PPARγ-deficient Mice Research Articles

The Loss of PPARγ Expression and Signaling Is a Key Feature of Cutaneous Actinic Disease and Squamous Cell Carcinoma: Association with Tumor Stromal Inflammation.

Given the importance of peroxisome proliferator-activated receptor (PPAR)-gamma in epidermal inflammation and carcinogenesis, we analyzed the transcriptomic changes observed in epidermal PPARγ-deficient mice (Pparg-/-epi). A gene set enrichment analysis revealed a close association with epithelial malignancy, inflammatory cell chemotaxis, and cell survival. Single-cell sequencing of Pparg-/-epi mice verified changes to the stromal compartment, including increased inflammatory cell infiltrates, particularly neutrophils, and an increase in fibroblasts expressing myofibroblast marker genes. A comparison of transcriptomic data from Pparg-/-epi and publicly available human and/or mouse actinic keratoses (AKs) and cutaneous squamous cell carcinomas (SCCs) revealed a strong correlation between the datasets. Importantly, PPAR signaling was the top common inhibited canonical pathway in AKs and SCCs. Both AKs and SCCs also had significantly reduced PPARG expression and PPARγ activity z-scores. Smaller reductions in PPARA expression and PPARα activity and increased PPARD expression but reduced PPARδ activation were also observed. Reduced PPAR activity was also associated with reduced PPARα/RXRα activity, while LPS/IL1-mediated inhibition of RXR activity was significantly activated in the tumor datasets. Notably, these changes were not observed in normal sun-exposed skin relative to non-exposed skin. Finally, Ppara and Pparg were heavily expressed in sebocytes, while Ppard was highly expressed in myofibroblasts, suggesting that PPARδ has a role in myofibroblast differentiation. In conclusion, these data provide strong evidence that PPARγ and possibly PPARα represent key tumor suppressors by acting as master inhibitors of the inflammatory changes found in AKs and SCCs.

Brown Adipose Tissue PPARγ Is Required for the Insulin-Sensitizing Action of Thiazolidinediones.

Brown adipose tissue (BAT) plays a critical role in metabolic homeostasis. BAT dysfunction is associated with the development of obesity through an imbalance between energy expenditure and energy intake. The nuclear receptor peroxisome proliferator-activated receptor gamma (PPARγ) is the master regulator of adipogenesis. However, the roles of PPARγ and thiazolidinediones (TZDs) in the regulation of BAT metabolism remain unclear. TZDs, which are selective PPARγ activators, improve systemic insulin resistance in animals and humans. In the present study, we generated brown adipocyte-specific PPARγ-deficient mice (BATγKO) to examine the in vivo roles of PPARγ and TZDs in BAT metabolism. In electron microscopic examinations, brown adipocyte-specific PPARγ deletion promoted severe whitening of brown fat and morphological alteration of mitochondria. Brown adipocyte-specific PPARγ deletion also reduced mRNA expression of BATselective genes. Although there was no difference in energy expenditure between control and BATγKO mice in calorimetry, norepinephrine-induced thermogenesis was impaired in BATγKO mice. Moreover, pioglitazone treatment improved diet-induced insulin resistance in the control mice but not in the BATγKO mice. These findings suggest that BAT PPARγ is necessary for the maintenance of brown adipocyte function and for the insulin-sensitizing action of TZDs.

Lack of Nogo-B expression ameliorates PPARγ deficiency-aggravated liver fibrosis by regulating TLR4-NF-κB-TNF-α axis and macrophage polarization

