Mouse Model Of Obesity Research Articles

Semaglutide Reduces Cardiomyocyte Damage Caused by High-Fat Through HSDL2.

Obesity-induced inflammation and oxidative stress can cause damage to cardiomyocytes. Semaglutide has the potential to reduce glucose levels and weight, while hydroxysteroid dehydrogenase-like protein 2 (HSDL2) also plays a role in regulating lipid metabolism. This study aimed to investigate the expression of oxidative stress markers and HSDL2 in myocardium and serum under high-fat conditions, in order to elucidate the mechanism of obesity-induced myocardial injury and evaluate the impact of semaglutide on myocardial injury through HSDL2. Mouse models of obesity were established with semaglutide treatment. Palmitic acid-cultured mouse cardiomyocytes with HSDL2 knockout were used, as well as palmitic acid-induced high-fat environment models followed by semaglutide treatment. The levels of inflammatory and oxidative stress markers in serum and cardiomyocytes were measured. Additionally, the expression of HSDL2 and autophagy levels in different cell groups were assessed to evaluate the effect of semaglutide on high-fat diet-induced cardiomyocyte injury mediated by HSDL2. Obesity increased oxidative stress, which was alleviated by intervention with semaglutide. Furthermore, semaglutide down-regulated HSDL2 expression in obese individuals. Moreover, palmitic acid-induced oxidative stress and autophagy were reduced when using cells with knocked out HSDL2 gene. These findings suggest that semaglutide may mitigate cardiomyocyte injury caused by a high-fat diet through regulation of HDLSDSLEP-1 expression. These discoveries are expected to unveil novel molecular mechanisms and provide new targets for clinical treatment.

Rare ginsenosides transformed from stems and leaves of Panax ginseng reverse obesity by promoting browning of white fat through PKA/CREB pathway via REGγ negative regulation

BackgroundWhite adipose tissue (WAT) browning can promote thermogenesis and could be a promising target for treating obesity. Rare ginsenosides transformed from stems and leaves of Panax ginseng (T-GSSL) exhibit numerous biological activities. However, its potential anti-obesity effects and underlying mechanism remain largely unknown. MethodsFive amino acids were selected as the catalysts for the transformation of ginsenosides into rare ginsenosides. An obese mouse model was established by feeding mice a high-fat diet (HFD) for 14 weeks. The effects of T-GSSL on obese mice were assessed by measuring body weight, fat mass, energy expenditure (EE), and glucose tolerance. The 3T3-L1 cells were differentiated into mature adipocytes and incubated with T-GSSL. Immunohistochemistry, co-immunoprecipitation (Co-IP), enzyme-linked immunosorbent assays (ELISA), western blotting (WB), real-time polymerase chain reaction (PCR), and other methods were used to investigate the targets and mechanisms of action of T-GSSL. ResultsGinsenosides in GSSL were hydrolyzed using glutamic acid as a catalyst and 12 rare ginsenosides were produced, with a total conversion rate of 95 %. T-GSSL ameliorated metabolic disorders, lipid ectopic deposition, and obesity, and maintained glucose homeostasis in obese mice. T-GSSL treatment promoted adipose browning and enhanced EE in both HFD mice and 3T3-L1 cells. These effects were decreased in cells treated with a protein kinase A (PKA) antagonist or subjected to PKAcα knockdown, whereas they were increased in REGγ−/− mice. The inhibition of REGγ alongside the activation of the PKA/CREB pathway elucidates the mechanism through which T-GSSL reverses obesity by promoting the browning of adipose tissue. ConclusionsT-GSSL attenuates diet-induced obesity by promoting adipose browning through the inhibition of REGγ and subsequent activation of the PKA/CREB pathway.

