Project description:Activated brown adipose tissue contributes to control of energy and glucose homeostasis in rodents and humans. Defining cell-autonomous processes underlying BAT differentiation and activation may thus reveal novel therapeutic targets for obesity and type 2 diabetes mellitus intervention. Here we show that ageing- and obesity-associated demises in BAT function coincide with down-regulation of mature microRNAs in BAT in the presence of reduced expression of the critical microRNA processing enzyme Dicer1. To mimic this partial down-regulation of microRNA processing in obesity and ageing, we inactivated one allele of Dicer1 selectively in BAT of mice. BAT- restricted heterozygosity of Dicer1 caused glucose intolerance in lean mice and aggravated diet-induced-obesity (DIO)-evoked deterioration of glucose homeostasis. Using combinatorial analyses of altered microRNA-expression in BAT during in vitro preadipocyte commitment and mouse models of progeria, longevity and DIO, we identified 23 microRNAs dysregulated among these conditions. Of these, we identified miR-328 as a novel regulator of BAT differentiation. miR-328 over-expression promotes BAT-differentiation and impairs muscle progenitor commitment, while reducing miR-328 expression blocks BAT specification. We validated the ß-Secretase Bace1 as a target of miR-328, which is consequently over-expressed in BAT of obese and premature ageing mice. Reducing Bace1 expression enhances brown adipocyte, while impairing myogenic differentiation in vitro. In vivo small-molecule Bace1 inhibition in obese mice delayed DIO-induced weight gain, ameliorated obesity-associated deterioration of glucose metabolism and improved insulin sensitivity. Collectively, these experiments reveal reduced Dicer1-miR-328-Bace1 axis in presence of generalized impairment of microRNA processing in ageing and obesity as a novel determinant of ageing- and obesity-associated decline in BAT function. This may define in vivo Bace1-inhibition as an innovative therapeutic approach to not only target age-related neurodegenerative diseases but at the same time improving age-related impairment of BAT-function and metabolism. C57BL/6 mice ( 4 weeks of age) were treated with a calory-rich, high-sugar high-fat diet (HFD) for a course of 4 weeks. Then groups were stratified and one group continued to receive HFD (BAT13-15) or HFD supplemented with an experimental small-molecule Bace 1 inhibitor (BAT17, 33, 35).

Project description:Age- and Obesity Induced Decline of Brown Fat Function as Consequence of Impaired miR-328 Dependent Silencing of Bace1

Project description:Although the global prevalence of obesity and type 2 diabetes is rising, the molecular mechanisms of dysregulated glucose and lipid metabolism are still incompletely understood. Epigenetic mechanisms were shown to have an impact in disease manifestation, but the underlying hepatic miRNA expression signature is not completely elucidated. We used microarrays to perform a comprehensive screen of the complete microRNA transcriptome in liver samples of diet induced obese (DIO) mice in order to identify expressed microRNAs that might target genes of hepatic lipid and glucose metabolism.

Project description:miR-33 is an intronic microRNA within the gene encoding the SREBP2 transcription factor. Like its host gene, miR-33 has been shown to be an important regulator of lipid metabolism. Inhibition of miR-33 has been shown to promote cholesterol efflux in macrophages by targeting the cholesterol transporter ABCA1, thus reducing atherosclerotic plaque burden. Inhibition of miR-33 has also been shown to improve high-density lipoprotein (HDL) biogenesis in the liver and increase circulating HDL-C levels in both rodents and nonhuman primates. However, evaluating the extent to which these changes in HDL metabolism contribute to atherogenesis has been hindered by the obesity and metabolic dysfunction observed in whole-body miR-33–knockout mice. To determine the impact of hepatic miR-33 deficiency on obesity, metabolic function, and atherosclerosis, we have generated a conditional knockout mouse model that lacks miR-33 only in the liver. Characterization of this model demonstrates that loss of miR-33 in the liver does not lead to increased body weight or adiposity. Hepatic miR-33 deficiency actually improves regulation of glucose homeostasis and impedes the development of fibrosis and inflammation. We further demonstrate that hepatic miR-33 deficiency increases circulating HDL-C levels and reverse cholesterol transport capacity in mice fed a chow diet, but these changes are not sufficient to reduce atherosclerotic plaque size under hyperlipidemic conditions. By elucidating the role of miR-33 in the liver and the impact of hepatic miR-33 deficiency on obesity and atherosclerosis, this work will help inform ongoing efforts to develop novel targeted therapies against cardiometabolic diseases.