Liver fibrosis is an important pathologic process in response to chronic or repetitive liver injury. It can advance to liver cirrhosis. Both peroxisome proliferator-activated receptor gamma (PPARγ) and Nogo-B play critical roles in fibrogenesis, while PPARγ is essential for the development. However, the effect of Nogo-B deficiency on the development of liver fibrosis in cell-specific PPARγ deficient mice remains unknown. In this study, hepatocyte or macrophage PPARγ deficient (hPPARγ KO or mPPARγ KO) mice, Nogo-B deficient mice, and cell-specific PPARγ plus Nogo-B double deficient (hPPARγ/Nogo-B DKO or mPPARγ/Nogo-B DKO) mice were induced liver fibrosis by CCl4 injection. We found hPPARγ KO mice showed enhanced liver fibrotic signatures compared to mPPARγ KO mice after CCl4 administration. Hepatocyte or macrophage PPARγ deficiency further enhanced CCl4-induced severe inflammation infiltration, apoptosis and M1 macrophage polarization in the liver. In contrast, Nogo-B deficiency effectively ameliorated PPARγ deficiency-aggravated liver injury and fibrosis. It ameliorated PPARγ deficiency-aggravated liver inflammation and fibrosis by suppressing hepatic stellate cell activation, TLR4-NF-κB/TNF-α signaling and M1 macrophage polarization. In conclusion, our study demonstrates that PPARγ deficiency increases susceptibility of mice to develop CCl4-induced liver injury/fibrosis, which is potently reduced by Nogo-B deficiency, indicating Nogo-B inhibition might be a therapeutic approach for liver fibrosis treatment.

The Cannabidiol Analog PECS-101 Prevents Chemotherapy-Induced Neuropathic Pain via PPARγ Receptors

Chemotherapy-induced peripheral neuropathy (CIPN) is the main dose-limiting adverse effect of chemotherapy drugs such as paclitaxel (PTX). PTX causes marked molecular and cellular damage, mainly in the peripheral nervous system, including sensory neurons in the dorsal root ganglia (DRG). Several studies have shown the therapeutic potential of cannabinoids, including cannabidiol (CBD), the major non-psychotomimetic compound found in the Cannabis plant, to treat peripheral neuropathies. Here, we investigated the efficacy of PECS-101 (former HUF-101), a CBD fluorinated analog, on PTX-induced neuropathic pain in mice. PECS-101, administered after the end of treatment with PTX, did not reverse mechanical allodynia. However, PECS-101 (1 mg/kg) administered along with PTX treatment caused a long-lasting relief of the mechanical and cold allodynia. These effects were blocked by a PPARγ, but not CB1 and CB2 receptor antagonists. Notably, the effects of PECS-101 on the relief of PTX-induced mechanical and cold allodynia were not found in macrophage-specific PPARγ-deficient mice. PECS-101 also decreased PTX-induced increase in Tnf, Il6, and Aif1 (Iba-1) gene expression in the DRGs and the loss of intra-epidermal nerve fibers. PECS-101 did not alter motor coordination, produce tolerance, or show abuse potential. In addition, PECS-101 did not interfere with the chemotherapeutic effects of PTX. Thus, PECS-101, a new fluorinated CBD analog, could represent a novel therapeutic alternative to prevent mechanical and cold allodynia induced by PTX potentially through the activation of PPARγ in macrophages.

Abstract P228: RhoBTB1 Is Expressed In Placental Syncytiotrophoblast Cells

Preeclampsia is a pregnancy-specific disorder of hypertension and end-organ dysfunction that poses serious clinical problems for women and their offspring that extend beyond the peripartum period. Abnormal placentation is at the core of preeclampsia. PPARγ-deficient mice exhibit numerous placental defects including malformation of the labyrinth zone, lack of infiltration of fetal blood vessels, and rupture of maternal blood sinuses, suggesting that PPARγ is a critical regulator of placental development and possibly function. Rho-related BTB domain-containing protein 1 (RhoBTB1) is a PPARγ target gene which controls the level of cGMP in vascular smooth muscle cells by functioning as an adaptor delivering phosphodiesterase 5 (PDE5) to the Cullin-3 ubiquitin ligase complex. Analysis of gene expression databases revealed that placenta is among the tissues with the highest level of RhoBTB1 expression. Thus, we examined if the level or cell-specificity of RhoBTB1 expression was altered in preeclampsia. Placental samples were obtained from the Medical College of Wisconsin Maternal Research Placenta and Cord Blood Bank. We examined placentas from term healthy (n=3), preterm non-preeclamptic (n=2), term preeclamptic (n=2) and preterm preeclamptic (n=2) pregnancies. RNAscope in situ hybridization was used to qualitatively evaluate expression of RhoBTB1 and several placental markers. Our results reveal that RhoBTB1 co-localizes with CYP19A1, a gene encoding cytochrome P450 enzyme, a target specific to the syncytiotrophoblast cell layer in the placenta. Expression of RhoBTB1 was not co-localized with platelet-endothelial cell adhesion molecule-1 (PECAM) or with melanoma cell adhesion molecule (MCAM), both endothelial cell markers. These results indicate that RhoBTB1 is specifically expressed in the syncytiotrophoblast cell layer in human placentas. This finding persisted in preterm and preeclamptic placental samples. These data compel us to assess the functional significance of placental RhoBTB1 using conditional knockout and a conditional activatable RhoBTB1 models. Further investigative work is being done to determine if placental RhoBTB1 expression is altered based on ethnic and racial differences.