In silico screening and in vivo testing of nitrone compounds to reduce insulin resistance in a mouse model of diet-induced obesity

In silico screening and in vivo testing of nitrone compounds to reduce insulin resistance in a mouse model of diet-induced obesity

A polysaccharide from edible red seaweed Bangia fusco-purpurea prevents obesity in high-fat diet-induced C57BL/6 mice

The study aimed to investigate the impacts of a polysaccharide (BFP) from Bangia fusco-purpurea on high-fat diet (HFD)-induced obesity in C57BL/6 mice, as well as its underlying mechanisms. Our results showed that orally administrated BFP was more effective than inulin (INU) in reducing body weight and fat accumulation in obese mice, indicating its anti-obesity effect. BFP effectively improved the compositions and metabolites of intestinal microbiota in obese mice, leading to enhanced energy metabolism and lipid metabolism, thus contributing to its anti-obesity effect. Notably, the better anti-obesity effect of BFP compared to INU were attributed to their varying degrees of modulation of specific intestinal microbial taxa, such as Clostridium and Aerococcus, as well as the regulation of differential metabolites (including biotin, piperine, G6P, etc.) also varies. Also, both in vitro (3T3-L1 preadipocytes) and in vivo (HFD-induced obese mice) models confirmed that BFP achieved anti-obesity effect attributed to enhance energy metabolism, promote lipolysis, increase fatty acid oxidation, and inhibit adipogenesis via activating the AMP-activated protein kinase and Acetyl-CoA carboxylase signaling pathways and suppressing the peroxisome proliferator-activated receptor γ expression. Our findings suggest that BFP has the potential to be used as prebiotics, dietary agents, and nutritional supplements against obesity.

P-Coumaric Acid alleviates non-alcoholic fatty liver disease by promoting GLP-1 secretion via the GRP78-Ca2+ signaling axis

In individuals with obesity-related non-alcoholic fatty liver disease (NAFLD), endogenous Glucagon-like peptide-1 (GLP-1) secretion is compromised, and supplementation with GLP-1 receptor agonists has shown efficacy in ameliorating NAFLD. However, there is currently a scarcity of research focused on the direct promotion of endogenous GLP-1 secretion from L-cells by plant-derived phenolic acids. Hence, this study reveals that p-Coumaric Acid (p-CA), a widely occurring phenolic acid in the plant, holds potential as a therapeutic approach by stimulating the secretion of GLP-1 to improve glucose-lipid metabolism alterations and alleviate NAFLD symptoms. In diet-induced obese (DIO) mouse models, administration of high doses of p-CA led to a significant elevation in serum GLP-1 levels, as well as improvements in body weight gain, glucose level, insufficient insulin secretion, and biochemical abnormalities associated with NAFLD in mice fed with a high-fat diet. Moreover, the number of lipid droplets in the liver tissue of p-CA-treated mice was notably reduced, suggesting its effectiveness in mitigating liver fat accumulation and ameliorating NAFLD severity. Experimental evidence suggests that p-CA exerts its effects by influencing the transcriptional regulation of Glucose-regulated protein 78 kDa (GRP78) through interaction with Nucleophosmin 1 (NPM1), thereby downregulating GRP78 expression. This decrease in GRP78 expression subsequently leads to an increase in intracellular Calcium ions (Ca2+) concentration, which promotes the production and exocytosis of GLP-1-containing vesicles in L cells, consequently enhancing GLP-1 secretion. This research demonstrates the mechanistic role and therapeutic effects of p-CA in regulating GLP-1 secretion and its implications for improving NAFLD, underscoring the pharmacological significance of this natural compound as a dietary supplement.

Fluoxetine Ameliorates Cognitive Deficits in High-Fat Diet Mice by Regulating BDNF Expression.

High-fat diet (HFD) induced obesity is associated with depression-related behavioral and neurogenic changes and may lead to cognitive impairment. Fluoxetine (FXT), the most commonly used antidepressant, may alleviate depressive symptoms by increasing neurogenesis, but the potential efficacy of FXT for HFD-induced cognitive deficits is unclear. In this study, we established an obese HFD mouse model by feeding three-week-old male C57BL/6N mice with a chronic HFD for 18 weeks, then assessed adipose tissue morphology by magnetic resonance imaging and histopathology, assessed cognitive function by Morris water maze and novel object recognition tests, and detected DCX+ and BrdU+ expression in the hippocampal dentate gyrus (DG) region by immunofluorescence bioassay. Western blot detected brain-derived neurotrophic factor (BDNF) levels and CREB-BDNF pathway-related genes were assayed by Quantitative RT-PCR. The results of the study showed that HFD contributes to obesity and cognitive deficits, and more importantly, it also reduces BDNF expression and neurogenesis levels in the hippocampus. Subsequently, we found that treatment with FXT (10 mg/kg/day) ameliorated chronic HFD-induced cognitive deficits and increased the expression of Nestin, BrdU+, and DCX+ in the DG, restored BDNF expression in the hippocampus and increased the expression of genes related to CREB, BDNF, NGF, and MAPK1. In conclusion, our data elucidated that FXT ameliorates cognitive deficits and reduces chronic HFD-induced neurogenesis by restoring BDNF expression and CREB-BDNF signaling, this provides a good basis and scientific significance for future research on the clinical treatment of obesity.

