The fine structure of brown adipose tissue. I. Cold-induced changes in the rat

Structural basis of respiratory complex adaptation to cold temperatures

In response to cold, mammals activate brown fat for respiratory-dependent thermogenesis reliant on the electron transport chain. Yet, the structural basis of respiratory complex adaptation upon cold exposure remains elusive. Herein, we combined thermoregulatory physiology and cryoelectron microscopy (cryo-EM) to study endogenous respiratory supercomplexes from mice exposed to different temperatures. A cold-induced conformation of CI:III2 (termed type 2) supercomplex was identified with a ∼25° rotation of CIII2 around its inter-dimer axis, shortening inter-complex Q exchange space, and exhibiting catalytic states that favor electron transfer. Large-scale supercomplex simulations in mitochondrial membranes reveal how lipid-protein arrangements stabilize type 2 complexes to enhance catalytic activity. Together, our cryo-EM studies, multiscale simulations, and biochemical analyses unveil the thermoregulatory mechanisms and dynamics of increased respiratory capacity in brown fat at the structural and energetic level.

Structural basis of respiratory complexes adaptation to cold temperatures

In response to cold, mammals activate brown fat for respiratory-dependent thermogenesis reliant on the electron transport chain (1, 2). Yet, the structural basis of respiratory complex adaptation to cold remains elusive. Herein we combined thermoregulatory physiology and cryo-EM to study endogenous respiratory supercomplexes exposed to different temperatures. A cold-induced conformation of CI:III 2 (termed type 2) was identified with a ∼25° rotation of CIII 2 around its inter-dimer axis, shortening inter-complex Q exchange space, and exhibiting different catalytic states which favor electron transfer. Large-scale supercomplex simulations in lipid membrane reveal how unique lipid-protein arrangements stabilize type 2 complexes to enhance catalytic activity. Together, our cryo-EM studies, multiscale simulations and biochemical analyses unveil the mechanisms and dynamics of respiratory adaptation at the structural and energetic level.

FAM210A is essential for cold-induced mitochondrial remodeling in brown adipocytes

Cold stimulation dynamically remodels mitochondria in brown adipose tissue (BAT) to facilitate non-shivering thermogenesis in mammals, but what regulates mitochondrial plasticity is poorly understood. Comparing mitochondrial proteomes in response to cold revealed FAM210A as a cold-inducible mitochondrial inner membrane protein. An adipocyte-specific constitutive knockout of Fam210a (Fam210aAKO) disrupts mitochondrial cristae structure and diminishes the thermogenic activity of BAT, rendering the Fam210aAKO mice vulnerable to lethal hypothermia under acute cold exposure. Induced knockout of Fam210a in adult adipocytes (Fam210aiAKO) does not affect steady-state mitochondrial structure under thermoneutrality, but impairs cold-induced mitochondrial remodeling, leading to progressive loss of cristae and reduction of mitochondrial density. Proteomics reveals an association between FAM210A and OPA1, whose cleavage governs cristae dynamics and mitochondrial remodeling. Mechanistically, FAM210A interacts with mitochondrial protease YME1L and modulates its activity toward OMA1 and OPA1 cleavage. These data establish FAM210A as a key regulator of mitochondrial cristae remodeling in BAT and shed light on the mechanism underlying mitochondrial plasticity in response to cold.

Adipose tissue at single-cell resolution

Adipose tissue exhibits remarkable plasticity with capacity to change in size and cellular composition under physiological and pathophysiological conditions. The emergence of single-cell transcriptomics has rapidly transformed our understanding of the diverse array of cell types and cell states residing in adipose tissues and has provided insight into how transcriptional changes in individual cell types contribute to tissue plasticity. Here, we present a comprehensive overview of the cellular atlas of adipose tissues focusing on the biological insight gained from single-cell and single-nuclei transcriptomics of murine and human adipose tissues. We also offer our perspective on the exciting opportunities for mapping cellular transitions and crosstalk, which have been made possible by single-cell technologies.

The Unity of Redox and Structural Remodeling of Brown Adipose Tissue in Hypothyroidism

Brown adipose tissue (BAT) is important for maintaining whole-body metabolic and energy homeostasis. However, the effects of hypothyroidism, one of the most common diseases worldwide, which increases the risk of several metabolic disorders, on BAT redox and metabolic homeostasis remain mostly unknown. We aimed to investigate the dynamics of protein expression, enzyme activity, and localization of antioxidant defense (AD) enzymes in rat interscapular BAT upon induction of hypothyroidism by antithyroid drug methimazole for 7, 15, and 21 days. Our results showed an increased protein expression of CuZn- and Mn-superoxide dismutase, catalase, glutamyl-cysteine ligase, thioredoxin, total glutathione content, and activity of catalase and thioredoxin reductase in hypothyroid rats, compared to euthyroid control. Concomitant with the increase in AD, newly established nuclear, mitochondrial, and peroxisomal localization of AD enzymes was found. Hypothyroidism also potentiated associations between mitochondria, peroxisomes, and lipid bodies, creating specific structural-functional units. Moreover, hypothyroidism induced protein expression and nuclear translocation of a master regulator of redox-metabolic homeostasis, nuclear factor erythroid 2-related factor 2 (Nrf2), and an increased amount of 4-hydroxynonenal (4-HNE) protein adducts. The results indicate that spatiotemporal overlap in the remodeling of AD is orchestrated by Nrf2, implicating the role of 4-HNE in this process and suggesting the potential mechanism of redox-structural remodeling during BAT adaptation in hypothyroidism.