Tectorigenin alleviates intrahepatic cholestasis by inhibiting hepatic inflammation and bile accumulation via activation of PPARγ.

Increasing evidence suggests that human cholestasis is closely associated with the accumulation and activation of hepatic macrophages. Research indicates that activation of PPARγ exerts liver protective effects in cholestatic liver disease (CLD), particularly by ameliorating inflammation and fibrosis, thus limiting disease progression. However, existing PPARγ agonists, such as troglitazone and rosiglitazone, have significant side effects that prevent their clinical application in the treatment of CLD. In this study, we found that tectorigenin alleviates intrahepatic cholestasis in mice by activating PPARγ. Wild-type mice were intragastrically administered α-naphthylisothiocyanate (ANIT) or fed a diet containing 0.1% 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) to simultaneously establish an experimental model of intrahepatic cholestasis and tectorigenin intervention, followed by determination of intrahepatic cholestasis and the mechanisms involved. In addition, PPARγ-deficient mice were administered ANIT and/or tectorigenin to determine whether tectorigenin exerts its liver protective effect by activating PPARγ. Treatment with tectorigenin alleviated intrahepatic cholestasis by inhibiting the recruitment and activation of hepatic macrophages and by promoting the expression of bile transporters via activation of PPARγ. Furthermore, tectorigenin increased expression of the bile salt export pump (BSEP) through enhanced PPARγ binding to the BSEP promoter. In PPARγ-deficient mice, the hepatoprotective effect of tectorigenin during cholestasis was blocked. In conclusion, tectorigenin reduced the recruitment and activation of hepatic macrophages and enhanced the export of bile acids by activating PPARγ. Taken together, our results suggest that tectorigenin is a candidate compound for cholestasis treatment.

Rosiglitazone alleviates intrahepatic cholestasis induced by α-naphthylisothiocyanate in mice: The role of circulating 15-deoxy-Δ12,14 -PGJ2 and Nogo.

Intrahepatic cholestasis is mainly caused by dysfunction of bile secretion and has limited effective treatment. Rosiglitazone is a synthetic agonist of PPARγ, whose endogenous agonist is 15-deoxy-Δ12,14 -PGJ2 (15d-PGJ2 ). Reticulon 4B (Nogo-B) is the detectable Nogo protein family member in the liver and secreted into circulation. Here, we determined if rosiglitazone can alleviate intrahepatic cholestasis in mice. Wild-type, hepatocyte-specific PPARγ or Nogo-B knockout mice received intragastric administration of α-naphthylisothiocyanate (ANIT) and/or rosiglitazone, followed by determination of intrahepatic cholestasis and the involved mechanisms. Serum samples from primary biliary cholangitis (PBC) patients and non-PBC controls were analysed for cholestasis-related parameters. Rosiglitazone prevented wild type, but not hepatocyte-specific PPARγ deficient mice from developing ANIT-induced intrahepatic cholestasis by increasing expression of bile homeostatic proteins, reducing hepatic necrosis, and correcting abnormal serum parameters and enterohepatic circulation of bile. Nogo-B knockout provided protection similar to that of rosiglitazone treatment. ANIT-induced intrahepatic cholestasis decreased 15d-PGJ2 but increased Nogo-B in serum, and both were corrected by rosiglitazone. Nogo-B deficiency in the liver increased 15d-PGJ2 production, thereby activating expression of PPARγ and bile homeostatic proteins. Rosiglitazone and Nogo-B deficiency also alleviated cholestasis-associated dyslipidemia. In addition, rosiglitazone reduced symptoms of established intrahepatic cholestasis in mice. In serum from PBC patients, the decreased 15d-PGJ2 and increased Nogo-B levels were significantly correlated with classical cholestatic markers. Levels of 15d-PGJ2 and Nogo are important biomarkers for intrahepatic cholestasis. Synthetic agonists of PPARγ could be used for treatment of intrahepatic cholestasis and cholestasis-associated dyslipidemia.

