Peroxisome proliferator-activated receptors (PPARs) are nuclear receptors (NRs) that regulate genes involved in lipid and glucose metabolism. PPAR activity is regulated by interactions with cofactors and of interest are cofactors with ubiquitin ligase activity. The E6-associated protein (E6-AP) is an E3 ubiquitin ligase that affects the activity of other NRs, although its effects on PPARs have not been examined. E6-AP inhibited the ligand-independent transcriptional activity of PPARα and PPARβ, with marginal effects on PPARγ, and decreased basal mRNA levels of PPARα target genes. Inhibition of PPARα activity required the ubiquitin ligase function of E6-AP, but occurred in a proteasome-independent manner. PPARα interacted with E6-AP, and in mice treated with PPARα agonist clofibrate, mRNA and protein levels of E6-AP were increased in wildtype, but not in PPARα null mice, indicating a PPARα-dependent regulation. These studies suggest coordinate regulation of E6-AP and PPARα, and contribute to our understanding of the role of PPARs in cellular metabolism.
1. Introduction
The peroxisome proliferator activated receptors (PPARs) are
nuclear hormone receptors that regulate lipid and glucose metabolism, and are
critical to the maintenance of cellular energy homeostasis. In addition, they
regulate several biological processes such as inflammation, differentiation,
apoptosis, and wound healing [1, 2]. Three different subtypes of
PPARs mediate these responses: PPARα, PPARβ, and PPARγ. PPARα is activated by fatty acids, fatty acid
metabolites, and peroxisome proliferators, a diverse group of xenobiotics that
includes the fibrate hypolidemic drugs, phthalate esters, and herbicides [3]. Regulation of gene
expression by PPARα follows the classical ligand-dependent
transcription factor mechanism. Upon ligand binding, PPARα binds to PPAR-response elements (PPREs) in the
promoter of target genes as a heterodimer with retinoid X receptor (RXR). The
multiple protein-PPARα interactions that occur in the transcription
complex are important for proper target gene regulation [4]. These proteins, often called
coregulators, can increase (coactivators) or repress (corepressors)
transcriptional activity. Some coregulators possess enzymatic activity such as
histone acetyl transferase or histone deacetylase, and modulate chromatin
structure to regulate gene transcription [5]. Several proteins with
ubiquitin ligase activity have been characterized in the last few years as
coregulators for nuclear receptors. The recruitment of ubiquitin-proteasome
components to the promoters of nuclear receptor target genes suggest an
additional layer of transcriptional regulation by the ubiquitin-proteasome
pathway [6–8].
This study examines regulation of PPARα by E6-associated protein (E6-AP), a protein
linked to the Angelman syndrome and an E3 ubiquitin ligase that belongs to the
HECT (homologous to the E6-AP C-terminus) family [9]. Ablation of E6-AP in mice is
associated with steroid hormone resistance and reproductive defects [10]. E6-AP coactivates nuclear receptors such as
the estrogen receptor (ER) and the progesterone receptor [11]. In addition, it mediates
proteasomal degradation of proteins such as the nuclear receptor coactivator
AIB1 [12], and tumor suppressors Rb
(retinoblastoma protein), and p53 [13–15]. The studies presented here suggest
a role for the ubiquitin ligase function of E6-AP in regulating PPARα activity.
2. Materials and Methods2.1. Plasmids
The
plasmids pBKRSV-E6AP, pBKRSV-E6AP-C833S, and pM-E6AP were a kind gift from Dr.
Zafar Nawaz (Department of Cell Biology, Baylor College of Medicine, Houston, Tex, USA). The construction of the pVP16-PPARα plasmid has been described previously [16]. The pFR-luciferase (UAS luciferase) plasmid
was purchased from BD Biosciences Clontech (Palo Alto,
Calif, USA),
while pRL/TK and pRL/CMV were from Promega (Madison, Wis, USA). The peroxisome proliferator
response element (PPRE) reporter pACO (-581/-471) G.Luc was supplied by Dr.