Cellular Heterogeneity in Adipose Tissues

Adipose tissue depots in distinct anatomical locations mediate key aspects of metabolism, including energy storage, nutrient release, and thermogenesis. Although adipocytes make up more than 90% of adipose tissue volume, they represent less than 50% of its cellular content. Here, I review recent advances in genetic lineage tracing and transcriptomics that reveal the identities of the heterogeneous cell populations constituting mouse and human adipose tissues. In addition to mature adipocytes and their progenitors, these include endothelial and various immune cell types that together orchestrate adipose tissue development and functions. One salient finding is the identification of progenitor subtypes that can modulate adipogenic capacity through paracrine mechanisms. Another is the description of fate trajectories of monocyte/macrophages, which can respond maladaptively to nutritional and thermogenic stimuli, leading to metabolic disease. These studies have generated an extraordinary source of publicly available data that can be leveraged to explore commonalities and differences among experimental models, providing new insights into adipose tissues and their role in metabolic disease.

Cold Induced Depot-Specific Browning in Ferret Aortic Perivascular Adipose Tissue

Brown adipose tissue is responsible for facultative thermogenesis to produce heat and increase energy expenditure in response to proper stimuli, e.g., cold. Acquisition of brown-like features (browning) in perivascular white adipose tissue (PVAT) may protect against obesity/cardiovascular disease. Most browning studies are performed in rodents, but translation to humans would benefit from a closer animal model. Therefore, we studied the browning response of ferret thoracic aortic PVAT (tPVAT) to cold. We performed global transcriptome analysis of tPVAT of 3-month-old ferrets acclimatized 1 week to 22 or 4°C, and compared the results with those of inguinal subcutaneous adipose tissue. Immunohistochemistry was used to visualize browning. Transcriptome data revealed a stronger cold exposure response of tPVAT, including increased expression of key brown/brite markers, compared to subcutaneous fat. This translated into a clear white-to-brown remodeling of tPVAT, with the appearance of multilocular highly UCP1-stained adipocytes. The pathway most affected by cold exposure in tPVAT was immune response, characterized by down-regulation of immune-related genes, with cardio protective implications. On the other hand, subcutaneous fat responded to cold by increasing energy metabolism based on increased expression of fatty acid oxidation and tricarboxylic acid cycle genes, concordant with lower inguinal adipose tissue weight in cold-exposed animals. Thus, ferret tPVAT responds to cold acclimation with a strong induction of browning and immunosuppression compared to subcutaneous fat. Our results present ferrets as an accessible translational animal model displaying functional responses relevant for obesity and cardiovascular disease prevention.

Effects of long-term sucrose overfeeding on rat brown adipose tissue: a structural and immunohistochemical study

The aim of this study was to determine the effects of long-term sucrose overfeeding on functional capacity and ultrastructural characteristics of the rat brown adipose tissue (BAT). For the study, 16 male Wistar rats, chow-fed and kept under standard laboratory conditions, were divided into 2 equal groups. The rats from a control group drank tap water, whereas those from a sucrose overfed group were allowed to drink 10% sucrose solution for 21 days. Structural changes of BAT were analysed at the level of light and electron microscopy on routinely prepared tissue sections or using immunohistochemical staining, in combination with stereological methods. Obtained results have shown that the significantly increased energy intake in sucrose overfed rats did not result in a higher gain of body mass compared with controls. The light microscopy analysis revealed that the BAT acquired the appearance of a thermogenically active tissue, with intensified vascularisation, reduced size of brown adipocytes and increased multilocularity. At the ultrastructural level, mitochondria of brown adipocytes became more abundant, enlarged and contained more cristae in comparison to control animals. The immunoexpression of uncoupling protein 1 (UCP1) and noradrenaline, as markers of BAT thermogenic status, was increased, whereas the pattern of peroxisome proliferator-activated receptor gamma coactivator 1-alpha (PGC1α) was slightly modified. Taken together, the results of this investigation indicated that BAT possesses the ability to increase thermogenic capacity/activity in response to high energy intake and to prevent body mass gain. These findings are particularly relevant in view of recent reports on the existence of functional BAT in adult humans and its potential use to combat obesity.

Responses of the insulin signaling pathways in the brown adipose tissue of rats following cold exposure

The insulin signaling pathway is critical for the control of blood glucose levels. Brown adipose tissue (BAT) has also been implicated as important in glucose homeostasis. The effect of short-term cold exposure on this pathway in BAT has not been explored. We evaluated the effect of 4 hours of cold exposure on the insulin pathway in the BAT of rats. Whole genomic microarray chips were used to examine the transcripts of the pathway in BAT of rats exposed to 4°C and 22°C for 4 hours. The 4 most significantly altered pathways following 4 hours of cold exposure were the insulin signaling pathway, protein kinase A, PI3K/AKT and ERK/MAPK signaling. The insulin signaling pathway was the most affected. In the documented 142 genes of the insulin pathway, 42 transcripts (29.6%) responded significantly to this cold exposure with the least false discovery rate (Benjamini-Hochberg Multiple Testing: −log10 (p-value)  = 7.18). Twenty-seven genes (64%) were up-regulated, including the insulin receptor (Insr), insulin substrates 1 and 2 (Irs1 and Irs2). Fifteen transcripts (36%) were down-regulated. Multiple transcripts of the primary target and secondary effector targets for the insulin signaling were also up-regulated, including those for carbohydrate metabolism. Using western blotting, we demonstrated that the cold induced higher Irs2, Irs1, and Akt-p protein levels in the BAT than in the BAT of controls maintained at room temperature, and higher Akt-p protein level in the muscle. Conclusion: this study demonstrated that 4 hours of cold exposure stimulated the insulin signaling pathway in the BAT and muscle of overnight fasted rats. This raises the possibility that acute cold stimulation may have potential to improve glucose clearance and insulin sensitivity.