Identification of Nogo-B as a new molecular target of peroxisome proliferator-activated receptor gamma

Nonalcoholic fatty liver disease (NAFLD) is a fast-growing chronic liver disease worldwide which can lead to liver cirrhosis. Peroxisome proliferator-activated receptor γ (PPARγ), a ligand-activated transcription factor, plays an important role in lipogenesis. Increased Nogo-B expression can be determined in the liver of cirrhosis patients. However, the effect of PPARγ activation on hepatic Nogo-B expression remains unknown. In this study, we found PPARγ activation by rosiglitazone or dephosphorylation increased Nogo-B expression at mRNA and protein levels in HepG2 cells and mouse primary hepatocytes. Furthermore, we identified a PPARγ response element (PPRE) in Nogo-B promoter and found PPARγ enhanced Nogo-B transcription in a PPRE-dependent manner. ChIP assay further confirms rosiglitazone enhanced the binding of PPARγ to Nogo-B promoter. Using a liver specific PPARγ deficient mice, we determined the critical role of PPARγ expression in regulating hepatic Nogo-B expression. Increased glucose and palmitate in culture medium activated Nogo-B and PPARγ expression in mouse primary hepatocytes, and corresponding, high-fat diet (HFD) induced fatty liver associated with increased hepatic Nogo-B and PPARγ expression in mice. Similarly, serum Nogo-B levels in patients with NAFLD were increased. However, rosiglitazone treatment reduced HFD-induced fatty liver and Nogo-B expression. In summary, our study identifies Nogo-B as a new molecular target of PPARγ, and suggests increased Nogo-B might be a potential indicator for NAFLD.

Myeloid PPAR-γ suppresses acute host diseases and inhibits chronic fibrosis development following influenza infection

Abstract Influenza virus is the leading cause of respiratory infection. In addition to its induction of acute pulmonary diseases, severe influenza infection can lead to the development of chronic lung conditions including pulmonary fibrosis. Currently, the underlying mechanisms regulating the development of influenza sequelae in the respiratory tract are poorly defined. We found that PPAR-γ expression in macrophages is differentially regulated during low pathogenic (sublethal) or highly pathogenic (lethal) influenza infection. Myeloid deletion of PPAR-γ resulted in increased host mortality and morbidity following influenza infection. In the acute phase, myeloid PPAR-γ deficient mice exhibit enhanced macrophage cytokine production, diminished T cell immunity (day 10), delayed viral clearance and impaired lung repair responses following influenza infection. Strikingly, myeloid PPAR-γ deficiency also triggered the development chronic pulmonary fibrosis following influenza infection. We demonstrated that myeloid PPAR-γ deficiency caused scar formation, collagen deposition and fibrotic gene expression in the lungs at 60 days post infection. Mechanistically, myeloid PPAR-γ expression is required for the regeneration of tissue resident alveolar macrophages following influenza clearance, and the depletion of alveolar macrophages at the recovery stage resulted in impaired lung repair and chronic collagen deposition. Thus, our data has revealed that myeloid PPAR-γ expression is critical for the suppression of both acute and chronic pathogenesis of influenza, and suggested that the promotion of PPAR-γ activation may be employed to treat both acute influenza-associated diseases and to prevent chronic fibrosis development.

PPARγ controls pregnancy outcome through activation of EG-VEGF: new insights into the mechanism of placental development.

