A rapid, homogeneous, fluorescence polarization binding assay for peroxisome proliferator-activated receptors alpha and gamma using a fluorescein-tagged dual PPARalpha/gamma activator

Peroxisome proliferator-activated receptors (PPARs) and other members of the nuclear hormone receptor family are important drug targets for the treatment of metabolic diseases. PPARalpha and PPARgamma play crucial roles in lipid and glucose metabolism, respectively. Therefore, screening methods that help to rapidly identify activators of these receptors should be of considerable value. A homogeneous fluorescence polarization (FP) ligand binding assay capable of rapidly identifying ligands that bind to both PPARalpha and PPARgamma has been developed using purified PPARalpha or PPARgamma ligand binding domains and a fluorescein-labeled analog (FLA) of a potent dual PPARalpha/gamma activator. FLA activator showed good binding affinity toward both PPARalpha (K(i)=0.7microM) and PPARgamma (K(i)=0.4microM). The binding of FLA activator was rapid and reached a plateau within 10 min. The resulting FP signal was stable for at least 18h. The FP binding assay performed robustly in a 384-well format, and the average Z' value was 0.77. There was a good correlation between the binding potency (IC(50) values) and rank order of binding potency for a panel of standard PPAR ligands obtained in FP binding assay and scintillation proximity assay or gel filtration binding assays using (3)H-labeled PPARalpha (r(2)=0.99) and PPARgamma (r(2)=0.99) ligands. There was also a good correlation of IC(50) values obtained by FP binding assay and scintillation proximity assay for the clinically used PPAR activators. Thus, the FP binding assay with a single fluorescein-labeled PPARalpha/gamma dual activator offers a homogeneous nonradioactive, sensitive, robust, and less expensive high-throughput assay for detecting compounds that bind to both PPARgamma and PPARalpha. Using this FP binding assay, we have identified a large number of PPARalpha/gamma dual activators. A similar assay platform may be easily adapted to other members of the nuclear hormone receptor family.     

AZ 242, a novel PPARalpha/gamma agonist with beneficial effects on insulin resistance and carbohydrate and lipid metabolism in ob/ob mice and obese Zucker rats

Abnormalities in fatty acid (FA) metabolism underlie the development of insulin resistance and alterations in glucose metabolism, features characteristic of the metabolic syndrome and type 2 diabetes that can result in an increased risk of cardiovascular disease. We present pharmacodynamic effects of AZ 242, a novel peroxisome proliferator activated receptor (PPAR)alpha/gamma agonist. AZ 242 dose-dependently reduced the hypertriglyceridemia, hyperinsulinemia, and hyperglycemia of ob/ob diabetic mice. Euglycemic hyperinsulinemic clamp studies showed that treatment with AZ 242 (1 micromol/kg/d) restored insulin sensitivity of obese Zucker rats and decreased insulin secretion. In vitro, in reporter gene assays, AZ 242 activated human PPARalpha and PPARgamma with EC(50) in the micro molar range. It also induced differentiation in 3T3-L1 cells, an established PPARgamma effect, and caused up-regulation of liver fatty acid binding protein in HepG-2 cells, a PPARalpha-mediated effect. PPARalpha-mediated effects of AZ 242 in vivo were documented by induction of hepatic cytochrome P 450-4A in mice. The results indicate that the dual PPARalpha/gamma agonism of AZ 242 reduces insulin resistance and has beneficial effects on FA and glucose metabolism. This effect profile could provide a suitable therapeutic approach to the treatment of type 2 diabetes, metabolic syndrome, and associated vascular risk factors.     

Expression of peroxisome proliferator-activated receptors alpha and gamma in differentiating human colon carcinoma Caco-2 cells