Free radical equilibrium in interscapular brown adipose tissue: relationship between metabolic profile and antioxidative defense

Interscapular brown adipose tissue (IBAT) hyperplasia involves a new metabolic and structural profile, resulting from acclimation of animals to a cold environment. Cold-induced changes of several antioxidative defense (AD) components in IBAT and their interrelationship with uncoupling protein 1 (UCP1), sympathetic innervation and apoptosis were studied using cold-acclimated adult rat males (4 +/- 1 degrees C, 45 days). Their age-matches were maintained at 22 +/- 1 degrees C serving as the controls. In cold-adapted rats, activities of CuZn- and Mn-superoxide dismutase (SOD) and apoptosis were reduced, while catalase (CAT), glutathione peroxidase (GSH-Px), glutathione S-transferase (GST) activities and glutathione (GSH) content were increased compared to the control. IBAT mass, protein content, plasma free fatty acid (FFA) concentration, sympathetic innervation and UCP1 level were significantly increased in cold-acclimated group compared to the corresponding control. These results suggest that decreased CuZn and MnSOD activities in IBAT represent an adaptive response due to UCP1-induced mitochondrial uncoupling. Additionally, intensive fatty acid oxidation led to an increased H(2)O(2) production which resulted in increased CAT, GSH-Px and GST activities and GSH level. Generally speaking, cold-induced changes of AD in the IBAT are closely connected with newly established metabolic profile in this tissue, thus making an important part of the entire tissue homeostasis including cell survival.

The effects of l-arginine and l-NAME supplementation on redox-regulation and thermogenesis in interscapular brown adipose tissue

Changes in inducible nitric oxide synthase (iNOS) protein levels and its relationship with the hyperplasia and uncoupling protein 1 (UCP1) levels were examined in interscapular brown adipose tissue (IBAT) of adult rat males receiving l-arginine (l-Arg; 2.25%) or N-nitro-l-arginine methyl ester (l-NAME; 0.01%)as a drinking liquid and maintained at low (4±1°C) or room(22±1°C) temperature for 45 days.

Cold generally diminished both iNOS immunopositivity and protein level in IBAT, as well as the rate of apoptosis. Among groups acclimated to cold,higher iNOS immunopositivity and protein levels were detected only in the l-Arg-treated group. Furthermore, chronic l-Arg treatment increased IBAT mass and UCP1 protein content, while l-NAME had an opposite effect, decreasing both IBAT mass and UCP1 protein level, as compared to the control maintained at 4±1°C.

These data suggest that nitric oxide (NO) produced by iNOS could also contribute to overall NO-associated regulation of thermogenesis in IBAT. Namely, that iNOS, i.e. NO, in correlation with enhanced thermogenesis,additionally induced IBAT hyperplasia and UCP1 level compared to that induced by low temperature. Cooperative action of decreased apoptosis accompanied by increased tissue hyperplasia and UCP1 level, observed in IBAT of cold-acclimated rats, would be a way of meeting the metabolic requirements for increased thermogenesis.

Mice with targeted disruption of the Dio2 gene have cold-induced overexpression of the uncoupling protein 1 gene but fail to increase brown adipose tissue lipogenesis and adaptive thermogenesis

The Dio2 gene encodes the type 2 deiodinase (D2) that activates thyroxine (T4) to 3,3',5-triiodothyronine (T3), the disruption of which (Dio2(-/-)) results in brown adipose tissue (BAT)-specific hypothyroidism in an otherwise euthyroid animal. In the present studies, cold exposure increased Dio2(-/-) BAT sympathetic stimulation approximately 10-fold (normal approximately 4-fold); as a result, lipolysis, as well as the mRNA levels of uncoupling protein 1, guanosine monophosphate reductase, and peroxisome proliferator-activated receptor gamma coactivator 1, increased well above the levels detected in the cold-exposed wild-type animals. The sustained Dio2(-/-) BAT adrenergic hyperresponse suppressed the three- to fourfold stimulation of BAT lipogenesis normally seen after 24-48 h in the cold. Pharmacological suppression of lipogenesis with betabeta'-methyl-substituted alpha-omega-dicarboxylic acids of C14-C18 in wild-type animals also impaired adaptive thermogenesis in the BAT. These data constitute the first evidence that reduced adrenergic responsiveness does not limit cold-induced adaptive thermogenesis. Instead, the resulting compensatory hyperadrenergic stimulation prevents the otherwise normal stimulation in BAT lipogenesis during cold exposure, rapidly exhausting the availability of fatty acids. The latter is the preponderant determinant of the impaired adaptive thermogenesis and hypothermia in cold-exposed Dio2(-/-) mice.

An ultrastructural study of brown adipose tissue in pre-term human new-borns

The ultrastructure of brown adipose tissue (BAT), the thermogenic type of adipose tissue, was investigated in biopsies from 4 pre-term human new-borns delivered at 25-27 week's gestational age and compared with peri-renal brown fat from 2 adult patients with phaeochromocytoma (a condition of brown fat activation). The cell size of brown adipocytes was smaller in pre-term new-borns than in adult patients; adipocytes were almost exclusively multilocular, suggesting active thermogenesis. In 3 of the pre-term new-borns, brown adipocyte ultrastructure indicated a good to high degree of differentiation (in particular at the level of mitochondria) as compared with activated brown fat cells found in adult patients; in one pre-term infant the tissue morphology was obviously suggestive of an earlier, proliferative phase of development and the differentiation process of brown adipocytes could be traced in some detail. The results suggest that (a) brown adipose tissue may be fairly well-differentiated and thermogenetically active in pre-term human new-borns weighing about 750 g at birth; (b) brown adipocytes apparently develop from vessel-associated cells, the early signs of adipocyte differentiation being glycogen and lipid accumulation; (c) the ultrastructural morphology of mitochondria of mitochondria in well-differentiated BAT from pre-term infants can strictly resemble that found in active brown adipose tissue of adult phaeochromocytoma patients.

