Effects of two types of energy restriction on methylation levels of adiponectin receptor 1 and leptin receptor overlapping transcript in a mouse mammary tumour virus-transforming growth factor-α breast cancer mouse model.

The role of adiponectin and leptin signalling pathways has been suggested to play important roles in the protective effects of energy restriction (ER) on mammary tumour (MT) development. To study the effects of ER on the methylation levels in adiponectin receptor 1 (AdipoR1) and leptin receptor overlapping transcript (Leprot) genes using the pyrosequencing method in mammary fat pad tissue, mouse mammary tumour virus-transforming growth factor-α (MMTV-TGF-α) female mice were randomly assigned to ad libitum (AL), chronic ER (CER, 15 % ER) or intermittent ER (3 weeks AL and 1 week 60 % ER in cyclic periods) groups at 10 weeks of age until 82 weeks of age. The methylation levels of AdipoR1 in the CER group were higher than those in the AL group at week 49/50 (P < 0·05), while the levels of methylation for AdipoR1 and Leprot genes were similar among the other groups. Also, the methylation levels at CpG2 and CpG3 regions of the promoter region of the AdipoR1 gene in the CER group were three times higher (P < 0·05), while CpG1 island of Leprot methylation was significantly lower compared with the other groups (P < 0·05). Adiponectin and leptin gene expression levels were consistent with the methylation levels. We also observed a change with ageing in methylation levels of these genes. These results indicate that different types of ER modify methylation levels of AdipoR1 and Leprot in different ways and CER had a more significant effect on methylation levels of both genes. Epigenetic regulation of these genes may play important roles in the preventive effects of ER against MT development and ageing processes.

Effect of obesity on breast cancer development.

In recent years, obesity has been identified as a risk factor for the development of breast cancer in postmenopausal women, and it has been associated with a poor outcome. Many factors appear to be important in the mechanism of this increased risk, including estrogen, estrogen receptors, and the adipokines leptin and adiponectin. Estrogen, a potent mitogen for mammary cells, has long been implicated in the development of mammary tumors. Because adipose-associated aromatase activity increases the conversion of androgen to estrogen, mammary adipose tissue is thought to be an important source of local estrogen production. Leptin, which increases in the circulation in proportion to body fat stores, has been demonstrated in vitro to promote breast cancer cell growth. Animal models have also identified leptin as an important factor for the development of mammary tumors. In contrast to leptin, serum adiponectin concentrations are inversely related to body fat stores, and the addition of adiponectin to human breast cancer cells reduces cell proliferation and enhances apoptosis. This review explores the relationship between these factors and the development of mammary cancer in humans and mouse models.

Effects of adiponectin on breast cancer cell growth and signaling.

Obesity is a risk factor for postmenopausal breast cancer. Adiponectin/Acrp30 is lower in obese individuals and may be negatively regulating breast cancer growth. Here we determined that five breast cancer cell lines, MDA-MB-231, MDA-MB-361, MCF-7, T47D, and SK-BR-3, expressed one or both of the Acrp30 receptors. In addition, we found that the addition of Acrp30 to MCF-7, T47D, and SK-BR-3 cell lines inhibited growth. Oestrogen receptor (ER) positive MCF-7 and T47D cells were inhibited at lower Acrp30 concentrations than ER-negative SK-BR-3 cells. Growth inhibition may be related to apoptosis since PARP cleavage was increased by Acrp30 in the ER-positive cell lines. To investigate the role of ER in the response of breast cancer cells to Acrp30, we established the MDA-ERalpha7 cell line by insertion of ER-alpha into ER-alpha-negative MDA-MB-231 cells. This line readily formed tumours in athymic mice and was responsive to oestradiol in vivo. In vitro, MDA-ERalpha7 cells were growth inhibited by globular Acrp30 while the parental cells were not. This inhibition appeared to be due to blockage of JNK2 signalling. These results provide information on how obesity may influence breast cancer cell proliferation and establish a new model to examine interactions between ER and Acrp30.

Effect of high fat diet on body weight and mammary tumor latency in MMTV-TGF-alpha mice.