Jonathan Tugwood (AstraZeneca Maccelsfield, UK) and has been described
previously [17]. The pcDNA3.1/V5-His-PPARα
plasmid has been described previously [16]. The pcDNA3.1/FLAG-PPARβ and pcDNA3.1-PPARγ plasmids were a kind gift from Dr. Curtis
Omiecinski (Department of Veterinary and Biomedical Sciences, The Pennsylvania
State University, Pa, USA).
2.2. Transfections and Reporter Assays
FaO cells (maintained
in DMEM/Nutrient F-12 Ham with 8% serum and 100 units each of penicillin and
streptomycin) were transfected using Lipofectamine RNAiMAX reagent (Invitrogen,
Carlsbad, Calif, USA), following manufacturer’s instructions. Lipofectamine
(Invitrogen) was used to transfect 293T cells (maintained in HG-DMEM with 8%
serum and 100 units each of penicillin and streptomycin) according to the
manufacturer’s instructions. For reporter assays examining transient PPRE
activity, all transfections included pRL/CMV (Promega) to control for
transfection efficiency and ACO-luciferase. When indicated, following
transfection, cells were treated with 0.1% DMSO or 5 μM MG132 for 6 hours. For reporter assays
examining transient Gal4 response element activity, all transfections included
pRL/CMV to control for transfection efficiency and pFR-Luciferase. In Gal4
response element assays, cells were treated for 6 hours with 0.1% DMSO or 50 μM Wy-14,643 before lysis. Cells were lysed and renilla and firefly luciferase activities were examined using the Dual
Luciferase Assay kit (Promega). Luciferase activity was corrected for
transfection efficiency (pRLTK/pRLCMV) and extraction yield (via total protein
assay).
2.3. Real-Time PCR
Total RNA was isolated using Tri Reagent (Sigma,
St. Louis, Mo, USA)
according to the manufacturer’s protocol. The total RNA was reverse transcribed
using the ABI High Capacity cDNA Archive Kit (Applied Biosystems, Foster City, Calif,
USA). Standard
curves were made using serial dilutions from pooled cDNA samples. Real Time PCR
was performed using the SYBR Green PCR Mater Mix (Applied Biosystems) according
to the manufacturer’s protocol and amplified on the ABI Prism 7300 Sequence
Detection system. Messenger RNA levels of all genes were normalized to β-actin mRNA. Primer sequences (5′-3′) are E6-AP
forward: gaaatgaggcctgcacgaat, E6-AP reverse: gaagaaaagttggacaggaagca, β-actin
forward: ggctctatcctggcctcactg, β-actin reverse: cttgctgatccacatctgctg. Primers
for Acyl CoA Oxidase (ACO) Cytochrome P450 IV A10 (CYP4A10), Angiopoietin-like
protein 4 (Angplt4), have been described previously [16]. Sequences (5′-3′) for other
genes measured are fatty acid binding protein 1 (FABP1) forward:
ttctccggcaagtaccaagtg, FABP1 reverse: tcatgaagggctcaaagttctctt, Enoyl CoA
Hydratase forward: cccgcaggatctttaacaagc, Enoyl CoA Hydratase reverse:
cactgtccatgttgggcaag.
2.4. Western Blotting
Mouse livers were homogenized in lysis buffer
containing 50 mM Tris (pH 8), 120 mM NaCl, 0.5% Nonidet P-40, and 1 : 100 dilution
of protease-inhibitor cocktail (Sigma) after which particulates were removed by
centrifugation. Liver lysates were subjected to SDS/PAGE. Proteins were
transferred to Immobilon-PVDF membrane (Millipore), followed by western using
anti-E6AP antibody (H-182, Santa Cruz Biotechnology). Band intensities were
quantitated using Optiquant Acquisition and Analysis Software.
2.5. Mice
8-week old-male
wild-type, and PPARα-null mice [18] were housed in a light (12 hours
light/12 hours dark) and temperature (25°C) controlled environment in
microisolator cages. Mice were gavaged daily with either vehicle control (corn
oil) or 500 mg clofibrate/kg body weight for 14 days. Mice were euthanized,
livers weighed and homogenized, RNA or protein isolated for analysis as
described above.