Oxytocin alleviates high-fat diet-induced anxiety by decreasing glutamatergic synaptic transmission in the ventral dentate gyrus in adolescent mice

A high-fat diet (HFD)-induced obesity is associated with mental disorders in adolescence. However, the mechanisms underlying these associations remain unclear. In this study, we hypothesized that synaptic remodeling occurs in the ventral hippocampus (vHP) of obese mice. To investigate this, we established a postnatal model of HFD-induced obesity in mice and observed increased body weight, elevated plasma luteinizing hormone and testosterone levels, premature puberty, and enhanced anxiety-like behavior in male subjects. We also examined the effect of HFD on the c-Fos protein expression in the ventral dentate gyrus (vDG) and explored the influence of intracerebroventricular (i.c.v) oxytocin injections on HFD-induced anxiety. Our results indicated an increase in c-Fos-positive cells in the vDG following HFD consumption. Additionally, we recorded the spontaneous synaptic activity of miniature excitatory postsynaptic currents (mEPSCs) in the vDG. Notably, HFD resulted in an elevated mEPSC frequency without affecting mEPSC amplitude. Subsequently, investigations demonstrated that i.c.v oxytocin injections reversed anxiety-like behavior induced by HFD. Moreover, the application of oxytocin in a bath solution reduced the mEPSC frequency in the vDG. These findings suggest that postnatal HFD intake induces synaptic dysfunction in the vDG, associated with the hyperactivity of vDG neurons, potentially contributing to the anxiety-like behavior in juvenile obesity.

Significance of LIF/LIFR Signaling in the Progression of Obesity-Driven Triple-Negative Breast Cancer.

American women with obesity have an increased incidence of triple-negative breast cancer (TNBC). The impact of obesity conditions on the tumor microenvironment is suspected to accelerate TNBC progression; however, the specific mechanism(s) remains elusive. This study explores the hypothesis that obesity upregulates leukemia inhibitory factor receptor (LIFR) oncogenic signaling in TNBC and assesses the efficacy of LIFR inhibition with EC359 in blocking TNBC progression. TNBC cell lines were co-cultured with human primary adipocytes, or adipocyte-conditioned medium, and treated with EC359. The effects of adiposity were measured using cell viability, colony formation, and invasion assays. Mechanistic studies utilized RNA-Seq, Western blotting, RT-qPCR, and reporter gene assays. The therapeutic potential of EC359 was tested using xenograft and patient-derived organoid (PDO) models. The results showed that adipose conditions increased TNBC cell proliferation and invasion, and these effects correlated with enhanced LIFR signaling. Accordingly, EC359 treatment reduced cell viability, colony formation, and invasion under adipose conditions and blocked adipose-mediated organoid growth and TNBC xenograft tumor growth. RNA-Seq analysis identified critical pathways modulated by LIF/LIFR signaling in diet-induced obesity mouse models. These findings suggest that adiposity contributes to TNBC progression via the activation of the LIF/LIFR pathway, and LIFR inhibition with EC359 represents a promising therapeutic approach for obesity-associated TNBC.

