Previous studies showed that exposure of C3H10T1͞2 stem cells to bone morphogenetic protein-4 (BMP-4) produced cells that convert into adipocytes at high frequency when treated with differentiation inducers. In the present investigation, an independent approach shows that BMP-4 is required for stable commitment of pluripotent stem cells to the adipocyte lineage. Exposure of proliferating 10T1͞2 stem cells to 5-azacytidine, a potent DNA methylation inhibitor, gave rise to a subpopulation of cells that can be cloned and that have the capacity to undergo conversion into adipocytes upon treatment with terminal differentiation inducers. 5-azacytidine ͉ adipogenesis ͉ determination ͉ mesenchymal stem cell ͉ preadipocyte
Sympathetic innervation of white adipose tissue and its regulation of fat cell number
. Sympathetic innervation of white adipose tissue and its regulation of fat cell number. Am J Physiol Regul Integr Comp Physiol 286: R1167-R1175, 2004 10.1152/ajpregu.00558.2003.-White adipose tissue (WAT) is innervated by the sympathetic nervous system (SNS), and the central origins of this innervation have been demonstrated for inguinal and epididymal WAT (iWAT and eWAT, respectively) using a viral transneuronal tract tracer, the pseudorabies virus (PRV). Although the more established role of this sympathetic innervation of WAT is as a major stimulator of lipid mobilization, this innervation also inhibits WAT fat cell number (FCN); thus, local denervation of WAT leads to marked increases in WAT mass and FCN. The purpose of this study was to extend our understanding of the SNS regulation of FCN using neuroanatomical and functional analyses. Therefore, we injected PRV into retroperitoneal WAT (rWAT) to compare the SNS outflow to this pad from what already is known for iWAT and eWAT. In addition, we tested the ability of local unilateral denervation of rWAT or iWAT to promote increases in WAT mass and FCN vs. their contralateral neurally intact counterparts. Although the overall pattern of innervation was more similar than different for rWAT vs. iWAT or eWAT, its SNS outflow appeared to involve more neurons in the suprachiasmatic and solitary tract nuclei. Denervation produced significant increases in WAT mass and FCN for both iWAT and rWAT, but FCN was increased significantly more in iWAT than in rWAT. These data suggest differences in origins of the sympathetic outflow to WAT and functional differences in the WAT SNS innervation that could contribute to the differential propensity for fat cell proliferation across WAT depots in vivo. body fat; cellularity; hyperplasia; pseudorabies virus; tract tracing; white fat ENERGY BALANCE IS MAINTAINED through alterations in energy intake and energy expenditure. Lipid is the primary form of stored energy in mammals and is largely found in white adipose tissue (WAT) as triacylglycerols. Prolonged positive energy balance promotes obesity that in humans is associated with a number of health risks (34). The deposition of lipid initially results in increases in fat cell size (FCS), but soon triggers increases in fat cell number (FCN; for review, see Ref. 16). The processes underlying this hypercellularity, a hallmark sign of obesity, are not well understood (for review, see Ref. 21). Furthermore, the accretion of lipid in and of itself is not necessarily associated with these health risks (38); rather it is the distribution of body fat that is critical (19). That is, visceral obesity is closely associated with development of the "metabolic syndrome" and type II diabetes (for review, see Ref. 44). Thus understanding how body fat is preferentially deposited and mobilized is necessary for the prevention and treatment of obesity, respectively.One mechanism that may underlie the differential accumulation of lipid by WAT depots, as well as the differential mobilization of lipid, i...
