Dietary fish oils modify adipocyte structure and function.

Dietary fish oils, enriched with omega-3 fatty acids (e.g., MaxEPA fish oil), inhibit lipogenesis and have a marked hypotriglyceridemic effect in man and experimental animals. Dietary omega-3 fatty acids also reduce adipose tissue trophic growth in rats. To understand the metabolic basis for this, we measured the effect of fish oil feeding upon rat plasma triglyceride concentration, fat pad mass, fat cell size, fat cell lipolysis, as well as lipoprotein binding to adipocyte plasma membranes. In adolescent (250 g) male Wistar rats fed 20% (w/w) fish oil supplemented diets for 3 weeks, plasma triglyceride levels and epididymal and perirenal fat pad mass were significantly (P less than 0.005) reduced compared to pair-fed controls given 20% lard diets. These differences in fat pad mass between the diets were greater than differences in whole animal mass or in the mass of livers, testes, kidneys, spleens, or hearts. Isoproterenol-stimulated lipolysis was significantly (P less than 0.005) higher in fish oil fed rats than in pair-fed controls. In young (100 g) rats plasma triglyceride levels were 10 times lower in the fish oil fed group after 5 weeks as compared to the lard-fed controls. This was accompanied by a reduction in epididymal and perirenal fat pad mass as well as a 2-3-fold decrease in adipocyte volumes; there was no significant difference between the two groups in fat cell number in each region. Plasma membranes of epididymal adipocytes from fish oil fed rats bound significantly (P less than 0.001) less HDL1 than the lard-fed rats, possibly as a result of a reduction in fat cell size and/or alteration of plasma membrane structure. Thus in both young and old rats, the reduction in plasma triglyceride concentration in conjunction with increased hormone-stimulated lipolysis may explain in part the selective reduction in adipose tissue trophic growth accompanying fish oil consumption.     

Effect of aging and cellularity on lipolysis in isolated mouse fat cells

The effects of age and cellularity on lipolysis have been investigated in isolated epididymal fat cells from both Swiss albino mice and Sprague-Dawley rats. No significant lipolytic response to glucagon could be demonstrated with adipocytes from either young or old mice, while glycerol output was increased by this hormone with fat cells from young rats. Larger adipocytes from older mice showed significantly greater isoproterenol-stimulated lipolysis than those from younger animals if the glycerol output was expressed on a per cell basis. However, the lipolytic response per cell appeared to be equivalent in young and old rat adipocytes with either isoproterenol or ACTH-(1-24). In a complete aging study, relationships between body weight, epididymal fat pad weight and cellularity were examined covering the life span of the mouse. ACTH-(1-24)- and dibutyryl cyclic AMP-stimulated lipolysis increased with age and cell size but fell at senescence when adipocyte size diminished. Although an effect of aging per se cannot be ruled out with the experimental techniques used in the present study, a dominant influence of adipocyte size on the lipolytic process was demonstrated.     

Adipose tissue development, growth, and food consumption in protein-malnourished rats.

Effects of protein malnutrition on adipose tissue development were studied in weanling male Sprague-Dawley rats fed isocaloric diets ad libitum containing either 22% (controls) or 8% (protein-malnourished rats) casein, and in rats pair-fed to the protein-malnourished rats with the 22% casein diet. After 32 days on the diet, protein-malnourished rats were 37% and pair-fed 67% the weight of the controls, while torso length was 37% and 73% of controls, respectively. Food consumption relative to body weight was greatest in protein-malnourished rats. Compared to control rats, the distal epididymal adipocyte number in the protein-malnourished rats was decreased in proportion to the decrease in body size and was more closely related to the protein intake than to the total calories consumed. After 32 days on diet, mean adipocyte number per 2 distal pads was 11.7 x 10(6) in controls and 4.3 x 10(6) in protein-malnourished rats. In pair-fed rats, cell number lagged behind controls at 4 and 11 days, but was normal at 32 days (11.4 x 10(6) cells). The distal epididymal pad adipocyte size and percent lipid were similar in all groups during the first 25 days of dietary treatment. Adipocyte size was increased significantly in controls at day 32 compared to the other two groups. At each time studied through day 25 on diet, epididymal pad weight was related to the adipose cell number rather than the cell size. It is concluded that severe restriction of dietary protein during the postweaning period of growth in rats results in decreased epididymal adipocyte proliferation and/or differentiation concomitant with generalized growth retardation, whereas isocaloric feeding of a diet of normal protein content is associated with only a transient delay in adipose tissue development.     