PPARγ-deficient mice die at E9.5 due to placental abnormalities. The mechanism by which this occurs is unknown. We demonstrated that the new endocrine factor EG-VEGF controls the same processes as those described for PPARγ, suggesting potential regulation of EG-VEGF by PPARγ. EG-VEGF exerts its functions via prokineticin receptor 1 (PROKR1) and 2 (PROKR2). This study sought to investigate whether EG-VEGF mediates part of PPARγ effects on placental development. Three approaches were used: 1) in vitro, using human primary isolated cytotrophoblasts and the extravillous trophoblast cell line (HTR-8/SVneo); 2) ex vivo, using human placental explants (n = 46 placentas); and 3) in vivo, using gravid wild-type PPARγ(+/-) and PPARγ(-/-) mice. Major processes of placental development that are known to be controlled by PPARγ, such as trophoblast proliferation, migration, and invasion, were assessed in the absence or presence of PROKR1 and PROKR2 antagonists. In both human trophoblast cell and placental explants, we demonstrated that rosiglitazone, a PPARγ agonist, 1) increased EG-VEGF secretion, 2) increased EG-VEGF and its receptors mRNA and protein expression, 3) increased placental vascularization via PROKR1 and PROKR2, and 4) inhibited trophoblast migration and invasion via PROKR2. In the PPARγ(-/-) mouse placentas, EG-VEGF levels were significantly decreased, supporting an in vivo control of EG-VEGF/PROKRs system during pregnancy. The present data reveal EG-VEGF as a new mediator of PPARγ effects during pregnancy and bring new insights into the fine mechanism of trophoblast invasion.

Osteoporosis pathophysiology: the updated mechanism

Backgrounds underlying the age-related bone loss can be classified into two categories: systemic abnormality and osteoblast dysfunction. The former includes insufficiency of vitamin D or estrogen, causing a negative balance of calcium metabolism. We propose the contribution of an ageing-suppressing gene, klotho, as a novel systemic factor, since the mouse deficient in the klotho gene exhibits multiple aging phenotypes including osteopenia with a low bone turnover. As a factor intrinsic to osteoblasts, we investigated the role of PPARγ, a key regulator of adipocyte differentiation, based on the facts that osteoblasts and adipocytes share a common progenitor. Heterozygous PPARγ-deficient mice exhibited high bone mass by stimulating osteoblastogenesis from bone marrow progenitors, and this effect became prominent with ageing, indicating involvement of PPARγ-dependent bone formation in the pathophysiology of age-related bone loss. The local environment of osteoblasts is mainly controlled by cytokines/growth factors, among which insulin-like growth factor-I (IGF-I) is the most possible candidate whose production and activity are decreased with ageing. Bone phenotypes of deficient mice of insulin receptor substrates (IRS-1 and IRS-2), essential molecules for intracellular signaling of IGF-I, revealed that IRS-1 is essential to maintain bone turnover by up-regulating anabolic and catabolic functions of osteoblasts, while IRS-2 is needed to keep the predominance of the anabolic function over the catabolic function. A next task ahead of us will be to elucidate the network system of these factors underlying the age-related osteoporosis.

OP0174 Ppar Gamma Deficient Mice Develop Spontaneous Polyarthritis

BackgroundPeroxisome proliferator-activated receptor gamma (PPARγ) is a member of the nuclear receptor superfamily of transcription factors. PPARγ is involved in the regulation of adipocyte differentiation, glucose homeostasis and inflammation. Others...

