Lung cancer is the leading cause of cancer death, and five-year survival remains poor, raising the urgency for new treatment strategies. Activation of PPARγ represents a potential target for both the treatment and prevention of lung cancer. Numerous studies have examined the effect of thiazolidinediones such as rosiglitazone and pioglitazone on lung cancer cells in vitro and in xenograft models. These studies indicate that activation of PPARγ inhibits cancer cell proliferation as well as invasiveness and metastasis. While activation of PPARγ can occur by direct binding of pharmacological ligands to the molecule, emerging data indicate that PPARγ activation can occur through engagement of other signal transduction pathways, including Wnt signaling and prostaglandin production. Data, both from preclinical models and retrospective clinical studies, indicate that activation of PPARγ may represent an attractive chemopreventive strategy. This article reviews the existing biological and mechanistic experiments focusing on the role of PPARγ in lung cancer, focusing specifically on nonsmall cell lung cancer.
1. Introduction
Lung cancer is the leading cause of
cancer death for both men and women in the USA.
In fact, more deaths will occur this year due to lung cancer than
breast, prostate, and colorectal cancers combined [1].
In spite of intensive research, 5-year survival in patients with lung cancer
remains dismally low, with overall survival at 15% [2]. A major reason for this problem is the
presence of metastasis at the time of diagnosis. While smoking cessation will clearly reduce
the risk of lung cancer, a majority of diagnosed cases are being detected in exsmokers
[3]. Therefore, in addition to new
chemotherapeutic approaches, there appears to be a critical need for
chemopreventive strategies which can be administered to patients at risk for
developing lung cancer. In this article,
we will review recent data, both from basic sciences experiments and from
clinical studies indicating that activation of the nuclear receptor peroxisome
proliferator-activated receptor γ (PPARγ) may represent a novel strategy for the
treatment and prevention of lung cancer.
2. Biology of Lung Cancer
Lung cancers are categorized as
small cell lung cancer (SCLC) and nonsmall cell lung cancer (NSCLC). As a group, the NSCLC constitute the bulk of
lung cancers and are subdivided into squamous, adenocarcinoma, and large cell
carcinoma phenotypes. Selective changes
in specific oncogenes can be used to distinguish the two types of cancer. Activating mutations in ras are associated
with NSCLC, with a mutation at codon 12 of the Ki-Ras gene observed in
approximately 30% of adenocarcinomas, and just under 10% of other NSCLC types [4]. These mutations appear to be virtually absent
from SCLC [5]. In mice, Ki-Ras mutations are found in over 90% of
spontaneous and chemically induced lung tumors [6].
Overexpression of the c-myc gene is also frequently observed in NSCLC, but
appears to be more prevalent in SCLC [7]. Elevated expression of the HER-2/neu gene, a
member of the epidermal growth factor receptor family has also been observed in
35% of adenocarcinomas and a slightly lower percentage of squamous carcinomas [8]. Alterations in tumor suppressor genes have also
been reported. Mutations in p53 have
been detected in 90% of SCLC and 50% of NSCLC [7]. Mutations in the retinoblastoma gene are more
specific for SCLC, occurring in more than 90%, while only a small fraction of
NSCLC have mutations in this gene.
Recently, mRNA expression profiling has been used to define subclasses
of lung adenocarcinoma, which can be defined by distinct patterns of gene
expression [9, 10]. These studies suggest that NSCLC may in fact
represent multiple diseases characterized by distinct molecular pathways. In contrast to most NSCLC, SCLC displays
neuroendocrine features exemplified by the presence of cytoplasmic
neurosecretory granules containing a wide variety of mitogenic neuropeptides
including gastrin-releasing peptide, arginine vasopressin, neurotensin, cholecystokinin,
and many others [11, 12]. Significantly, SCLC also expresses G
protein-coupled receptors (GPCR) for these neuropeptides, thereby establishing
autocrine-stimulated cell growth.
Therapeutic strategies have targeted these neuropeptides using
inhibitors of GPCRs. However, the existence
of potentially redundant loops mediated by multiple neuropeptides has limited
the usefulness of this strategy.
Recently, a great deal of attention
has been focused on the EGF receptor, and the use of selective inhibitors of
the EGF receptor tyrosine kinase (EGFR-TKI).
