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Department of Pharmacology, University of Pittsburgh, Pittsburgh, Pennsylvania
Received March 14, 2003; accepted May 9, 2003
How many times have you found yourself in the position of not knowing how
your favorite novel compound really works in a cell or organism? Your
hypothesis, so carefully constructed, just does not seem to align with the
data. You dream wearily of the day when a useful, if not universal, approach
for determining the real mechanism of action becomes available. The current
article, authored by T. Efferth and coworkers from nine international
laboratories (Efferth et al.,
2003
), provides a clever illustration of one such approach. Armed
with a semisynthetic derivative of artemisinin, the active principle of the
Artemisia annua (sweet worm-wood), the authors exploit a valuable
public asset developed by the Developmental Therapeutics Program of the U.S.
National Cancer Institute to decipher the mechanism of action of artesunate
(Fig. 1), an antimalarial agent
with previously described anticancer activity
(Efferth et al., 2001).
Artesunate is not a new agent; it is first-line therapy for Plasmodium
falciparum and Plasmodium vivax malaria in some areas of Asia
and also displays antischistosomal properties. More than 200 peer-reviewed
articles on artesunate have been published in the last seven years, a
testimony to its importance as a therapeutic agent. Nonetheless, only three of
those references refer to its potential use as an anticancer agent.
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The work of Efferth et al.
(2003) illustrates how a
hypothesis-generating (derisively termed "ignorance-based" by
some) approach rather than a hypothesis-driven approach can yield useful
insights into the possible mechanisms of action of a new anticancer compound.
The National Cancer Institute has tested tens of thousands of compounds
against their 60-tumor cell panel for growth inhibition and has provided
additional information about the molecular phenotype of each cell line.
Information from this substantial undertaking has been placed in the public
domain on a readily accessible website
(http://dtp.nci.nih.gov)
that can be mined with the National Cancer Institute's COMPARE program. As
Efferth et al. (2003) showed,
this informatics tool can generate testable candidate molecular targets for a
compound that does not have any obvious relationship, at least based on this
algorithm, to clinically used anticancer drugs. Rapidly growing tumors were
more sensitive to artesunate than slowly growing tumors, but this is seen with
many existing anticancer agents with the exception of the drugs that cause DNA
adducts, such as carboplatin, dacarbazine, and isosfamide.
With artesunate, the authors selected 465 genes whose expression levels
were obtained by microarray hybridization and are available in the National
Cancer Institute's data base. They used hierarchical cluster analysis and
found 60 genes whose expression correlated with sensitivity or resistance to
artesunate. Three genes were studied in greater detail because of the high
correlation of their cDNA levels with a cytotoxic response to artesunate,
their mathematically determined low false positive discovery rate, and the
availability of appropriate cell systems to test their importance. All three
selected gene products were validated as genes involved in the artesunate
cytotoxic response using gene transfer methodology. Transfection of cells with
the cDNA for epidermal growth factor receptor, the target of the recently
approved anticancer agent gefitinib (Iressa), and 
-glutamylcysteine
synthetase altered sensitivity to artesunate. The authors also used a
tetracycline repressor expression vector system, first developed by Blomberg
and Hoffmann (1999), to confirm
a role for the CDC25A gene in the cytotoxic mechanism of artesunate. This
latter observation is particularly interesting because, like the epidermal
growth factor receptor, the Cdc25A protein has been shown to be over-expressed
in a number of human tumors, including breast cancer
(Cangi et al., 2000), and has
been implicated in several aspects of the malignant phenotype
(Fig. 2). Thus, Cdc25A controls
cell cycle checkpoints that regulate progression through G1/S, S,
and mitosis due to its ability to dephosphorylate and, thus, activate
cyclin-dependent kinases. Consequently, elevated levels of functional Cdc25A
are thought to allow cells to replicate and duplicate damaged DNA and, thus,
to encourage genetic instability. Cdc25A also has been shown to block
apoptosis signal-regulating kinase-1 (ASK-1)
(Zou et al., 2001) and to
affect epidermal growth factor receptor
(Wang et al., 2002), raf-1
(Xia et al., 1999), and steroid
receptors (Ma et al., 2001).
The interaction between Cdc25A and ASK-1 or steroid receptors did not seem to
require a Cdc25A protein with phosphatase activity. Thus, an agent that
preferentially affects cells that over-express Cdc25A is of considerable
pharmacological interest (Lyon et al.,
2002). Efferth et al.
(2003) also show that the
growth-inhibitory activity of artesunate was not influenced by the most common
cellular multidrug resistance mechanisms or by the p53 or p21 status of
cells.
