Current
Cancer Drug Targets
ISSN: 1568-0096
Current Cancer Drug Targets
Volume 8, Number 2, March 2008
Contents
Apoptotic Pathways as Targets for Therapeutic Intervention
Guest Editor: Domagoj Vucic
Editorial Pp. 86
p53: A Guide to Apoptosis Pp. 87-97
Erik Meulmeester and Aart G. Jochemsen
[Abstract]
Targeting Cell Death in Tumors by Activating
Caspases Pp. 98-109
Sarah H. MacKenzie and A. Clay Clark
[Abstract]
Targeting IAP (Inhibitor of Apoptosis) Proteins
for Therapeutic Intervention in Tumors Pp. 110-117
Domagoj Vucic
[Abstract]
Ubiquitylation and Cancer Development
Pp.118-123
Maria Miasari, Hamsa Puthalakath and John Silke
[Abstract]
Tumor Necrosis Factor: Renaissance as a Cancer
Therapeutic? Pp. 124-131
D. Daniel and N.S. Wilson
[Abstract]
Modulation of TRAIL-Induced Apoptosis by HDAC
Inhibitors Pp. 132-140
Simone Fulda
[Abstract]
General Articles
Application of Proteome Analysis to the Assessment
of Prognosis and Response Prediction in Clinical Oncology
Pp. 141-145
Christoph Röcken, Ralf Ketterlinus and Matthias P.A.
Ebert
[Abstract]
Natural and Synthetic Agents Targeting Inflammation
and Angiogenesis for Chemoprevention of Prostate Cancer
Pp. 146-155
Elena M.V. Araldi, Isabella Dell’Aica, Ilaria Sogno,
Girieca Lorusso, Spiridione Garbisa and Adriana Albini
[Abstract]
Novel Monoclonal Antibodies for the Treatment
of Chronic Lymphocytic Leukemia Pp. 156-171
Tadeusz Robak
[Abstract]
Abstracts
[Back to top]
Editorial:
The evolutionarily conserved process of apoptosis plays an
important role in removing cells during development and in
maintaining tissue homeostasis. However, dysregulation of
apoptosis, leading to too much or too little cell death, contributes
to a number of diseases including cancer. Designing anti-cancer
therapeutic solutions requires the understanding of the interplay
between positive and negative regulators of the apoptotic
program. Indeed, much has been learned about the molecular
mechanisms of programmed cell death and the escape of tumor
cells from apoptotic demise in recent years. These findings
provide a foundation for novel drug design efforts that are
poised to utilize newly acquired knowledge. Several of these
strategies have already advanced to human clinical trials
while many more are still tested in pre-clinical settings.
Meulmeester and Jochemsen illustrate in great detail the role
of p53 as a master regulator of apoptosis. Often called the
guardian of the genome, the p53 tumor suppressor protein commands
cell fate by controlling initiation of apoptosis, cell cycle
arrest, senescence, and other seminal cellular processes.
These authors examine complex mechanistic regulation of p53-induced
apoptosis, and present evidence for both transcription independent
and dependent pathways. Given the strong association of mutations
in the p53 gene locus with occurrence of human tumors it is
not surprising that p53 is one of the primary targets for
anti-tumor therapeutic intervention. Increased understanding
of its mechanistic and functional properties should enable
development of p53-targeting anti-cancer agents.
In their review Sarah MacKenzie and Clay Clarke dissect the
role of caspases in apoptotic pathways. Caspases represent
a convergent point of apoptotic pathways. As such, they are
irreplaceable components of cell death machinery. The authors
note that caspase activity is often diminished in tumor cells
due to their decreased expression or inadequate activation.
Thus, triggering the activation of caspases, especially effector
caspases like caspase-3 that are the ultimate executors of
cell death, might reduce tumor resistance to cytotoxic drug
treatments. Dimerization of caspases is discussed as one of
the targeting modalities since dimerization is essential for
proper active site formation of all caspases. Hence, a small
molecule that binds the dimer interface of procaspases and
drives their activation could be useful in cancer treatment.