These agents (gefitinib and erlotinib) have shown therapeutic efficacy
in a subset of NSCLC patients which have somatic mutations in this receptor [13, 14]. However, responses have also been observed
in patients with wild-type EGFR.
Identifying strategies which would sensitize patients to EGFR-TKI
therapy is under active investigation (see [15] for review).
3. PPARγ Activation
PPARγ is a member of nuclear receptor
superfamily. Two major isoforms have
been described, PPARγ1 and PPARγ2 (see [16] for review). These are splice variants, with PPARγ2 being expressed predominantly in
adipose tissue, whereas PPARγ1 has a more widespread distribution,
and is expressed in cancer cells, including lung cancer [16]. More recently a number of additional splice
variants have been identified [17].
The role of these forms of PPARγ remains to be established. The structure of PPARγ is similar to that of most nuclear
receptors; the core of the molecule consists of a DNA-binding region (DBD) and a ligand-binding region (LBD), separated by a hinge region. There are
two activation domains, AF-1 at the amino terminal and AF-2 at the carboxyl
terminal. The classic pathway of PPARγ activation involves binding as a
heterodimer with the retinoic acid X receptor to specific DNA sequences
(PPAR-RE). The consensus PPAR site
consists of a direct repeat of the sequence AGGTCA, separated by a single
nucleotide, designated a DR-1 site.
Ligand binding to the LBD causes a conformational change, which results
in the release of corepressors and the binding of coactivators, resulting in
increased transcription of target genes.
PPARγ is activated by polyunsaturated fatty
acids and eicosanoids. In particular,
15-deoxy-Δ12,14-PGJ2(dPGJ2)
has been shown to specifically activate PPARγ with micromolar affinity [18]. Lipoxygenase products of linoleic acid, 9-
and 13-HODE have micromolar affinities for PPARγ [19]. It is not clear whether any of these agents
are actual physiologic regulators of PPARγ, and a recent study has found that
endogenous levels of dPGJ2 do not change during adipocyte
differentiation [20]. Synthetic activators of PPARγ include the thiazolidinediones, such as
rosiglitazone and pioglitazone [21].
These compounds have insulin-sensitizing and antidiabetic activity, which is
likely mediated at least in part through PPARγ activation. Finally, NSAIDs, which inhibit eicosanoid
production, activate PPARγ albeit at higher concentrations than
required for COX inhibition [22]. While all of these agents can activate PPARγ, it is clear that they also stimulate
“off-target” pathways which may impact their therapeutic potency [23].
Finally, it should be noted that PPARγ can directly bind to other transcription factors, including NF-κB and Sp1 [24]. This mechanism of action complicates the spectrum of genes that could be
regulated by PPARγ by engaging regulatory elements distinct from classic PPAR-RE
sites [25].
4. Clinical Associations with PPARγ in Lung Cancer
Analysis of human lung tumors has
reported that decreased expression of PPARγ is correlated with a poor prognosis [26]. Further work indicated that expression of
PPARγ as detected by immunohistochemistry was
more frequently detected in well-differentiated adenocarcinomas, compared to
poorly differentiated ones. Recently, a retrospective study
demonstrated a 33% reduction in lung cancer risk in diabetic patients using the
TZD rosiglitazone [27]. An even more dramatic reduction
was observed in African-American patients (75%). This
decreased risk appeared to be specific for lung cancer, and no protective
effect was observed for prostate or colon cancer. Genetic variants in the PPARγ gene have been identified which are associated with a decreased
risk for lung cancer [28]. These findings suggest that
chemoprevention strategies using PPARγ activators may be an attractive approach in patients at risk for
lung cancer, and that polymorphisms in the PPARγ gene may be a way to screen those patients. There are several chemoprevention trials
being initiated using TZDs. However, a
concern in these studies is the association of higher rates of adverse cardiac
events with chronic TZD treatment,
especially with rosiglitazone [29]. As discussed below, agents which target PPARγ through alternative pathways may therefore represent novel
therapeutic targets.