3. Results3.1. E6-AP Inhibits the Transcriptional Activity of PPARα, PPARβ, and PPARγ
The transcriptional activity of PPARα, PPARβ/δ, and PPARγ isotypes
was examined in the presence of E6-AP, by measuring the activity of a reporter
gene under the control of a natural PPRE. As seen in
Figure 1, transfecting increasing amounts of E6-AP inhibited PPAR
transactivation in a dose-dependent manner for all three PPAR isotypes. A 40%
decrease in transactivation was observed for PPARα and PPARβ, with a statistically significant
decrease observed first at a ratio of 1.5 : 1 for E6-AP : PPARα, and 2 : 1 for
E6-AP : PPARβ. A 30% decrease in
transactivation was seen with PPARγ, with a statistically significant decrease
observed first at a ratio of 3 : 1 for E6-AP : PPARγ. No changes were observed in ligand-induced
activity of the receptors in the presence of E6-AP (data not shown).
E6-AP inhibits the
transcriptional activity of PPARα, PPARβ, and PPARγ. 293T cells were transfected with plasmids
expressing 4X-ACO-Luciferase, pRLCMV, PPARα, PPARβ or PPARγ, and E6-AP. Cells were lysed and luciferase
activity was corrected for transfection efficiency and protein. Asterisks
indicate a significant difference in luciferase values when compared to the 0
ratio group. (*P<.05 with statistical analysis using ANOVA). The
graphs are representative of 3 independent experiments.
To further examine the effect of
E6-AP on the transcriptional activity of PPARα, E6-AP was expressed in FaO cells by transient
transfection, followed by treatment with PPARα ligand Wy-14,643. The effect of E6-AP
overexpression on mRNA levels of endogenous PPARα target genes was measured. The genes examined
(angiopoietin-like protein 4 or Angplt4, fatty acid binding protein 1 or FABP1,
acyl CoA oxidase or ACO and enoyl CoA hydratase) were chosen based on their
role in PPARα-mediated lipid metabolism, or were previously
identified in gene expression microarrays in FaO cells [19]. As seen in Figure 2, E6-AP
expression resulted in statistically significant changes in mRNA levels Angplt4
(24% decrease) and FABP1 (28% decrease), in the absence of ligand. As
previously seen with PPRE-driven reporter assays (Figure 1), no changes were
seen in ligand-induced mRNA levels of PPARα target genes with E6AP expression.
E6-AP expression results in decreased mRNA
levels of PPARα target genes. FaO cells were transfected
with empty vector or plasmid expressing E6-AP, followed by treatment with 0.1%
DMSO or 50 μM Wy-14,643 for 6 hours. Total RNA was isolated
from the cells and real-time PCR was performed on reverse transcribed RNA.
Asterisks indicate a significant difference when compared to the corresponding
control group. (*P<.05 with statistical analysis using ANOVA). The graphs represent mean values
obtained from 2 independent experiments.
3.3. E6-AP Interacts with PPARα
To examine if the effect of E6-AP
on the transcriptional activity of PPARα was due to a direct interaction between the
two proteins, mammalian-two-hybrid assays were performed using plasmids
expressing PPARα fused to the pVP16 activation domain and E6-AP in the pM
vector. The Gal4 response element reporter (pFR-luciferase) was used to assess
the interaction between E6-AP and PPARα. As seen in Figure 3, induction with PPARα
agonist Wy-14,643 was seen only when E6-AP was coexpressed with PPARα, indicating an interaction between the two
proteins.
E6-AP interacts with
PPARα. 293T cells were
transfected with plasmids expressing pFR-Luciferase, pRLCMV, pVP16-PPARα, pM-E6-AP. Cells were lysed and luciferase
activity was corrected for transfection efficiency and protein. Asterisks
indicate a significant difference in Wy-14,643 induction when compared to the
corresponding DMSO group. (*P<.05 with statistical analysis using
ANOVA). The graph is representative of 2 independent experiments.