OBJECTIVE: The role of high fat diets in breast cancer/mammary tumor (MT) development is controversial. This may be partially attributable to variable effects of high fat diets on body weight. Here, we used a moderately high fat diet (32.5% fat calories) expected to cause obesity in most mice, but predicted to result in some mice remaining in the weight range of mice fed the low fat diet (11% fat calories). This provided the opportunity to compare mice fed the high fat diet exhibiting different body weights and mice of similar weight consuming high vs low fat diets. EXPERIMENTAL METHODS: Transgenic MMTV-TGF-alpha mice, a model of postmenopausal breast cancer, consumed a low fat diet, that is, chow-fed (n=25) or a moderately high fat diet from 10 weeks of age (n=51). Body weight at 34 weeks of age was used to assign high fat diet mice to obesity-prone>overweight>obesity-resistant groups (n=17) (P<0.0001). Mice were euthanized when MTs developed or at 85 weeks of age. RESULTS: Final body weights were highest in obesity-prone>overweight >obesity-resistant=chow-fed mice. Fat pads and fat pad:carcass were heaviest in obesity-prone followed by overweight mice. However, obesity-resistant mice had fat pad weights and fat pad:carcass three-fold greater than chow-fed mice. All groups had MT incidences between 72 and 82%. Obesity-prone mice exhibited the shortest MT latency (P<0.0001), but obesity-resistant mice had significantly shorter latency than chow-fed mice. CONCLUSIONS: Consumption of a high fat diet increased adiposity and shortened MT latency in relation to its effect on body weight. These results indicate a complex role of dietary fat level on mammary tumorigenesis.

Weight gain does not preclude increased ubiquitin conjugation in skeletal muscle: an exploratory study in tumor-bearing mice.

BACKGROUND AND HYPOTHESIS: At least 13 studies have shown that the ubiquitin-proteasome system mediates muscle wasting in weight-losing cancer subjects. We hypothesized that cancer itself may activate the ubiquitin-proteasome system, regardless of weight loss. METHODS: We utilized hybrid mice obtained by crossing Mouse Mammary Tumor Virus-Transforming Growth Factor-alpha (TGF-alpha) mice with the Lep(ob) strain. Five hybrid MMTV-TGF-alpha heterozygous Lep(+)Lep(ob) female mice with mammary tumors were used; 4 nontransgenic heterozygous Lep(+)Lep(ob) female mice served as controls. Ubiquitin conjugates were quantitated from hamstring and paraspinal muscles by Western blotting. Myocyte apoptosis was determined by a modified TUNEL assay. RESULTS: All mice gained weight, even after tumor development. Higher concentrations of muscle ubiquitin conjugates were seen in the 5 tumor-bearing, TGF-alpha transgenic mice as compared with the 4 non-tumor-bearing mice: median (range) in arbitrary densitometric units: 0.67 (0.22-4.59) versus 0.18 (0.08-0.44) in hamstring muscle and 0.56 (0.23-20.15) versus 0.18 (0.08-0.25) in paraspinal muscle (p = 0.04 and p = 0.04, respectively; Mann-Whitney U test). Apoptosis was not seen in any muscle sample studied. CONCLUSIONS: Ubiquitin conjugates are increased in the skeletal muscle of tumor-bearing mice in the absence of weight loss. Such activation is not seen in the skeletal muscle on non-tumor-bearing mice. Further studies might focus of whether this observation is relevant to cancer-associated wasting of lean tissue.

Restoration of fertility in young obese (Lep(ob) Lep(ob)) male mice with low dose recombinant mouse leptin treatment.