5. Biological Effects of PPARγ in Lung Cancer Cells
A number of studies have
examined the effects of TZDs on the growth of lung cancer cells. The majority of these studies have focused on
NSCLC. Administration of TZDs has been
shown to inhibit growth and induce apoptosis in numerous NSCLC cell lines [30–34]. While the mechanisms for these effects are
not completely understood, they appear to be mediated through both PPARγ-dependent and independent effects. Induction of apoptosis may involve the tumor
necrosis factor-related apoptosis-inducing ligand (TRAIL)-induced apoptosis in
some cancer cell lines [35]; these effects appear to be mediated through PPARγ-independent pathways. Recent studies have also demonstrated that
PPARγ activation induces proline oxidase,
which will result in increased production of cytotoxic reactive oxygen species
(ROS) [36].
Growth arrest may be mediated through induction of the cyclin
kinase inhibitor p21 [37]. In this case, the mechanism of
action involves PPARγ-dependent induction of p21 through interactions with other
transcription factors. Several
studies, including work from our own laboratory have demonstrated that
activation of PPARγ leads to promotion of a more highly
differentiated phenotype in NSCLC [32, 38]. This can be assessed by growing cells in
3-dimensional tissue culture, which has been shown to reveal epithelial
features. E-cadherin is perhaps to most
widely studied marker of epithelial differentiation, and both pharmacological
PPARγ activators and molecular overexpression
of PPARγ had shown increased protein and mRNA
for E-cadherin. Epithelial mesenchymal
transition has been associated with cancer progression and metastasis [39].
While this is still somewhat of a controversial area [40], activation of PPARγ in lung cancer cells appears to inhibit invasiveness, at least in
part through inhibiting or reversing EMT.
It
has become evident during the past several years, that while genetic changes in
cancer cells are critical for tumor initiation, progression and metastasis entail
a critical contribution from the tumor microenvironment [41]. Specifically, interactions of
tumor cells with vascular cells, innate immune cells, and fibroblasts control
tumor angiogenesis and promote a more aggressive phenotype. These cell-cell interactions are mediated
through cytokines and growth factors initially produced by the tumor cells
which recruit stromal cells. Among these
cytokines are factors such as MCP-1 and CCL5, critical for macrophage
recruitment, and VEGF and other proangiogenic cytokines such as IL-8 which
recruit vascular cells [42].
Transcriptional control of these factors is mediated by multiple
transcription factors, but specifically, it has been shown that two specific
factors, NF-κB and HIF-1, are critical for many of these molecules. Several studies have demonstrated that PPARγ activation can inhibit activation of NF-κB in NSCLC [43, 44].
While effects on HIF-1 have not been documented in lung cancer cells,
PPARγ has been shown to inhibit HIF-1 in other systems [45]. These data indicate that
activation of PPARγ may disrupt communication between cancer cells and the
surrounding tumor microenvironment, thus blocking progression and metastasis,
distinct from antiproliferative effects on the tumor cells. In lung cancer, where metastasis has often
occurred at the time of diagnosis, agents, which specifically target
tumor-stromal interactions, represent a novel therapeutic approach.
6. Upstream Activation of PPARγ
While
TZDs have received most of the attention as PPARγ activators, it is becoming apparent that activation of PPARγ can occur as a consequence of activation of other signaling
pathways (see Figure 1). Phosphorylation
by the ERK members of the MAP kinase family has been shown to decrease PPARγ activity, likely through altering the
affinity for ligand binding [46].
Work in endothelial cells has
demonstrated that flow-mediated activation of ERK5, a member of the MAP kinase
family, results in activation of PPARγ [47], which may mediate
anti-inflammatory effects associated with laminar flow. In this case, the mechanism of activation
involves direct binding of ERK5 to the hinge region of PPARγ. In lung cancer, our
studies have focused on the role of the Wnt signaling pathway. While canonical Wnt signaling has been
implicated as promoting colon carcinogenesis, the role of the Wnt pathway in
nonsmall cell lung cancer appears to be more complex. Our studies have
demonstrated that Wnt7a signaling through its receptor Fzd9 inhibits transformed
growth of NSCLC cell lines [48].
Further studies indicated that this pathway leads to increased PPARγ activity through activation of ERK5, and that this increase in
PPARγ activity mediated the antitumorigenic
effects of Wnt7a/Fzd9 signaling [49].