3.4. The E3 Ubiquitin Ligase Function of E6-AP Is Required for Inhibition of PPARα Transcriptional Activity
In order to determine if the effect
of E6-AP on PPARα activity was mediated by the E3 ubiquitin
ligase function of E6-AP, E6-AP C833S, a mutant defective in ubiquitin ligase
function was used. Unlike the changes in reporter activity seen with wildtype
(WT) E6-AP (Figure 1), transfecting increasing amounts of E6-AP-C833S did not
result in any changes in activity (Figure 4(a)), indicating that the ubiquitin
ligase function of E6-AP is required for regulating the transcriptional
activity of PPARα. These differences were not due to different
transfection efficiencies, since both E6-AP WT and E6-AP-C833S expressed
equally well in these cells (data not shown). To further assess if
E6-AP-mediated inhibition of PPARα transactivation was via proteasomal
degradation, PPRE-dependent reporter assay was performed in the presence of
proteasome inhibitor MG132. Transfecting increasing amounts of E6-AP resulted
in decreased reporter activity in the presence and absence of MG132 (Figure 4(b)),
indicating that E6-AP-mediated inhibition of PPARα transactivation occurs via a
proteasome-independent mechanism.
E3 ubiquitin ligase
activity of E6-AP is required for regulating PPARα transactivation. (a) 293T cells were transfected with plasmids
expressing 4X-ACO-Luciferase, pRLCMV, PPARα, E6-AP, or E6-AP-C833S that is defective in
ubiquitin ligase function. (b)
Cells were treated with 0.1% DMSO or 5 μM MG132 for 6 hours. Cells were lysed and
luciferase activity was corrected for transfection efficiency and protein.
Asterisks indicate a significant difference when compared to the corresponding
0 ratio group. (*P<.05 with statistical analysis using ANOVA). The
graph is representative of 3 independent experiments.
3.5. E6-AP Is Regulated In Vivo in a PPARα-Dependent Manner
Since NR-mediated transcriptional
regulation of E3 ligases has been demonstrated in a few studies [20–22], regulation of E6-AP in
response to PPARα ligand was examined in
vivo. Wild type and PPARα null mice were maintained on a clofibrate or
control diet for two weeks, following which their livers were analyzed for mRNA
and protein levels of E6-AP. As expected, mRNA levels of known PPARα target
genes (acyl CoA oxidase or ACO and cytochrome P450 IV A10 or CYP4A10) were
induced in response to clofibrate and this response was defective in PPARα null mice (Figure 5(a)). E6-AP mRNA (Figure 5(a)) and protein (Figure 5(b))
levels were significantly increased in wildtype mice in response to clofibrate,
but not in PPARα null mice, indicating a PPARα-dependent regulation.
E6-AP is induced by
clofibrate in a PPARα-dependent
manner. Wildtype and PPARα
null mice were treated with control vehicle or clofibrate for 2 weeks. Groups
of five mice were used for each treatment. (a) Total RNA was isolated from liver and mRNA levels were
measured using real-time PCR. (b)
Protein isolated from liver was analyzed for E6AP expression by western
blot. The graph (lower panel) depicts
mean (n=5) band intensity. Asterisks indicate a significant increase in
clofibrate induction when compared to the PPARα null group. (*P<.05
with statistical analysis using ANOVA).
4. Discussion
The regulation of
PPARs by the ubiquitination has been the subject of limited investigation.
However, recent studies suggest ligand-mediated regulation of PPARs via the
ubiquitin-proteasome system, although no ubiquitin ligase has been identified.
PPARα and PPARβ ligands affect receptor ubiquitination and protein levels [23–26]. Ligand binding induces
transcriptional activation of PPARγ that is followed by degradation [27]. This study identifies the E3
ubiquitin ligase E6-AP, as regulator of PPAR activity. The transcriptional
activity of all three PPAR isotypes was inhibited by E6-AP. No changes were
observed in ligand-induced transcriptional activity in the presence of E6-AP.
PPARα and E6-AP interacted in mammalian two hybrid assays, and by using an
E6-AP mutant defective in ubiquitin ligase activity, we demonstrate that
inhibition of PPARα activity required the E3 ubiquitin ligase function of
E6-AP. Interestingly, the presence of proteasome inhibitor MG132 had no effect
on inhibition of PPARα transactivation, suggesting that the proteasomal
degradation is not required for E6-AP-mediated regulation of receptor
transcriptional activity. This finding points to nonproteolytic functions of
ubiquitination in modulating PPARα activity. The multifaceted roles of ubiquitin
in regulating protein localization, recruiting coregulators, and modifying
chromatin structure are now well-recognized [7, 8, 28]. It would be of interest to
examine these possibilities in regulation of PPARα function by E6-AP.