Project description:We report the generation and characterization of DICER1-deficient hESCs. We uncover an unexpected requirement for DICER1 as well as essential pro-survival roles of members of the mir-302- 367 and mir-371- 373 clusters in hESCs. Our work provides a robust platform for interrogating microRNA function in hESC and differentiation.

Project description:High-fat diet (HFD) induced obesity (DIO) has been shown impacts on metabolism, hormonal profile, male fertility, and spermatogenesis. We employed genome-wide transcriptional analysis on the testis of diet induced obesity (DIO) and normal chow (NC) C57BL/6 J male mice to search genes regulated by obesity in testis. Both blood glucose and lipids contents significantly increased in DIO mice after 8 weeks fat-rich feeding. RNA-seq analysis revealed 371 down-regulated and 460 up-regulated transcripts in DIO group comparing to NC group. Chromosome 3, 4, 9, 16, and 18 were significantly more active, while chromosome 5, 10, and 19 were significantly more inactive after 8-week fat-diet feeding. Wilcoxon enrichment analysis discovered that the thermogenesis pathway (KEGG) was significantly enriched in the testis of DIO group (with 8 enriched up-regulated genes: Smarca2, Adcy3, Atp5pb, Creb1, Gnas, Rps6kb2, Upcrc1 and Dpf1). Real-time PCR further confirmed that Smarca2 and Atp5pb were upregulated in the testis of DIO mice. These finding implied that diet-induced thermogenesis pathways could be altered in the testis of DIO mice.

Project description:Increases in organismal energy expenditure, as during cold exposure or exercise training, can improve metabolic health. This process is dependent also on brown adipose tissue (BAT) thermogenesis in mice and humans. Understanding and harnessing the molecular circuits activating BAT function is thus of great interest to devise novel approaches to counteract obesity and type 2 diabetes (T2D). In contrast to protein-coding genes, the role of long noncoding RNAs (lncRNAs) during BAT differentiation and function remains poorly understood. To address this, we performed RNA-Seq and identified the maternal allele-specific (imprinted) lncRNA H19 increased upon cold-mediated BAT activation and decreased upon chronic diet-induced obesity (DIO) BAT dysfunction. An inverse correlation of H19 expression with body-mass indices (BMI) was observed in a cohort of >160 lean and obese humans. H19 silencing impaired adipogenesis and oxidative metabolism in brown but not white adipocytes, while H19 gain-of-function increased nutrient oxidation and mitochondrial respiration, thus supporting a BAT-regulatory role for H19. In vivo H19 overexpression protected against DIO, improved insulin sensitivity and rescued DIO-mediated defects in energy expenditure in conjunction with improved mitochondrial biogenesis. In contrast, BAT-selective H19 loss decreased energy dissipation and sensitized towards high fat diet-induced body weight gains. When investigating other parent-of-origin specific, monoallelically expressed genes, we strikingly observed that paternally expressed genes (PEGs) were largely absent from BAT and coordinately downregulated during brown adipogenesis, whilst the same gene set was robustly expressed in white fat stores, a phenomenon not observed for maternally expressed genes (MEGs). Using H19 loss- and gain-of-function in primary adipocytes, we demonstrate that H19 acts as ‘PEG gatekeeper’ in brown, not white adipocytes, potentially due to recruitment of PEG-inactivating H19-MBD1 complexes in mature brown adipocytes. The exclusive PEG expression in white adipose tissuer could underly the observed susceptibility of mice exhibiting high PEG abundances towards DIO-evoked weight gain. Collectively, we here define novel roles for the imprinted lncRNA H19 in brown adipocyte differentiation and function in vitro, control of energy expenditure in vivo and repression of paternal allele-specific gene expression in BAT. This has far-reaching implications for our understanding of how monoallelical gene expression affects metabolic eustasis in both rodent models and, potentially, human patients.