Activation
pathways for PPARγ. PPARγ forms a heterodimer with the retinoic acid X receptor (RXR). Activation can occur by thiazolidinidiones
(TZD) such as rosiglitazone or pioglitazone directly binding to the
ligand-binding domain. This results in
the dissociation of corepressors such as NCor and SMRT, and the binding of
coactivators such as p300 and
Src, mediating activation of
transcription. In lung cancer cells,
binding of Wnt7a to its cognate receptor Fzd9 leads to activation of ERK5,
which presumably directly binds to the hinge region of PPARγ mediating activation.
Prostacyclin (PGI) and analogs such as iloprost can also lead to PPARγ activation, and this may involve ERK5 activation. Conversely, activation of the ERK or JNK
family of MAP kinases can inhibit PPARγ activation; this is mediated through direct phosphorylation of
the molecule which alters the ligand binding affinity. Finally, activation of
PPARγ/RXR heterodimers may be activated through retinoic acid (RA)
binding to RXR.
A
connection has also been made between prostacyclin and activation of PPARγ. Prostaglandin I2 (PGI2,
prostacyclin), produced through the cyclooxygenase pathway via prostacyclin
synthase (PGIS), is a bioactive lipid with anti-inflammatory,
antiproliferative, and potent antimetastatic properties [50, 51]. Our laboratory has shown that transgenic mice
with selective pulmonary PGI2 synthase (PGIS) overexpression
exhibited significantly reduced lung tumor multiplicity and incidence in
response to either chemical carcinogens or exposure to tobacco smoke [52, 53],
suggesting that manipulation of the
arachidonic acid pathway downstream from COX is a target for lung cancer
prevention. IIoprost, a long-lasting prostacyclin analog, also inhibits lung
tumorigenesis in wild-type mice. PGI2 can signal through a specific cell surface receptor, designated IP, which is a
member of the G-protein coupled receptor family, and signals through increases
in cAMP [54]. However, PGI2 has been shown to
signal through activation of PPARs, with reports of both PPARγ [55]
and PPARδ activation [56, 57].
To define the downstream effector of PGI2 in the
chemoprevention of lung cancer, studies were performed in which mice
overexpressing PGIS were crossed with mice deficient in IP (A. M. Meyer et al.,
unpublished observations). In a chemical carcinogenesis model, lack of IP did
not affect protection against lung tumorigenesis mediated by PGIS
overexpression, suggesting IP-independent pathways. Further study is required
to whether prostacyclin can activate PPARγ in vivo, and whether this effect is mediated through IP or
represents a direct, IP-independent activation.
To
test the role of PPARγ in chemoprevention of lung cancer, we have developed transgenic
mice overexpressing PPARγ under the control of the surfactant protein C promoter, which
targets expression to the distal lung epithelium. In a chemical carcinogenesis
model, these mice showed a marked protection against developing lung tumors [44]. While the connection between
prostacyclin analogs and PPARγ activation needs to be more precisely defined, from a therapeutic
standpoint, the ability to activate PPARγ through non-TZD mechanisms represents an attractive strategy that
may avoid some of the deleterious effects seen with TZD administration.
7. Mechanisms of PPARγ Action in Lung Cancer Cells
In spite of intensive study
examining the biological effects of PPARγ activation in lung cancer, much less is know regarding the direct
targets of PPARγ (see Figure 2). As a member of the nuclear receptor
superfamily, PPARγ is a ligand-activated transcription factor. Thus, one assumes that there are direct
transcriptional targets, where PPARγ, in combination with the RXR receptor, binds to regulatory
elements and induced transcription.
These targets have been difficult to identify in cancer cells. In fact, most of the responses that have been
demonstrated involve suppression of target genes (e.g., cytokines). While PPARγ has been shown to upregulate E-cadherin in NSCLC, there are no
studies demonstrating direct binding of PPARγ to the E-cadherin promoter.
A family of transcription factors have been identified which act as
suppressors of E-cadherin expression.
Members of this family include Snail1, Snail2 (Slug), ZEB1, and Twist [58, 59] are potent inducers of EMT. Both Snail and Twist appear to play critical
roles in breast cancer metastasis [60, 61].
Overexpression of ZEB-1 has been implicated in mediating EMT in NSCLC
cells [62].
Effector
pathways for PPARγ in NSCLC. PPARγ can increase either expression of enzymatic activity of PTEN.