Quantitative evaluations of gap junctions in old rat brown adipose tissue after cold acclimation: a freeze-fracture and ultra-structural study

The morphological and functional modifications of brown adipose tissue (BAT), the tissue responsible for non-shivering thermogenesis, are well established during the phases of active stimulation (i.e. neonatal period and cold acclimation) in young animals. The 'active' brown adipocytes are filled with numerous small lipid vacuoles and large mitochondria packed with cristae rich in the protonophore uncoupling protein (UCP), whereas the 'quiescent' cell shows larger, confluent vacuoles and smaller mitochondria with rarefied cristae poor of the uncoupling protein. It is well known from literature that also gap junctions (gjs), responsible for the electrical coupling among adjacent adipocytes, modify their size following the physiological stimulus in young animals. This is in agreement with the morphology of the functionally active brown adipocyte, i.e. the multilocular, UCP-positive cell. Although the presence of the BAT in old animals is well documented, less is known about its reactivity to physiological stimuli. The present work demonstrates that after cold acclimation brown adipocytes of old rats (2 years) change their ultrastructure in a similar way as in young rats. A quantitative analysis of gap junction areas on replicas obtained by the freeze fracture technique, showed that gj increase in size (mean area 53.2 vs 110.4 x 10(-3) microns2, p = 0.003). All these morphological modifications are quite similar to those observed in BAT of young and young adult rats, supporting the hypothesis of a physiological role of brown adipose tissue at every age.

Epididymal white adipose tissue after cold stress in rats. I. Nonmitochondrial changes

Epididymal adipose tissue in the rat is generally considered to be "pure" white adipose tissue (WAT) with a characteristic structure and function. Previous studies in cats have, however, indicated that adipose tissue with the morphological appearance of WAT could be converted into a tissue with the morphological appearance of brown adipose tissue (BAT) by intermittent cold stress. The present electron microscopic and morphometric study describes the effect of intermittent cold stress on the epididymal WAT of young rats. The tissue volume decreased markedly as did the lipid content. The mitochondrial volume increased dramatically. The extracellular matrix was vastly reduced as was the thickness of the plasma membrane, and the number of gap junctions between adipocytes increased markedly. Indications of neoinnervation and neovascularization were observed. A great abundance of preadipocytes indicated proliferative activity of the endothelium. The low amount of lipid droplets and a relative abundance of smooth and rough endoplasmic reticulum. Golgi apparatus, and lysosomes in the epididymal WAT of cold-stressed rats gave the cells the morphological appearance of young adipocytes or preadipocytes whereas the hypertrophic and hyperplastic mitochondria, the relative paucity of ribosomes on lipid droplet membranes, and the increased innervation and vascularization gave the cells the morphological characteristics of brown adipose tissue.

Epididymal white adipose tissue after cold stress in rats. II. Mitochondrial changes

We have previously shown that after severe cold stress of rats the epididymal white adipose tissue (WAT) acquires many of the morphological characteristics (innervation, vascularization, appearance of adipocytes) of brown adipose tissue (BAT). In the present study, the mitochondrial characteristics have been analyzed. Mitochondria from the epididymal fat pad of cold-stressed rats became enlarged and had a volume 1.7 times greater than that in the control group (0.5 microns 3 in the experimental versus 0.3 microns 3 in the control group). The mitochondria occupied about 60% of the cytoplasm (14% in the control group), thus approaching the highest value reported for any cell. The straight or slightly wavy cristae completely traversed the width of the mitochondria and occupied an area of 26 microns 2/1 microns 3 of mitochondrion in the experimental adipose tissue (7 microns 2 in the control group) and 15 microns 2/1 microns 3 of cytoplasm (1.4 microns 2 in the control). The mitochondrial matrix became electron lucid and could contain lamellar whorls, as could the surface of the mitochondria. These mitochondria of epididymal WAT resembled, both morphologically and morphometrically, mitochondria in the BAT of cold-exposed rodents. In the epididymal mitochondria, immunoelectron microscopy did not reveal the presence of the BAT-specific uncoupling protein thermogenin, nor could the slot-blot technique detect thermogenin mRNA. We conclude that even under these extreme conditions of cold stress, WAT cannot adopt the thermogenin-dependent thermogenesis of BAT. The dramatic mitochondriogenesis can be interpreted only as being indicative of an extremely high metabolism in the tissue, thus placing unprecedented pressure on the energy turnover capacity of the cell.

Development of adipose tissues

Studies on the development of brown and white adipose tissues and their relationship to ordinary connective tissue are the subject of the present review, which is updated to the fall of 1985. Primordial entities described as "primitive organs" have been noted at sites of adipose tissue development by numerous investigators. These "primitive organs" are clearly delineated from surrounding connective tissue and possess a well-defined vascular network in the interstices of which cellular organization takes place. The precursor cells of brown and white adipocytes appear to acquire their distinctive cytogenetic properties at a very early stage in the embryo. These progenitor cells temporarily exhibit structural similarities to fibroblasts and endothelial cells. This resemblance has led to speculation that fibroblasts and/or endothelial cells may be ancestral to adipocytes. However, recent in vivo and in vitro observations suggest that the brown adipose precursor cell is morphogenetically distinct from the white adipose precursor cell on one hand, and from fibroblasts and endothelial cells on the other. In vitro studies have also shown that the pericytic elements present in both brown and white adipose tissue depots in the adult are quiescent precursor cells that may be recruited under certain circumstances. Areas for further inquiry by means of recently developed techniques are indicated.

Brown adipose tissue. Its in vivo immunology and involvement in neuroimmunomodulation

