Isorhamnetin Inhibits Proliferation and Invasion and Induces Apoptosis through the Modulation of Peroxisome Proliferator-activated Receptor γ Activation Pathway in Gastric Cancer

Gastric cancer (GC) is a lethal malignancy and the second most common cause of cancer-related deaths. Although treatment options such as chemotherapy, radiotherapy, and surgery have led to a decline in the mortality rate due to GC, chemoresistance remains as one of the major causes for poor prognosis and high recurrence rate. In this study, we investigated the potential effects of isorhamnetin (IH), a 3′-O-methylated metabolite of quercetin on the peroxisome proliferator-activated receptor γ (PPAR-γ) signaling cascade using proteomics technology platform, GC cell lines, and xenograft mice model. We observed that IH exerted a strong antiproliferative effect and increased cytotoxicity in combination with chemotherapeutic drugs. IH also inhibited the migratory/invasive properties of GC cells, which could be reversed in the presence of PPAR-γ inhibitor. We found that IH increased PPAR-γ activity and modulated the expression of PPAR-γ regulated genes in GC cells. Also, the increase in PPAR-γ activity was reversed in the presence of PPAR-γ-specific inhibitor and a mutated PPAR-γ dominant negative plasmid, supporting our hypothesis that IH can act as a ligand of PPAR-γ. Using molecular docking analysis, we demonstrate that IH formed interactions with seven polar residues and six nonpolar residues within the ligand-binding pocket of PPAR-γ that are reported to be critical for its activity and could competitively bind to PPAR-γ. IH significantly increased the expression of PPAR-γ in tumor tissues obtained from xenograft model of GC. Overall, our findings clearly indicate that antitumor effects of IH may be mediated through modulation of the PPAR-γ activation pathway in GC.     

Fatty Acid-binding Proteins 1 and 2 Differentially Modulate the Activation of Peroxisome Proliferator-activated Receptor α in a Ligand-selective Manner

Nuclear hormone receptors (NHRs) regulate the expression of proteins that control aspects of reproduction, development and metabolism, and are major therapeutic targets. However, NHRs are ubiquitous and participate in multiple physiological processes. Drugs that act at NHRs are therefore commonly restricted by toxicity, often at nontarget organs. For endogenous NHR ligands, intracellular lipid-binding proteins, including the fatty acid-binding proteins (FABPs), can chaperone ligands to the nucleus and promote NHR activation. Drugs also bind FABPs, raising the possibility that FABPs similarly regulate drug activity at the NHRs. Here, we investigate the ability of FABP1 and FABP2 (intracellular lipid-binding proteins that are highly expressed in tissues involved in lipid metabolism, including the liver and intestine) to influence drug-mediated activation of the lipid regulator peroxisome proliferator-activated receptor (PPAR) α. We show by quantitative fluorescence imaging and gene reporter assays that drug binding to FABP1 and FABP2 promotes nuclear localization and PPARα activation in a drug- and FABP-dependent manner. We further show that nuclear accumulation of FABP1 and FABP2 is dependent on the presence of PPARα. Nuclear accumulation of FABP on drug binding is driven largely by reduced nuclear egress rather than an increased rate of nuclear entry. Importin binding assays indicate that nuclear access occurs via an importin-independent mechanism. Together, the data suggest that specific drug-FABP complexes can interact with PPARα to effect nuclear accumulation of FABP and NHR activation. Because FABPs are expressed in a regionally selective manner, this may provide a means to tailor the patterns of NHR drug activation in a tissue-specific manner.     

Ligand Binding Reduces SUMOylation of the Peroxisome Proliferator-activated Receptor γ (PPARγ) Activation Function 1 (AF1) Domain

Peroxisome proliferator-activated receptor gamma (PPARγ) is a ligand-activated nuclear receptor regulating adipogenesis, glucose homeostasis and inflammatory responses. The activity of PPARγ is controlled by post-translational modifications including SUMOylation and phosphorylation that affects its biological and molecular functions. Several important aspects of PPARγ SUMOylation including SUMO isoform-specificity and the impact of ligand binding on SUMOylation remain unresolved or contradictory. Here, we present a comprehensive study of PPARγ1 SUMOylation. We show that PPARγ1 can be modified by SUMO1 and SUMO2. Mutational analyses revealed that SUMOylation occurs exclusively within the N-terminal activation function 1 (AF1) domain predominantly at lysines 33 and 77. Ligand binding to the C-terminal ligand-binding domain (LBD) of PPARγ1 reduces SUMOylation of lysine 33 but not of lysine 77. SUMOylation of lysine 33 and lysine 77 represses basal and ligand-induced activation by PPARγ1. We further show that lysine 365 within the LBD is not a target for SUMOylation as suggested in a previous report, but it is essential for full LBD activity. Our results suggest that PPARγ ligands negatively affect SUMOylation by interdomain communication between the C-terminal LBD and the N-terminal AF1 domain. The ability of the LBD to regulate the AF1 domain may have important implications for the evaluation and mechanism of action of therapeutic ligands that bind PPARγ.     