Rosiglitazone Causes Cardiotoxicity via Peroxisome Proliferator-Activated Receptor γ-Independent Mitochondrial Oxidative Stress in Mouse Hearts

This study aims to test the hypothesis that thiazolidinedione rosiglitazone (RSG), a selective peroxisome proliferator-activated receptor γ (PPARγ) agonist, causes cardiotoxicity independently of PPARγ. Energy metabolism and mitochondrial function were measured in perfused hearts isolated from C57BL/6, cardiomyocyte-specific PPARγ-deficient mice, and their littermates. Cardiac function and mitochondrial oxidative stress were measured in both in vitro and in vivo settings. Treatment of isolated hearts with RSG at the supratherapeutic concentrations of 10 and 30 μM caused myocardial energy deficiency as evidenced by the decreases in [PCr], [ATP], ATP/ADP ratio, energy charge with a concomitant cardiac dysfunction as indicated by the decreases in left ventricular systolic pressure, rates of tension development and relaxation, and by an increase in end-diastolic pressure. When incubated with tissue homogenate or isolated mitochondria at these same concentrations, RSG caused mitochondrial dysfunction as evidenced by the decreases in respiration rate, substrate oxidation rates, and activities of complexes I and IV. RSG also increased complexes I- and III-dependent O₂⁻ production, decreased glutathione content, inhibited superoxide dismutase, and increased the levels of malondialdehyde, protein carbonyl, and 8-hydroxy-2-deoxyguanosine in mitochondria, consistent with oxidative stress. N-acetyl-L-cysteine (NAC) 20 mM prevented RSG-induced above toxicity at those in vitro settings. Cardiomyocyte-specific PPARγ deletion and PPARγ antagonist GW9662 did not prevent the observed cardiotoxicity. Intravenous injection of 10 mg/kg RSG also caused cardiac dysfunction and oxidative stress, 600 mg/kg NAC antagonized these adverse effects. In conclusion, this study demonstrates that RSG at supratherapeutic concentrations causes cardiotoxicity via a PPARγ-independent mechanism involving oxidative stress-induced mitochondrial dysfunction in mouse hearts.

Fifty Shades of Brown

The relationship between increased body mass index and risk for diabetes mellitus or cardiovascular disease is well established. Such observations have driven considerable interest into the nature of adipose tissue and what mechanisms might help explain how adipose tissue and specific aspects of adipocyte biology influence cardiometabolic disorders. For example, adipocytes are now recognized as a source of mediators released into the circulation, like the adipokines resistin and adiponectin, which can modulate inflammation, insulin sensitivity, and atherosclerosis. Other molecules released from adipocytes like free fatty acids and reactive oxygen species can also exert both local and distant effects that may be integral to the development of diabetes mellitus, atherosclerosis, and their complications. To an increasing extent, adipose tissue is now understood as an organ playing important physiological and pathological roles. Both the absence of fat, as with certain lipodystrophies, and excess adiposity are associated with diabetes mellitus, with mechanisms that appear to include infiltration of inflammatory cells into adipose tissue and the release of systemic mediators. Article see p 1067 To these and the many other adipocyte actions that continue to be uncovered, recent work has added another critical dimension to our evolving view of fat: the specific location of a given adipose depot. Subcutaneous white fat, visceral white fat, brown fat, epicardial fat, and perivascular fat—including fat around the coronaries, the thoracic aorta, and the abdominal aorta—have all been identified as distinct depots that exert unique local and systemic effects (Table). These issues are of particular interest given studies. suggesting that brown adipose tissue (BAT), which drives thermogenesis, is variably present in humans, associated with decreased adiposity, and may be a therapeutic target. In this issue of Circulation , Chang and colleagues add to this still emerging picture by providing the intriguing observation that a deficiency of peroxisome proliferator-activated …

Thiazolidinediones and bone fractures.

Thiazolidinediones and bone fractures.

Activation of peroxisome proliferator-activated receptor-γ downregulates soluble epoxide hydrolase in cardiomyocytes