Chronic ethanol and triglyceride turnover in white adipose tissue in rats: inhibition of the anti-lipolytic action of insulin after chronic ethanol contributes to increased triglyceride degradation

Chronic ethanol consumption disrupts whole-body lipid metabolism. Here we tested the hypothesis that regulation of triglyceride homeostasis in adipose tissue is vulnerable to long-term ethanol exposure. After chronic ethanol feeding, total body fat content as well as the quantity of epididymal adipose tissue of male Wistar rats was decreased compared with pair-fed controls. Integrated rates of in vivo triglyceride turnover in epididymal adipose tissue were measured using (2)H(2)O as a tracer. Triglyceride turnover in adipose tissue was increased due to a 2.3-fold increase in triglyceride degradation in ethanol-fed rats compared with pair-fed controls with no effect of ethanol on triglyceride synthesis. Because increased lipolysis accompanied by the release of free fatty acids into the circulation is associated with insulin resistance and liver injury, we focused on determining the mechanisms for increased lipolysis in adipose tissue after chronic ethanol feeding. Chronic ethanol feeding suppressed beta-adrenergic receptor-stimulated lipolysis in both in vivo and ex vivo assays; thus, enhanced triglyceride degradation during ethanol feeding was not due to increased beta-adrenergic-mediated lipolysis. Instead, chronic ethanol feeding markedly impaired insulin-mediated suppression of lipolysis in conscious rats during a hyperinsulinemic-euglycemic clamp as well as in adipocytes isolated from epididymal and subcutaneous adipose tissue. These data demonstrate for the first time that chronic ethanol feeding increased the rate of triglyceride degradation in adipose tissue. Furthermore, this enhanced rate of lipolysis was due to a suppression of the anti-lipolytic effects of insulin in adipocytes after chronic ethanol feeding.     

Hypertrophy and/or Hyperplasia: Dynamics of Adipose Tissue Growth

Adipose tissue grows by two mechanisms: hyperplasia (cell number increase) and hypertrophy (cell size increase). Genetics and diet affect the relative contributions of these two mechanisms to the growth of adipose tissue in obesity. In this study, the size distributions of epididymal adipose cells from two mouse strains, obesity-resistant FVB/N and obesity-prone C57BL/6, were measured after 2, 4, and 12 weeks under regular and high-fat feeding conditions. The total cell number in the epididymal fat pad was estimated from the fat pad mass and the normalized cell-size distribution. The cell number and volume-weighted mean cell size increase as a function of fat pad mass. To address adipose tissue growth precisely, we developed a mathematical model describing the evolution of the adipose cell-size distributions as a function of the increasing fat pad mass, instead of the increasing chronological time. Our model describes the recruitment of new adipose cells and their subsequent development in different strains, and with different diet regimens, with common mechanisms, but with diet- and genetics-dependent model parameters. Compared to the FVB/N strain, the C57BL/6 strain has greater recruitment of small adipose cells. Hyperplasia is enhanced by high-fat diet in a strain-dependent way, suggesting a synergistic interaction between genetics and diet. Moreover, high-fat feeding increases the rate of adipose cell size growth, independent of strain, reflecting the increase in calories requiring storage. Additionally, high-fat diet leads to a dramatic spreading of the size distribution of adipose cells in both strains; this implies an increase in size fluctuations of adipose cells through lipid turnover.     