Injectable Gene/Fiber‐Plexes Reverse Adipose Niche Senescence via Mito‐TERT Activation by Endogenous Mitochondrial Translocation

AbstractAddressing adipose niche senescence is crucial for preventing obesity‐related aging. Telomerase reverse transcriptase (TERT) is a promising target for gene therapy, but traditional methods lack precision and safety. A novel mitochondrion‐located TERT (mito‐TERT) activating approach is presented by injectable gene/short‐fiber complexes (gene/fiber‐plexes) to safely reverse adipose niche senescence from mitochondrial enhancement. The gene/fiber‐plexes are prepared from polydopamine‐coated short‐fibers to adsorb cationic dendrimers (PAMAM G3, PG3) carrying TERT plasmids and Coenzyme Q10 (CoQ10), termed PG3‐TERT@CoQ10. Upon intraperitoneal injection, the gene/fiber‐plexes adhere to the peritoneum and release PG3‐TERT@CoQ10, precisely targeting the adipose niche. Transient active oxygen scavenging by CoQ10 activates TERT transfection and endogenous mitochondrion translocation sequentially, enhancing mitochondrial function. In vitro and in vivo studies shows that gene/fiber‐plexes effectively targeted visceral adipose tissue, increased mito‐TERT levels and restored mitochondrial function. In an obese mouse model, they restored adipose tissue homeostasis and metabolic stability. RNA sequencing indicated reduced senescence‐related genes and restored cell cycle. This mito‐TERT activation strategy shows great promise for treating premature aging and metabolic diseases linked to adipose tissue senescence.

Discovery of ZG-2305, an Orally Bioavailable Factor Inhibiting HIF Inhibitor for the Treatment of Obesity and Fatty Liver Disease.

Genetic loss of the 2-oxoglutarate oxygenase factor inhibiting hypoxia-inducible factor (FIH) enhances both glycolysis and aerobic metabolism. FIH is thus a potential target for adiposity control and improving hepatic steatosis. We describe development of a series of novel, potent, and selective FIH inhibitors that occupy both the FIH catalytic site and a recently defined tyrosine conformational-flip pocket. ZG-2305, with a Ki of 79.6 nM for FIH, manifests 38-fold selectivity over the hypoxia-inducible factor (HIF) prolyl hydroxylase PHD2. Oral administration of ZG-2305 in the western-diet induced obesity mouse model results in improved lipid accumulation and recovery from abnormal body weight/hepatic steatosis. Amelioration of nonalcoholic steatohepatitis (NASH) related pathological phenotypes in the HF-CDAA-diet induced NASH mouse model was observed. Preliminary preclinical studies indicate ZG-2305 has good pharmacokinetic properties and an acceptable safety profile. The results imply ZG-2305 is a promising candidate for treatment of obesity and fatty liver disease.

Sympathetic Innervation of Interscapular Brown Adipose Tissue Is Not a Predominant Mediator of Oxytocin-Induced Brown Adipose Tissue Thermogenesis in Female High Fat Diet-Fed Rats.

Recent studies have indicated that hindbrain [fourth ventricle (4V)] administration of the neurohypophyseal hormone, oxytocin (OT), reduces body weight, energy intake and stimulates interscapular brown adipose tissue temperature (TIBAT) in male diet-induced obese (DIO) rats. What remains unclear is whether chronic hindbrain (4V) OT can impact body weight in female high fat diet-fed (HFD) rodents and whether this involves activation of brown adipose tissue (BAT). We hypothesized that OT-elicited stimulation of sympathetic nervous system (SNS) activation of interscapular brown adipose tissue (IBAT) contributes to its ability to activate BAT and reduce body weight in female high HFD-fed rats. To test this hypothesis, we determined the effect of disrupting SNS activation of IBAT on OT-elicited stimulation of TIBAT and reduction of body weight in DIO rats. We first measured the impact of bilateral surgical SNS denervation to IBAT on the ability of acute 4V OT (0.5, 1, and 5 µg ≈ 0.5, 0.99, and 4.96 nmol) to stimulate TIBAT in female HFD-fed rats. We found that the high dose of 4V OT (5 µg ≈ 4.96 nmol) stimulated TIBAT similarly between sham rats and denervated rats (p = NS). We subsequently measured the effect of bilateral surgical denervation of IBAT on the effect of chronic 4V OT (16 nmol/day ≈ 16.1 μg/day) or vehicle infusion to reduce body weight, adiposity and energy intake in female HFD-fed rats (N = 7-8/group). Chronic 4V OT reduced body weight gain (sham: -18.0 ± 4.9 g; denervation: -15.9 ± 3.7 g) and adiposity (sham: -13.9 ± 3.7 g; denervation: -13.6 ± 2.4 g) relative to vehicle treatment (p < 0.05) and these effects were similar between groups (p = NS). These effects were attributed, in part, to reduced energy intake evident during weeks 2 (p < 0.05) and 3 (p < 0.05). To test whether these results translate to other female rodent species, we also examined the effect of chronic 4V infusion of OT on body weight and adiposity in two strains of female HFD-fed mice. Similar to what we found in the HFD-fed rat model, we also found that chronic 4V OT (16 nmol/day) infusion resulted in reduced body weight gain, adiposity and energy intake in female DIO C57BL/6J and DBA/2J mice (p < 0.05 vs. vehicle). Together, these findings suggest that (1) sympathetic innervation of IBAT is not necessary for OT-elicited increases in BAT thermogenesis and weight loss in female HFD-fed rats and (2) the effects of OT to reduce weight gain and adiposity translate to other female mouse models of diet-induced obesity (DIO).