The expression of peroxisome proliferator-activated receptors alpha (PPARalpha) and gamma (PPARgamma) was studied in the human adenocarcinoma Caco-2 cells induced to differentiate by long term culture (15 days). The differentiation of Caco-2 cells was attested by increases in the activities of sucrase-isomaltase and alkaline phosphatase (two brush border enzymes), fatty acyl-CoA oxidase (AOX) and catalase (two peroxisomal enzymes), by an elevation in the protein levels of villin (a brush border molecular marker), AOX, peroxisomal bifunctional enzyme (PBE), catalase and peroxisomal membrane protein of 70 kDa (PMP70). and by the appearance of peroxisomes. The expression of PPARalpha and PPARgamma was investigated by Western blotting, immunocytochemistry, Northern blotting and S1 nuclease protection assay during the differentiation of Caco-2 cells. The protein levels of PPARalpha, PPARgamma, and PPARgamma2 increased gradually during the time-course of Caco-2 cell differentiation. Immunocytochemistry revealed that PPARalpha and gamma were localized in cell nuclei. The PPARgamma1 protein was encoded by PPARgamma3 mRNA because no signal was obtained for PPARgamma1 mRNA using a specific probe in S1 nuclease protection assay. The amount of PPARgamma3 mRNA increased concomitantly to the resulting PPARgamma1 protein. On the other hand, the mRNA of PPARalpha and PPARgamma2 were not significantly changed, suggesting that the increase in their respective protein was due to an elevation of the translational rate. The role played by the PPAR subtypes in Caco-2 cell differentiation is discussed.     

Biochemical mechanism of insulin sensitization, lipid modulation and anti-atherogenic potential of PPAR alpha/gamma dual agonist: Ragaglitazar

The current goal in the treatment of diabetes is not only to enhance the glycemic control but also to improve the associated cardiovascular risk factors. Among many of the strategies available, a co-ligand of PPARalpha and gamma in a single molecule which combines the insulin sensitizing potential of PPARgamma and the beneficial lipid modulating properties of PPARalpha agonism, has gained attention in the recent past. Here we report the biochemical mechanism by which a dual PPAR alpha/gamma agonist Ragaglitazar (Raga) achieves this goal. The PPARalpha component of Raga appears to contribute to a significant increase in beta oxidation, ApoA1 secretion and inhibition of TG biosynthesis in HepG2 cells. These effects of Raga at 60 microM were similar to that shown by Fenofibrate (Feno) at 250 microM. The PPARgamma component of Raga showed significant G3PDH activity and TG accumulation with a corresponding increase in aP2 expression in 3T3L1 cells. Significantly reduced levels of IL-6 and TNFalpha were observed in the culture supernatants of Raga treated 3T3L1 cells. Raga resulted in significant insulin dependent glucose uptake in 3T3L1 with a corresponding increase in GLUT4 expression. Further, Raga showed a significant cholesterol efflux with a corresponding increase in ABCA1 protein expression in THP-1 macrophages. In conclusion, Raga activates both PPARalpha and gamma regulated pathway in adipocytes as well as in hepatocytes which together contributes for its insulin sensitizing and lipid lowering activity. In addition the dual activation of PPAR alpha/gamma also shows an athero-protective potential by inducing reverse cholesterol efflux and inhibiting the pro-inflammatory cytokines.     

Be fit or be sick: peroxisome proliferator-activated receptors are down the road

Investigating metabolism by unveiling the functions of the nuclear receptors peroxisome proliferator-activated receptors (PPARs) in the numerous intricate pathways ensuring energy homeostasis and fitness has been extremely rewarding. Major lines of research were initially determined by the first-characterized crucial roles of PPARalpha in fatty oxidation and of PPARgamma in adipocyte differentiation and lipid storage. Today, the molecular bases of the functional links between glucose, lipid, and protein metabolism, under the important but nonexclusive control of PPARalpha and PPARgamma, are starting to be uncovered. In addition, in the last couple of years evidence has been provided for an important role of PPARbeta (delta) in lipid metabolism. Inevitably, such actors of metabolic homeostasis are implicated in the physiopathology of complex metabolic disorders, such as those constituting the metabolic syndrome, resulting in atherosclerosis and cardiovascular diseases. This review presents a summary of the recent findings on their dual involvement in health and disease.     