Gene expression profile of rat adipose tissue at the onset of high-fat-diet obesity

Morbid obesity is the result of massive expansion of white adipose tissue (WAT) and requires recruitment of adipocyte precursor cells and their supporting infrastructure. To characterize the change in the expression profile of the preexisting WAT at the start of obesity, when adipocyte hypertrophy is present but hyperplasia is still minimal, we employed a cDNA subtraction screen for genes differentially expressed in epididymal fat pads harvested 1 wk after the start of a 60% fat diet. Ninety-six genes were upregulated by at least 50% above the WAT of control rats receiving a 4% fat diet. Of these genes, 30 had not previously been identified. Sixteen of the 96 genes, including leptin, adipocyte complement-related protein 30 kDa, and resistin, were predicted to encode a signal peptide. Ten of the 16 had been previously identified in other tissues and implicated in cell growth, proliferation, differentiation, cell cycle control, and angiogenesis. One was a novel gene. Twenty-nine novel fragments were identified. Thus, at the onset of high-fat-diet-induced obesity in rats, adipose tissue increases its expression of factors previously implicated in the expansion of nonadipocyte tissues and of several uncharacterized novel factors. The only one of these thus far characterized functionally was found to promote lipogenesis.     

Duration of feeding on a sucrose-rich diet determines metabolic and morphological changes in rat adipocytes.

In this work, we studied the effect of a short-term (3 wk) and a long-term (15 wk) administration of a sucrose-rich diet (SRD) to Wistar rats on the morphological aspects and metabolic function of the epididymal adipose tissue that may contribute to the mechanism underlying the impaired glucose homeostasis and insulin resistance. The present work showed the following. 1) There was both a moderate increase of basal lipolysis and a decrease of the antilipolytic action of insulin in the adipocytes of rats fed a SRD for 3 wk. Neither size alterations nor increases in adipose tissue mass were recorded in this period. 2) There was a significant (P < 0.05) increase of epididymal weight after 15 wk on a SRD as well as a hypertrophy of adipocytes with a clear alteration in the cell size distribution. This was accompanied by a significant increase (P < 0.05) of basal and stimulated lipolysis and a marked decrease (P < 0.05) of the antilipolytic action of insulin. Moreover, these changes appear together with a worsening of both impaired glucose homeostasis and insulin resistance. Our results also indicate that the length of time on the SRD plays an important role in the evolution of the adiposity and metabolic changes observed in the fat pad. Furthermore, the latter precedes the detection of adiposity.     

Fat mobilization in vitro and in vivo in the genetically obese Zucker rat "fatty"

Fat mobilization was studied in vitro with epididymal fat pad tissue and also with cell suspensions from epididymal, retroperitoneal, and subcutaneous fat from the obese mutant "fatty" (fafa) and control rats of four different ages. Fat mobilization per cell in response to epinephrine was well above normal in young "fatties"; in older "fatties" the output per cell fell to near normal, but the much greater number of fat cells per rat indicated that the fat mobilizing capacity of the older "fatty" is well above normal. The "fatty" showed normal reactions to epinephrine in vivo: hyperglycemia, glycogenolysis, lipolysis with elevated free fatty acids and glycerol, and increased entry of free fatty acids into muscle and liver. Response was at least as great in "fatty" as in control animals. Metabolic indices-levels of circulating free fatty acids, glycerol, and in some cases glucose and lipid-determined at various ages in fed "fatties" and controls, and at intervals during prolonged fasting (70 days), were consistent with a picture of excessive adipose tissue lipolysis, excessive reesterification in the adipose tissue, fat mobilization in excess of need, and return of the excess to the adipose tissue via lipoproteins.     

Effect of beta agonists on protein turnover in adipose tissue.

Chronic administration (21 days) of the beta agonist cimaterol to rats decreased epididymal fat by 27%, and inhibited in vitro rates of protein synthesis by 34% and net protein breakdown by 71% in adipose tissue. Likewise, incubation of rat adipose tissue with cimaterol and isoproterenol stimulated lipolysis, and inhibited protein synthesis and degradation. Thus, in addition to affecting muscle mass and lipid metabolism, beta agonists appear to slow rates of protein turnover in adipose tissue.     