OBJECTIVE: We investigated the effects of low-dose leptin treatment on restoration of fertility in young adult male leptin deficient obese mice. EXPERIMENTAL DESIGN AND RESULTS: MMTV-TGF-alpha Lep(ob) Lep(ob) mice (8--10 weeks old) were treated with recombinant mouse leptin. In experiment 1, four mice (5 microg/g body weight leptin followed by 2.5 microg/g) lost weight and impregnated females (number of pregnancies/number of females, 3/6, 5/6, 5/10, 4/10). In experiment 2, Leptin-Obese (2.5 microg/g) and Control-Lean mice weighed significantly less than Control-Obese mice. Epididymal pad weights of Control-Obese mice were the heaviest, followed by those of Leptin-Obese mice, and Control-Lean mice were the lightest. Testes weight was greater in Control-Lean vs Control-Obese mice. Leptin-Obese mice had testes weight not significantly different from either control group. Four of five Leptin-Obese mice impregnated females (4/10, 5/10, 2/10, 5/12, 0/10). CONCLUSIONS: These results indicate that low-dosage mouse recombinant leptin treatment restored fertility to young Lep(ob) Lep(ob) male mice. Although body weights of Leptin-Obese mice were similar to those of lean age-matched mice, epididymal fat pad weights were heavier. International Journal of Obesity (2001) 25, 95-97

Obesity is associated with a decreased leptin transport across the blood-brain barrier in rats.

Leptin exerts important effects on the regulation of food intake and energy expenditure by acting in the brain. Leptin is secreted by adipocytes into the bloodstream and must gain access to specific regions in the brain involved in regulating energy balance. Its action is mediated by interaction with a receptor that is mainly expressed in the hypothalamus but is also present in other cerebral areas. To reach these target areas, leptin most likely needs to cross the blood-brain barrier (BBB). In this study, we compared the permeability of leptin at the BBB in homozygous lean (FA/FA), high-fat diet-induced (HFD) obese rats (FA/FA rats on a highfat diet), and genetically obese fa/fa Zucker rats by quantifying the permeability coefficient surface area (PS) product after correction for the residual plasma volume (Vp) occupied by leptin in the vessel bed of different brain regions. The intravenous bolus injection technique was used in the cannulated brachial vein and artery using leptin radioiodinated with 2 isotopes of iodine (125I and 131I) to separately determine the PS and Vp values. The PS for leptin at the BBB in lean FA/FA rats ranged from 11.0 +/- 1.6 at the cortex to 14.8 +/- 1.4 x 10(-6) ml x g(-1) x ml(-1) at the posterior hypothalamus. The PS for leptin in HFD obese FA/FA and obese fa/fa rats ranged from 3.0- to 4.0-fold lower than in lean FA/FA rats. The Vp values were not significantly different among the 3 groups studied. SDS-PAGE analysis of the radioiodinated leptin after 60 min of uptake revealed intact protein in the 8 different brain regions. Plasma leptin levels were significantly higher in both obese rat groups compared with those in lean FA/FA rats. Leptin levels in cerebrospinal fluid were not significantly different among the 3 groups of rats. These findings strongly suggest that the leptin receptor (OB-R) in the BBB can be easily saturated. Saturation of the BBB OB-R in obese individuals would explain the defect in leptin transport into the brain described in this study.

The presence of the "fa" gene in heterozygous (FA/fa) lean female rats, effects on body weight, body fat and serum leptin.

OBJECTIVE: In previous studies, suckling lean heterozygous (FA/fa) pups had higher body fat levels in comparison to lean homozygous (FA/FA) pups. However, in older male rats fed either low- or high-fat diets, we found no effects of the "fa" gene in heterozygous lean rats compared to homozygous lean rats. Other studies have reported effects of the "fa" gene on aspects of insulin metabolism for lean heterozygous female rats compared to their homozygous counterparts. In the present study, the effect of the "fa" gene on body weight and body fat in lean female rats was investigated. RESEARCH METHODS AND PROCEDURES: Homozygous lean female rats were obtained by mating homozygous lean male and female rats. Heterozygous lean female rats were obtained by mating homozygous obese male rats with heterozygous lean female rats. Following weaning, rats were maintained on a standard laboratory diet until 10 weeks of age when they were killed after an overnight fast. RESULTS: Body weight (p<0.03) and inguinal (p = 0.01) and combined retroperitoneal+parametrial (p = 0.06) fat pad weights were heavier in heterozygous lean compared to homozygous lean female rats. Combined fat pad-to-body weight ratio (p = 0.05) and fat cell sizes (p = 0.06) were also higher in the heterozygous lean compared to homozygous lean rats. No differences in serum triacylglycerol, cholesterol, glucose, or insulin concentrations were found between the two groups, but serum leptin levels were significantly higher (p<0.004) in heterozygous lean rats. DISCUSSION: These results indicate that effects of the "fa" gene are present during the postweaning period in lean female rats. Implications for increased body fat and leptin with respect to sexual maturation and fertility are discussed.

