White-to-brown transdifferentiation of omental adipocytes in patients affected by pheochromocytoma.

In all mammals, white adipose tissue (WAT) and brown adipose tissue (BAT) are found together in several fat depots, forming a multi-depot organ. Adrenergic stimulation induces an increase in BAT usually referred to as "browning". This phenomenon is important because of its potential use in curbing obesity and related disorders; thus, understanding its cellular mechanisms in humans may be useful for the development of new therapeutic strategies. Data in rodents have supported the direct transformation of white into brown adipocytes. Biopsies of pure white omental fat were collected from 12 patients affected by the catecholamine-secreting tumor pheochromocytoma (pheo-patients) and compared with biopsies from controls. Half of the omental fat samples from pheo-patients contained uncoupling protein 1 (UCP1)-immunoreactive-(ir) multilocular cells that were often arranged in a BAT-like pattern endowed with noradrenergic fibers and dense capillary network. Many UCP1-ir adipocytes showed the characteristic morphology of paucilocular cells, which we have been described as cytological marker of transdifferentiation. Electron microscopy showed increased mitochondrial density in multi- and paucilocular cells and disclosed the presence of perivascular brown adipocyte precursors. Brown fat genes, such as UCP1, PR domain containing 16 (PRDM16) and ß3-adrenoreceptor, were highly expressed in the omentum of pheo-patients and in those cases without visible morphologic re-arrangement. Of note, the brown determinant PRDM16 was detected by immunohistochemistry only in nuclei of multi- and paucilocular adipocytes. Quantitative electron microscopy and immunohistochemistry for Ki67 suggest an unlikely contribution of proliferative events to the phenomenon. The data support the idea that, in adult humans, white adipocytes of pure white fat that are subjected to adrenergic stimulation are able to undergo a process of direct transformation into brown adipocytes. This article is part of a Special Issue entitled Brown and White Fat: From Signaling to Disease.

In vivo physiological transdifferentiation of adult adipose cells.

Grafts of adipose tissue from adult Rosa26 mice from different sites of the body, irrespective of the sex of the donor, share with the mammary fat the property of giving rise to milk-secreting epithelial cells when exposed to the microenvironment of the mammary gland in pregnant and lactating females. To rule out the possibility that the labeled mammary glandular tissue was derived from stem cells associated with the stroma vascular part of the grafts, we injected into the mammary gland a pure suspension of adipocytes obtained by treating a fragment of adipose tissue with collagenase. X-gal-positive cells were inserted into the alveoli of the native gland, and electron microscopy showed that the labeled cells had transformed into milk-secreting glandular cells. At the site of the adipocyte injection, the labeled alveoli contained a mixture of X-gal-positive and X-gal-negative cells, and a single epithelial cell was occasionally stained in an otherwise unlabeled alveolus. This suggests that growing ducts individually recruit adjacent adipocytes that transdifferentiate into secretory epithelial cells as they became part of the glandular alveoli. After dissociation, the isolated adipocytes retained the morphology and protein markers typical of differentiated fat cells but expressed high levels of stem cell genes and the reprogramming transcription factor Klf4. Thus, the well-documented osteogenic, chondrogenic, myogenic, and angiogenic transformation of preadipocytes associated with the stroma vascular component of the adipose tissue may reflect an intrinsic capability of adipocytes to reprogram their gene expression and transform into different cytotypes.

The presence of UCP1 demonstrates that metabolically active adipose tissue in the neck of adult humans truly represents brown adipose tissue.

Classically, adult humans have been considered not to possess active brown adipose tissue (BAT). However, positron-emission-tomography has shown fluorodeoxyglucose uptake that is distributed in such a way (e.g., in the neck) that it would seem to be BAT. Until now this has not been supported by direct evidence that these areas truly represented BAT, that is, the presence of the BAT-unique uncoupling protein-1 (UCP1). Samples of adipose tissue from the neck of 35 patients undergoing surgery for thyroid diseases were obtained and analyzed. In 1/3 of the subjects (the younger and leaner), distinct islands composed of UCP1 immunoreactive brown adipocytes could clearly be discerned, accounting for up to 1/3 of all adipocytes. The brown-adipose islands were richly sympathetically innervated (indicating acute central control); adjacent white adipose areas were not. The capillary density was high, implying a high capacity for oxygen delivery. Cells with features of brown adipocyte precursors were found in pericapillary areas. These data demonstrate that human adults indeed possess BAT and thus imply possibilities of future therapeutic strategies for the treatment of obesity, including maintenance of brown adipocytes and stimulation of the growth of preexisting brown precursors.

Publisher Correction: Muscle and adipose tissue morphology, insulin sensitivity and beta-cell function in diabetic and nondiabetic obese patients: effects of bariatric surgery.