Impaired fat storage capacity in adipocyte precursors of I versus C57BL mice

I mouse strain displays adipocyte hypoplasia responsible for smaller fat pad size compared with C57BL mice. We investigated possible alterations in the proliferation and/or differentiation capacity of preadipocytes from the stroma-vascular fraction of adipose tissue in the I mouse strain. Control C57BL and I mice were studied at 8 weeks of age, and both adipose and stromal cells were isolated from epididymal and inguinal adipose tissue localizations. Results showed that the lower epididymal adipose mass in I mice was accompanied by a decrease in stromal cell number compared with C57BL mice. In inguinal fat pads, total cell number in the stroma-vascular fraction was unmodified; lipoprotein lipase activity significantly increased in stromal cells from I mice compared with control mice. In this depot, further characterization of cells from the stroma-vascular fraction by separation of cells according to density showed an increased number of preadipocytes in the I mouse whole stromal cell population. These preadipocytes seemed unable to undergo terminal maturation, thus leading to a decrease in the number of mature adipocytes. These results indicated that resistance to fat accumulation in I mice is characterized by site-dependent impairment of both the proliferative rate and the differentiation capacity of adipocyte precursors.     

Influence of dietary macronutrient composition on adiposity and cellularity of different fat depots in Wistar rats

The aim of this study was to investigate the role of dietary macronutrient content on adiposity parameters and adipocyte hypertrophy/hyperplasia in subcutaneous and visceral fat depots from Wistar rats using combined histological and computational approaches. For this purpose, male Wistar rats were distributed into 4 groups and were assigned to different nutritional interventions: Control group (chow diet); high-fat group, HF (60% E from fat); high-fat-sucrose group, HFS (45% E from fat and 17% from sucrose); and high-sucrose group, HS (42% E from sucrose). At day 35, rats were sacrificed, blood was collected, tissues were weighed and fragments of different fat depots were kept for histological analyses with the new softwareAdiposoft. Rats fed with HF, HFS and HS diets increased significantly body weight and total body fat against Control rats, being metabolic impairments more pronounced on HS rats than in the other groups. Cellularity analyses usingAdiposoft revealed that retroperitoneal adipose tissue is histologically different than mesenteric and subcutaneous ones, in relation to bigger adipocytes. The subcutaneous fat pad was the most sensitive to the diet, presenting adipocyte hypertrophy induced by HF diet and adipocyte hyperplasia induced by HS diet. The mesenteric fat pad had a similar but attenuated response in comparison to the subcutaneous adipose tissue, while retroperitoneal fat pad only presented adipocyte hyperplasia induced by the HS diet intake after 35 days of intervention. These findings provide new insights into the role of macronutrients in the development of hyperplastic obesity, which is characterized by the severity of the clinical features. Finally, a new tool for analyzing histological adipose samples is presented.     

Gene deletion reveals roles for annexin A1 in the regulation of lipolysis and IL-6 release in epididymal adipose tissue

In this study, epididymal adipose tissue from male annexin 1 (ANXA1)-null and wild-type control mice were used to explore the potential role of ANXA1 in adipocyte biology. ANXA1 was detected by Western blot analysis in wild-type tissue and localized predominantly to the stromal-vascular compartment. Epididymal fat pad mass was reduced by ANXA1 gene deletion, but adipocyte size was unchanged, suggesting that ANXA1 is required for the maintenance of adipocyte and/or preadipocyte cell number. Epididymal tissue from wild-type mice responded in vitro to noradrenaline and isoprenaline with increased glycerol release, reduced IL-6 release, and increased cAMP accumulation. Qualitatively similar but significantly attenuated responses to the catecholamines were observed in tissue from ANXA1-null mice, an effect that was not associated with changes in beta-adrenoceptor mRNA expression. Lipopolysaccharide (LPS) also stimulated lipolysis in vitro, but its effects were muted by ANXA1 gene deletion. By contrast, LPS failed to influence IL-6 release from wild-type tissue but stimulated the release of the cytokine from tissue from ANXA1-null mice. ANXA1 gene deletion did not affect glucocorticoid receptor expression or the ability of dexamethasone to suppress catecholamine-induced lipolysis. It did, however, augment IL-6 expression and modify the inhibitory effects of glucocorticoids on IL-6 release. Collectively, these studies suggest that ANXA1 supports aspects of adipose tissue mass and alters the sensitivity of epididymal adipose tissue to catecholamines, glucocorticoids, and LPS, thereby modulating lipolysis and IL-6 release.     