Fenofibrate and rosiglitazone lower serum triglycerides with opposing effects on body weight

Activators of peroxisome proliferator activated receptors (PPARs) are effective drugs to improve the metabolic abnormalities linking hypertriglyceridemia to diabetes, hyperglycemia, insulin-resistance, and atherosclerosis. We compared the pharmacological profile of a PPARalpha activator, fenofibrate, and a PPARgamma activator, rosiglitazone, on serum parameters, target gene expression, and body weight gain in (fa/fa) fatty Zucker rats and db/db mice as well as their association in db/db mice. Fenofibrate faithfully modified the expression of PPARalpha responsive genes. Rosiglitazone increased adipose tissue aP2 mRNA in both models while increasing liver acyl CoA oxidase mRNA in db/db mice but not in fatty Zucker rats. Both drugs lowered serum triglycerides yet rosiglitazone markedly increased body weight gain while fenofibrate decreased body weight gain in fatty Zucker rats. KRP 297, which has been reported to be a PPARalpha and gamma co-activator, also affected serum triglycerides and insulin in fatty Zucker rats although no change in body weight gain was noted. These results serve to clearly differentiate the metabolic finality of two distinct classes of drugs, as well as their corresponding nuclear receptors, having similar effects on serum triglycerides.     

Peroxisome proliferator-activated receptors and skin development

PPARs are nuclear hormone receptors. PPAR subtypes (alpha, gamma, delta, the latter a xPPARbeta homologue) were initially investigated in skin because of their known role in regulating lipid metabolism. Studies adding specific PPAR ligand activators to cultured skin or skin cells are compatible with the concepts that PPARalpha activation mediates early lipogenic steps common to the function of both skin epidermal cells (keratinocytes) and sebaceous cells (sebocytes), PPARgamma activation plays a unique role in stimulating sebocyte lipogenesis, and PPARdelta activation may contribute to lipid biosynthesis in both sebocytes and keratinocytes under certain circumstances. Epidermal keratinocytes appear to express small amounts of PPARalpha and PPARdelta mRNA and a trace of PPARgamma mRNA which is up-regulated with differentiation. Sebocytes express all subtypes; PPARgamma gene expression excedes that in epidermis. The emerging data on PPAR protein expression suggests that epidermis normally expresses predominantly PPARalpha, while sebocytes express more PPARgamma than PPARalpha. These expression patterns may change during hyperplasia, differentiation and inflammation. Gene disruption studies in mice are compatible with a contribution of PPARalpha to skin barrier function, suggest that PPARgamma is necessary for sebocyte differentiation, and indicate that PPARdelta can ameliorate inflammatory responses in skin. PPARs appear to play a role in keratinocyte synthesis of the lipids that they export to the intercellular space to form the skin permeability barrier. They also appear to be important for sebocyte formation of the intracellular fused lipid droplets that constitute the holocrine secretion of the sebaceous gland. In addition, they may play roles in keratinocyte growth and differentiation and the inhibition of skin inflammation by diverse mechanisms not necessarily related to fat metabolism.     

Safety issues and prospects for future generations of PPAR modulators

Because of their wide range of actions on glucose homeostasis, lipid metabolism and vascular inflammation, peroxisome proliferator-activated receptors (PPARs) are promising targets for the development of new drugs for the treatment of metabolic disorders such as diabetes, dyslipidemia and atherosclerosis. In clinical practice, PPARalpha agonists, such as the already available fibrates, improve dyslipidemia, while PPARgamma agonists, such as thiazolidinediones, improve insulin resistance and diabetes. The complementary action of simultaneous activation of each PPAR in patients suffering from metabolic syndrome and type 2 diabetes has led to new pharmacological strategies focused on the development of agonists targeting more than one receptor such as the dual PPARalpha/gamma agonists. However, despite the proven benefits of targeting PPARs, safety concerns have recently led to late stage development failures of various PPAR agonists including novel specific PPARgamma agonists and dual PPARalpha/gamma agonists. These safety concerns include potential carcinogenicity in rodents, signs of myopathy and rhabdomyolysis, increase in plasma creatinine and homocysteine, weight gain, fluid retention, peripheral edema and potential increased risk of cardiac failure. Although the discontinued compounds shared common side effects, the reason for discontinuation was always compound specific and the toxicological or adverse effects which have motivated the discontinuation could be either due to the activation of PPARgamma, PPARalpha or both (class effect) or due to a PPAR unrelated effect. Thus, the risk evaluation of each adverse effect should be viewed on a case by case basis considering both the PPAR profile of the drug, its absorption/distribution profile, the nature of the side effect and the putative PPAR-related mechanism of action. This review mainly focuses on the preclinical and clinical adverse events of PPAR agonists that could be of concern when considering the development of new PPAR agonists. The selective modulation of PPAR activities is a promising approach to develop new drugs with preserved efficacy but diminished adverse effects.     