Genotype and diet effects in lean and obese Zucker rats fed either safflower or coconut oil diets.

Previously we reported that suckling lean heterozygous (FA/fa) Zucker rats had a number of adipose tissue measurements intermediate between those of homozygous lean (FA/FA) and obese (fa/fa) rats. However, in young adult male rats maintained on a low-fat diet, these differences were no longer apparent (i.e., values for the two lean genotypes were similar). In the present study we determined whether the heterozygous effect of the "fa" gene was dependent on the consumption of a high-fat diet. Mother rats were fed high-fat diets containing either safflower (SOD) or coconut (COD) oil throughout mating and lactation. Homozygous lean male and female rats were bred, as well as obese male and lean heterozygous female rats. Suckling rats were studied at 17 days of age. Additional male rats were maintained on the same diet as their mothers until 11-12 weeks of age. Obese suckling rats had higher body weights than lean pups. Inguinal fat pad weights and pad-to-body weight ratios followed the pattern of obese greater than lean (FA/fa) pups that were greater than lean (FA/FA) pups. A similar relationship was found for adipose tissue lipogenic enzyme activities. At 11-12 weeks of age, measurements followed the general pattern of obese rats having greater values than lean rats (i.e., FA/fa = FA/FA). SOD-fa/fa rats had higher hepatic lipogenic enzyme activities than COD-fa/fa rats. In addition, SOD rats had higher fat cell numbers than COD rats. These results suggest that specific fatty acids can alter adipocyte proliferation and/or differentiation in vivo. In addition, there appears to be a defect of fatty acid regulation in livers of genetically obese rats. The heterozygous effect of the "fa" gene in suckling Zucker rats was confirmed. However, high-fat feeding did not result in a heterozygous effect in young adult lean male rats. We will next evaluate the role of sex on this effect.

The role of body mass index in the relative risk of developing premenopausal versus postmenopausal breast cancer.

Many women in industrialized countries are overweight. Excess body fat is associated with excess morbidity and mortality from atherosclerosis and diabetes. In some cases, overweight/obesity also is implicated with increased incidence of breast cancer, but the results of these studies are not consistent. Human breast cancer is usually distinguished as either premenopausal or postmenopausal. In this review, we focus on literature that presents body mass index (BMI, weight/height2) ranges and identifies menstrual status. The majority of the relevant prospective studies support an inverse relationship between BMI and the relative risk (RR) of developing premenopausal breast cancer. In contrast, a positive relationship between BMI and the RR of developing postmenopausal breast cancer is reported in only half of all prospective studies on this topic. Those studies that do not show a positive RR, in general, have used younger postmenopausal women, and their body weights were obtained prior to menopause. Many case-control studies also report an inverse association between BMI and the RR of developing premenopausal breast cancer, and a positive association between BMI and the RR of developing postmenopausal breast cancer. Other studies do not find these associations, but a number of these studies have used small sample sizes and, for the postmenopausal subjects, have represented populations with low obesity and/or breast cancer rates. Other factors that might play a role in breast cancer development, such as body fat distribution, weight at earlier ages, and weight gain, are also addressed, as well as the effect of obesity in breast cancer prognosis. In addition, limited data available for animal studies related to this topic, as well as potential mechanisms by which body fat may play a role in breast cancer development, are discussed. Finally, the need for better animal models in which to perform controlled dietary and/or drug intervention studies to test rigorously the proposed mechanisms by which body fat may contribute to breast cancer development is addressed.

Inhibition of ultraviolet B-induced activator protein-1 (AP-1) activity by aspirin in AP-1-luciferase transgenic mice.