5 alpha-reductase activity in rat adipose tissue

We measured the 5 alpha-reductase activity in isolated cell preparations of rat adipose tissue using the formation of [3H]dihydrotestosterone from [3H]testosterone as an endpoint. Stromal cells were prepared from the epididymal fat pad, perinephric fat, and subcutaneous fat of male rats and from perinephric fat of female rats. Adipocytes were prepared from the epididymal fat pad and perinephric fat of male rats. Stromal cells from the epididymal fat pad and perinephric fat contained greater 5 alpha-reductase activity than did the adipocytes from these depots. Stromal cells from the epididymal fat pad contained greater activity than those from perinephric and subcutaneous depots. Perinephric stromal cells from female rats were slightly more active than those from male rats. Estradiol (10(-8) M), when added to the medium, caused a 90% decrease in 5 alpha-reductase activity. Aromatase activity was minimal, several orders of magnitude less than 5 alpha-reductase activity in each tissue studied.     

Lipid metabolism of monosodium glutamate obese rats after partial removal of adipose tissue

We analyzed the effects of partial fat pad removal on retroperitoneal and epididymal fat depots and carcass metabolism of control (C) and MSG-obese (M) rats. Three-month-old C and M male Wistar rats were submitted to either partial surgical excision of epididymal and retroperitoneal fat tissue (lipectomy, L) or sham surgery (S) and studied after 7 or 30 days. Retroperitoneal and epididymal tissue re-growth after lipectomy was not observed, as indicated by the low pads weight of the L groups. The lipolysis rate was stimulated in LC7 and LM7, probably due to surgical stress and low insulin levels. In LM7, but not in LC7, in vivo lipogenesis rate increased in retroperitoneal and epididymal fat tissue, as did the diet-derived lipid accumulation in epididymal fat tissue. Although these local increases were no longer present in LM30, this group showed a large increase in the percentage of small area adipocytes in both pads as well as increased carcass lipogenesis rate. The present data showed that the partial removal of fat depots affected the metabolism of control and MSG-obese rats differently. In the obese animals only, it stimulated both local and carcass lipogenesis rate as well as adipocyte differentiation, i.e. responses likely to favor excised tissue re-growth and/or compensatory growth of non-excised depots.     

Effects of dietary carbohydrate and phenotype on adipose cellularity in female SHR/N-cp rats.

1. Adipose mass and cellularity were studied in congenic female SHR/N-cp rats fed iosenergetic diets containing 54% carbohydrate as sucrose (SU) or cooked cornstarch (CS), 20% protein, 16% mixed dietary fat plus vitamins, minerals, and non-nutritive fiber ad libitum from 5 weeks until 8.5 months of age. Measures of adipocyte lipid content, cell number per depot, and mass of principal white (WAT) and interscapular brown (IBAT) adipoe tissue depots were determined at the end of the study. 2. Final body weights (BW) of corpulent rats were more than twice those for their lean littermates, and were greater when fed the SU than the CS diet in both phenotypes. Phenotype effects (corpulent greater than lean) were present for fat pad weight, adipocyte number, and adipocyte lipid content in the dorsal (DOR) and retroperitoneal (RP) WAT depots. Diet effects were present for depot weight, adipocyte number, and adipocyte lipid content in both WAT depots, and were of qualitatively similar magnitude in both phenotypes. 3. IBAT weights, IBAT:BW ratios, and IBAT cell number of corpulent greater than lean, and were greater than with SU than CS diet in both phenotypes. 4. These results indicate that obesity in the corpulent phenotype of the SHR/N-cp rat occurs as the result of hypertrophy and hyperplasia of white adipose tissue, and that isoenergetic substitution of simple for complex carbohydrate resulted in greater fat accretion in both phenotypes. The greater diet and phenotype-associated adiposity occurred despite greater mass and cellularity of BAT. The results also indicate that sexual dimorphism occurs regarding effects of diet and phenotype on expression of adipose tissue development in this strain.     