SUMOylation of Human Peroxisome Proliferator-activated Receptor �� Inhibits Its Trans-activity through the Recruitment of the Nuclear Corepressor NCoR

The nuclear receptor peroxisome proliferator-activated receptor α (PPARα) is a key regulator of genes implicated in lipid homeostasis and inflammation. PPARα trans-activity is enhanced by recruitment of coactivators such as SRC1 and CBP/p300 and is inhibited by binding of corepressors such as NCoR and SMRT. In addition to ligand binding, PPARα activity is regulated by post-translational modifications such as phosphorylation and ubiquitination. In this report, we demonstrate that hPPARα is SUMOylated by SUMO-1 on lysine 185 in the hinge region. The E2-conjugating enzyme Ubc9 and the SUMO E3- ligase PIASy are implicated in this process. In addition, ligand treatment decreases the SUMOylation rate of hPPARα. Finally, our results demonstrate that SUMO-1 modification of hPPARα down-regulates its trans-activity through the specific recruitment of corepressor NCoR but not SMRT leading to the differential expression of a subset of PPARα target genes. In conclusion, hPPARα SUMOylation on lysine 185 down-regulates its trans-activity through the selective recruitment of NCoR.     

Ceramide Stimulates ABCA12 Expression via Peroxisome Proliferator-activated Receptor �� in Human Keratinocytes