Endoplasmic reticulum stress induces renal fibrosis in high‑fat diet mice via the TGF‑β/SMAD pathway.

The aim of the present study was to investigate the role and mechanism of endoplasmic reticulum stress (ERS) in kidney injury caused by high‑fat diet (HFD). An obese mouse model was established via HFD feeding and intervention was performed by intraperitoneal injection of the ERS inhibitor salubrinal (Sal). Changes in the body and kidney weight and serum biochemical indices of the mice were determined. Hematoxylin and eosin and Masson staining were used to observe the pathological changes of renal tissues. Reverse transcription‑quantitative PCR and western blotting were used to observe the expression of ERS‑related proteins and TGF‑β/SMAD pathway‑related proteins. Immunohistochemistry was employed to explore the distribution of these proteins. Compared with those in the control group, the weight gain, lipid metabolism disorders and deterioration of renal function in the model group were greater. Malondialdehyde was elevated and superoxide dismutase was decreased in renal tissues. The mRNA and protein levels of TGF‑β1, SMAD2/3, α‑smooth muscle actin, collagen I, glucose‑regulated protein 78 and C/EBP‑homologous protein were markedly elevated, whereas SMAD7 was markedly decreased. Sal markedly inhibited the aforementioned effects. This investigation revealed a link between ERS and renal injury caused by HFD. ERS in HFD‑fed mice triggers renal fibrosis through the TGF‑β/SMAD pathway.

Impact of obesity on allergic respiratory diseases and on mental and cognitive performance

Summary Background Obesity and allergies are among the most common diseases of our civilization. Given the simultaneous rise in the prevalence of these diseases in recent years, a potential causal link between the two has been proposed. In particular, obese patients are at an increased risk of developing bronchial asthma, likely due to mechanical restrictions but also to metabolic changes that adversely affect immune function. Neuroscience studies have also shown that obesity can lead to impaired brain function and mental health. In the following review, we will take a closer look at our studies that focus on the influence of obesity on allergic diseases and cognitive performance. Results Both human studies and animal models (mice) have shown that obesity leads to increased allergic responses in the airways. Our studies in a mouse model of obesity confirm that an obese phenotype is associated with increased allergic sensitization and manifestation. These changes are associated with significant shifts in the composition of the gut microbial flora. The microbiome changes are further associated with allergic airway inflammation and an increased incidence of T helper 1 (Th1) type pulmonary macrophages. Interestingly, despite the changes in the microbiome, it is possible to effectively prevent allergy development by inducing oral tolerance. Furthermore, it was observed that obese mice show increased signs of anxiety and depression, as well as reduced cognitive performance. Conclusion Obesity is a complex metabolic disease that significantly impacts our body’s gut microbiome and immune system, resulting in an increased incidence of allergic asthma and neurological/psychological changes. Attention should be given to both the prophylactic and therapeutic measures to mitigate the impact of obesity, including oral tolerance for managing existing allergic diseases.

