Antrodia cinnamomea Confers Obesity Resistance and Restores Intestinal Barrier Integrity in Leptin-deficient Obese Mice

Obesity is associated with metabolic disorders. Thus, obesity prevention and treatment are essential for health. Antrodia cinnamomea (AC) is a multifunctional medicinal fungus used for the treatment of various diseases and for preventing diet-induced obesity. Leptin deficiency causes over-eating and spontaneous obesity. The concomitant metabolic symptoms are more severe than diet-induced obesity. Here, we used leptin-deficient (ob/ob) mice as an animal model for over-feeding to study the effect of AC on obesity. We fed C57BL/6 mice (WT, ob+/+) and ob/ob mice with AC for four weeks before performing qRT-PCR and immunoblot analysis to elaborate AC-modulated mechanisms. Further, we used Caco-2 cells as a human intestinal epithelial barrier model to examine the effect of AC on intestinal permeability. Our results suggested that AC reduces lipid deposits of the liver and epididymal white adipose tissue (EWAT) by promoting lipid metabolism and inhibiting lipogenesis-associated genes and proteins in ob/ob mice. Moreover, AC effectively repaired intestinal-barrier injury caused by leptin deficiency and enhanced intestinal barrier integrity in Caco-2 cells. Interestingly, AC significantly reduced body weight and EWAT with no compromise on food intake in ob/ob mice. Thus, AC effectively reduced obesity caused by leptin-deficiency and can potentially be used as a nutraceutical for treating obesity.

ob+/+-AC, ob/ob-Ctrl, and ob/ob-AC. To mimic treatment on early-stages and exclude downregulated metabolism by aging, the experiment was started in 4-5-week-old male mice and the mice were euthanized after a 4-week treatment period; the experiment was performed as previously described [18], with some modifications. Each group comprised 4-5-week-old male mice of similar initial body weight (no blinding). Body weight was monitored every week from the day before the first time (T0) to the day after the 4-week (T4) treatment (with AC or PBS) period; daily food and water intake and fecal and urine weight were recorded at T0 and T4 using a metabolic cage. All animal experiments were performed according to the protocols approved by the institutional animal care and use committee of the National Health Research Institutes (Approval No. NHRI-IACUC-107046-A). All experiments were performed following the guidelines.

Sample Collection and Histological Observation
The mice were euthanized using carbon dioxide overdose. The liver, intestine, and epididymal white adipose tissue (EWAT) were harvested, fixed in 4% formaldehyde, paraffin-embedded, sectioned, and stained using hematoxylin and eosin (H&E) or immunohistochemistry (IHC). IHC was performed as previously described [19]. The appropriate volume of primary anti-cluster of differentiation 36 (CD36) (1:100, GTX100642, GeneTex) antibody was added to cover the specimen and the samples were incubated at 4 • C overnight. Nuclei were stained with hematoxylin. The images were captured using Pannoramic MIDI II (3DHISTECH Ltd., Budapest, Hungary).

RNA Extraction and Real Time RT-PCR
For real time RT-PCR, tissues were collected in RNAlater RNA Stabilization Reagent (QIAGEN, Hilden, Germany), snap-frozen in liquid nitrogen and stored at -80 • C. Total RNA was isolated from 50-100 mg of homogenized liver, intestine, and EWAT using the TRIzol reagent (ThermoFisher, Waltham, Massachusetts), as described previously [20]. cDNA was synthesized from 2 µg total RNA using M-MLV reverse transcriptase (Promega, Madison, WI, USA). Real-Time PCR reactions were performed on a LightCycler 480 System (Roche) and FastStart Universal SYBR Green Master (Rox) (Roche Diagnostics GmbH, Mannheim, Germany) was used for the reactions. Relative quantification was performed using the comparative 2 -∆∆ CT method [11]. The RNA expression profiles from liver, intestine, and EWAT were normalized to the 18S ribosome, TBP1, and HPRT respectively [15]. For detailed information of primers used in this study, see Supplementary Table S1.