ABCA12 (ATP binding cassette transporter, family 12) is a cellular membrane transporter that facilitates the delivery of glucosylceramides to epidermal lamellar bodies in keratinocytes, a process that is critical for permeability barrier formation. Following secretion of lamellar bodies into the stratum corneum, glucosylceramides are metabolized to ceramides, which comprise ∼50% of the lipid in stratum corneum. Gene mutations of ABCA12 underlie harlequin ichthyosis, a devastating skin disorder characterized by abnormal lamellar bodies and a severe barrier abnormality. Recently we reported that peroxisome proliferator-activated receptor (PPAR) and liver X receptor activators increase ABCA12 expression in human keratinocytes. Here we demonstrate that ceramide (C₂-Cer and C₆-Cer), but not C₈-glucosylceramides, sphingosine, or ceramide 1-phosphate, increases ABCA12 mRNA expression in a dose- and time-dependent manner. Inhibitors of glucosylceramide synthase, sphingomyelin synthase, and ceramidase and small interfering RNA knockdown of human alkaline ceramidase, which all increase endogenous ceramide levels, also increased ABCA12 mRNA levels. Moreover, simultaneous treatment with C₆-Cer and each of these same inhibitors additively increased ABCA12 expression, indicating that ceramide is an important inducer of ABCA12 expression and that the conversion of ceramide to other sphingolipids or metabolites is not required. Finally, both exogenous and endogenous ceramides preferentially stimulate PPARδ expression (but not other PPARs or liver X receptors), whereas PPARδ knockdown by siRNA transfection specifically diminished the ceramide-induced increase in ABCA12 mRNA levels, indicating that PPARδ is a mediator of the ceramide effect. Together, these results show that ceramide, an important lipid component of epidermis, up-regulates ABCA12 expression via the PPARδ-mediated signaling pathway, providing a substrate-driven, feed-forward mechanism for regulating this key lipid transporter.The outermost layer of mammalian epidermis, the stratum corneum, is essential for permeability barrier function and critical for terrestrial life. The stratum corneum consists of terminally differentiated, anucleate keratinocytes, or corneocytes, surrounded by lipid-enriched lamellar membranes composed of three major lipids, ceramides, cholesterol, and free fatty acids (1). These lipids are delivered to the extracellular spaces of the stratum corneum through exocytosis of lamellar body contents from outermost stratum granulosum cells (2). Mature lamellar bodies contain primarily cholesterol, phospholipids, and glucosylceramides (3). Following lamellar body secretion, the secreted phospholipids and glucosylceramides are converted to free fatty acids and ceramides by phospholipases and β-glucocerebrosidase, respectively (1, 4). ABCA12 (ATP binding cassette transporter, family 12), a lipid transporter predominantly expressed in epidermis, has been shown to play a vital role in the formation of mature lamellar bodies (5, 6), although how this transporter is regulated remains unresolved.ABCA12 is a member of the ABCA subfamily of transporters, which are involved in the transport of a variety of lipids (7). Mutations in ABCA1 cause Tangier disease, which is due to a defect in transporting cholesterol and phospholipids from intracellular lipid stores to apolipoproteins, particularly apolipoprotein A-I (8–11). Mutations in ABCA3 cause neonatal respiratory failure due to a defect in surfactant transport from alveolar type II cells into the alveolar space (12). Mutations in ABCA4 cause Stargardt''s macular degeneration, with visual loss due to a defect in transporting phosphatidylethanolamine-retinylidene out of retinal pigment cells (13).Recently, mutations in ABCA12 have been shown to cause harlequin ichthyosis and a subgroup of lamellar ichthyosis, two disorders of keratinization (5, 14, 15). ABCA12 mutations lead to an abnormality in lamellar body formation, a decrease in lamellar membranes in the extracellular spaces of the stratum corneum, an accumulation of glucosylceramide in the epidermis with a reduction in ceramide (16), and ultimately loss of permeability barrier function (17), which in harlequin ichthyosis can result in neonatal lethality (5, 15). Strikingly, genetic correction of ABCA12 deficiency in patients'' keratinocytes by gene transfer normalized loading of glucosylceramides into lamellar bodies (5). These studies demonstrate a critical role for ABCA12 in epidermal physiology, specifically in the formation of mature lamellar bodies and subsequent permeability barrier homeostasis. Hence, it is crucial to understand how ABCA12 is regulated.Our laboratory recently demonstrated that activation of peroxisome proliferator-activated receptor (PPARδ and PPARγ) or liver X receptor (LXR) stimulates ABCA12 expression in cultured human keratinocytes (18). Both PPARs and LXR are important lipid sensors that stimulate keratinocyte differentiation and enhance permeability barrier function (19). Additionally, PPARα and -δ as well as LXR activators stimulate ceramide synthesis in keratinocytes (20, 21). Likewise, ceramide synthesis increases in keratinocytes during differentiation, foreshadowing the formation of lamellar bodies (22, 23).In addition to serving as structural membrane components, ceramides are also important signaling molecules that can induce growth arrest, differentiation, and apoptosis in various cells, including keratinocytes (24–26). Moreover, distal ceramide metabolites, sphingosine and sphingosine-1-phosphate (Fig. 1), are also important signaling molecules (27).Open in a separate windowFIGURE 1.The central role of ceramide in sphingolipid metabolism in keratinocytes. C1P, ceramide 1-phosphate; Sph, sphingosine; S1P, sphingosine-1-phosphate; GlcCer, glucosylceramide; SM, sphingomyelin.It is well established that the expression of ABCA1 is regulated by cellular cholesterol levels in many cell types, including keratinocytes (28). Cholesterol, if metabolized to certain oxysterols, can activate LXR, which then stimulates ABCA1 expression and the transport of cholesterol out of cells (29). This example of feed-forward regulation leads us to hypothesize that either ceramide or a metabolite of ceramide might stimulate ABCA12 expression, thereby leading to an increase in the transport of glucosylceramides into maturing lamellar bodies. Here, we provide evidence that ceramide stimulates ABCA12 expression in keratinocytes via a mechanism involving PPARδ signaling.     

Selective Antibody Intervention of Toll-like Receptor 4 Activation through Fc γ Receptor Tethering

Inflammation is mediated mainly by leukocytes that express both Toll-like receptor 4 (TLR4) and Fc γ receptors (FcγR). Dysregulated activation of leukocytes via exogenous and endogenous ligands of TLR4 results in a large number of inflammatory disorders that underlie a variety of human diseases. Thus, differentially blocking inflammatory cells while sparing structural cells, which are FcγR-negative, represents an elegant strategy when targeting the underlying causes of human diseases. Here, we report a novel tethering mechanism of the Fv and Fc portions of anti-TLR4 blocking antibodies that achieves increased potency on inflammatory cells. In the presence of ligand (e.g. lipopolysaccharide (LPS)), TLR4 traffics into glycolipoprotein microdomains, forming concentrated protein platforms that include FcγRs. This clustering produces a microenvironment allowing anti-TLR4 antibodies to co-engage TLR4 and FcγRs, increasing their avidity and thus substantially increasing their inhibitory potency. Tethering of antibodies to both TLR4 and FcγRs proves valuable in ameliorating inflammation in vivo. This novel mechanism of action therefore has the potential to enable selective intervention of relevant cell types in TLR4-driven diseases.     