The inhibition of PPARα transcriptional activity by E6-AP is in
contrast to previous findings with the progesterone receptor, where E6-AP
coactivated receptor function, and the ubiquitin ligase activity was
dispensable for its coactivating ability [11]. These observations suggest
different mechanisms of E6-AP-mediated regulation of nuclear receptors. E6-AP
is recruited to the ER-responsive pS2 promoter and is preferentially associated
with E2-liganded ERα [29]. It would be of interest to
determine if E6-AP is recruited to promoters of PPARα target genes, as a
mechanism of transcriptional regulation. Evidence also exists for NR-mediated
transcriptional regulation of E3 ligases. Estrogen activation of ERα induces
the expression of two ubiquitin ligases, MDM2 and Siah2 [20–22]. MDM2 is also regulated by
the thyroid hormone receptor [30] orphan receptor TR3 [31], and constitutive androstane
receptor (CAR) [32]. The breast cancer associated gene (BCA2) was
identified as an E3 ubiquitin ligase and BCA2 expression correlates with
positive ER status in breast tumors, suggesting that BCA2 and ER might be
coregulated [21]. Our study shows that E6-AP
mRNA and protein levels are increased in mice in response to PPARα ligand
clofibrate in wildtype but not PPARα null mice, indicating a coordinate mode of
regulation between PPARα and E6-AP. In contrast to the ligand-independent
decrease in PPARα transcriptional activity mediated by E6AP in
FaO cells, ligand treatment resulted in an increase in E6-AP expression in mice
that was PPARα-dependent. These results allude to the
existence of a feedback loop between PPARα and E6-AP wherein PPARα increases the expression of a negative
regulator for control of its transcriptional activity.
Studies in our
laboratory have identified MDM2 as another ubiquitin ligase for PPARα
(unpublished results). MDM2 regulated the transcriptional activity of PPARα by
being recruited to the promoters of PPARα target genes in response to ligand,
and it interacted with the A/B domain of PPARα. The various biological processes
regulated by PPARs are crucial in control of disorders such as diabetes,
inflammation, and cardiovascular ailments, and ubiquitin ligases such as E6-AP
and MDM2 may present useful targets for pharmacological intervention and
improved PPAR-based therapeutics.
In addition to
contributing to understanding PPAR regulation by ubiquitination, other
interesting connections can be made about the significance of the E6-AP-PPARα interaction. E6-AP mediates ubiquitination and
degradation of the Hepatitis C virus (HCV) core protein, which plays a crucial
role in HCV-related liver disease [33]. HCV infections are
associated with reduced hepatic PPARα expression [34–37], and PPARα is implicated in
HCV core protein-mediated hepatic steatosis and dysregulated lipid metabolism [37]. The regulation of PPARα by E6-AP may provide a basis for HCV-induced
progression of liver disease, and is worthy of investigation.
5. Conclusions
This study
identifies E6-AP, an E3 ubiquitin ligase, as a PPARα-interacting protein that inhibited
ligand-independent PPARα transactivation and decreased the basal mRNA
levels of PPARα target genes. The E3 ubiquitin ligase function
of E6AP was required for inhibition of PPARα transcriptional activity, and this inhibition
occurred in a proteasome-independent manner. E6-AP was induced in vivo in response to PPARα ligand, and was regulated in a PPARα-dependent manner. A better understanding of
the role of E6-AP and other ubiquitin ligases in the regulation of PPARs could
help improve treatment strategies against metabolic diseases.
Acknowledgments
This work was funded
by NIH ES07799 awarded to J. P. Vanden Heuvel. The authors thank Cherie Anderson for help with
mouse experiments.