A novel high-throughput screening assay for putative antidiabetic agents through PPARalpha interactions

As natural peroxisome proliferator-activated receptor-alpha (PPARalpha) ligands, high levels of fatty acids and glucose could lead to hyperactivation of PPARalpha, like that seen in diabetes. Important diabetes research goals are to uncover new metabolic or signaling pathways involved in hyperglycemic cellular injury and to develop therapeutics for preventing or reversing this injury. Consequently, 1040 putative antidiabetic agents were screened for their ability to 1) affect PPARalpha lipid binding, 2) directly bind PPARalpha, and 3) alter PPARalpha transactivation in the presence of high glucose. A high-throughput fluorescent binding assay was developed to examine each compound's ability to restore fatty acyl-CoA binding to PPARalpha in the presence of high glucose concentrations. Approximately 1% of the compounds restored acyl-CoA binding by 60% or more. These compounds directly interacted with PPARalpha with high affinity (nM K(d)s), validating the primary screen. Furthermore, these compounds altered PPARalpha transactivation, and 1 strongly reversed the hyperactivation of PPARalpha found in the presence of clofibrate and high glucose levels.     

Peroxisome proliferator-activated receptor alpha activates transcription of the brown fat uncoupling protein-1 gene. A link between regulation of the thermogenic and lipid oxidation pathways in the brown fat cell

High expression of the peroxisome proliferator-activated receptor alpha (PPARalpha) differentiates brown fat from white, and is related to its high capacity of lipid oxidation. We analyzed the effects of PPARalpha activation on expression of the brown fat-specific uncoupling protein-1 (ucp-1) gene. Activators of PPARalpha increased UCP-1 mRNA levels severalfold both in primary brown adipocytes and in brown fat in vivo. Transient transfection assays indicated that the (-4551)UCP1-CAT construct, containing the 5'-regulatory region of the rat ucp-1 gene, was activated by PPARalpha co-transfection in a dose-dependent manner and this activation was potentiated by Wy 14,643 and retinoid X receptor alpha. The coactivators CBP and PPARgamma-coactivator-1 (PGC-1), which is highly expressed in brown fat, also enhanced the PPARalpha-dependent regulation of the ucp-1 gene. Deletion and point-mutation mapping analysis indicated that the PPARalpha-responsive element was located in the upstream enhancer region of the ucp-1 gene. This -2485/-2458 element bound PPARalpha and PPARgamma from brown fat nuclei. Moreover, this element behaved as a promiscuous responsive site to either PPARalpha or PPARgamma activation, and we propose that it mediates ucp-1 gene up-regulation associated with adipogenic differentiation (via PPARgamma) or in coordination with gene expression for the fatty acid oxidation machinery required for active thermogenesis (via PPARalpha).     

WY14,643, a peroxisome proliferator-activated receptor alpha (PPARalpha ) agonist, improves hepatic and muscle steatosis and reverses insulin resistance in lipoatrophic A-ZIP/F-1 mice

WY14,643 is a specific peroxisome proliferator-activated receptor alpha (PPARalpha) agonist with strong hypolipidemic effects. Here we have examined the effect of WY14,643 in the A-ZIP/F-1 mouse, a model of severe lipoatrophic diabetes. With 1 week of treatment, all doses of WY14,643 that were tested normalized serum triglyceride and fatty acid levels. Glucose and insulin levels also improved but only with high doses and longer treatment duration. WY14,643 reduced liver and muscle triglyceride content and increased levels of mRNA encoding fatty acid oxidation enzymes. In liver, the elevated lipogenic mRNA profile (including PPARgamma) in A-ZIP/F-1 mice remained unchanged. These results suggest that WY14,643 acts by increasing beta-oxidation rather by than decreasing lipogenesis or lipid uptake. Hyperinsulinemic euglycemic clamp studies indicated that WY14,643 treatment improved liver more than muscle insulin sensitivity and that hepatic mRNA levels of gluconeogenic enzymes were reduced. Combination treatment with both WY14,643 and a PPARgamma ligand, rosiglitazone, did not lower glucose levels more effectively than did treatment with WY14,643 alone. These data support the hypothesis that reducing intracellular triglycerides in non-adipose tissues improves insulin sensitivity and suggest that further investigation of the role of PPARalpha agonists in the treatment of lipoatrophic diabetes is warranted.