Immunoblotting
For immunoblotting, tissues were collected, snap-frozen in liquid nitrogen, and stored at −80 • C. The tissues were homogenized and lysed in 1% Nonidet P40 Substitute lysis solution in the presence of 0.1% protease inhibitor. Immunoblotting was performed as previously described [21]. A total of 40-60 µg of protein samples were separated on a 12% 1D-SDS-PAGE and transferred to polyvinylidene difluoride membranes (Pall Corp., Port Washington, NY, USA). The membranes were blocked with 5% (w/v) skim milk or bovine serum albumin in Tris-buffered saline with Tween-20 (TBST; 50 mM Tris, 150 mM NaCl, and 0.1% Tween-20 (v/v); pH 8.0) for 1 h. Thereafter, the membranes were probed with the following primary antibodies (all from GeneTex): anti-acetyl-CoA carboxylase (ACC) Subsequently, the membranes were washed in TBST (4 × 10 min) and incubated with horseradish peroxidase-coupled secondary antibodies (Jackson ImmunoResearch Laboratories, Inc., Baltimore, PA, USA) in TBST for 1 h. The membranes were then washed in TBST (6 × 10 min), and the immunoprobed proteins were visualized using the enhanced Nutrients 2020, 12, 726 4 of 14 chemiluminescence method (Visual Protein Biotech Corp., Taiwan). Protein expression was quantified using the ImageQuant TL Software (GE Healthcare Life Sciences, Pittsburgh, PA, USA) and was normalized to that of β-actin, which was used as the internal control.

Statistical Analysis
All statistical analyses were performed using GraphPad Software of Prism 6.0. Comparisons between two and more than two groups were done using the unpaired T test and two-way ANOVA, followed by Tukey's multiple comparisons test. Data are presented as mean ± SEM. Statistical significance levels are indicated as * p < 0.05, ** p < 0.01, and *** p < 0.001; non-significant comparisons are marked as ns.

AC has an Anti-obesity Effect in ob/ob Mice
To understand the effect of AC on overfeeding-induced obesity, ob+/+ and ob/ob mice were fed with AC thrice a week for four weeks and their body weight was measured every week. The experiment was started in 4-5-week-old mice before spontaneous obesity developed [24]. After four weeks of treatment, the average body weights in ob+/+ mice, fed without or with AC, were 23.73 g and 23.17 g, respectively; 39.17 g and 35.95 g in ob/ob mice fed without or with AC, respectively ( Figure 1A). AC significantly reduced the 8% weight gain in ob/ob mice compared to ob/ob mice fed without AC ( Figure 1B). Simultaneously, AC significantly increased daily water intake and urine weight in ob/ob mice; however, food intake and fecal weight remained unchanged in ob+/+ mice ( Figure 1C-F). These results suggested that AC inhibits the obesity phenotype of ob/ob mice without any compromise on food consumption and defecation. week-old ob+/+ and ob/ob fed a diet with or without AC were measured every week for 4 weeks. B Body weights of ob+/+ and ob/ob fed with or without AC were measured after 4 weeks (T4). C-F Daily food or water intake and fecal or urine weights were monitored using a metabolic cage at T0 and T4. All data are expressed as mean ± SEM, *p < 0.05, **p < 0.01, ***p < 0.001. Non-significant; ns. n = 5-14 mice in each group.

AC Alleviates Hepatic Lipid Accumulation and Lipid Deposition in EWAT in ob+/+ and ob/ob Mice
We examined the effect of AC on the liver and EWAT of ob/ob mice after a four-week stimulation period. Although liver weight remained unaltered, EWAT weight was significantly reduced in ob/ob mice (Figure 2A,B). We also used H&E staining to examine the degree of lipid content in liver cells and EWAT. The number of cells in the liver and EWAT was evaluated using the number of nuclei or cells per field. We observed a change in lipid drop size in the cells. AC significantly reduced hepatic week-old ob+/+ and ob/ob fed a diet with or without AC were measured every week for 4 weeks. (B) Body weights of ob+/+ and ob/ob fed with or without AC were measured after 4 weeks (T4). (C-F) Daily food or water intake and fecal or urine weights were monitored using a metabolic cage at T0 and T4. All data are expressed as mean ± SEM, * p < 0.05, ** p < 0.01, *** p < 0.001. Non-significant; ns. n = 5-14 mice in each group.

