(+)-z-bisdehydrodoisynolic Acid enhances Basal metabolism and Fatty Acid oxidation in female obese zucker rats.

We have previously reported that the synthetic estrogen, (+)-Z-bisdehydrodoisynolic Acid [(+)-Z-BDDA], attenuated weight gain and cardiovascular risk in obese rodents. To determine if these antiobesity effects were attributed to changes in basal metabolism, we assessed indirect calorimetry and metabolic profile in female obese Zucker (OZR) rats provided (+)-Z-BDDA (0.0002% food admixture) for 11 weeks. Similar to our previous findings, (+)-Z-BDDA reduced weight gain and improved lipid and glucose homeostasis in OZR rats. Furthermore, resting energy expenditure was increased by (+)-Z-BDDA, as evident by heat production and oxygen consumption. We also observed a marked reduction in respiratory quotient (RQ) along with a corresponding induction of hepatic AMPK in rodents provided (+)-Z-BDDA. Collectively, these findings indicate that (+)-Z-BDDA partially attenuated obesity and associated pathologies through increased resting energy expenditure and fatty acid utilization. Further investigation is required to fully elucidate the mechanisms involved as well as to determine the potential therapeutic implications for (+)-Z-BDDA on obesity and its related pathologies.

1. Introduction

Doisynolic acids (DAs), such as (+)-Z-BDDA, are a group of synthetically produced compounds that exhibit distinct selective estrogen receptor modulator (SERM) activity in vivo [1]. Based on the structural similarity to 17β-estradiol, DAs were originally investigated as an alternative to hormone replacement therapy [2, 3]. More recently, we demonstrated that administration of these estrogenic compounds suppressed weight gain in normal weight and obese rodents [4-6]. In particular, IP injection of various BDDA isoforms lowered body weight and total adiposity in Wistar and Sprague-Dawley rats, independently of gender or energy intake [5]. Similarly, (+)-Z-BDDA (0.0002% food admixture) reduced weight gain and attenuated hyperglycemia and dyslipidemia in female Zucker Diabetic Fatty (ZDF) rats [4]. We also reported that (+)-Z-BDDA and related compounds exhibited significant cardiovascular protective and antioxidant properties in several studies [4, 7]. However, the specific mechanisms involved in the antiobesity effects of these compounds remain unclear.

Our previous studies showed a marked induction of peroxisome-proliferator-activated receptor-α (PPARα) and carnitine palmitoyltransferase-1 (CPT1) expression in liver of obese rodents administered (+)-Z-BDDA [4]. The modification of these key regulators of fatty acid metabolism is indicative of enhanced energy and substrate metabolism, which may account for the suppression of weight gain and prevention of obesity-related comorbidities. Thus, the objective of the current study was to determine how the synthetic estrogen, (+)-Z-BDDA, impacts energy expenditure and nutrient utilization in obesity. To achieve this, we evaluated indirect calorimetry and metabolic profile in female obese Zucker (OZR) rats provided a 0.0002% food admixture of (+)-Z-BDDA for 10 weeks.

2. Material and Methods

2.1. Animals

As previously described [4], (+)-Z-BDDA prepared from (+)-Z-BDDA-3-OCH3 was administered to female OZR (fa/fa) rats (4–6 weeks of age) as 0.0002% food admixture. Animals were provided unlimited access to semipurified diet (Table 1) with or without (+)-Z-BDDA for 11 weeks (n = 8). All experimental protocols for animal care and use were approved by the Institutional Animal Care and Use Committee.

Table 1

Composition of experimental diets.

	Control	(+)-Z-BDDA2
	g/kg
Casein1	230	230
Sucrose	267.9	267.9
Cornstarch	310	310
Soybean oil	25	25
Lard	65	65
Cellulose1	50	50
Vitamin Mix1	10	10
Mineral Mix1	35	35
Choline Bitartrate1	2.5	2.5
DL-methionine	1.6	1.6
L-cysteine1	3	3
tert-butylhydroquinon1	.014	.014
(+)-Z-BDDA	—	.0018

1ICN Biomedicals, Irvine, CA.

20.00018% food add/mix of (+)-Z-BDDA.

Body weight and energy intake were measured weekly. Nonfasted blood glucose (Glucometer Elite, Mishawaka, IN) was examined periodically to monitor progression of diabetic phenotype (data not shown). Oral glucose tolerance test (OGTT) was performed at week 10 following overnight fast (8–10 hour) [8]. At termination, rats were fasted overnight, euthanized by CO2 asphyxiation, and decapitated for collection of trunk blood in heparinized tubes. Plasma was utilized for quantitative determination of glucose, insulin, cholesterol, and triacylglyceride (TAG) concentration [4]. Tissue was also immediately extracted, weighed, and frozen for biochemical analysis.