Adrenalectomy Reduces Adiposity by Decreasing Feed Efficiency,Not Direct Effects on White Adipose Tissue

EDENS, N. K., A. MOSHIRFAR, G. M. POTTER, S. K. FRIED, AND T. W. CASTONGUAY. Adrenalectomy reduces adiposity by decreasing feed efficiency, not direct effects on white adipose tissue. Obes Res. Objective: This study was conducted to establish the effects of adrenalectomy (ADX) on adipose tissue metabolism in male Sprague—Dawley rats fed a standard chow diet. Research Methods and Procedures: The effects of adrenalectomy on adipose cell size, lipoprotein lipase activity, and basal and insulin-stimulated glucose conversion to lipid and lipolysis were measured. Results: ADX decreased body weight gain during the postoperative period in the absence of changes in food intake; feed efficiency was decreased significantly. ADX decreased adipocyte size by 30%. ADX increased adipocyte response to the effect of submaximal concentrations of insulin on lipid synthesis and lipolysis. ADX decreased maximally insulin-stimulated lipid synthesis, but this effect was accounted for by decreased adipocyte size. In contrast, ADX had no effect on maximally insulin-inhibited lipolysis. ADX did not affect heparin-releasable LPL. The small effect of ADX on residual extractable adipose tissue LPL activity was accounted for by decreased fat cell size. Discussion: ADX decreased adiposity in the absence of changes in food intake, lipoprotein lipase activity, and adipocyte lipid metabolism. The effect is best attributed to decreased feed efficiency.     

Cyclic AMP metabolism in adipose tissue of exercise-trained rats.

Cyclic AMP metabolism in epididymal adipose tissue of exercise-trained rats was examined to determine if training induced changes in cyclic AMP production or inactivation. Beginning at 7 weeks of age, male rats were physically trained by 12 weeks of treadmill running. Pair-fed control rats remained sedentary in their cages for the duration of the experiment. Tissue levels of cyclic AMP were measured in epididymal adipose tissue slices incubated with norepinephrine. Adenyl cyclase was assayed in adipocyte ghost cell prepartions and low-Km phosphodiesterase was assayed in homogenates of adipose tissue. In response to norepinephrine stimulation, tissue cyclic AMP levels were reduced in trained compared to untrained rats. Training increased the ratio of activity of phosphodiesterase relative to adenyl cyclase. The results of this study indicate that cyclic AMP production in response to norepinephrine stimulation is not increased by training and may even be reduced, implying that adipose tissue cyclic AMP levels may be under a greater degree of control in trained rats. Modulation of adipose tissue cyclic AMP levels may function to regulate more closely the duration of lipolysis in exercise-trained rats.     

Effect of ingestion of saline, glucose, and ethanol on mobilization and hepatic incorporation of epididymal pad palmitate-1-14C in rats