In my review I discuss inhibitor of apoptosis (IAP) proteins
and their role in cancer. IAP proteins are a family of anti-apoptotic
regulators that block cell death in response to diverse stimuli.
They are expressed in the majority of human malignancies at
elevated levels and play an active role in promoting tumor
maintenance through the inhibition of cellular death and participation
in signaling pathways associated with malignancies. These
features make them attractive targets for therapeutic intervention.
Several IAP-targeting strategies are discussed, including
small molecule IAP antagonists (SMAC mimetics), anti-sense
RNAs, and immunotherapy.
Maria Miasari, Hamsa Puthalakath and John Silke report on
ubiquitylation and cancer development in their review. The
Ubiquitin Protea-some System has garnered a lot of attention
recently, and there is increased awareness of its importance
in various cellular processes, including cell growth and death.
The authors discuss the relevance of ubiquitylation and proteasomal
degradation for tumor maintenance. Furthermore, they analyze
in detail the proteasomal regulation of p53 and the Bcl-2
family of apoptotic regulators, as well as the proteasomal
involvement in unfolded proteins-triggered ER stress in multiple
myelomas.
Tumor Necrosis Factor (TNF) and the TNF super-family as cancer
therapeutics is the subject of the review by Dylan Daniel
and Nick Wilson. Several ligands of the TNF super-family,
including TNF-alpha, lymphotoxin, FAS ligand (FasL), and Apo2
ligand/TNF-related apop-tosis-inducing ligand (Apo2L/TRAIL)
have been tested in various stages of clinical research for
their anti-tumor efficacy. Moreover, several antibodies to
TNF receptor (TNFR) super-family members are now being explored
as cancer therapeutics. The authors integrate the results
of pre-clinical and clinical trials with a concise synopsis
of the TNF signaling network, and attempt to reconcile our
understanding of how the cell biology and tumor biology relate
mechanistically.
In her review, Simone Fulda focuses on the modulation of Apo2L/TRAIL-induced
apoptosis by HDAC inhibitors. Apo2L/TRAIL, a member of the
TNF super-family of death inducing ligands, is of special
interest for cancer therapy as it predominantly kills cancer
cells while sparing normal cells. Many cancers, however, fail
to undergo apoptosis in response to Apo2L/TRAIL treatment.
Thus, combination therapies are needed for cancer-specific
sensitization towards Apo2L/TRAIL. In recent years, HDAC inhibitors
(HDACI) that reverse aberrant epigenetic changes have emerged
as a potential strategy to sensitize cancer cells to Apo2L/TRAIL-induced
apoptosis. Simone discusses recent advances in the understanding
of the molecular events that underlie the synergistic interaction
of HDACI and Apo2L/TRAIL as well as ways of translating this
knowledge into the design of novel cancer-selective therapeutics.
In conclusion, the review articles in this issue of Current
Cancer Drug Targets are intended to provide instructive and
thought-provoking analyses of apoptotic pathways, together
with an in-depth examination of their usability as targets
for therapeutic intervention in human malignancies.
Domagoj Vucic
Department of Protein Engineering
Genentech, Inc.
South San Francisco
CA 94080
USA
Tel: 650-225-8839
Fax: 650-225-6127
E-mail: vucic.domagoj@gene.com
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p53: A Guide to Apoptosis
Erik Meulmeester and Aart G. Jochemsen
Approximately 50% of sporadic human tumors harbor somatic
mutations in the p53 gene locus, while germ line mutations
confer a high familial risk and are associated with Li-Fraumeni
Syndrome patients. The p53 tumor suppressor protein is often
referred to as the “guardian of the genome” since
its response to DNA-damage or checkpoint failure gives rise
to a series of anti-proliferative responses. One of the most
important functions of p53 is its ability to induce apoptosis,
while disruption of this route can promote tumor progression
and chemo resistance. Besides its ability to promote apoptosis
through transcription dependent mechanisms, p53 may also be
able to activate apoptosis independent of transcriptional
regulation. Therefore, to ensure normal cell growth, p53 levels
and activity are tightly regulated. Upon diverse forms of
cellular stress the steady state levels and transcriptional
activity of p53 are considerably increased. The stabilization
and activation of p53 are a result of hindered inhibition
by its negative regulators, e.g. Mdmx (also known as Mdm4)
and Mdm2, while on the other hand activators such as HIPK2
and DYRK2 enhance the p53 response. The continually increasing
understanding of the mechanisms of regulation of p53 may provide
the basis for new drug designs that could eventually lead
to therapeutics to reactivate p53 in cancers.