Aspirin is under consideration as a promising chemopreventative agent for human cancers. To study the usefulness of aspirin as a chemopreventative agent for UV-induced human skin cancer, we investigated the effect of aspirin on UVB-induced activator protein-1 (AP-1) activity. In the JB6 cell culture system, aspirin or sodium salicylate (SA) inhibited UVB-induced AP-1 activity in a dose-dependent manner; this inhibitory effect occurred only in cells pretreated with aspirin or SA before UVB irradiation but not cells treated with aspirin or SA after UVB irradiation. Furthermore, these inhibitory effects on UVB-induced AP-1 activity appeared to be mediated through blocking of activation of MAP kinase family members, including extracellular signal-regulated protein kinases, c-Jun N-terminal kinases, and p38. It was not due to absorption of UVB light by aspirin. In the skin of AP-1-luciferase transgenic mice, UVB irradiation induced a rapid increase in AP-1 activity, which reached the peak at 48 h post-UVB irradiation. The topical pretreatment of mouse skin with aspirin markedly blocked the UVB-induced AP-1 transactivation in vivo. These data provide the first evidence that aspirin and SA are inhibitors of UV-induced signal transduction and thus could be used as a chemopreventative agent for skin cancer.

Liver, serum and adipose tissue fatty acid composition in suckling Zucker rats.

Young adult obese Zucker rats have altered tissue fatty acid (FA) composition. The present study was aimed at determining whether such changes were seen in either liver, serum or adipose tissue obtained from 17-day-old obese (fafa) rats in comparison to both homozygous (FaFa) and heterozygous (Fafa) lean rats. Body weights of obese pups (30.3 g) were significantly greater than those of homozygous lean rats (25.2 g) (P < 0.05). Liver weight and lipid content were similar in all groups. Inguinal fat pad weight and lipid content were greatest in obese pups (573 mg) followed by heterozygous lean pups (303 mg); homozygous lean pups (146 mg) had the lowest values. There were no differences among the groups in hepatic FA composition in either triacylglycerol (TG) or phospholipid fractions. Serum TG was similar among the groups, while serum phospholipid was greater (P < 0.05) in obese (269 mg/dL) than in homozygous lean pups (184 mg/dL); heterozygous lean pups had an intermediate value not significantly different from either homozygous group. On a percent basis, there were no differences in FA composition in either serum lipid fraction among the three groups. There were a number of significant differences in adipose tissue FA composition between the groups on a percent basis. The adipose tissue FA composition on a percent basis reflected that of maternal milk. The results indicate that suckling obese Zucker rats do not have tissue FA profiles that are characteristic of essential FA deficiency.

Metabolic measurements among homozygous (fa/fa) obese, heterozygous (Fa/fa) lean and homozygous (Fa/Fa) lean Zucker rat pups at 17 days of age.

Factors associated with the development of obesity were compared among obese (fa/fa), heterozygous (Fa/fa) lean and homozygous (Fa/Fa) lean Zucker rats at 17 d of age. Inguinal pad weight, pad-to-body weight ratio and fat cell size were highest in obese pups (fa/fa > Fa/fa > Fa/Fa). Hepatic glucose-6-phosphate dehydrogenase activity was greater in fa/fa than in Fa/Fa pups; 6-phosphogluconate dehydrogenase activity was higher in fa/fa and Fa/fa pups than in Fa/Fa pups, and fatty acid synthetase was greater in fa/fa compared with lean pups (Fa/fa = Fa/Fa). The fa/fa pups had greater adipose tissue glucose-6-phosphate dehydrogenase, malic enzyme and fatty acid synthetase activities than lean pups, which did not differ from one another (Fa/fa = Fa/Fa), whereas 6-phosphogluconate dehydrogenase and lipoprotein lipase activities were highest in obese pups, intermediate in heterozygotes and lowest in homozygous lean rats (fa/fa > Fa/fa > Fa/Fa). Glucose conversion to carbon dioxide and fatty acids in isolated adipocytes was highest in obese pups (fa/fa > Fa/fa > Fa/Fa). Glyceride-glycerol production was greater in Fa/Fa than in fa/fa or Fa/fa pups. These findings indicate that many characteristics of obesity are evident in preobese Zucker rats, and for some factors the presence of the "fa" gene in lean rats results in intermediate measurements relative to the two homozygous genotypes.

Studies on nuclear binding of dehydroepiandrosterone in hepatocytes.