Project description:Increases in organismal energy expenditure, as during cold exposure or exercise training, can improve metabolic health. This process is dependent also on brown adipose tissue (BAT) thermogenesis in mice and humans. Understanding and harnessing the molecular circuits activating BAT function is thus of great interest to devise novel approaches to counteract obesity and type 2 diabetes (T2D). In contrast to protein-coding genes, the role of long noncoding RNAs (lncRNAs) during BAT differentiation and function remains poorly understood. To address this, we performed RNA-Seq and identified the maternal allele-specific (imprinted) lncRNA H19 increased upon cold-mediated BAT activation and decreased upon chronic diet-induced obesity (DIO) BAT dysfunction. An inverse correlation of H19 expression with body-mass indices (BMI) was observed in a cohort of >160 lean and obese humans. H19 silencing impaired adipogenesis and oxidative metabolism in brown but not white adipocytes, while H19 gain-of-function increased nutrient oxidation and mitochondrial respiration, thus supporting a BAT-regulatory role for H19. In vivo H19 overexpression protected against DIO, improved insulin sensitivity and rescued DIO-mediated defects in energy expenditure in conjunction with improved mitochondrial biogenesis. In contrast, BAT-selective H19 loss decreased energy dissipation and sensitized towards high fat diet-induced body weight gains. When investigating other parent-of-origin specific, monoallelically expressed genes, we strikingly observed that paternally expressed genes (PEGs) were largely absent from BAT and coordinately downregulated during brown adipogenesis, whilst the same gene set was robustly expressed in white fat stores, a phenomenon not observed for maternally expressed genes (MEGs). Using H19 loss- and gain-of-function in primary adipocytes, we demonstrate that H19 acts as ‘PEG gatekeeper’ in brown, not white adipocytes, potentially due to recruitment of PEG-inactivating H19-MBD1 complexes in mature brown adipocytes. The exclusive PEG expression in white adipose tissuer could underly the observed susceptibility of mice exhibiting high PEG abundances towards DIO-evoked weight gain. Collectively, we here define novel roles for the imprinted lncRNA H19 in brown adipocyte differentiation and function in vitro, control of energy expenditure in vivo and repression of paternal allele-specific gene expression in BAT. This has far-reaching implications for our understanding of how monoallelical gene expression affects metabolic eustasis in both rodent models and, potentially, human patients.

Project description:Obesity and its co-morbidities including type 2 diabetes are increasing at epidemic rates in the U.S. and worldwide. Brown adipose tissue (BAT) is a potential therapeutic to combat obesity and type 2 diabetes. Increasing BAT mass by transplantation improves metabolic health in rodents, but its clinical translation remains a challenge. Here, we investigated if transplantation of 2-4 million differentiated brown pre-adipocytes from mouse BAT stromal fraction (SVF) or human pluripotent stem cells (hPSCs) could improve metabolic health. Transplantation of differentiated brown pre-adipocytes, termed ‘committed pre-adipocytes’ from BAT SVF from mice or derived from hPSCs improves glucose homeostasis and insulin sensitivity in recipient mice under conditions of diet-induced obesity, and this improvement is mediated through the collaborative actions of the liver transcriptome, tissue AKT signaling and FGF21. These data demonstrate that transplantation of a small number of brown adipocytes has significant long-term translational and therapeutic potential to improve glucose metabolism.

Project description:To identify genes regulated by miR-328-3p, we transfected miR-328-3p mimics in ovarian cancer cell line OV2008, and compared the gene expression profiles between miR-328-3p mimics transfected and Negative Control miRNA-transfected cells.