The material presented here summarizes the bulk of the presently available immunologic data bearing upon the in vivo relationship between brown adipose tissue and the immune system. The experiments were carried out in rats adipectomized (by surgical excision of the interscapular brown adipose tissue at birth), thymectomized (by neonatal removal of the thymus), adipectomized and thymectomized, and corresponding sham-operated controls. The following immune phenomena were studied: antibody production to soluble and corpuscular antigens; Arthus and delayed hypersensitivity skin reactions to bovine serum albumin; rejection of allogeneic skin and thyroid grafts; lymph node enlargement in a host-versus-graft reaction; experimental allergic encephalomyelitis and thyroiditis; immune response in normal animals treated with extracts from brown adipose tissue; allergic encephalomyelitis in thymoadipectomized animals; plaque-forming cell response and hemagglutinating antibody titers in animals injected with met-enkephalin and leu-enkephalin; and survival rate of adipectomized mice inoculated with Sarcoma-I cells. The results indicated that the cell-mediated immune reactions were potentiated in adipectomized rats. Antibody production was not significantly changed by neonatal adipectomy. Adipectomized mice, inoculated with Sa-I tumor cells, survived longer than controls, thus indicating that adipectomy made possible the recognition of discrete histocompatible differences between Sa-I cells and A/JAX mice. Adipectomy increased the ability of rats to develop autoimmune diseases. Saline extracts from brown adipose tissue of newborn rats suppressed hypersensitivity skin reactions in normal adult rats. Thymoadipectomized rats showed an almost normal ability to develop allergic encephalomyelitis, a finding that suggested that the potentiating influence of adipectomy on encephalomyelitis was neutralized by thymectomy. It appears that brown adipose tissue functions as a natural antagonist of the thymus. Enkephalins were found to be more effective immunosuppressors in adipectomized than in normal animals. The last finding establishes a functional link between brown adipose tissue and neuropeptides. It seems that the potentiation of immune response in adipectomized animals is effected by altered release of yet unidentified mediators and modulators. The evidence indicates that brown adipose tissue, in which neurohumoral activity occurs, may be an important component of an integrated immunoneuroendocrine system.

The effect of intermittent cold treatment on the adipose tissue of the cat. Apparent transformation from white to brown adipose tissue

Young cats (Felis domestica), aged 10-13 weeks, were intermittently exposed to a temperature of -30 degrees C for two periods of 1 hr per day. Animals were sacrificed on the 7th day and adipose tissue from the perirenal, pericardial, axillary, interscapular, and subcutaneous-inguinal depots was examined by electron microscopy and analysed stereologically. All examined depots were morphologically changed after cold treatment. Adipose tissue of perirenal, pericardial, and axillary depots showed a greater decrease in lipid content than the interscapular and subcutaneous-inguinal depots, but other changes were similar. Compared to the control group, which consisted of typical white adipose tissue, the diameter of adipose cells examined after cold treatment was diminished, in extreme cases to 18 micron (from 75 micron in the control group). The number of capillaries per cell was doubled (as evaluated on semithin sections). The most dramatic changes were observed in the mitochondria. Their volume increased to 0.48 micron 3 (from 0.13 micron 3 in the control), and the surface density of mitochondrial cristae per mitochondrial volume increased to 50 micron 2/micron 3 (from 32 in the control). Pleomorphism in mitochondrial size and inner structure and the presence of intramitochondrial electron-dense bodies and crystalline structures led us to conclude that the cold stress induced an increase in the absolute number of mitochondria in the adipose cells. The adipose tissue after cold treatment thus morphologically resembled the brown adipose tissue of cold-acclimated rodents. This implies that the adipose tissue of young cats can change its morphology and function, depending on the requirements of the organism.

Rapid changes in number of GDP binding sites on brown adipose tissue mitochondria

GDP binding to brown adipose tissue (BAT) mitochondria increased more than twofold in 20 min when rats were moved from 27 to 4 degrees C. When animals housed at 4 degrees C for 2 h were returned to 27 degrees C, GDP binding decreased sharply in 20 min and returned to control levels in 2 h. These results are consistent with a rapid unmasking and remasking of GDP binding sites. GDP binding to mitochondria from warm and acutely cold treated rats was not modified by prior swelling, by freeze-thawing, nor by sonication of the mitochondria before assay. GDP-inhibitable proton conductance, as measured by passive swelling, was unaffected by this brief exposure to cold but more than doubled in rats kept at 4 degrees C for 10 days. We hypothesize that the rate of GDP-inhibitable swelling may be a reflection of uncoupling protein concentration in the BAT mitochondria, whereas physiological thermogenic activity is more appropriately indicated by GDP binding. The alterations in binding activity appear not to be due to changes in the mitochondrial membrane integrity.

The effects of age, dietary restriction, exercise and maternity on the abundance and volume of adipocytes in twelve adipose depots of adult guinea-pigs

1. The mean adipocyte volume and cellularity of adipose tissue in twelve anatomically defined depots were measured in 190 virgin and reproductive guinea-pigs aged 6 months to 2 years, maintained on five different regimens of diet and exercise. 2. The total adipocyte complement was constant up to the age of about 10 months and increased by 65-70% during the 2nd year of life. At constant percentage body-weight as fat, age-related accumulation of adipocytes was accompanied by reduction in average adipocyte volume. A period of high percentage body-weight as fat was not a necessary antecedent to age-related accumulation of adipocytes, and the effect was not observed in specimens that exercised regularly. 3. In guinea-pigs over 13 months old, changes in adipose tissue cellularity made a major contribution to total fatness. The mean volume of samples of adipocytes was a satisfactory indicator of fatness only in younger specimens in which adipose tissue cellularity was not changing. 4. The lean body mass and the total adipocyte complement were lower in guinea-pigs on the sedentary, restricted-diet regimen, whether the regimen began at the age of 19 weeks or 31 weeks, but the depots studied were not equally affected. Both moderate and strenuous exercise on an ad lib. diet caused a reduction in the percentage body-weight as fat in males but not in females. The total adipocyte complement and lean body mass were unchanged, although the males became almost as thin following exercise as those on the restricted-diet regimen. 5. Among guinea-pigs under 400 d old, there were no significant differences between males and virgin females in the site-specific volume of adipocytes relative to the size of those in other depots of the same specimen; there was only one significant difference in this index between the older and the younger specimens. The diet and exercise regimens modified the site-specific adipocyte volume relative to those in other depots; adipocytes under the trapezius muscle of the neck (UMN), at the interscapular depot (HUMP) and those in the depots anterior to the forelimb became relatively smaller following exercise, while those in the popliteal fat mass were relatively larger. Adipocytes in the UMN and HUMP also became more numerous relative to those in the other depots following both moderate and strenuous exercise. Those in the groin site, the intra-abdominal depots and the intermuscular depots became relatively smaller following dietary restriction without exercise.(ABSTRACT TRUNCATED AT 400 WORDS)

