Pemetrexed, A Modulator of AMP-activated Kinase Signaling and an Inhibitor of Wild type and Mutant p53

Agarwal, Stuti

01 January 2015

New drug discoveries and new approaches towards diagnosis and treatment have improved cancer therapeutics remarkably. One of the most influential and effective discoveries in the field of cancer therapeutics was antimetabolites, such as the antifolates. The interest in antifolates increased as some of the antifolates showed responses in cancers, such as mesothelioma, leukemia, and breast cancers. When pemetrexed (PTX) was discovered, our laboratory had established that the primary mechanism of action of pemetrexed is to inhibit thymidylate 22 synthase (TS) (E. Taylor et al., 1992). Preclinical studies have shown that PTX has a broad range of antitumor activity in human and murine models of cancer (Adjei, 2000; Adjei, 2004; S. Chattopadhyay, Moran, & Goldman, 2007; Miller et al., 2000). Accordingly, in February 2004, the FDA issued first-line treatment approval for pemetrexed in malignant pleural mesothelioma and in 2008 for first line treatment for locally advanced or metastatic NSCLC (reviewed in (Rollins & Lindley, 2005). As an antifolate this level of therapeutic activity of PTX against lung cancers was surprising and atypical (Hazarika, White, Johnson, & Pazdur, 2004). This led us to the question whether the effects of pemetrexed on other folate-dependent targets could explain the clinical activity of the drug. Our lab showed that, in addition to inhibiting thymidylate synthase, PTX also inhibits aminoimidazolecarboxamide ribonucleotide formyltransferase (AICART), the second folate-dependent enzyme of de novo purine synthesis. Inhibition of AICART leads to massive accumulation of its substrate 5-amino-4-imidazolecarboxamide ribonucleotide (ZMP), causing activation of AMP-dependent kinase (AMPK), which ultimately leads to suppression of mTORC1 signaling, a central regulator of cell growth and proliferation. This secondary mechanism could explain the unusual activity of PTX against mesothelioma and lung cancers. The large proportion of lung cancers are either null or mutant for p53 function. Therefore, this thesis focused on defining what the role of p53 is in the PTX-mediated AMPK activation and mTORC1 inhibition and how the loss of p53 affects mTORC1 signaling. These two questions proved to be interlinked. Chapter 2 investigates this relationship in detail. We found that, upon loss of p53, mTORC1 signaling is enhanced to a significant degree in colon carcinoma and lung cancer cell lines. Clearly, this observation required explanation. We found that the major factors responsible for these differences in mTORC1 activity upon loss of p53 23 were lower levels of two p53 target genes Tuberin (TSC2) and sestrin2. Immunoprecipitation studies of mTORC1 complexes from p53 wt and p53 null cells revealed quite interesting differences in the components of the mTORC1 complex. Immunoprecipitates from p53 null cells had higher levels of mTOR and lower levels of TSC2 and PRAS40 bound to raptor. This suggested that, in comparision to p53 competent cells, p53 null cells have more mTORC1 complex with enhanced activity due to decreased interaction of TSC2 and PRAS40, both of which are inhibitors of mTORC1. These observations explained the higher mTORC1 in p53 null cells and laid the foundation for determining the role of p53 in PTX-activated AMPK and mTORC1 inhibition. In the experiments described in Chapter 3, we found that PTX-mediated AMPK activation inhibited mTORC1 regardless of the p53 status in colon carcinoma cells. This suggested that mTORC1 inhibition by PTX was either independent of p53 mediated negative regulation of mTORC1 or was somewhere bypassing it. Therefore, we compared the effects of PTX with the classic AMPK activator aminoimidazolecarboxamide ribonucleoside (AICAR). In spite of a common mechanism of AMPK activation, namely, expansion of cellular ZMP levels, signaling from AMPK activated by PTX or AICAR were quite different. PTX-activated AMPK phosphorylated the mTORC1 component Raptor but not tuberin (TSC2), whereas AICARactivated AMPK phosphorylated both the targets. This differential behavior of two AMPK activators was due to differential behavior of p53 under these two treatments. Both, AICAR and PTX treatment led to increase in p53 levels but the p53 that accumulated after AICAR treatment was transcriptionally active while the p53 that accumulated after PTX treatment was not. Transcription of p53 targets, including TSC2 and sestrin2, was activated in AICAR- but not in PTX-treated cells. In the absence of p53 function, TSC2 was deficient and mTORC1 activity 24 enhanced, but Raptor phosphorylation by AMPK following PTX was robust and independent of both p53 and TSC2. Therefore we concluded that p53 deficiency suppresses TSC2 and upregulates mTORC1, but AMPK-phosphorylation of Raptor after pemetrexed treatment was sufficient to suppress mTORC1, even in TSC2 deficiency. This suggested pemetrexed as a drug for treatment of Tuberous Sclerosis, a genetic disease caused by functional inactivity of TSC1 or TSC2 due to point mutations in these genes. Mutation of p53 is one of the most common genetic alterations in human cancers and tumors. Cancers that express mutant p53 tend to be more aggressive, resistant to chemotherapy and show worse prognosis then p53-null tumors (Elledge et al., 1993; Olivier et al., 2006). This tumor-promoting activity of mutant p53 has been correlated with acquired and novel transcriptional activities of mutant p53. It has been shown that mutp53 can activate the transcription of cell growth promoting genes, such as, NFκB2, PCNA, MDR1, Axl, EGFR, hTERT, and HSP70, which are not usually transcriptional targets of wt p53. Interestingly, we found that whereas DNA damaging drugs enhance the acquired oncogenic transcriptional activities of mutp53, PTX interferes with this transcription activation. We also found in Chapter 4 that PTX can limit or block the DNA damaging drug-mediated increment of transcriptional activation of mutp53. This suggests that blockade of transcriptional activation of mutp53 by pemetrexed may provide an additional therapeutic benefit in mutp53 bearing cancers. As discussed in Chapter Three, although pemetrexed (with TdR) increases the levels of p53 and its binding to the promoter of its target gene, p21, this p53 is transcriptionally inactive. In order to understand the mechanism of the pemetrexed-mediated transcriptional defect of wt p53, we studied the PTX-mediated signaling towards ATM and ATR and their effects on their substrates Chk2 and Chk1, respectively. These studies suggested that the difference between 25 signaling under AICAR treatment and PTX treatment was that, unlike PTX, AICAR treatment was leading to DNA damage, followed by Chk2 phosphorylation at Thr68. We found there were three major differences between AICAR and pemetrexed (+ TdR) mediated signaling: AICAR caused DNA damage, followed by ATM mediated phosphorylation of Chk2 at Thr68 and phosphorylation of p53 at Ser15 all of which lead to activation of p53 transcriptional activity, events which do not take place under PTX treatment. Studies aimed at understanding the effects of PTX on wt and mutp53 transcriptional activities are discussed in detail in Chapters Three and Four of this dissertation. Overall, we concluded that PTX interferes with the transcription activity of wild type as well as gain-of-function mutant p53. The blockade of DNA damaging agent-mediated enhancement of mutp53 transcription activity by PTX, suggests the clinical relevance of PTX in carcinomas with mutp53. We suggest that this could be one of the contributing factors in the effects of PTX against human lung cancers.