The effect of anti‐imbalance on glycolipid metabolic homeostasis via the liver–gut axis intervened by 3′‐sialyllactose in obese mice

AbstractSialic acid could ameliorate disorders associated with glycolipid metabolism. 3′‐Sialyllactose (3′‐SL), a type of oligosaccharide, contains sialic acid. We examined the effects of 3′‐SL on glycolipid metabolism in obese mice with high fat diet and explore the underlying mechanisms. A total of 160 male C57BL/6J mice were fed with high‐fat diet for 8 weeks to construct obese mice model. Sixty successfully constructed obese mice were randomly divided three 3′‐SL dosage‐dependent groups, one free sialic acid N‐acetylneuraminic acid (Neu5Ac) group, and one blank control group. Each group of obese mice (n = 12) was continuously supplemented by 3′‐SL or Neu5Ac for 10 weeks. Ten‐week 3′‐SL supplementation and Neu5Ac supplementation both yielded remarkedly lower body weight, reduced fat content, increased energy expenditure and active daily exercises with improved glycolipid biomarkers, and attenuated proinflammation. 3′‐SL increased the colonic abundances of Akkermansia, Lactobacillus, and Solibacillus and reduced those of Enterobacter and Enterococcus. Changes were also observed in colonic and liver transcript and metabolites, which were mainly enriched in glycolipid metabolism, ameliorated immune function, and mitigated inflammatory signals, autophagy, bile acid metabolism, and insulin resistance. Akkermansia and Solibacillus were significantly associated with changes in colonic metabolites and transcriptome genes. The liver bile component and glucose metabolites were significantly correlated with transcriptional gene expression in the aforementioned differential pathways. Therefore, 3′‐SL can enhance the gut microbiota, regulate intestinal immunity and bile acid metabolism, reduce liver oxidative stress and autophagy processes, alleviate chronic inflammation levels, and improve islet function and lower blood sugar levels by acting through the gut–liver axis.

Potential Anti-Obesity Effect of Hazel Leaf Extract in Mice and Network Pharmacology of Selected Polyphenols

Background: Obesity is gradually becoming a widespread health problem, and treatment using natural compounds has seen an increasing trend. As a by-product of hazelnut, hazel leaf is usually disposed of as waste, but it is widely used in traditional and folk medicines around the world. Aim of this study: Based on previous studies, the effects of the regulation of lipid metabolism and the mechanism of hazel leaf polyphenol extraction obesity were investigated. Methods: In this study, a high-fat diet-fed mouse model of obesity and 3T3-L1 preadipocytes were established. The ameliorative effects of the hazel leaf polyphenol extract on obesity and the regulating lipid metabolisms were explored based on network pharmacology, gut microbiota, and molecular docking. Results: Network pharmacology showed that hazel leaf polyphenols may play a role by targeting key targets, including PPARγ, and regulating the PPAR signaling pathway. They significantly improved body weight gain, the liver index, and adiposity and lipid levels; regulated the gut microbiota and short-chain fatty acid contents; down-regulated the expression of lipid synthesis proteins SREBP1c, PPARγ, and C/EBP-α; and up-regulated the expression of p-AMPK in obese mice. They inhibited the differentiation of 3T3-L1 cells, and the expression of related proteins is consistent with the results in vivo. The molecular docking results indicated that gallic acid, quercetin-3-O-beta-D-glucopyranoside, quercetin, myricetin, and luteolin-7-O-glucoside in the hazel leaf polyphenol extract had strong binding activities with PPARγ, C/EBP-α, and AMPK. Conclusions: The results demonstrate that the hazel leaf polyphenol extract can improve obesity by regulating lipid metabolism, which provides a valuable basis for developing health products made from hazel leaf polyphenols in the future.