The effect of ingestion of saline, glucose, and ethanol (isocaloric with the glucose) on the mobilization of radiopalmitate from epididymal fat prelabeled in vivo and the incorporation of the mobilized label into liver lipids was investigated in rats. The mobilization of radiopalmitate from epididymal fat and the incorporation of the mobilized label into liver triglyceride were most markedly elevated by ingestion of ethanol. Increased mobilization and diversion of epididymal adipose tissue fatty acids to liver lipids of ethanol-treated rats were shown also by the close resemblance of the fatty acids of liver triglyceride to the fatty acids of epididymal fat. The amount of radiopalmitate mobilized by the saline-treated rats, comprising approximately a third of that mobilized by the ethanol-treated animals, was larger than the amount mobilized by the rats treated with glucose; most of it was oxidized rather than incorporated into the liver fats. In glucose-treated rats a larger fraction of radiopalmitate mobilized from one prelabeled epididymal pad was diverted to and incorporated into the lipids of the contralateral pad of the same animal. The specific activity of hepatic triglyceride of ethanol- and saline-treated rats was similar and significantly higher than that of animals treated with glucose. These data indicate that the ethanol-induced fatty liver can be attributed to an increased mobilization and incorporation of adipose tissue fatty acids into liver lipid and to an altered hepatic metabolism of fatty acids and triglyceride.     

Targeted disruption of the adipocyte lipid-binding protein (aP2 protein) gene impairs fat cell lipolysis and increases cellular fatty acid levels

The availability of mice containing an adipocyte lipid-binding protein (ALBP/aP2) gene disruption allowed for a direct examination of the presumed role of lipid-binding proteins in the mobilization and trafficking of intracellular fatty acids. Total body and epididymal fat pad weights, as well as adipose cell morphology, were unaltered in male ALBP/aP2 disrupted mice when compared to their wild-type littermates. Analysis of adipocytes isolated from wild-type and ALBP/aP2 null mice revealed that a selective 40- and 13-fold increase in the level of the keratinocyte lipid-binding protein (KLBP) mRNA and protein, respectively, accompanied the ALBP/aP2 gene disruption. Although KLBP protein was significantly up-regulated, the total lipid-binding protein level decreased 8 -fold as a consequence of the disruption. There was no appreciable difference in the rate of fatty acid influx or esterification in adipocytes of wild-type and ALBP/aP2 null animals. To the contrary, basal lipolysis decreased approximately 40% in ALBP/aP2 nulls as compared to wild-type littermates. The glycerol release from isproterenol-stimulated ALBP/aP2 null fat cells was similarly reduced by approximately 35%. Consistent with a decrease in basal efflux, the non-esterified fatty acid (NEFA) level was nearly 3-fold greater in adipocytes from ALBP/aP2 nulls as compared to wild-type animals. The significant decrease in both basal and isoproterenol-stimulated lipolysis in adipose tissue of ALBP/aP2 null mice supports the model whereby intracellular lipid-binding proteins function as lipid chaperones, facilitating the movement of fatty acids out of the fat cell.     

Influence of early nutrition on growth and adipose tissue characteristics in male and female rats

The purpose of this investigation was to assess the effects of early nutrition on adipose tissue characteristics and growth by altering litter size. After birth, rats were redistributed into large (15-18 pups), control (10 pups), or small (4 pups) litters. During the postweaning phase of growth half of the small-litter animals were pair-fed to animals raised in large litters for 5 wk and then allowed to feed ad libitum until they were 80 days of age. The small-litter males gained weight at a more rapid rate than the other litter types, both before and after weaning, and attained a final body weight twofold greater than the other groups. The small-litter males had significantly higher (P less than 0.05) numbers of adipocytes per epididymal fat pad than the other litter groups with 60.4, 51.4, and 79.0% greater cell number per pad than control, large, and pair-fed animals, respectively. Limiting food intake to small-litter animals after weaning (pair-fed) inhibited this growth and prevented fat cell proliferation. Litter manipulation had significant effects on male rats, but the same treatment did not influence female rats. Litter size influenced fat cell characteristics but had little effect on the adipocytes' ability to take up or metabolize glucose. The major finding, in terms of insulin responsiveness, was the difference between the sexes. The uptake of tritiated 2-deoxyglucose by the fat cells of female litter groups was significantly higher than that of the males whether insulin was present or not, whereas the conversion of [1-14C]glucose to CO2 by the adipocytes of females was lower than that of the males.(ABSTRACT TRUNCATED AT 250 WORDS)