounts of energy and thus increasing its amount or activity is a promising therapeutic approach to combat metabolic disease. In humans, major deposits of brown fat cells are found intimately associated with large blood vessels, corresponding to perivascular adipose tissue (PVAT). However, the cellular origins of PVAT are poorly understood. We applied single cell transcriptomic analyses, ex vivo adipogenesis assays, and genetic fate mapping to determine the identity of perivascular adipocyte progenitors. In mice, we found that thoracic PVAT develops from a fibroblastic lineage, consisting of progenitor cells (Pdgfra+; Ly6a+; Pparg-) and preadipocytes (Pdgfra+; Ly6a+; Pparg+). Progenitor and preadipocyte cells in PVAT shared transcriptional similarity with analogous cell types in inguinal white adipose tissue (IWAT), pointing towards a conserved hierarchical structure of adipose lineage cells. Interestingly, the aortic adventitia of adult animals contained a novel population of adipogenic smooth muscle cells (SMCs) (Myh11+; Pdgfra-; Pparg+) that contributed to perivascular adipocyte formation. Similarly, human PVAT contained presumptive fibroblastic and SMC-like adipocyte progenitors, as revealed by single nucleus RNAseq. Taken together, these studies define distinct populations of progenitor cells for thermogenic PVAT, providing a foundation for developing strategies to augment brown fat activity