9179 Type 2 Diabetes Alters Metabolic Fuel Selection During Intermittent Fasting

Abstract Disclosure: M.O. Conn: None. D.M. Marko: None. J.D. Schertzer: None. Type 2 Diabetes Alters Metabolic Fuel Selection During Intermittent Fasting Diabetes is characterized by elevated blood glucose resulting from defective insulin secretion and/or insulin resistance. Intermittent fasting, a popular weight loss strategy involving periodic reduction of caloric intake, can improve glycemia. Fasting shifts metabolism from carbohydrates to free fatty acids and ketones. However, high blood insulin can inhibit lipolysis and alter metabolic substrate selection in prediabetes, resulting in muscle catabolism to maintain energy homeostasis. Clinical studies have observed a significant decrease in muscle mass in subjects with obesity and diabetes. Our research aims to characterize lean mass versus fat loss after intermittent fasting in a mouse model of obesity and type 2 diabetes (T2D) and investigate the role of muscle alanine catabolism. We hypothesized that intermittent fasting would promote less lipolysis and more muscle alanine catabolism, causing more muscle loss in diabetic mice than controls. We compared male db/db mice manifesting obesity, hyperglycemia, and hyperinsulinemia to age-matched db/+ (control) mice. Our lab established a 5:2 repeated fasting protocol of ad-libitum access to food for 5 days a week and 2 days of fasting on non-consecutive days. Blood glucose was monitored weekly in fed and fasted states to assess glycemic control. While intermittent fasting lowered fasted blood glucose in both groups, no significant body weight or metabolic tissue mass changes were observed. Metabolic cage data demonstrated increased reliance on fat-based substrates for energy in control mice that underwent intermittent fasting during feeding and fasting periods. Diabetic mice did not show significant changes in the fasted state, but intermittent fasting led to increased reliance on carbohydrate oxidation during re-feeding periods, indicating impaired metabolic flexibility. After 10 weeks, the mice were sacrificed, and metabolic tissue histology (adipose, liver, skeletal muscle) will be performed. We will also analyze serum markers (alanine, fatty acids, glycerol, glucose, insulin) and the activity of the metabolic enzyme alanine transaminase (ALT) in the muscle and liver. This experiment will improve our understanding of how lipolysis and protein breakdown in muscle regulate lean mass versus fat mass loss in obesity and T2D, leading to more effective tailoring of fasting to specific populations. Presentation: 6/3/2024

Exploring the Effects of Whole Food-Based Dragon Fruit on Metabolic Disorders in High-Fat Diet-Induced Mice.

Metabolic syndrome (MetS) significantly contributes to premature mortality, with obesity being a major risk factor. Dragon fruit, cultivated globally, exhibits bioactivity in preventing obesity-related diseases. Traditional studies using organic solvents for extraction do not align with actual consumption patterns. This study evaluates whole red dragon fruit's effectiveness in ameliorating metabolic disorders using a high-fat diet-induced obesity model in mice for 20 weeks. The experimental groups include the supernatant (RS), precipitate (RP), and pomace (PO) of red dragon fruit juice, compared to the supernatant of white dragon fruit juice (WS). The study finds that dragon fruit extracts reduced adipose tissue weight, body fat percentage, pro-inflammatory cytokines, and improved blood lipid profiles. RP is the most effective, reducing body weight by 4.33g, improving lipid metabolism and glucose homeostasis, and altering gut microbiota to enhance beneficial bacteria and short-chain fatty acids. RP's efficacy in preventing MetS and obesity is attributed to its bioactive components. These findings advocate for using whole fruits in developing functional products, amplifying the agricultural economic value of red dragon fruit.

Elongation factor 1A1 inhibition elicits changes in lipid droplet size, the bulk transcriptome, and cell type-associated gene expression in MASLD mouse liver.

Eukaryotic elongation factor 1A1 (EEF1A1), originally identified for its role in protein synthesis, has additional functions in diverse cellular processes. Of note, we previously discovered a role for EEF1A1 in hepatocyte lipotoxicity. We also demonstrated that a 2-wk intervention with the EEF1A1 inhibitor didemnin B (DB) (50 µg/kg) decreased liver steatosis in a mouse model of obesity and metabolic dysfunction-associated steatotic liver disease (MASLD) [129S6/SvEvTac mice fed Western diet (42% fat) for 26 wk]. Here, we further characterized the hepatic changes occurring in these mice by assessing lipid droplet (LD) size, bulk differential expression, and cell type-associated alterations in gene expression. Consistent with the previously demonstrated decrease in hepatic steatosis, we observed decreased median LD size in response to DB. Bulk RNA sequencing (RNA-Seq) followed by gene set enrichment analysis revealed alterations in pathways related to energy metabolism and proteostasis in DB-treated mouse livers. Deconvolution of bulk data identified decreased cell type association scores for cholangiocytes, mononuclear phagocytes, and mesenchymal cells in response to DB. Overrepresentation analyses of bulk data using cell type marker gene sets further identified hepatocytes and cholangiocytes as the primary contributors to bulk differential expression in response to DB. Thus, we show that chemical inhibition of EEF1A1 decreases hepatic LD size and decreases gene expression signatures associated with several liver cell types implicated in MASLD progression. Furthermore, changes in hepatic gene expression were primarily attributable to hepatocytes and cholangiocytes. This work demonstrates that EEF1A1 inhibition may be a viable strategy to target aspects of liver biology implicated in MASLD progression.NEW & NOTEWORTHY Chemical inhibition of EEF1A1 decreases hepatic lipid droplet size and decreases gene expression signatures associated with liver cell types that contribute to MASLD progression. Furthermore, changes in hepatic gene expression are primarily attributable to hepatocytes and cholangiocytes. This work highlights the therapeutic potential of targeting EEF1A1 in the setting of MASLD, and the utility of RNA-Seq deconvolution to reveal valuable information about tissue cell type composition and cell type-associated gene expression from bulk RNA-Seq data.