Histopathology of interscapular brown adipose tissue, thyroid, and pancreas in 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD)-treated rats

The time course of histological changes was studied in rats lethally intoxicated (150 micrograms/kg) with 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD). In addition to TCDD-caused tissue damage described by others, the thyroid, pancreas, and interscapular brown adipose tissue (IBAT) were identified as tissues affected by TCDD. Because histological changes in the thyroid and pancreas occurred late (7 days after dosing), these effects are viewed as secondary due to altered hormonal homeostases. Both light and electron microscopic examination of IBAT identified this tissue as a target in TCDD toxicity. Histological changes in IBAT are characterized by three phases: (1) "fatty" IBAT (Days 1 to 3 after dosing); (2) fat depletion accompanied by glycogen accumulation (Days 4 to 7 after dosing); and (3) complete fat and glycogen depletion together with massive cellular damage (Days 8 to 14), particularly affecting the mitochondria. It is concluded that brown adipose tissue is a primary target in TCDD toxicity. It seems that destruction of brown adipose tissue by TCDD leads to an energy imbalance resulting in reduced oxygen consumption which forces animals to contribute a greater proportion of energy to the maintenance of their body temperature by anaerobic pathways. It is suggested that this less efficient energy utilization is the cause of a wasting syndrome.

Immunocytochemical investigation of native matrix granules of the rat heart mitochondrion

We have examined the ultrastructure and the protein content of native matrix granules (NMG) in rat heart mitochondria, by postembedding immunocytochemistry. Cytochrome c oxidase was found to be present in these granules. It is believed that these granules contain incomplete inner mitochondrial membrane fractions, which can be incorporated in the membrane after stimulation of the metabolism.

Brown adipose tissue is a target tissue in 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) induced toxicity

This paper demonstrates by electron microscopy that interscapular brown adipose tissue (IBAT) is a target tissue of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) in rats. Because of the known importance of IBAT in energy metabolism, it is suggested that brown adipose tissue may be a major target tissue in the toxicity of TCDD.

The pre- and postnatal development and ageing of interscapular brown adipose tissue in the rat

Development and ageing changes in interscapular brown adipose tissue have been studied in white Wistar rats by light, fluorescence and electron microscopy. Cellular aggregation was noted in the fetal interscapular area on the 15th day of gestation and vascularised primitive lobules of brown adipose tissue became unequivocally identifiable on the 17th day in utero. Brown adipocyte precursors appeared to be derived directly from mesenchymal cells and were uniquely characterised by larger (0.8-1.7 micrometer diameter) mitochondria. Numbers of these precursors cells (pre-adipocytes) were seen in mitosis during intrauterine life. Pericapillary cells similar in appearance to embryonic pre-adipocytes were regularly observed within brown fat lobules throughout later life. Cardinal features noted in mature brown adipose tissue were parenchymal cells with a multilocular lipid distribution and numerous large mitochondria with distinctive in-parallel cristae, as well as an extensive vascular network and a dense catecholaminergic vasomotor and parenchymal innervation. Brown adipocytes generally retained a multilocular lipid distribution into old age, and although the catecholaminergic fluorescence of the nerves supplying the tissue was reduced, a widespread distribution of noradrenergic vasomotor and parenchymal nerves and of nexuses between brown adipocytes continued to be demonstrable by electron microscopy in the brown adipose tissue of senile rats.

Seasonal adaptation of brown adipose tissue in the Djungarian Hamster

The composition and oxidative capacity of brown adipose tissue (BAT) were investigated in Djungarian hamsters kept under natural photoperiod, either indoors at neutral Ta (23 degrees C) or under outdoor conditions. BAT comprises up to 5% of the body weight in summer/indoor hamsters, with lipid representing 86% of the total tissue mass. Tissue mass and thermogenic capacity are inversely related during seasonal adaptation: 30% decrease of total DNA, accompanied by extensive lipid depletion, reduces the amount of BAT by almost 60% during acclimatization from summer/indoor to winter/outdoor conditions. Mitochondrial protein in BAT is increased by a factor of 2.6 concomitantly, and by a factor of 4 when related to body weight (body weight reduction 36%). Cytochrome oxidase activity in different brown fat deposits varies by up to 150% in summer/indoor hamsters; depending on the fat pad, the enzyme activity is increased 200%-700% during adaptation to winter/outdoor conditions. Natural photoperiod is decisive in determining the seasonal adaptation of DNA content in BAT and of body weight. Short photoperiod alone may lead to depletion of lipid content of BAT and thus decrease the tissue mass practically to the lowest seasonal level, even though both parameters may be also influenced by Ta. One third of the maximum adaptive increase of tissue mitochondria may be attributed to seasonal changes in photoperiod and up to two thirds to Ta. Photoperiod establishes a fixed fundament of slow-reacting functional adaptation of BAT, whereas the effect of decreased Ta depends on the rate and duration of cold influence.

Brown adipose tissue from fetal rhesus monkey (Macaca mulatta): morphological and biochemical aspects

Brown adipose tissue (BAT) from fetal rhesus monkeys microscopically resembled adult rodent BAT containing multiocular fat cells with numerous mitochondria. Mitochondrial carnitine palmitoyl transferase activity was lower than that in adult rodents and adenine nucleotide translocase activity was similar to that reported for rats. Rhesus monkey BAT mitochondria (BATM) possess an uncoupling protein that is characteristic of BAT as evidenced by the binding of [3H]GDP, the inhibition by GDP of the high Cl- permeability or rapid alpha-glycerol-3-phosphate oxidation. Electrophoretic analysis of BATM showed the presence of a 32,000 mol.wt protein which was enriched by procedures established for the isolation of BATM uncoupling protein.