Reduction of Nuclear Peroxisome Proliferator-Activated Receptor γ Expression in Methamphetamine-Induced Neurotoxicity and Neuroprotective Effects of Ibuprofen

We examined changes in nuclear peroxisome proliferator-activated receptor γ (PPARγ) in the striatum in methamphetamine (METH)-induced dopaminergic neurotoxicity, and also examined effects of treatment with drugs possessing PPARγ agonistic properties. The marked reduction of nuclear PPARγ-expressed cells was seen in the striatum 3 days after METH injections (4 mg/kg × 4, i.p. with 2-h interval). The reduction of dopamine transporter (DAT)-positive signals and PPARγ expression, and accumulation of activated microglial cells were significantly and dose-dependently attenuated by four injections of a nonsteroidal anti-inflammatory drug and a PPARγ ligand, ibuprofen (10 or 20 mg/kg × 4, s.c.) given 30 min prior to each METH injection, but not by either a low or high dose of aspirin. Either treatment of ibuprofen or aspirin, that showed no effects on METH-induced hyperthermia, significantly blocked the METH-induced striatal cyclooxygenase (COX) expression. Furthermore, the treatment of an intrinsic PPARγ ligand 15d-PG J2 also attenuated METH injections-induced reduction of striatal DAT. Therefore, the present study suggests the involvement of reduction of PPARγ expression in METH-induced neurotoxicity. Taken together with the previous report showing protective effects of other PPARγ ligand, these results imply that the protective effects of ibuprofen against METH-induced neurotoxicity may be based, in part, on its anti-inflammatory PPARγ agonistic properties, but not on its COX-inhibiting property or hypothermic effect. Special issue article in honor of Dr. Akitane Mori.     

Control of Steroid 21-oic Acid Synthesis by Peroxisome Proliferator-activated Receptor �� and Role of the Hypothalamic-Pituitary-Adrenal Axis

A previous study identified the peroxisome proliferator-activated receptor α (PPARα) activation biomarkers 21-steroid carboxylic acids 11β-hydroxy-3,20-dioxopregn-4-en-21-oic acid (HDOPA) and 11β,20-dihydroxy-3-oxo-pregn-4-en-21-oic acid (DHOPA). In the present study, the molecular mechanism and the metabolic pathway of their production were determined. The PPARα-specific time-dependent increases in HDOPA and 20α-DHOPA paralleled the development of adrenal cortex hyperplasia, hypercortisolism, and spleen atrophy, which was attenuated in adrenalectomized mice. Wy-14,643 activation of PPARα induced hepatic FGF21, which caused increased neuropeptide Y and agouti-related protein mRNAs in the hypothalamus, stimulation of the agouti-related protein/neuropeptide Y neurons, and activation of the hypothalamic-pituitary-adrenal (HPA) axis, resulting in increased adrenal cortex hyperplasia and corticosterone production, revealing a link between PPARα and the HPA axis in controlling energy homeostasis and immune regulation. Corticosterone was demonstrated as the precursor of 21-carboxylic acids both in vivo and in vitro. Under PPARα activation, the classic reductive metabolic pathway of corticosterone was suppressed, whereas an alternative oxidative pathway was uncovered that leads to the sequential oxidation on carbon 21 resulting in HDOPA. The latter was then reduced to the end product 20α-DHOPA. Hepatic cytochromes P450, aldehyde dehydrogenase (ALDH3A2), and 21-hydroxysteroid dehydrogenase (AKR1C18) were found to be involved in this pathway. Activation of PPARα resulted in the induction of Aldh3a2 and Akr1c18, both of which were confirmed as target genes through introduction of promoter luciferase reporter constructs into mouse livers in vivo. This study underscores the power of mass spectrometry-based metabolomics combined with genomic and physiologic analyses in identifying downstream metabolic biomarkers and the corresponding upstream molecular mechanisms.