The relative balance between the quantity of white and brown adipose tissue can profoundly affect lipid storage and whole-body energy homeostasis. However, the mechanisms regulating the formation, expansion, and interconversion of these 2 distinct types of fat remain unknown. Recently, the lysosomal degradative pathway of macroautophagy has been identified as a regulator of cellular differentiation, suggesting that autophagy may modulate this process in adipocytes. The function of autophagy in adipose differentiation was therefore examined in the current study by genetic inhibition of the critical macroautophagy gene autophagy-related 7 (Atg7). Knockdown of Atg7 in 3T3-L1 preadipocytes inhibited lipid accumulation and decreased protein levels of adipocyte differentiation factors. Knockdown of Atg5 or pharmacological inhibition of autophagy or lysosome function also had similar effects. An adipocyte-specific mouse knockout of Atg7 generated lean mice with decreased white adipose mass and enhanced insulin sensitivity. White adipose tissue in knockout mice had increased features of brown adipocytes, which, along with an increase in normal brown adipose tissue, led to an elevated rate of fatty acid, β-oxidation, and a lean body mass. Autophagy therefore functions to regulate body lipid accumulation by controlling adipocyte differentiation and determining the balance between white and brown fat. IntroductionObesity is characterized by an expansion of adipose tissue mass resulting from increased adipocyte number and/or size. Lipids in the form of triglycerides (TG) accumulate in various anatomical locations that differ in several regards including whether they are composed primarily of white or brown adipocytes. These 2 distinct types of adipocytes differ in their lipid content and metabolic functions. White adipose tissue (WAT) serves the primary function of lipid storage in the fed state and with fasting releases fatty acids from the breakdown of TG into the circulation for muscle energy production. In contrast, brown adipose tissue (BAT) has more limited TG storage and does not secrete fatty acids but instead uses them for autonomous energy expenditure and heat generation (1). Although the amount of BAT in adult humans has been previously considered to be minimal, recent findings of significant concentrations of brown adipocytes in adult humans (2-5) have raised the possibility that the balance between WAT and BAT mass may be one factor that regulates the development of obesity and its severity (6). Manipulating the process of adipocyte differentiation in order to promote more BAT in place of WAT may therefore be a novel approach to the treatment of obesity and its associated problems (7).Factors determining the differential development of WAT versus BAT remain poorly defined. In mammals, WAT and BAT generally develop before birth, although in rodents, WAT develops postnatally (8). Recent studies suggest that these fat cell populations are not static and may in fact continue to undergo significant cell turnover (9)...
Expression of bone morphogenetic protein 4 (BMP4) in adipocytes of white adipose tissue (WAT) produces "white adipocytes" with characteristics of brown fat and leads to a reduction of adiposity and its metabolic complications. Although BMP4 is known to induce commitment of pluripotent stem cells to the adipocyte lineage by producing cells that possess the characteristics of preadipocytes, its effects on the mature white adipocyte phenotype and function were unknown. Forced expression of a BMP4 transgene in white adipocytes of mice gives rise to reduced WAT mass and white adipocyte size along with an increased number of a white adipocyte cell types with brown adipocyte characteristics comparable to those of beige or brite adipocytes. These changes correlate closely with increased energy expenditure, improved insulin sensitivity, and protection against diet-induced obesity and diabetes. Conversely, BMP4-deficient mice exhibit enlarged white adipocyte morphology and impaired insulin sensitivity. We identify peroxisome proliferator-activated receptor gamma coactivator 1-α (PGC1α) as the target of BMP signaling required for these brown fat-like changes in WAT. This effect of BMP4 on WAT appears to extend to human adipose tissue, because the level of expression of BMP4 in WAT correlates inversely with body mass index. These findings provide a genetic and metabolic basis for BMP4's role in altering insulin sensitivity by affecting WAT development.oth white adipose tissue (WAT) and brown adipose tissue (BAT) function in the energy homeostasis of humans and other mammals. WAT stores energy in form of triglycerides during periods of excessive caloric intake for later use when energy demand exceeds intake (1). In contrast, brown adipose tissue (BAT) uses "stored triglycerides" to generate energy in the form of heat, most notably when environmental temperature falls (2).The excessive accumulation of body fat in WAT is the result of both hypertrophy and hyperplasia of white adipocytes (3). Such changes give rise to insulin resistance, type-2 diabetes, and an inflammatory response, thus implicating white adipocytes in the etiology of these conditions (4, 5). In contrast, promotion of BAT activities helps prevent genetic obesity, insulin resistance, and diabetes (6).Unlike the expansive mass of brown adipocytes in the interscapular region, brown adipose tissue mass in the normal adult human is proportionally smaller and previously was believed to be functionally less important. Recently, however, by using [18F]-2-fluoro-D-2-deoxy-D-glucose PET, metabolically active regions were detected in the cervical, supraclavicular, axillary, and paravertebral regions of adult human subjects (7-9). The metabolically active areas were found to consist of an admixture of brown-like adipocytes in WAT (10) which increase dramatically following cold exposure or treatment with antidiabetic drugs, thiazolidinediones, or adrenergic activators (11-13). These cells recently have been designated as "beige" (14) or "brite" (15, 16) cells derived from ...
Circular RNAs are generated from many protein-coding genes, but their role in cardiovascular health and disease states remains unknown. Here we report identification of circRNA transcripts that are differentially expressed in post myocardial infarction (MI) mouse hearts including circFndc3b which is significantly down-regulated in the post-MI hearts. Notably, the human circFndc3b ortholog is also significantly down-regulated in cardiac tissues of ischemic cardiomyopathy patients. Overexpression of circFndc3b in cardiac endothelial cells increases vascular endothelial growth factor-A expression and enhances their angiogenic activity and reduces cardiomyocytes and endothelial cell apoptosis. Adeno-associated virus 9 -mediated cardiac overexpression of circFndc3b in post-MI hearts reduces cardiomyocyte apoptosis, enhances neovascularization and improves left ventricular functions. Mechanistically, circFndc3b interacts with the RNA binding protein Fused in Sarcoma to regulate VEGF expression and signaling. These findings highlight a physiological role for circRNAs in cardiac repair and indicate that modulation of circFndc3b expression may represent a potential strategy to promote cardiac function and remodeling after MI.
[1] Pure ferrimagnetic greigite (Fe 3 S 4 ) has been synthesized by reacting ferric chloride with thiourea and formic acid at 170°C. Sample purity was confirmed by X-ray diffraction, neutron diffraction and Mössbauer spectroscopy, coupled with magnetic measurements. Scanning electron microscope observations indicate clear cubo-octahedral and polyhedral crystal morphologies. The grain sizes are as large as 44 mm. Detailed low-and high-temperature magnetic measurements document the previously poorly known magnetic properties of greigite. The synthetic greigite samples are dominated by pseudo-single-domain and multi-domain behavior. The saturation magnetization (M s ) at room temperature is $59 Am 2 kg À1 (3.13 m B per formula unit), which is higher than any value previously reported for greigite in the literature largely because of the high purity of this sample compared to others. No low-temperature magnetic transition has been detected; however, a local coercivity minimum is observed at around 130 K, which is probably associated with domain walls present in the studied samples. The high-temperature magnetic properties of greigite are dominated by chemical decomposition above around 250°C, which precludes determination of the Curie temperature, but our evidence indicates that it must exceed 350°C. On the basis of the Bloch spin wave expansion, the spin wave stiffness of greigite was determined for the first time as $193 meVÁÅ 2 from low-temperature M s measurements, with the corresponding exchange constant J AB of $1.03 meV.
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