AC Alleviates Hepatic Lipid Accumulation and Lipid Deposition in EWAT in ob+/+ and ob/ob Mice
We examined the effect of AC on the liver and EWAT of ob/ob mice after a four-week stimulation period. Although liver weight remained unaltered, EWAT weight was significantly reduced in ob/ob mice (Figure 2A,B). We also used H&E staining to examine the degree of lipid content in liver cells and EWAT. The number of cells in the liver and EWAT was evaluated using the number of nuclei or cells per field. We observed a change in lipid drop size in the cells. AC significantly reduced hepatic lipid  A, B Percentage of liver or epididymal white adipose tissue (EWAT) weight were normalized to body weight after ob+/+ and ob/ob mice were fed with or without AC for 4 weeks. C, E The liver and EWAT were examined using hematoxylin and eosin staining. D, F The number of liver or EWAT cells per field was estimated using the ImageJ software. Magnification, 100×. Scale bars are 20 μm for the liver and 50 μm for EWAT. All data are expressed as mean ± SEM, *p < 0.05, **p < 0.01, ***p < 0.001. Nonsignificant; ns. n = 4-14 mice in each group.

AC Downregulates Fatty Acid Uptake and Lipogenesis-associated Genes and Proteins in the Liver of ob+/+ and ob/ob Mice
To investigate how AC improves lipid accumulation in ob/ob mice, we used real time RT-PCR to evaluate regulation of expression of genes involved in lipid catabolism and lipogenesis by AC. We found that AC significantly suppressed the gene expression of peroxisome proliferator-activated receptor gamma (PPARγ), CD36, ME1, and SCD1 in ob+/+ and ob/ob mice ( Figure 3A). In addition, a comparison of ob+/+-Ctrl and ob/ob-AC results showed that AC could restore lipid catabolism and lipogenesis-related gene expression to the normal level in ob/ob mice. Next, we used immunoblotting to further clarify the mechanism. AC significantly decreased expression of fatty acid synthesis-related Percentage of liver or epididymal white adipose tissue (EWAT) weight were normalized to body weight after ob+/+ and ob/ob mice were fed with or without AC for 4 weeks. (C,E) The liver and EWAT were examined using hematoxylin and eosin staining. (D,F) The number of liver or EWAT cells per field was estimated using the ImageJ software. Magnification, 100×. Scale bars are 20 µm for the liver and 50 µm for EWAT. All data are expressed as mean ± SEM, * p < 0.05, ** p < 0.01, *** p < 0.001. Non-significant; ns. n = 4-14 mice in each group.

AC Downregulates Fatty Acid Uptake and Lipogenesis-associated Genes and Proteins in the Liver of ob+/+ and ob/ob Mice
To investigate how AC improves lipid accumulation in ob/ob mice, we used real time RT-PCR to evaluate regulation of expression of genes involved in lipid catabolism and lipogenesis by AC. We found that AC significantly suppressed the gene expression of peroxisome proliferator-activated receptor gamma (PPARγ), CD36, ME1, and SCD1 in ob+/+ and ob/ob mice ( Figure 3A). In addition, a comparison of ob+/+-Ctrl and ob/ob-AC results showed that AC could restore lipid catabolism and lipogenesis-related gene expression to the normal level in ob/ob mice. Next, we used immunoblotting to further clarify the mechanism. AC significantly decreased expression of fatty acid synthesis-related proteins, such as Nutrients 2020, 12, 726 7 of 14 ACC, FAS, and HMGCR in ob+/+ and ob/ob mice ( Figure 3B,C). In addition, AC treatment appeared to increase fatty acid β-oxidation in the mitochondria and peroxisomes, as seen by the up-regulation of CPT1A and FACL4, respectively ( Figure 3D,E). Notably, AC promoted gluconeogenesis by increasing FBP1 expression and decreasing lipid accumulation ( Figure 3D,E). These results demonstrated that AC could prevent lipid accumulation in the liver of ob/ob mice by reducing the expression, at the mRNA and protein level, of genes involved in lipid uptake and lipogenesis, as well as promoting the expression, at the mRNA and protein level, of genes involved in lipid catabolism. proteins, such as ACC, FAS, and HMGCR in ob+/+ and ob/ob mice ( Figure 3B,C). In addition, AC treatment appeared to increase fatty acid β-oxidation in the mitochondria and peroxisomes, as seen by the up-regulation of CPT1A and FACL4, respectively ( Figure 3D,E). Notably, AC promoted gluconeogenesis by increasing FBP1 expression and decreasing lipid accumulation ( Figure 3D,E). These results demonstrated that AC could prevent lipid accumulation in the liver of ob/ob mice by reducing the expression, at the mRNA and protein level, of genes involved in lipid uptake and lipogenesis, as well as promoting the expression, at the mRNA and protein level, of genes involved in lipid catabolism.