1. The antidiabetic agents, thiazolidinediones (TZD), ligands for peroxisome proliferator-activated receptor-γ (PPARγ), have been reported to reduce cardiac hypertrophy. However, the underlying mechanism is still elusive. 2. We previously reported that soluble epoxide hydrolase (sEH) was specifically upregulated by angiotensin-II (AngII), which directly mediated AngII-induced cardiac hypertrophy. In the present study, we examined the role of sEH in PPARγ inhibiting AngII-induced cardiac hypertrophy. 3. The protein level of sEH was elevated in the left ventricle of AngII-infused Sprague-Dawley rats. Administration of the TZD rosiglitazone decreased this induction. In vitro, AngII upregulated the expression of sEH and hypertrophy markers, including atrial natriuretic factor and β-myosin heavy chain, in rat neonatal cardiomyocytes and H9c2 cells, which was attenuated by rosiglitazone and pioglitazone. An elevated level of sEH was also found in the left ventricle of heterozygous PPARγ-deficient mice. The effect of TZD on sEH level could be reversed by treatment with the PPARγ antagonists, GW9662 and BADGE, which suggests PPARγ activation. In elucidating the mechanisms by which PPARγ inhibited AngII-induced sEH expression, we found that rosiglitazone inhibited AngII-induced sEH promoter activity in H9c2 cells. In contrast, the activity of the human sEH 3'UTR was not affected by AngII and TZD. 4. Our results suggest that the protective role of PPARγ activation in AngII-induced cardiac hypertrophy is, at least in part, through downregulating sEH.

Involvement of Inducible 6-Phosphofructo-2-kinase in the Anti-diabetic Effect of Peroxisome Proliferator-activated Receptor γ Activation in Mice

PFKFB3 is the gene that codes for the inducible isoform of 6-phosphofructo-2-kinase (iPFK2), a key regulatory enzyme of glycolysis. As one of the targets of peroxisome proliferator-activated receptor gamma (PPARgamma), PFKFB3/iPFK2 is up-regulated by thiazolidinediones. In the present study, using PFKFB3/iPFK2-disrupted mice, the role of PFKFB3/iPFK2 in the anti-diabetic effect of PPARgamma activation was determined. In wild-type littermate mice, PPARgamma activation (i.e. treatment with rosiglitazone) restored euglycemia and reversed high fat diet-induced insulin resistance and glucose intolerance. In contrast, PPARgamma activation did not reduce high fat diet-induced hyperglycemia and failed to reverse insulin resistance and glucose intolerance in PFKFB3(+/-) mice. The lack of anti-diabetic effect in PFKFB3(+/-) mice was associated with the inability of PPARgamma activation to suppress adipose tissue lipolysis and proinflammatory cytokine production, stimulate visceral fat accumulation, enhance adipose tissue insulin signaling, and appropriately regulate adipokine expression. Similarly, in cultured 3T3-L1 adipocytes, knockdown of PFKFB3/iPFK2 lessened the effect of PPARgamma activation on stimulating lipid accumulation. Furthermore, PPARgamma activation did not suppress inflammatory signaling in PFKFB3/iPFK2-knockdown adipocytes as it did in control adipocytes. Upon inhibition of excessive fatty acid oxidation in PFKFB3/iPFK2-knockdown adipocytes, PPARgamma activation was able to significantly reverse inflammatory signaling and proinflammatory cytokine expression and restore insulin signaling. Together, these data demonstrate that PFKFB3/iPFK2 is critically involved in the anti-diabetic effect of PPARgamma activation.

Endothelial and Vascular Muscle PPARγ in Arterial Pressure Regulation

Peroxisome proliferator-activated receptor gamma (PPARγ, NR1C3) is a ligand-activated transcription factor belonging to the retinoic acid receptor and thyroid hormone receptor family of nuclear receptors. Classically, these transcription factors regulate expression of target genes by binding to PPAR response elements (PPRE) in the 5′ flanking region of target genes as a heterodimer with retinoid X receptors (RXR). PPARγ first gained prominence when it was discovered that it was expressed specifically in adipocytes and its expression induced their differentiation.1 It has now become clear that although expression of PPARγ may be the highest in adipose tissue, it is expressed in many, if not all, cell types and tissues. Among the many roles ascribed to PPARγ are adipogenesis, insulin action, glucose homeostasis, and lipid metabolism. Other tissue-specific functions for PPARγ in liver, muscle, heart, macrophages, bone, and, more recently, the vasculature have been proposed, ascribed mainly from the analysis of cultured cells and a large and rapidly expanding set of tissue-specific PPARγ knockouts. The standing of PPARγ as a clinically important molecule emerged when it was discovered that PPARγ is the molecular target of the thiazolidinediones (TZD) class of antidiabetic agents.2 Although of understandable interest to diabetes researchers and clinicians, interest among “hypertensionists” increased when it became clear that TZD, in addition to improving glycemic control, tended to lower blood pressure. Many of these studies involved high-risk patients with diabetes or metabolic syndrome and an average decrease of ≈5 mmHg systolic blood pressure and 3 mmHg (diastolic blood pressure [DBP]) was typically reported. According to guidelines from the American Heart Association, 65 million Americans have hypertension and millions of others have prehypertension. Therefore, an analysis of any drug effective at lowering arterial pressure or physiological pathway targeted by that drug involved in regulating arterial pressure deserves serious attention. In this …