FeigeJ. N.GelmanL.MichalikL.DesvergneB.WahliW.walter.wahli@unil.chFrom molecular action to physiological outputs: peroxisome proliferator-activated receptors are nuclear receptors at the crossroads of key cellular functions200645212015910.1016/j.plipres.2005.12.002DesvergneB.Beatrice.desvergne@cig.unil.chMichalikL.WahliW.walter.wahli@cig.unil.chBe fit or be sick: peroxisome proliferator-activated receptors are down the road20041861321133210.1210/me.2004-0088EscherP.WahliW.walter.wahli@iba.unil.chPeroxisome proliferator-activated receptors: insight into multiple cellular functions2000448212113810.1016/S0027-5107(99)00231-6YuS.ReddyJ. K.jkreddy@northwestern.eduTranscription coactivators for peroxisome proliferator-activated receptors20071771893695110.1016/j.bbalip.2007.01.008GlassC. K.RosenfeldM. G.mrosenfeld@ucsd.eduThe coregulator exchange in transcriptional functions of nuclear receptors2000142121141IsmailA.NawazZ.znawaz@med.miami.eduNuclear hormone receptor degradation and gene transcription: an update200557748349010.1080/15216540500147163KinyamuH. K.ChenJ.ArcherT. K.archer1@niehs.nih.govLinking the ubiquitin-proteasome pathway to chromatin remodeling/modification by nuclear receptors200534228129710.1677/jme.1.01680Rochette-EglyC.cegly@igbmc.u-strasbg.frDynamic combinatorial networks in nuclear receptor-mediated transcription200528038325653256810.1074/jbc.R500008200MatsuuraT.SutcliffeJ. S.FangP.De novo truncating mutations in E6-Ap ubiquitin-protein ligase gene (UBE3A) in Angelman syndrome1997151747710.1038/ng0197-74SmithC. L.DeVeraD. G.LambD. J.Genetic ablation of the steroid receptor coactivator-ubiquitin ligase, E6-AP, results in tissue-selective steroid hormone resistance and defects in reproduction200222252553510.1128/MCB.22.2.525-535.2002NawazZ.LonardD. M.SmithC. L.The Angelman syndrome-associated protein, E6-AP, is a coactivator for the nuclear hormone receptor superfamily199919211821189ManiA.OhA. S.BowdenE. T.E6AP mediates regulated proteasomal degradation of the nuclear receptor coactivator amplified in breast cancer 1 in immortalized cells200666178680868610.1158/0008-5472.CAN-06-0557MunakataT.LiangY.KimS.Hepatitis C virus induces E6AP-dependent degradation of the retinoblastoma protein2007391335134710.1371/journal.ppat.0030139ScheffnerM.HuibregtseJ. M.VierstraR. D.HowleyP. M.The HPV-16 E6 and E6-AP complex functions as a ubiquitin-protein ligase in the ubiquitination of p53199375349550510.1016/0092-8674(93)90384-3LiuY.BalejaJ. D.jim.baleja@tufts.eduStructure and function of the papillomavirus E6 protein and its interacting proteins200813112113410.2741/2664TienE. S.DavisJ. W.Vanden HeuvelJ. P.jpv2@psu.eduIdentification of the CREB-binding protein/p300-interacting protein CITED2 as a peroxisome proliferator-activated receptor α coregulator200427923240532406310.1074/jbc.M401489200GrayJ. P.DavisJ. W.IIGopinathanL.LeasT. L.NugentC. A.Vanden HeuvelJ. P.jpv2@psu.eduThe ribosomal protein rpL11 associates with and inhibits the transcriptional activity of peroxisome proliferator-activated receptor-α200689253554610.1093/toxsci/kfj040LeeS. S.