AC Promotes Lipolysis-associated Protein Expression in EWAT of ob/ob Mice
We used H&E staining to show that lipid depositions were significantly reduced by AC in the EWAT of ob/ob mice. To investigate the effects of AC in the EWAT of ob+/+ and ob/ob mice, we used immunoblotting. The protein of ACC expression was reduced in the EWAT of ob/ob mice fed with AC, suggesting that AC suppressed lipogenesis ( Figure 4A,B). Notably, the protein levels of ATGL, a lipid droplet degradation (lipolysis) protein, were increased 2.4 times in the EWAT of ob/ob mice, fed with AC, after four weeks. ATGL played a key role in the EWAT by decreasing lipid accumulation ( Figure 4A,B). These results suggested that AC down-regulated lipogenesis and up-regulated a lipolysis-associated protein to decrease fat deposition in the EWAT of ob/ob mice.

AC Promotes Lipolysis-associated Protein Expression in EWAT of ob/ob Mice
We used H&E staining to show that lipid depositions were significantly reduced by AC in the EWAT of ob/ob mice. To investigate the effects of AC in the EWAT of ob+/+ and ob/ob mice, we used immunoblotting. The protein of ACC expression was reduced in the EWAT of ob/ob mice fed with AC, suggesting that AC suppressed lipogenesis ( Figure 4A,B). Notably, the protein levels of ATGL, a lipid droplet degradation (lipolysis) protein, were increased 2.4 times in the EWAT of ob/ob mice, fed with AC, after four weeks. ATGL played a key role in the EWAT by decreasing lipid accumulation ( Figure 4A,B). These results suggested that AC down-regulated lipogenesis and up-regulated a lipolysis-associated protein to decrease fat deposition in the EWAT of ob/ob mice.

AC may Restore the Intestinal Barrier in ob/ob Mice
The intestine is at the front line of absorbing nutrients and lipids and the intestinal barrier integrity and permeability are thought to be involved in certain chronic inflammatory diseases such as inflammatory bowel disease (IBD), obesity, and other metabolic disorders [25]. Previously, AC was shown to produce an anti-obesity and anti-inflammatory effect by maintaining intestinal integrity in DIO mice; moreover, CD36 deletion in endothelial cells of the small intestine resulted in impaired barrier function of the small intestinal in mice [11,26]. We found that CD36 expression was restored in the small intestine of ob/ob mice and unaffected in ob+/+ mice, after AC treatment ( Figure 5A). Levels of tight junction proteins, like zonula occludens-1 (ZO-1) and zonula occludens-2 (ZO-2), that maintain intestinal permeability were unchanged. However, the level of occludin (Ocln) was slightly increased in ob+/+ or ob/ob mice fed with AC, after four weeks ( Figure 5A). Moreover, H&E staining showed increased intestinal barrier integrity in ob/ob mice fed with AC than ob/ob mice not fed AC ( Figure 5B). We also examined CD36 and ZO-1 localization in the intestine using IHC. AC restored CD36 expression in endothelial cells ( Figure 5B). Moreover, AC promoted ZO-1 localization in intestinal epithelial cells in ob/ob mice compared to ob/ob-Ctrl ( Figure 5C). Thus, AC repairs the intestinal barrier by up-regulating CD36 expression, redistributing ZO-1, and reducing intestinal permeability in ob+/+ and ob/ob mice.

AC may Restore the Intestinal Barrier in ob/ob Mice
The intestine is at the front line of absorbing nutrients and lipids and the intestinal barrier integrity and permeability are thought to be involved in certain chronic inflammatory diseases such as inflammatory bowel disease (IBD), obesity, and other metabolic disorders [25]. Previously, AC was shown to produce an anti-obesity and anti-inflammatory effect by maintaining intestinal integrity in DIO mice; moreover, CD36 deletion in endothelial cells of the small intestine resulted in impaired barrier function of the small intestinal in mice [11,26]. We found that CD36 expression was restored in the small intestine of ob/ob mice and unaffected in ob+/+ mice, after AC treatment ( Figure 5A). Levels of tight junction proteins, like zonula occludens-1 (ZO-1) and zonula occludens-2 (ZO-2), that maintain intestinal permeability were unchanged. However, the level of occludin (Ocln) was slightly increased in ob+/+ or ob/ob mice fed with AC, after four weeks ( Figure 5A). Moreover, H&E staining showed increased intestinal barrier integrity in ob/ob mice fed with AC than ob/ob mice not fed AC ( Figure 5B). We also examined CD36 and ZO-1 localization in the intestine using IHC. AC restored CD36 expression in endothelial cells ( Figure 5B). Moreover, AC promoted ZO-1 localization in intestinal epithelial cells in ob/ob mice compared to ob/ob-Ctrl ( Figure 5C). Thus, AC repairs the intestinal barrier by up-regulating CD36 expression, redistributing ZO-1, and reducing intestinal permeability in ob+/+ and ob/ob mice.