White adipose tissue lacks significant vagal innervation and immunohistochemical evidence of parasympathetic innervation
Converging evidence indicates that white adipose tissue (WAT) is innervated by the sympathetic nervous system (SNS) based on immunohistochemical labeling of a SNS marker (tyrosine hydroxylase [TH]), tract tracing of WAT sympathetic postganglionic innervation, pseudorabies virus (PRV) transneuronal labeling of WAT SNS outflow neurons, and functional evidence from denervation studies. Recently, WAT para-SNS (PSNS) innervation was suggested because local surgical WAT sympathectomy (sparing hypothesized parasympathetic innervation) followed by PRV injection yielded infected cells in the vagal dorsomotor nucleus (DMV), a traditionally-recognized PSNS brain stem site. In addition, local surgical PSNS WAT denervation triggered WAT catabolic responses. We tested histologically whether WAT was parasympathetically innervated by searching for PSNS markers in rat, and normal (C57BL) and obese (ob/ob) mouse WAT. Vesicular acetylcholine transporter, vasoactive intestinal peptide and neuronal nitric oxide synthase immunoreactivities were absent in WAT pads (retroperitoneal, epididymal, inguinal subcutaneous) from all animals. Nearly all nerves innervating WAT vasculature and parenchyma that were labeled with protein gene product 9.5 (PGP9.5; pan-nerve marker) also contained TH, attesting to pervasive SNS innervation. When Siberian hamster inguinal WAT was sympathetically denervated via local injections of catecholaminergic toxin 6-hydroxydopamine (sparing putative parasympathetic nerves), subsequent PRV injection resulted in no central nervous system (CNS) or sympathetic chain infections suggesting no PSNS innervation. By contrast, vehicle-injected WAT subsequently inoculated with PRV had typical CNS/sympathetic chain viral infection patterns. Collectively, these data indicate no parasympathetic nerve markers in WAT of several species, with sparse DMV innervation and question the claim of PSNS WAT innervation as well as its functional significance.
The rapid proliferation of cancer cells mandates a high protein turnover. The endoplasmic reticulum (ER) is intimately involved in protein processing.
An overactive renin-angiotensin system is associated with obesity and the metabolic syndrome. However, the mechanisms behind it are unclear. Cleaving angiotensinogen to angiotensin I by renin is a rate-limiting step of angiotensin II production, but renin is suggested to have angiotensin-independent effects. We generated mice lacking renin (Ren1c) using embryonic stem cells from C57BL/6 mice, a strain prone to diet-induced obesity. Ren1c(-/-) mice are lean, insulin sensitive, and resistant to diet-induced obesity without changes in food intake and physical activity. The lean phenotype is likely due to a higher metabolic rate and gastrointestinal loss of dietary fat. Most of the metabolic changes in Ren1c(-/-) mice were reversed by angiotensin II administration. These results support a role for angiotensin II in the pathogenesis of diet-induced obesity and insulin resistance.
Extra View A Role for Bone Morphogenetic Protein-4 in Adipocyte Development ABstRActObesity is characterized by increases in the number of mature adipocytes. Nascent adipocytes arise from mesenchymal stem cells (MSCs) by a multi-step process-MSCs are recruited to the adipocyte lineage forming determined preadipocytes, these committed progenitors proliferate, undergo growth arrest, and finally differentiate into mature adipocytes. Although the genetic mechanisms that control the differentiation of preadipocytes into mature adipocytes are understood to a large extent, the earliest events in adipogenesis-especially the commitment of MSCs into preadipocytes-are largely unknown. Recently, bone morphogenetic protein-4 (BMP-4) has been implicated in the commitment of pluripotent MSCs to the adipocyte lineage by two independent lines of investigation. First, growth-arrested 10T1/2 cells do not normally respond to a hormonal cocktail that causes various growth-arrested preadipocyte cell lines to differentiate into adipocytes, but if 10T1/2 cells are first treated with BMP-4 they will respond to these hormonal inducers by undergoing terminal adipocyte differentiation. Second, a preadipocyte cell line, A33 cells, derived from 10T1/2 cells after exposing the cells to the DNA methyltransferase inhibitor 5-azacytidine was shown to express BMP-4, and this endogenous BMP-4 expression is required for acquisition of the preadipocyte phenotype of these cells. A role for the BMP-4 signaling pathway in adipogenesis is discussed.