Experiments were conducted to determine if dehydroepiandrosterone (DHEA) specifically binds to liver nuclei or interferes in the binding of other steroid hormones. Hepatocytes were isolated from obese, female Zucker rats that were treated with and without 0.6% DHEA in their diets for 2 weeks. The hepatocytes were incubated with either [3H]DHEA, [3H]estrone, or [3H]corticosterone. The nuclei isolated from the incubated cells from either control or DHEA-treated rats had no binding with [3H]DHEA, but had the expected binding with [3H]estrone and [3H]corticosterone. Furthermore, increasing concentrations of cold, unlabeled DHEA in the incubation media with [3H]estrone or [3H]corticosterone failed to have any effect on the binding of either of these steroid hormones to the nuclei. These results suggest that DHEA treatment does not exert its effects on cellular metabolism through a receptor-mediated mechanism like other steroid hormones or by interfering in the expression of steroid hormones such as estrone and corticosterone.

Metabolic effects of coconut, safflower, or menhaden oil feeding in lean and obese Zucker rats.

The aim of the present investigation was to study the effects of fish oil feeding in obese Zucker rats to establish its suitability as an animal model of hyperlipidaemia, and to understand the possible mechanism of fish oil-induced perturbations in cell metabolism. Lean and obese Zucker rats were fed on diets containing 180 g coconut, safflower, or menhaden oil/kg for 10 weeks. Body-weights and food intakes of lean coconut (LC), safflower (LS), and menhaden (LM) groups were similar. Obese menhaden (OM) rats had lower food intakes and body-weights compared with obese coconut (OC) and obese safflower (OS) groups, but values for all obese rats were higher than those for lean rats. Liver weights were higher in obese compared with lean rats, but on a percentage body-weight basis menhaden oil rats had higher values within genotype. Serum cholesterol and triacylglycerol levels were lower in the OM group compared with the OC and OS groups, and in the LM group compared with the LC group. Glucose and insulin levels were highest in OS rats followed by OC and OM rats and then the lean rats. Serum triiodothyronine and thyroxine were lower in OM rats compared with OC and OS rats. Liver mitochondrial state 3 rates with glutamate-malate and succinate were lower; mitochondrial beta-oxidation was unaffected and peroxisomal beta-oxidation was higher in menhaden oil rats compared with both coconut and safflower oil rats. In general, consumption of menhaden oil lowered hepatic malic enzyme (EC 1.1.1.38, 1.1.1.40), glucose-6-phosphate dehydrogenase (EC 1.1.1.49) and glutathione peroxidase (EC 1.11.1.9) activities and elevated long-chain fatty acyl-CoA hydrolase (EC 3.1.2.2) activity when compared with the two other diets. It is concluded that obese Zucker rats do respond like human subjects to fish oil feeding but not to vegetable oils. The hypolipidaemic effect of fish oil appears to be mediated through a lowering of lipogenic enzymes, glucose-6-phosphate dehydrogenase and malic enzyme.

Short-term effects of dehydroepiandrosterone treatment in rats on mitochondrial respiration.

Administration of dehydroepiandrosterone (DHEA) to rats results in alterations in liver and serum factors. This study was undertaken to determine the earliest metabolic change(s) associated with DHEA treatment. Serum cholesterol, triacylglycerol, glucose, insulin, glucagon, thyroid hormones and hepatic glucose-6-phosphate dehydrogenase activity were, in general, unaltered in obese Zucker rats after 7 d and 24, 12 and 3 h of DHEA treatment. Malic enzyme, long-chain fatty acyl-coenzyme A hydrolase and catalase activities and peroxisomal beta-oxidation rates were elevated after 7 d and 24 h in DHEA treatment, but not after 12 h. Mitochondrial beta-oxidation was not altered. Hepatic mitochondrial state 3 respiration per g liver with glutamate-malate was elevated after 7 d and 24, 12 and 3 h in DHEA-treated rats and was elevated per mg protein except after 7 d. Succinate-supported state 3 respiration per g liver was also elevated after 7 d and 24 and 12 h of DHEA treatment. Mitochondria from rats treated for 7 d had lower levels of cardiolipin and phosphatidylethanolamine and an increase in phosphatidylcholine. Changes in fatty acid composition of these phospholipids occurred after 7 d and 24 h of DHEA treatment. In an additional study, rats were treated with DHEA or DHEA plus ethidium bromide for 3 d. Ethidium bromide inhibited the increase in mitochondrial protein and respiration associated with DHEA treatment. These findings indicate that mitochondrial respiration is the earliest factor affected by DHEA and may be associated with protein synthesis.