Reversion of metabolic dysfunction-associated steatohepatitis by skeletal muscle-directed FGF21 gene therapy

The highly prevalent metabolic dysfunction-associated steatohepatitis (MASH) is associated with liver steatosis, inflammation and hepatocyte injury that can lead to fibrosis and may progress to hepatocellular carcinoma and death. New treatment modalities such as gene therapy may be transformative for MASH patients. Here, we describe that one-time intramuscular administration of adeno-associated viral vectors of serotype 1 (AAV1) encoding native fibroblast growth factor 21 (FGF21), a key metabolic regulator, resulted in sustained increased circulating levels of the factor, which mediated long-term (>1 year) MASH and hepatic fibrosis reversion and halted development of liver tumors in obese male and female mouse models. AAV1-FGF21 treatment also counteracted obesity, adiposity, and insulin resistance, which are significant drivers of MASH. Scale-up to large animals successfully resulted in safe skeletal muscle biodistribution and biological activity in key metabolic tissues. Moreover, as a step towards the clinic, circulating FGF21 levels were characterized in obese, insulin resistant and MASH patients. Overall, these results underscore the potential of the muscle-directed AAV1-FGF21 gene therapy to treat MASH and support its clinical translation.

Obesity modulates hematopoietic stem cell fate decision via IL-1β induced p38/MAPK signaling pathway

BackgroundObesity is accompanied by inflammation, which significantly affects the homeostasis of the immune microenvironment. Hematopoietic stem cells (HSCs), residing primarily in the bone marrow, play a vital role in maintaining and producing diverse mature blood cell lineages for the adult hematopoietic and immune systems. However, how HSCs development is affected by obese-promoting inflammation, and the mechanism by which HSC hematopoietic potency is affected by inflammatory signals originating from the obese-promoting changes on bone marrow niche remain unclear. This study elucidates the relationship between obesity-promoting inflammation and HSC fate determination.MethodsThe obesity mice model was established by feeding C57BL/6J mice a high-fat diet (HFD) containing 60% kcal fat. After 6 weeks, HSCs were analyzed using flow cytometry and identified key inflammation cytokine. Transcriptome sequencing techniques were used to discern the distinct pathways in HSCs. Ultimately, confirming the biological mechanism of obesity-induced HSC fate changes via Anakinra blocking specific inflammatory signals.ResultsObesity caused by HFD changed the physical and biochemical properties of the bone marrow niche. In the HFD mice, the population of long-term HSCs in the bone marrow was decreased and facilitated HSCs differentiation towards the myeloid lineage. In addition, HFD increased expression of the inflammatory factor IL-1β in the bone marrow, and a significantly increased expression of IL-1r1 and active p38/MAPK signaling pathway were detected in the HSCs. Inhibition of IL-1β further normalized the expression of genes in p38/MAPK pathway and reversed HSC fate.ConclusionsThese findings have been demonstrated that the p38/MAPK signaling pathway in HSCs is activated by elevated levels of IL-1β within the HSC niche in obese models, thereby regulating HSC differentiation. It suggested a direct link between obesity-promoting inflammation and myeloid differentiation bias of HSCs in the HFD mice.Graphical abstract