While investigating the reversible seasonal obesity of Siberian hamsters, direct sympathetic nervous system (SNS) postganglionic innervation of white adipose tissue (WAT) has been demonstrated using anterograde and retrograde tract tracers. The primary function of this innervation is lipid mobilization. The brain SNS outflow to WAT has been defined using the pseudorabies virus (PRV), a retrograde transneuronal tract tracer. These PRV-labelled SNS outflow neurons are extensively co-localized with melanocortin-4 receptor mRNA, which, combined with functional data, suggests their involvement in lipolysis. The SNS innervation of WAT also regulates fat cell number, as noradrenaline inhibits and WAT denervation stimulates fat cell proliferation in vitro and in vivo respectively. The sensory innervation of WAT has been demonstrated by retrograde tract tracing, electrophysiological recording and labelling of the sensory-associated neuropeptide calcitonin gene-related peptide in WAT. Local injections of the sensory nerve neurotoxin capsaicin into WAT selectively destroy this innervation. Just as surgical removal of WAT pads triggers compensatory increases in lipid accretion by nonexcised WAT depots, capsaicin-induced sensory denervation triggers increases in lipid accretion of non-capsaicin-injected WAT depots, suggesting that these nerves convey information about body fat levels to the brain. Finally, parasympathetic nervous system innervation of WAT has been suggested, but the recent finding of no WAT immunoreactivity for the possible parasympathetic marker vesicular acetylcholine transporter (VAChT) argues against this claim. Collectively, these data suggest several roles for efferent and afferent neural innervation of WAT in body fat regulation.Sympathetic nervous system: Sensory nerves: Parasympathetic nervous system: Pseudorabies virus: Lipolysis A critical ability of all animals is to meet energy demands quickly with utilizable metabolic fuels. In mammals glycogen serves as a rapidly available, but extremely limited, carbohydrate energy source. Energy is predominately stored as lipid in white adipose tissue (WAT) in the form of triacylglycerol (Newsholme & Leech, 1983). Access to this energy in fat can be mediated by several means, principally by the sympathetic nervous system (SNS) innervation of WAT. The present review starts by discussing the SNS innervation of WAT and then considers its sensory innervation and possible parasympathetic nervous system (PSNS) innervation. As the title of the review suggests, the cross talk occurring between the brain and WAT, which use these innervations as conduits, will be highlighted. However, the provocative and interesting cross talk between WAT and the brain that occurs via humoral factors will not be discussed.Adrenal medullary catecholamines, once thought to be the principal stimulators of lipid mobilization, do not play a major role in lipolysisTraditionally, adrenal medullary secretion of catecholamines, primarily adrenaline, is thought to be the underlying means by whi...
Central administration of melanocortin 3 and 4 receptor (MC3/4-R) agonists increases energy expenditure, with the hypothalamus commonly held as the primary site of action. It is also clear, however, that MC4-R are expressed in caudal brainstem structures of relevance to the control of energy expenditure. Three experiments investigated whether hindbrain MC-R contribute to the energy expenditure effects of central MC3/4-R agonist treatments; in each, we examined the effect of fourth intracerebroventricular (i.c.v.) administration of a MC3/4-R agonist, MTII (three injections, each separated by 12 h), on uncoupling protein 1 (UCP-1) gene expression in brown adipose tissue (BAT). First, we compared the effects of fourth and third i.c.v. administration of MTII and found that the hindbrain and forebrain treatments were equally effective at elevating UCP-1 mRNA expression in BAT compared with the respective vehicle-treated group results. A second experiment demonstrated that the fourth i.c.v. MTII-induced rise in UCP-1 expression was mediated by sympathetic outflow to BAT by showing that this response was abolished by surgical denervation of BAT. In the third experiment, we showed that chronic decerebrate rats, like their neurologically intact controls, elevated UCP-1 mRNA expression in response to fourth i.c.v. MTII administration. Taken together, the results indicate that: 1) there is an independent caudal brainstem MC3/4-R trigger for a sympathetically stimulated elevation in BAT UCP-1 gene expression, and 2) the MTII-induced rise in UCP-1 expression can be mediated by circuitry intrinsic to the caudal brainstem and spinal cord.
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