Ethanol Extracts of A. Cinnamomea Decrease Intestinal Permeability in Caco-2 Cells
To further examine the effect of AC on the human intestine, we used Caco-2 cells, as a human intestinal epithelial cell barrier model, treated with 500 µL/mL EEAC, according to the cell viability assay (IC25), to understand whether EEAC affected intestinal permeability ( Figure 6A) [23]. Integrity of the Caco-2 membrane was assessed using TEER values after cell seeding for 7, 14, and 21 days. After 21 days, the TEER values of the Caco-2 membrane, treated with EEAC, were significantly higher than that of the control group (Ctrl) ( Figure 6B). EEAC increased the gene of PPARγ expression and induced the upregulation of tight junction proteins, including ZO-1 and ZO-2, in Caco-2 cells ( Figure 6C). Moreover, ZO-1 levels were enhanced in Caco-2 cells treated with EEAC ( Figure 6D). These results suggested that AC enhanced intestinal barrier integrity and decreased intestinal permeability.

Ethanol Extracts of A. Cinnamomea Decrease Intestinal Permeability in Caco-2 Cells
To further examine the effect of AC on the human intestine, we used Caco-2 cells, as a human intestinal epithelial cell barrier model, treated with 500 μL/mL EEAC, according to the cell viability assay (IC25), to understand whether EEAC affected intestinal permeability ( Figure 6A) [23]. Integrity of the Caco-2 membrane was assessed using TEER values after cell seeding for 7, 14, and 21 days. After 21 days, the TEER values of the Caco-2 membrane, treated with EEAC, were significantly higher than that of the control group (Ctrl) ( Figure 6B). EEAC increased the gene of PPARγ expression and induced the upregulation of tight junction proteins, including ZO-1 and ZO-2, in Caco-2 cells ( Figure  6C). Moreover, ZO-1 levels were enhanced in Caco-2 cells treated with EEAC ( Figure 6D). These results suggested that AC enhanced intestinal barrier integrity and decreased intestinal permeability.
Thus, AC administration inhibited hepatic lipogenesis and lipid uptake; promoted lipolysis and reduced lipogenesis to prevent fat deposition in the EWAT in ob/ob mice. In addition, AC restored intestinal barrier integrity in ob/ob mice, enhanced intestinal barrier integrity, and decreased intestinal permeability in Caco-2 cells. Our study provides a rationale for the anti-obesity effect and intestinal protection effect of AC in leptin-deficient obese mice.  Thus, AC administration inhibited hepatic lipogenesis and lipid uptake; promoted lipolysis and reduced lipogenesis to prevent fat deposition in the EWAT in ob/ob mice. In addition, AC restored intestinal barrier integrity in ob/ob mice, enhanced intestinal barrier integrity, and decreased intestinal permeability in Caco-2 cells. Our study provides a rationale for the anti-obesity effect and intestinal protection effect of AC in leptin-deficient obese mice.