mTORC1

p53

AMPK

TSC2

Rheb

Pemetrexed

Mutant p53

Sestrin2

Biochemistry

Biotechnology

Cancer Biology

Cell Biology

Molecular Biology

Pharmacology

Untersuchungen zur Regulation des TSC - Komplexes in Schizosaccharomyces pombe

Schaubitzer, Kerstin

07 September 2009

Die Anpassung des Zellwachstums eukaryotischer und prokaryotischer Zellen an sich ändernde intra- und extrazelluläre Signale wie Nährstoffverfügbarkeit, Wachstumsfaktoren und dem zellulären Energielevel bedarf eines effektiven Regulationssystems. In Säugern übernimmt der TSC-Komplex als negativer Regulator des TOR-Signalweges eine wichtige Rolle bei der Regulation des Zellwachstums. In S. pombe ist der TSC-Komplex konserviert. Zudem existieren Homologe der Untereinheiten der AMPK, welche in Säugern den TSC-Komplex positiv regulieren. In der vorliegenden Arbeit konnte die Existenz von zwei funktionell getrennten AMPK-Komplexen nachgewiesen werden: AMPK I, bestehend aus Ssp2, SPCC1919.03c und Cbs2 und AMPK II, bestehend aus Ppk9, SPCC1919.03c und Cbs2. Genetische Daten lassen eine Beteiligung von AMPK I an der Regulation der sexuellen Differenzierung, der Adaption an osmotischen Stress und der Verwertung nicht-fermentierbarer Kohlenstoffquellen vermuten. AMPK II scheint für die Adaption an Cadmiumstress wichtig zu sein.In der vorliegenden Arbeit wurde weiterhin die Beteiligung der beiden AMPK alpha-Isoformen am TSC/Rhb1/TOR-Signalweg in S. pombe näher untersucht. Dabei deutete sich an, dass Ppk9 und der TSC-Komplex weder synergistische noch antagonistische Funktionen in der Zelle ausüben. Im Gegensatz dazu scheinen Ssp2 und die TSC-Proteine antagonistische Funktionen auszuüben. Einige Wachstumsdefekte der ssp2 -Deletionsmutanten können durch eine Hyperaktivierung des TSC/Rhb1/TOR-Signalweges supprimiert werden. Die Deletion von ssp2 führt zu einer Suppression des Wachstumsdefektes von Leucin-auxotrophen tsc-Mutanten. Diese Beobachtung erlaubt die Einordnung von Ssp2 in einem zum TSC/Rhb1/TOR-Weg parallelen Signalweg. Im Gegensatz zu Säugern scheinen in S. pombe TSC/Rhb1/TORC1 und Ssp2 einen gemeinsamen Effektor unabhängig voneinander zu regulieren, um verschiedene Wachstumsbedingungen miteinander zu integrieren und das Zellwachstum entsprechend anzupassen.

AMPK

Ssp2

Ppk9

Tsc1

Tsc2

Tor

Schizosaccharomyces pombe

42.13 - Molekularbiologie

42.15 - Zellbiologie

42.20 - Genetik

32 - Biologie

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