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As with any manuscript, the current contribution is not without potential
issues. For example, the fundamental tool for selecting the candidate genes
was cDNA microarray data. No persuasive evidence was provided that
glutamate-cysteine ligase regulatory subunit, epidermal growth factor
receptor, and CDC25A protein expression was elevated in concert with the cDNA
levels. Moreover, if one accepts that the Cdc25A acts as an oncogene because
it promotes genetic instability, then it is difficult to deduce theoretically
how the very transient Cdc25A over-expression occurring after tetracycline
withdrawal could render a cell more sensitive to artesunate. Perhaps
artesunate was acting to disrupt Cdc25A interactions with ASK-1, raf-1, or
epidermal growth factor (Fig.
2). The current article provides no mechanistic information on how
the candidate gene products alter sensitivity to artesunate. Furthermore, the
failure to see any effect of Cdc25A expression on doxorubicin-induced growth
inhibition is not fully in agreement with a recent report
(Xiao et al., 2003), which was
published after the manuscript by Efferth et al. was submitted. Xiao et al.
(2003) demonstrated that high
expression of Cdc25A caused resistance to doxorubicin, whereas low-level
expression did not alter doxorubicin sensitivity. Although the difference in
results of the two groups might reflect the use of different species,
knowledge about the Cdc25A protein expression levels in the Efferth study
would be useful comparative information.
Like many good articles, the hypothesis-generating study of Efferth et al.
provides as many new questions as it answers. What was the mechanism of action
by which -glutamylcysteine synthetase, epidermal growth factor
receptor, and Cdc25A phosphatase affected cell sensitivity to artesunate? What
about the other 57 genes? How does one determine the hierarchical importance
of the 60 identified genes, really, in the ultimate antiproliferative activity
of artesunate? These and other questions may arise in the mind of the readers
of this article, perhaps stimulating them to answer these questions or even
emulate the sophisticated approach taken by the authors of this
contribution.
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Footnotes |
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Address correspondence to: John S. Lazo, Department of Pharmacology, University of Pittsburgh, E1340 Biomedical Science Tower, Pittsburgh, PA 15261-0001. Email: lazo{at}pitt.edu
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References |
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 Top References |
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Cangi MG, Cukor B, Soung P, Signoretti S, Moreira GJ, Ranashinge M, Cady B, Pagano M, and Loda M (2000) Role of the Cdc25A phosphatase in human breast cancer. J Clin Investig 106: 753–761.[Medline]
Efferth T, Dunstan H, Sauerbrey A, Miyachi H, and Chitambar CR (2001) The anti-malarial artesunate is also active against cancer. Int J Oncol 18: 767–773.[Medline]
Efferth T, Sauerbrey A, Olbrich A, Gebhart E, Rauch P, Weber HO,
Hengstler JG, Halatsch M-E, Volm M, Tew KD, et al. (2003)
Molecular modes of action of artesunate in tumor cell lines. Mol
Pharmacol 64:
382–394.
Lyon MA, Ducruet AP, Wipf P, and Lazo JS (2002) Dual-specificity phosphatases as targets for antineoplastic agents. Nat Rev Drug Discov 1: 961–976.[CrossRef][Medline]
Ma ZQ, Liu Z, Ngan ES, and Tsai SY (2001) Cdc25B
functions as a novel coactivator for the steroid receptors. Mol
Cell Biol 21:
8056–8067.
Wang Z, Wang M, Lazo JS, and Carr BI (2002)
Identification of epidermal growth factor receptor as a target of Cdc25A
protein phosphatase. J Biol Chem
277:
19470–19475.
Xia K, Lee RS, Narsimhan RP, Mukhopadhyay NK, Neel BG, and Roberts
TM (1999) Tyrosine phosphorylation of the proto-oncoprotein Raf-1
is regulated by Raf-1 itself and the phosphatase Cdc25A. Mol Cell
Biol 19:
4819–4824.
Xiao Z, Chen Z, Gunasekera AH, Sowin TJ, Rosenberg SH, Fesik S, and Zhang H (2003) Chk1 mediates S and G2 arrests through Cdc25A degradation in response to DNA damaging agents. J Biol Chem, in press.
Zou X, Tsutsui T, Ray D, Blomquist JF, Ichijo H, Ucker DS, and
Kiyokawa H (2001) The cell cycle-regulatory Cdc25A phosphatase
inhibits apoptosis signal-regulating kinase 1. Mol Cell
Biol 21:
4818–4828.
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