Discussion
Leptin maintains the physiological balance of energy. It has an impact on metabolism and body weight and plays a key role in promoting body fat degradation [27]. Leptin secretions are regulated by factors such as excess energy stored as fat, overfeeding, glucose and insulin levels, and inflammatory cytokines [28]. Leptin deficiency could cause symptoms including early-onset morbid obesity, hyperphagia, hypogonadotropic hypogonadism, advanced bone age, hyperinsulinemia, and immune dysfunction [28]. The previous studies have used Roux-en-Y gastric bypass surgery, food or calorie restriction, leptin administration, and adipose tissue transplantation to treat leptin-deficient mice [9, [29][30][31]. Currently, metreleptin (Myalept), a recombinant human leptin analog, is used as an injectible to treat complications of leptin deficiency in patients with congenital or acquired generalized lipodystrophy. Although metreleptin was approved by the Food and Drug Administration in 2014, it has common side effects like headache, ovarian cysts, ear infection, high levels of protein in the urine, fever, and leptin resistance [32,33].
The leptin-deficient ob/ob mice and DIO mice exhibit over-feeding and excessive energy uptake-derived obesity, and they are prone to many diseases like nonalcoholic fatty liver disease (NAFLD), hyperphagia, and type II diabetes [34][35][36]. Interestingly, we found that AC decreased body weight and lipid accumulation in the liver and EWAT, but it did not significantly affect food intake. Although a previous study showed that AC prevents obesity and fatty liver in DIO by regulating AMPK and SREBP signaling, here, the AMKP and SREBP signaling pathways were not affected by AC in ob/ob mice [12]. We further examined fatty acid uptake, lipogenesis, and the lipid catabolism pathway. PPARγ is a lipogenesis-related protein that has been shown to regulate lipid uptake, lipogenesis, and lipid storage. CD36 is an integral membrane protein, also called fatty acid translocase, that is involved in translocation of long-chain fatty acids [37,38]. Our results suggested that AC suppressed PPARγ and CD36 gene expression and reduced fatty acid transportation. Simultaneously, AC inhibited lipogenesis by decreasing the expression of ME1, which generates NADPH used for lipogenesis in the liver and adipose tissues, and SCD1, which is involved in fatty acid synthesis in the liver [39,40]. Moreover, ACC and FAS have been shown to be involved in fatty acid synthesis and HMGCR in the cholesterol synthesis pathway [41,42]. Here, our immunoblotting results showed that AC significantly inhibited lipogenesis by decreasing protein expression of ACC, FAS, and HMGCR in ob+/+ and ob/ob mice. AC also promoted fatty acid β-oxidation in the mitochondria and peroxisomes by increasing protein expression of CPT1A and FACL4, which are the key enzymes that catalyze mitochondrial fatty acid oxidation in the liver [42,43]. Gluconeogenesis is a pathway of glucose metabolism that might assist to keep 3C substrates out of lipid metabolism, and synthesized glucose may be transported to other tissue. [44]. Our results showed that AC alleviated fatty liver mainly by decreasing fatty acid uptake (CD36), lipogenesis (PPARγ, SCD1, ACC, FAS, and ME1), and increasing gluconeogenesis (FBP1) in ob/ob mice. Simultaneously, AC also decreased lipid accumulation in the adipose tissue by decreasing lipogenesis (ACC) and facilitating lipolysis (ATGL) in ob/ob mice.
Intestinal barrier integrity and permeability are thought to contribute to inflammatory bowel disease, obesity, and metabolic disorders [45]. In previous studies, CD36 deletion in endothelial cells of the small intestine impaired the small intestinal barrier [26]. Therefore, CD36 influences lipid utilization, homeostasis, and barrier maintenance in the intestine, especially in intestinal endothelial cells [46]. Also, a previous study showed that AC can regulate gut microbiota and enhance antimicrobial peptide production [11]. Our results showed that AC restored the integrity of the intestinal barrier by increasing CD36 expression in endothelial cells and decreasing intestinal permeability in ob/ob mice. Further, tight junction proteins of the intestine are important in preventing the entry of harmful substances, such as microbial components, into the body [47]. Intestinal permeability is associated with various diseases and is a potential target for disease prevention and therapy [48]. A previous study has shown that AC regulates gut microbiota, prevents DIO, and decreases intestinal inflammation and obesity [11]. In our study, AC slightly increased the expression of intestinal Ocln gene and redistributed ZO-1 to the membrane in ob/ob mice. These results suggested that AC reduces obesity by regulating intestinal permeability and barrier integrity.
Caco-2 human intestinal epithelial cells, used as a gut barrier model, when treated with EEAC also demonstrated that AC could decrease intestinal permeability and reinforce intestinal barrier integrity by regulating ZO-1 expression on the membrane. Taken together, these results suggested that AC alleviates leptin-deficiency induced obesity and disorders by regulating lipid catabolism and restoring intestinal barrier integrity.
In conclusion, our results indicated that AC supplementation inhibited hepatic lipogenesis and lipid uptake in ob/ob mice. At the same time, AC promoted lipolysis and decrease lipogenesis to prevent fat deposition in the EWAT in ob/ob mice. Furthermore, AC enhanced intestinal barrier integrity as preventive protection in ob/ob mice. Our work provides evidence that AC supplementation effectively reduced leptin-deficiency-mediated obesity by regulating metabolism in the liver and EWAT and restoring the gut barrier integrity without any significant compromise on food intake. The AC extract could be potentially used as a nutraceutical for the treatment of obesity, and AC compounds could be further analyzed as potential targets for drug design.