A correction to this article has been published and is linked from the HTML and PDF versions of this paper. The error has not been fixed in the paper.

Muscle and adipose tissue morphology, insulin sensitivity and beta-cell function in diabetic and nondiabetic obese patients: effects of bariatric surgery.

Obesity is characterized by insulin-resistance (IR), enhanced lipolysis, and ectopic, inflamed fat. We related the histology of subcutaneous (SAT), visceral fat (VAT), and skeletal muscle to the metabolic abnormalities, and tested their mutual changes after bariatric surgery in type 2 diabetic (T2D) and weight-matched non-diabetic (ND) patients. We measured IR (insulin clamp), lipolysis (2H5-glycerol infusion), ß-cell glucose-sensitivity (ß-GS, mathematical modeling), and VAT, SAT, and rectus abdominis histology (light and electron microscopy). Presurgery, SAT and VAT showed signs of fibrosis/necrosis, small mitochondria, free interstitial lipids, thickened capillary basement membrane. Compared to ND, T2D had impaired ß-GS, intracapillary neutrophils and higher intramyocellular fat, adipocyte area in VAT, crown-like structures (CLS) in VAT and SAT with rare structures (cyst-like) ~10-fold larger than CLS. Fat expansion was associated with enhanced lipolysis and IR. VAT histology and intramyocellular fat were related to impaired ß-GS. Postsurgery, IR and lipolysis improved in all, ß-GS improved in T2D. Muscle fat infiltration was reduced, adipocytes were smaller and richer in mitochondria, and CLS density in SAT was reduced. In conclusion, IR improves proportionally to weight loss but remains subnormal, whilst SAT and muscle changes disappear. In T2D postsurgery, some VAT pathology persists and beta-cell dysfunction improves but is not normalized.

Modulation of syndecans in the uterus throughout the menstrual cycle: comparison between endometrium and myometrium.

Immunohistochemistry and semiquantitative analysis were used to examine and compare the expression of syndecans 1-4 in the endometrium and myometrium throughout the menstrual cycle. Syndecans molecules show different temporal and spatial expression during the menstrual cycle, and the modulation of syn-2 expression is statistically significantly correlated to morphologic and functional changes of the endometrium, particularly in the periovulatory period.

Plac8 is an inducer of C/EBPß required for brown fat differentiation, thermoregulation, and control of body weight.

Brown adipocytes oxidize fatty acids to produce heat in response to cold or to excessive energy intake; stimulation of brown fat development and function may thus counteract obesity. Brown adipogenesis requires activation of the transcription factor C/EBPß and recruitment of the zinc finger protein Prdm16, but upstream inducers of these proteins are incompletely defined. Here, we show that genetic inactivation of Plac8, a gene encoding an evolutionarily conserved protein, induces cold intolerance, and late-onset obesity, as well as abnormal morphology and impaired function of brown adipocytes. Using brown preadipocyte lines we show that Plac8 is required for brown fat differentiation, that its overexpression induces C/EBPß and Prdm16, and that upon induction of differentiation Plac8 associates with C/EBPß and binds to the C/EBPß promoter to induce its transcription. Thus, Plac8 is a critical upstream regulator of brown fat differentiation and function that acts, at least in part, by inducing C/EBPß expression.

Quantification of intermuscular adipose tissue in the erector spinae muscle by MRI: agreement with histological evaluation.

Deposition of fat between skeletal muscle bundles and beneath the muscle fascia, recently called intermuscular adipose tissue (IMAT), is gaining attention as potential contributor to insulin resistance, metabolic syndrome, muscle function impairment, and disability. The aim of this study was to compare IMAT as measured at the erector spinae level by magnetic resonance imaging (MRI), a well-recognized gold standard method to evaluate fat content inside muscles, and histology estimates. In 18 healthy elderly men and women with a wide range of BMI (25.05-35.58 kg/m(2)), undergoing elective vertebral surgery, IMAT within the erector spinae muscle was evaluated by MRI, by body composition using dual-energy X-ray absorptiometry and histological evaluation of intraoperative biopsy sample. The concordance between IMAT/total area (TA) ratio evaluated by MRI and histological examination was analyzed employing Lin's concordance correlation coefficient and the procedure proposed by Bland and Altman. Two thresholds to distinguish between muscle and IMAT calculated, respectively, by 20 and 10% reduction of the gray-level intensity evaluated by MRI from surrounding subcutaneous adipose tissue (SAT) were used. With a 20% reduction, calculated IMAT/TA as evaluated by MRI on average exceeds histological evaluation by 21.79%, whereas by reducing the threshold by 10% agreement between MRI and histology improved with a 12.42% difference. Our data show a good degree of concordance between IMAT assessment by MRI and histology and seems to show that agreement between the two methods could be improved by using a more restrictive threshold between muscle and fat.