-T.PineauT.DragoJ.Targeted disruption of the α isoform of the peroxisome proliferator-activated receptor gene in mice results in abolishment of the pleiotropic effects of peroxisome proliferators199515630123022TienE. S.GrayJ. P.PetersJ. M.Vanden HeuvelJ. P.jpv2@psu.eduComprehensive gene expression analysis of peroxisome proliferator-treated immortalized hepatocytes: identification of peroxisome proliferator-activated receptor α-dependent growth regulatory genes2003631857675780KinyamuH. K.ArcherT. K.archer1@niehs.nih.govEstrogen receptor-dependent proteasomal degradation of the glucocorticoid receptor is coupled to an increase in Mdm2 protein expression200323165867588110.1128/MCB.23.16.5867-5881.2003BurgerA. M.GaoY.AmemiyaY.A novel RING-type ubiquitin ligase breast cancer-associated gene 2 correlates with outcome in invasive breast cancer20056522104011041210.1158/0008-5472.CAN-05-2103ZhangJ.GuentherM. G.CarthewR. W.LazarM. A.lazar@mail.med.upenn.eduProteasomal regulation of nuclear receptor corepressor-mediated repression199812121775178010.1101/gad.12.12.1775BlanquartC.BarbierO.FruchartJ.-C.StaelsB.GlineurC.Peroxisome proliferator-activated receptor α (PPARα) turnover by the ubiquitin-proteasome system controls the ligand-induced expression level of its target genes200227740372543725910.1074/jbc.M110598200BlanquartC.MansouriR.FruchartJ.-C.StaelsB.GlineurC.Corine.Glineur@pasteur-lille.frDifferent ways to regulate the PPARα stability2004319266367010.1016/j.bbrc.2004.05.035GeniniD.CatapanoC. V.carlo.catapano@irb.unisi.chBlock of nuclear receptor ubiquitination: a mechanism of ligand-dependent control of peroxisome proliferator-activated receptor δ activity200728216117761178510.1074/jbc.M609149200RieckM.WedekenL.Müller-BrüsselbachS.MeissnerW.MüllerR.rmueller@imt.uni-marburg.deExpression level and agonist-binding affect the turnover, ubiquitination and complex formation of peroxisome proliferator activated receptor β2007274195068507610.1111/j.1742-4658.2007.06037.xHauserS.AdelmantG.SarrafP.WrightH. M.MuellerE.SpiegelmanB. M.bruce_spiegelman@dfci.harvard.eduDegradation of the peroxisome proliferator-activated receptor γ is linked to ligand-dependent activation200027524185271853310.1074/jbc.M001297200ConawayR. C.BrowerC. S.ConawayJ. W.Emerging roles of ubiquitin in transcription regulation200229655711254125810.1126/science.1067466ReidG.HübnerM. R.MétivierR.Cyclic, proteasome-mediated turnover of unliganded and liganded ERα on responsive promoters is an integral feature of estrogen signaling200311369570710.1016/S1097-2765(03)00090-XQiJ.-S.YuanY.Desai-YajnikV.SamuelsH. H.samueh01@mcrcr.med.nyu.eduRegulation of the mdm2 oncogene by thyroid hormone receptor1999191864872ZhaoB.-X.ChenH.-Z.LeiN.-Z.p53 mediates the negative regulation of MDM2 by orphan receptor TR3200625245703571510.1038/sj.emboj.7601435HuangW.ZhangJ.WashingtonM.Xenobiotic stress induces hepatomegaly and liver tumors via the nuclear receptor constitutive androstane receptor20051961646165310.1210/me.2004-0520ShirakuraM.MurakamiK.IchimuraT.E6AP ubiquitin ligase mediates ubiquitylation and degradation of hepatitis C virus core protein20078131174118510.1128/JVI.01684-06DharancyS.MalapelM.PerlemuterG.Impaired expression of the peroxisome proliferator-activated receptor alpha during hepatitis C virus infection2005128233434210.1053/j.gastro.2004.11.016ChengY.yangcheng@myrealbox.comDharancyS.MalapelM.DesreumauxP.Hepatitis C virus infection down-regulates the expression of peroxisome proliferator-activated receptor α and carnitine palmitoyl acyl-CoA transferase 1A2005114875917596De GottardiA.andrea.degottardi@medcli.unige.chPazienzaV.PugnaleP.Peroxisome proliferator-activated receptor-α and -γ mRNA levels are reduced in chronic hepatitis C with steatosis and genotype 3 infection200623110711410.1111/j.1365-2036.2006.02729.xRakicB.SaganS. M.NoesthedenM.Peroxisome proliferator-activated receptor α antagonism inhibits hepatitis C virus replication2006131233010.1016/j.chembiol.2005.10.006