Circulating free fatty acids are increased independently of PPARγ activity after administration of poloxamer 407 to mice

Poloxamer 407 (P-407) is a copolymer surfactant that induces a dose-controlled dyslipidemia in both mice and rats. Human macrophages cultured with P-407 exhibit a concentration-dependent reduction in cholesterol efflux to apolipoprotein A1 (apoA1) linked to downregulation of the ATP-binding cassette transporter A1 (ABCA1). Activators of peroxisome proliferator-activated receptor gamma (PPARgamma), as well as PPARalpha, increase expression of liver X receptor alpha (LXRalpha) in macrophages and promote the expression of ABCA1, which, in turn, mediates cholesterol efflux to apoA1. The present study investigated whether P-407 interferes with this signaling pathway. A transactivation assay was used to evaluate whether P-407 can either activate or inhibit the transcriptional activity of PPARgamma. Because thiazolidinedione drugs (PPARgamma agonists) improve glycemic control in type 2 diabetes by reducing blood glucose concentrations, P-407 was also evaluated for its potential to alter plasma insulin and blood glucose concentrations in wild-type (C57BL/6) and PPARgamma-deficient mice. Additionally, because thiazolidinediones attenuate release of free fatty acids (FFAs) from adipocytes and, consequently, decrease circulating plasma levels of FFAs, plasma concentrations of circulating FFAs were also determined in P-407-treated mice. P-407 was unable to modulate PPARgamma activity in cell-based transactivation assays. Furthermore, P-407 did not perturb plasma insulin and blood glucose concentrations after administration to mice. However, by an as yet unidentified mechanism, P-407 caused a significant increase in the serum concentration of FFAs in mice beginning 3 h after administration and lasting more than 24 h postdosing. It is concluded that P-407 does not interfere with the functional activity of PPARgamma after administration to mice.

Peroxisome proliferator-activated receptor-γ protects against hepatic ischemia/reperfusion injury in mice

The function of peroxisome proliferator-activated receptor-gamma (PPARgamma) in hepatic inflammation and injury is unclear. In this study, we sought to determine the role of PPARgamma in hepatic ischemia/reperfusion injury in mice. Male mice were subjected to 90 minutes of partial hepatic ischemia followed by up to 8 hours of reperfusion. PPARgamma was found to be constitutively activated in hepatocytes but not in nonparenchymal cells. Upon induction of ischemia, hepatic PPARgamma activation rapidly decreased and remained suppressed throughout the 8-hour reperfusion period. This reduced activation was not a result of decreased protein availability as hepatic nuclear PPARgamma, retinoid X receptor-alpha (RXRalpha), and PPARgamma/RXRalpha heterodimer expression was maintained. Accompanying the decrease in PPARgamma activation was a decrease in the expression of the natural ligand 15-deoxy-Delta(12,14)-prostaglandin J(2). This was associated with reduced interaction of PPARgamma and the coactivator, p300. To determine whether PPARgamma activation is hepatoprotective during hepatic ischemia/reperfusion injury, mice were treated with the PPARgamma agonists, rosiglitazone and connecting peptide. These treatments increased PPARgamma activation and reduced liver injury compared to untreated mice. Furthermore, PPARgamma-deficient mice had more liver injury after ischemia/reperfusion than their wild-type counterparts. These data suggest that PPARgamma is an important endogenous regulator of, and potential therapeutic target for, ischemic liver injury.