2.2. Indirect Calorimetry

Assessment of 24-hour indirect calorimetry (Accuscan Instruments Indirect Calorimeter, Columbus, OH) was performed as previously described [9]. Briefly, zirconia and infrared sensors were used to monitor oxygen (O2) and carbon dioxide (CO2) inside respiratory chambers. All animals were studied simultaneously using different chambers connected to the same O2 and CO2 sensors. After a 24-hour acclimation period, rats were monitored in the metabolic chambers for 24 hours with unlimited access to food and water. Gas samples were collected and analyzed every 5 minutes per animal, and the data were averaged for each hour. Output parameters included VO2 (L/d), RQ (VCO2/VO2), and heat production (kJ/d).

2.3. Immunoblotting

Liver extracts were prepared and proteins separated by SDS page as previously described [10]. The separated proteins were transferred to a nitrocellulose membrane at 80 V for 90 min. Blots were blocked overnight in 5% nonfat milk in tris-buffered saline with 0·05% Tween 20 (TBST) followed by incubation with the specified primary antibody/antibodies for 2 h (Santa Cruz, CA, USA). After immunoblotting, membranes were washed three times with TBST and incubated with the appropriate secondary antibody conjugated with HRP for another hour. After washing off excess secondary antibody, blots were developed with SuperSignal West Pico Chemiluminescent Substrate (Thermo Scientific, Rockford, IL, USA). X-ray film densitometry was used for quantification (BioSpectrum Imaging System, Upland, CA, USA) and signals measured with VisionWorksLS (UVP, Upland, CA, USA).

2.4. Statistical Analysis

Data are presented as means ± SE, compared by Student's t-test (SYSTAT7 10.0, SPSS Incorporated, Chicago, IL).

3. Results

Consistent with our previous work [4, 5], (+)-Z-BDDA reduced body weight and total weight gain, independent of energy intake (Table 2, P < 0.05). These effects corresponded with an improved metabolic phenotype in female OZR rats. In particular, liver weight and plasma total cholesterol were reduced by 18% and 56% in (+)-Z-BDDA-treated animals (Table 2, P < 0.05), respectively. In addition, oral glucose tolerance was improved by approximately 30% with (+)-Z-BDDA treatment. Although we did not detect improvements in plasma insulin or TAG concentration (Table 2), these data confirm that (+)-Z-BDDA administration partially attenuates obesity-related comorbidities through reduced weight gain.

Table 2

Metabolic parameters in female obese Zucker rats (n = 8) provided (+)-Z-BDDA for 11 weeks.

Parameter	Control	(+)-Z-BDDA
Final Body WT (g)	447 ± 20.5	390 ± 34.0*
Total WT Gain (g)	218 ± 13.5	190 ± 11.9*
Total Energy Intake (kJ)	6351 ± 493	5598 ± 547
Liver wt (% Body WT)	6.40 ± 0.15	5.30 ± 0.36*
OGTT AUC (Arbitrary Units)	632 ± 61.5	444 ± 66.1*
Plasma Insulin (nmol/L)	1.21 ± 0.19	0.91 ± 0.03
Plasma Triglycerides (mmol/L)	4.24 ± 0.51	3.69 ± 1.27
Plasma Cholesterol (mmol/L)	7.02 ± 0.79	3.12 ± 0.41*

*indicates significant reduction by (+)-Z-BDDA treatment compared to control as determined by Student's t-test (P < 0.05).

Using 24-hour indirect calorimetry, we then examined if changes in basal metabolism and substrate utilization were responsible for the antiobesity properties of (+)-Z-BDDA. Here, we observed that heat production (Figure 1(a)) and oxygen consumption (Figure 1(b)) for both light and dark cycles were approximately 60% greater with (+)-Z-BDDA treatment when adjusted for dietary intake (P < 0.05). Furthermore, we detected markedly lower RQ values in obese rodents provided (+)-Z-BDDA (Figure 1(c), P < 0.05). These data indicate that (+)-Z-BDDA enhanced resting energy expenditure and fatty acid utilization, which likely contributed to improvements in obesity phenotype.

Figure 1

(+)-Z-BDDA enhanced basal metabolism and fatty acid oxidation in female OZR rats. After a 24-hour acclimation period, rats were monitored in the metabolic chambers (Accuscan Instruments Indirect Calorimeter, Columbus, OH) for 24 h with unlimited access to food and water. Gas samples were collected and analyzed every 5 minutes, averaged for each hour, and presented as total for 24 h period. Output parameters included heat production (kJ/d), VO2 (L/d), and RQ (VCO2/VO2). All measures were obtained from female OZR rats after 11 weeks of (+)-Z-BDDA treatment (n = 8). Graphed values represent means ± SE. Asterisks (*) represent significant differences among means as determined by Student's t-test (P < 0.05). (a) Heat production expressed as kilojoules per day; (b) oxygen consumption expressed as liters per day; (c) respiratory quotient (RQ).