The development of cold-induced thermogenesis and the structure of brown adipocyte mitochondria in genetically-obese (ob/ob) mice

The onset of cold-induced thermogenesis was studied in a strain of mice which produced among their offspring genetically-obese (ob/ob) individuals. A thermogenic response was present in a majority by day 5 after birth. The thermogenic response to cold was measured on days 5, 10 or 15 after birth, and the animals reared and the onset of obesity noted. The correlation between the subsequent development of obesity and a poor thermogenic response in early life was low. A poor thermogenic response at day 15 was associated with the presence in brown adipocytes of mitochondria with disordered internal structures. At day 42 both non-obese and obviously-obese mice showed a similar thermogenic response to moderate cold exposure. It would seem that in this strain of mice disordered internal mitochondrial structure in brown adipose tissue is associated with a poor thermogenic response to cold, but not invariably with the subsequent onset of obesity.

Quantitative evaluation of gap junctions in rat brown adipose tissue after cold acclimation

The decrease in the metabolic capacity of rat brown adipose tissue during the late postnatal period can be reversed by cold acclimation of the animals. In order to find out whether a parallel decrease in capability for intercellular communication observed during this period is also reversed by cold acclimation, gap junction size and number per unit area of cell surface have been quantified in freeze-fracture replicas; cell diameters have been measured in semi-thin sections. It was found that the specific number of gap junctions remains unchanged during cold acclimation. However, the mean gap junction size increases by 75% and the ratio of gap junctional area per cell volume, an index for intercellular exchange capacity, is doubled. This result illustrates further the parallelism between metabolic capacity and cell communication in brown fat.

Beta-adrenergic stimulation of lipoprotein lipase in rat brown adipose tissue during acclimation to cold

Lipoprotein lipase activity in adult rats was investigated in animals subjected to cold and to different hormonal treatments. In contrast to changes in tissue wet weight and total protein content, which showed a lag time of about 1 day, lipoprotein lipase activity was markedly (fourfold) increased after only 4 h in the cold. Total lipoprotein lipase activity reached a plateau already after 1-3 days, whereas wet weight and protein content did not plateau until 3 wk. Neither insulin nor glucose injections could mimic the cold-induced increase in lipoprotein lipase activity seen after 4 h. However, the effect of norepinephrine injections was identical to the effect of cold. The beta-agonist isoprenaline was as effective as norepinephrine, whereas the alpha-agonist phenylephrine had no effect. The beta-antagonist propranolol inhibited the cold-induced increase in lipoprotein lipase activity. It is concluded that, in contrast to white adipose tissue, brown adipose tissue lipoprotein lipase is stimulated in vivo by a beta-adrenergic mechanism and that it is this beta-adrenergic mechanism that is responsible for the rapid recruitment of lipoprotein lipase during cold exposure.

Development of brown fat cells in monolayer culture. II. Ultrastructural characterization of precursors, differentiating adipocytes and their mitochondria

The stroma of mature brown fat has been shown to contain cells which can proliferate and accumulate fat in monolayer cultures, and which have inherent characteristics distinct from those of white fat precursor cells. The purpose of the present investigation was to characterize by electron microscopic analysis these brown fat cells and their subsequent development when they were grown in vitro. By comparison with the existing ultrastructural data on brown fat in situ, it could thus be determined whether or not the precursor cells have the capacity to differentiate in culture. The stromal-vascular fraction isolated from the brown fat of weaned rats was identified as containing adipocyte stem cells, preadipocytes, endothelial cells and a few mature adipocytes. During the first week in culture (i.e., growth phase to confluence), when multilocular fat accumulation occurred, the mitochondria of the preadipocytes developed cristae and matrix granules, as they do in differentiating brown fat in situ. Such granules have been shown to be a sign of intense inner membrane synthetic activity. After confluence, the mitochondria regressed in internal structure and became morphologically more similar to white fat mitochondria. It was concluded that mature brown fat contains precursor cells which can differentiate in vitro. However, this differentiation was incomplete, and the necessity of specific factors for a full mitochondrial development in brown fat is discussed.

Development of brown fat cells in monolayer culture. I. Morphological and biochemical distinction from white fat cells in culture

The ability of cells from the stromal-vascular fraction of rat brown adipose tissue to develop into adipocytes in primary cell cultures was investigated. Comparison was made with precursor cells isolated by the same procedure from the white adipose tissue of the same animals and cultured in parallel under identical conditions. The culture procedure used allowed the cells isolated from both tissues to rapidly proliferate and differentiate. During the first week in culture the brown fat cells grew to confluence and accumulated fat in a multilocular way. During the second week, further fat was accumulated, but the cells remained multilocular. Analysis of the parallel white fat cell cultures revealed clear differences between the two adipocyte types, although the rates of cell growth were identical. Measurement of the size of the cellular lipid inclusions as a function of the time in culture indicated a much higher number of fat droplets larger than 30 micron in the white adipocytes. Moreover, after isolation of pelleting fractions of both cultured cell types, comparative functional analysis of their mitochondria by oxygen consumption measurement, as well as direct cytochrome-c-oxidase determinations, showed a significantly higher amount of mitochondria in the brown fat cell fractions than in the white fat cell fractions. It was concluded that mature brown fat contains precursor cells which can proliferate and develop into adipocytes in monolayer cell culture and which have inherent characteristics distinct from those of white fat precursor cells.

The toxicity of menthol in short-term bioassays

The toxicity of menthol was studied on 4 different in vitro systems covering organ, cellular and subcellular levels. The 50% inhibitory concentration (IC50) for the cellular and subcellular systems ranged from 0.32 mM to 0.76 mM. At a concentration of 0.5 mM menthol the receptor mediated respiratory stimulation of isolated brown adipocytes was markedly inhibited while the intracellular mitochondrial functions were still unaffected. However, using isolated rat liver mitochondria 0.5 mM menthol was found to cause increase in the 'state 4' respiratory rate and osmotic swelling, indicating a leakage of the mitochondrial membrane. We therefore suggest that one effect of menthol is a deterioration of biological membranes. For the determination of the cellular toxicity of foreign compounds isolated brown adipocytes represents a convenient and sensitive model, providing the possibility to localize the primary site of action in terms of mitochondrial or extramitochondrial level.