This results in inhibition of Akt activation (pAkt), which may be involved in
the growth inhibitory responses seen with PPARγ activation. Decreased Akt
activity also can lead to decreased activity of the transcription factor NF-κB. NF-κB is a critical transcription factor in the production of
proangiogenic and proinflammatory cytokines such as VEGF, IL-8. Decreased production of these factors would
be expected to inhibit recruitment of inflammatory cells such as macrophages,
and block tumor angiogenesis. PPARγ-mediated suppression of members of the Snail family of
transcription factors, such as Snail, Zeb, or Twist, would lead to derepression
of E-cadherin expression and promote the epithelial phenotype, leading to
decreased migration and invasiveness.
PPARγ-mediated suppression of COX-2 expression in NSCLC has been shown
by several investigators. This would
result in decreased PGE2 production, which will impact growth. TZDs can inhibit PGE2 production
through a PPARγ-independent pathway involving induction of 15-hydroxyprostaglandin
dehydrogenase (PGDH). Pathways indicated in green are
increased or activated by PPAR, while those in red represent pathways that are
inhibited or repressed.
Several
studies have reported increased expression of the protein and lipid phosphatase
PTEN in response to PPARγ activation [63, 64].
Increased expression/activity of PTEN would be anticipated to inhibit
signaling through PI-3 kinase/Akt, and downstream effectors such as mTOR. Decreased activation of Akt could lead to
inhibition of NF-κB signaling [65–67], although the molecular mechanisms
are not well defined.
Elevated
expression of cyclooxygenase-2 (COX-2) is common in NSCLC, and mediates
increased production of PGE2 [68].
Activation of PPARγ has been shown in inhibit COX-2 expression and decrease PGE2 production in NSCLC [44, 69].
While the mechanisms whereby PGE2 contributes to growth and
progression of NSCLC are
not completely understood, recent data in colon cancer have shown that PGE2 acting through its cell surface receptor can engage β-catenin signaling, leading to proliferation [70].
Consistent with such a model, TZDs also inhibit expression of the EP2
receptor, which couples to β-catenin signaling [71].
Regulation of PGE2 production by TZDs can also occur through
PPARγ-independent pathways. Both
rosiglitazone and pioglitazone can directly activate 15 hydroxyprostaglandin
dehydrogenase, promoting breakdown of PGE2.
8. Conclusions and Future Directions
Activation of PPARγ appears to inhibit lung tumorigenesis at several different
stages. Animal studies indicate that
increased PPARγ may be chemopreventive against developing lung tumors, suggesting
that it can block the early stages of epithelial transformation. In established lung cancer, activation of
PPARγ can inhibit proliferation, induce apoptosis, and promote a less
invasive phenotype through promoting epithelial differentiation, and perhaps
blocking EMT. Finally, through
disruption of tumor-stromal communication via inhibition of chemokine
production, PPARγ can negatively impact tumor progression and metastasis. These data make PPARγ activators attractive agents for the treatment and prevention of
lung cancer.
However,
a number of significant issues remain to be resolved. In many of the studies described in this
article, it is not clear if the biological responses are mediated through
“on-target” activation of PPARγ, or through other “off-target” effects. A strategy to address this issue is the use
of molecular approaches, either overexpressing or silencing PPARγ in cancer cells to complement studies with pharmacological
agents. Genetic mouse models using targeted knockouts of PPARγ in either cancer cells or stromal compartments will also be
informative. This strategy also applies
to defining the mechanisms mediating the adverse cardiovascular events reported
in patients taking TZDs. Defining the
molecular targets of TZDs mediating a specific response will be critical in the
further development of second-generation PPARγ drugs. If adverse cardiac
events are mediated through “off-target” effects, then a more selective PPARγ activator would be therapeutically effective, without leading to
adverse cardiac events. Alternatively,
if the antitumorigenic effects of TZDs are mediated through “off-target”
effectors, then identifying these pathways would lead to novel therapeutic
targets. Finally, the majority of
studies have focused on NSCLC. Studies
defining mechanisms of activation and downstream targets in SCLC are needed to
determine if PPARγ represents a therapeutic target for treating these forms of lung
cancer.
Acknowledgment
This work was
supported by National Institutes of Health Grants nos. CA103618, CA108610, and
CA58187.
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