Our previous work [4] has shown that PPARα and CPT1 expression—key regulators of fatty acid oxidation—were induced in liver by (+)-Z-BDDA treatment. To determine if enhanced fatty acid oxidation in liver might contribute to changes in energy expenditure, we measured activation of AMPK, an upstream regulator of fatty acid oxidation. From this analysis, we identified a nearly 40% induction of hepatic AMPK phosphorylation in (+)-Z-BDDA-treated OZR rats (Figure 2, P < 0.05), which occurred without changes in total AMPK (Figure 2). Thus, the antiobesity properties of (+)-Z-BDDA may partially reflect enhanced fatty acid in liver.

Figure 2

(+)-Z-BDDA enhanced hepatic AMPK phosphorylation in female OZR rats. Liver extracts were prepared and proteins separated by SDS page as previously described [10]. Following incubation with primary and secondary antibodies (Santa Cruz), immunoblots were developed with SuperSignal West Pico Chemiluminescent Substrate (Thermo Scientific). X-ray film densitometry was used for quantification (BioSpectrum Imaging System) and analysis (VisionWorksLS, UVP). All measures were obtained from female OZR rats after 11 weeks of (+)-Z-BDDA treatment (n = 4). (a) Hepatic AMPK phosphorylation (AMPK1/2 Thr172), total AMPK (AMPKα1/2 H-300), and CD36 (H-300) are presented as representative blots from control and (+)-Z-BDDA groups; (b) all displayed values represent percentage of control (means ± SE). Significant differences between groups were determined by Student's t-test (P < 0.05) and indicated by asterisk (*).

4. Discussion

In this study, we confirmed earlier findings [4-6] that (+)-Z-BDDA reduced weight gain, independently of energy intake. Similarly, female Zucker diabetic fatty (ZDF) rats administered (+)-Z-BDDA for six months had lower body weight, total adiposity, and enhanced physiological and cardiovascular function [4]. Here, we observed an improvement in lipid and glucose homeostasis with (+)-Z-BDDA treatment (Table 1). The augmentation of these metabolic parameters may be attributed to lower body weight and total adiposity. Additionally, (+)-Z-BDDA may attenuate the development of obesity-related pathologies independently of weight gain. For instance, estrogenic compounds have been reported to reduce inflammation in obese postmenopausal women without changes in body weight [11, 12]. The direct impact of (+)-Z-BDDA and related compounds on these comorbidities should be addressed in future studies. In particular, the efficacy of (+)-Z-BDDA should be compared to natural estrogens. Our previous work with soy phytoestrogens (i.e., genistein and daidzein) has shown significant hepatoprotective properties in vivo [13, 14]. Thus, it is possible that these compounds share a similar signaling mechanism that results in changes to energy expenditure and substrate utilization.

Obese rodents typically exhibit lower heat production and oxygen consumption compared to lean counterparts [15]. For this study, we demonstrated that (+)-Z-BDDA treatment reduced this effect and enhanced resting energy expenditure in female OZR rats. These effects were even more apparent after normalization of heat production and oxygen consumption for dietary intake. This was an important adjustment as heat increment can be considerably influenced by differences in energy consumption [16]. In addition to changes in basal energy expenditure, we observed markedly lower RQ values with (+)-Z-BDDA treatment. Although implementation of RQ as a marker of fatty acid oxidation is not ideal [17], these values are consistent with enhanced fat oxidation. However, the impact of (+)-Z-BDDA on fatty acid utilization in obesity will need to be clarified by further analysis (i.e., non-protein RQ).

We previously demonstrated that (+)-Z-BDDA induced expression of PPARα and CPT1 in liver of female ZDF rats [4]. Based on these findings, we measured phosphorylation of AMPK—a master regulator of fatty acid metabolism in liver. Here, we observed a marked increase in hepatic AMPK phosphorylation with (+)-Z-BDDA treatment. Although this is not a direct measure of fatty acid oxidation, the data are consistent with an induction of mitochondrial fatty oxidation. In the current study, we did not examine the potential involvement of extrahepatic tissues in regulation of these mechanisms. In particular, 17β-estradiol is reported to directly stimulate AMPK phosphorylation in primary muscle cells [18]. To address these limitations, we are currently working with primary hepatocytes and myotubes to determine how (+)-Z-BDDA modifies energy and fatty acid metabolism in these tissues. Moreover, future in vivo experiments need to incorporate additional measurements of AMPK induction, including the ATP to ADP ratio.

Collectively, these data—along with previous work [4, 5]—support a potential therapeutic role for (+)-Z-BDDA in the prevention of obesity and its related comorbidities. Furthermore, we have identified that the antiobesity effects of (+)-Z-BDDA are partially mediated through enhanced resting energy expenditure and fatty acid utilization. Future work will need to address the specific cellular targets and mechanisms involved with these metabolic effects, as well as identify the potential for (+)-Z-BDDA and related compounds to be used as weight loss agents.

5. Conclusions

These findings indicate that the synthetic estrogen, (+)-Z-BDDA partially attenuated obesity and its related pathologies through enhancement of resting energy expenditure and fatty acid utilization. Further investigation is required to identify the specific molecular targets of these compounds as well as to determine their potential therapeutic implications in humans.