The antiobesity effect of dehydroepiandrosterone in rats.

Initial studies showed that dehydroepiandrosterone (DHEA) treatment in mice resulted in lower body weight gain. Subsequent studies have shown that DHEA treatment in rats has a similar effect. In adult rodents, weight loss is a consequence of DHEA treatment. In general, these effects are independent of changes in food intake and are accompanied by lower body fat. DHEA treatment has been shown in some circumstances to alter a number of serum factors including glucose, insulin, cholesterol, and triacylglycerol. Recent studies have focused on the effects of DHEA on liver metabolism. Studies have been undertaken to determine whether the antiobesity effect of DHEA is mediated by the previously described inhibition of glucose-6-phosphate dehydrogenase by this steroid. It appears that inhibition of glucose-6-phosphate dehydrogenase in liver is not the initial metabolic response to DHEA but may play a contributing role. Inhibition of glucose-6-phosphate dehydrogenase in adipose tissue may affect differentiation of fat cells. A number of other enzymes involved in lipid and carbohydrate metabolism have also been shown to be altered by DHEA treatment, and several futile cycles involving some of these enzymes have been proposed to play a role in DHEA's antiobesity action. In addition, mitochondrial protein content is elevated by DHEA treatment. There appear to be time-dependent changes due to DHEA treatment on hepatic mitochondrial state three rates of respiration. Studies continue to evaluate the role of alterations in mitochondrial metabolism in DHEA's antiobesity action.

Effects of dehydroepiandrosterone treatment in rats with diet-induced obesity.

Previous studies showed that administration of dehydroepiandrosterone (DHEA) to lean and genetically obese Zucker rats reduced body weight. In the present experiments, the effect of DHEA treatment in rats with diet-induced obesity was evaluated. In experiment 1, male Sprague-Dawley rats (300 g) were fed a nonpurified diet (reference group) or a condensed milk-corn oil nonpurified diet [diet-induced obese (DIO) rats] for 7 wk. Then, 0.6% DHEA was included in the food of one-half of the DIO rats (DIO + DHEA rats). After 6 wk, DIO rats weighed 23% more and had greater fat pad weights, cell size and cell number than reference and DIO + DHEA rats. Brown fat mitochondrial respiration was similar in all groups. DIO rats had higher serum cholesterol and triacylglycerol concentrations than reference and DIO + DHEA rats. DIO + DHEA rats had lower serum insulin levels than DIO and reference rats. In experiment 2, male Sprague-Dawley rats (460 g) were fed either the nonpurified diet or the condensed milk diet for 8 wk. Condensed milk-fed rats were then divided into DIO and diet-resistant groups. One-half of the rats in each group were fed 0.6% DHEA for 2 wk. Body weights and serum glucose, insulin, triacylglycerol and triiodothyronine levels were lowered by DHEA treatment in all groups. Liver mitochondrial state 3 respiration rates per gram and per liver and peroxisomal beta-oxidation were higher in DHEA-treated than in control rats. In DIO rats, DHEA treatment appears to interfere with hyperplastic adipose tissue growth. In this strain of rats, DHEA appears to have hypolipidemic and hypoinsulinemic effects.

Effect of dehydroepiandrosterone treatment on liver metabolism in rats.

1. Administration of the 17-ketosteroid, dehydroepiandrosterone (DHEA), to rats results in lowered body weight. 2. A number of changes are seen in livers of treated rats. 3. These include higher liver weights and DNA, RNA and/or protein content, but lowered lipid and glycogen levels. 4. Activities of a number of liver enzymes involved in lipid and carbohydrate metabolism are altered by treatment. 5. In addition, net mitochondrial respiration is elevated by DHEA treatment. 6. Some of these findings may explain DHEA's antiobesity effect.