Trophic response of rat brown fat by glucose feeding: involvement of sympathetic nervous system

Brown adipose tissue has earlier been suggested as an important site of the diet-induced thermogenesis that results from cafeteria feeding in rats. The aim of the present communication has been to see if any defined component of this diet can mimic the effects of the diet on the trophic response of brown fat and if these effects are mediated by the sympathetic nervous system. Rats fed a lipid emulsion did not show hypertrophy of brown adipose tissue. Rats fed a glucose solution, whether voluntarily or by force feeding, showed a clear trophic response of brown fat, as seen by the morphology of the tissue and its increased wet weight, increased protein content, increased total and specific cytochrome c oxidase activity, and increased mitochondrial guanosine diphosphate binding. Chemical sympathectomy of young rats by guanethidine prior to glucose feeding impaired the glucose-induced effects on brown fat. beta-Adrenergic blockade in adult rats also tended to depress the glucose effect. Consequently we conclude that chronic glucose ingestion can mimic cafeteria feeding with respect to the trophic response of brown fat and that an intact sympathetic nervous system is required for the mediation of the glucose effect to the brown adipose tissue.

Cold-induced developmental changes in fat cell size and number in brown adipose tissue of the rat

Seven-week-old Long-Evans rats were acclimated to a constant temperature of either 28 degrees C (control group) or 5 degrees C (cold-acclimated group). Cold acclimation induced a 70% increase in the interscapular brown adipose tissue (IBAT) relative mass, a 35% increase in DNA content, and a 44% decrease in triglyceride (TG) content, which resulted in a 51% decrease of the TG/DNA ratio. A procedure is described by which brown fat cells were isolated, with a yield of 21% from the IBAT of the control group and of 38% in the cold-acclimated group. In both groups, the brown fat cells accounted for 35-37% of the total cells in the tissue. Cold acclimation induced decreases in the mean fat cell diameter (about 20%), the mean fat cell TG content (50%), and the fat cell TG/DNA ratio (50%). The total number of IBAT fat cells was significantly increased in cold-acclimated rats. It is concluded that cold acclimation involves a hyperplasia of the IBAT, associated with a decrease of fat cell size without any alteration of the fat cell-to-nonfat cell ratio.

Seasonal changes in ultrastructure of brown adipose tissue in the common shrew (Sorex araneus l.)

Seasonal changes have been detected in the ultrastructure of brown adipose tissue (BAT) of the common shrew, Sorex araneus (a true nonhibernator) living under natural conditions and collected at the time when the most representative growth phase of the animal for the given season could be expected. In summer and autumn, BAT is characterized by the presence of large, regular, spherical lipid droplets and mitochondria closely adhering to one another. During winter, mitochondria possess densely packed cristae and are dispersed in the cytoplasm, sometimes invaginating into lipid droplets; the latter are diminished and often irregular in contour. The BAT in winter specimens is distinguished also by a large amount of blood capillaries penetrating the tissue. In spring, mitochondria of BAT are found more frequently adhering to each other, and are characterized by loosely arranged cristae. In addition to the spherical lipid droplets, agglomerations of lipid material may be found in the cytoplasm. The observed seasonal fluctuations in the ultrastructure of BAT in the shrew correspond to the metabolic rhythm of this animal. The latter point is discussed.

Cold adaptation in the rat: increased brown fat peroxisomal beta-oxidation relative to maximal mitochondrial oxidative capacity

Brown fat hypertrophy in the rat resulting from cold adaptation is shown here to involve increased mitochondrial, peroxisomal, and lysosomal enzyme activities. Mitochondrial activity in homogenates of brown fat was estimated as cytochrome c oxidase. After 4 wk in the cold (+5 C), the total activity was 3-fold higher than in control rats, although the specific activity was somewhat lower. Peroxisomal activity was followed as cyanide-insensitive palmitoyl-CoA-dependent NAD+ reduction (palmitoyl-CoA oxidase) and as catalase. The total activity of both palmitoyl-CoA oxidase and catalase was more than 10-fold higher than in controls and the specific activity about 3-fold higher. Acid phosphatase, used as a lysosomal marker, showed a 6-fold higher total activity and almost twice as high specific activity. The relatively greater increase in peroxisomes and lysosomes compared with mitochondria indicates an involvement in thermogenesis also for these organelles.

Effects of tobacco smoke compounds on the noradrenaline induced oxidative metabolism in isolated brown fat cells

The effect on cell metabolism of 320 individual smoke components have been investigated by measuring their inhibition of noradrenaline induced respiration in isolated hamster brown fat cells. The compounds are representative of the gaseous and semivolatile phases of tobacco smoke. The strongest inhibitors were found within the groups of aliphatic alcohols, aldehydes and acids, of alkylated phenols and indoles and of alpha,beta-unsaturated aliphatic aldehydes and ketones. Some of the aliphatic aldehydes and acids significantly increased the basal respiration of the cells, probably by acting as substrates and/or uncoupling of mitochondrial respiratory control.

Thermogenic mechanisms and their control

The alterations in properties of mitochondria and of plasma membrane of brown adipose tissue and skeletal muscle of cold-acclimated rats are reviewed in order to bring out any adaptive changes which are related to the mechanism of nonshivering thermogenesis, and thus to the enhanced calorigenic action of catecholamines known to exist in these animals. Since prevention of the morphological changes in the mitochondria by treatment of the animals with oxytetracycline during acclimation to cold also prevents the development of the enhanced calorigenic response to the catecholamines it is concluded that the changes noted are either a cause of the development of the increased capacity for nonshivering thermogenesis during acclimation to cold or are secondary to the operation of nonshivering thermogenesis.