[Back to top]
Targeting Cell Death in Tumors by Activating Caspases
Sarah H. MacKenzie and A. Clay Clark
Cytotoxic approaches to killing tumor cells, such as
chemotherapeutic agents, γ-irradiation,
suicide genes or immunotherapy, have been shown to induce
cell death through apoptosis. The intrinsic apoptotic pathway
is activated following treatment with cytotoxic drugs, and
these reactions ultimately lead to the activation of caspases,
which promote cell death in tumor cells. In addition, activation
of the extrinsic apoptotic pathway with death-inducing ligands
leads to an increased sensitivity of tumor cells toward cytotoxic
stimuli, illustrating the interplay between the two cell death
pathways. In contrast, tumor resistance to cytotoxic stimuli
may be due to defects in apoptotic signaling. As a result
of their importance in killing cancer cells, a number of apoptotic
molecules are implicated in cancer therapy. The knowledge
gleaned from basic research into apoptotic pathways from cell
biological, structural, biochemical, and biophysical approaches
can be used in strategies to develop novel compounds that
eradicate tumor cells. In addition to current drug targets,
research into molecules that activate procaspase–3 directly
may show the direct activation of the executioner caspase
to be a powerful therapeutic strategy in the treatment of
many cancers.
[Back to top]
Targeting IAP (Inhibitor of Apoptosis) Proteins for Therapeutic
Intervention in Tumors
Domagoj Vucic
Apoptosis, or programmed cell death, is a cell suicide
process with a major role in development and homeostasis in
vertebrates and invertebrates. Dysregulation of apoptosis
leading to early cell death or the absence of normal cell
death contributes to a number of disease conditions including
neurodegenerative diseases and cancer. Inhibition of apoptosis
enhances the survival of cancer cells and facilitates their
escape from immune surveillance and cytotoxic therapies. Inhibitor
of apoptosis (IAP) proteins, a family of anti-apoptotic regulators
that block cell death in response to diverse stimuli through
interactions with inducers and effectors of apoptosis are
among the principal molecules contributing to this phenomenon.
IAP proteins are expressed in the majority of human malignancies
at elevated levels and play an active role in promoting tumor
maintenance through the inhibition of cellular death and participation
in signaling pathways associated with malignancies. Herein,
the role of IAP proteins in cancer and strategies toward targeting
IAP proteins for therapeutic intervention will be discussed.
[Back to top]
Ubiquitylation and Cancer Development
Maria Miasari, Hamsa Puthalakath and John Silke
Ubiquitylation is an essential cellular process, and
yet many cancer cells appear to be more reliant upon it than
normal cells as they are surprisingly sensitive to proteasome
inhibitors (PI) and proteasome inhibitor drugs are well tolerated
in vivo. Several reviews have suggested that specific
protein targets account for PI induced cell death, but fail
to adequately explain why cancer cells are more sensitive
than normal cells to PIs. We review the evidence for these
models, focusing primarily on inducers of cell death including
p53 and the pro-apoptotic Bcl-2 Homology proteins (BH3 proteins)
and propose an additional hypothesis; that a tumour cell's
abnormal physiology makes it particularly reliant upon the
proteasome. This hypothesis is well supported in the case
of Multiple Myelomas, that may produce large amounts of antibodies
and are therefore under considerable ER strain and in turn
particularly reliant upon the proteasome to clear the large
numbers of misfolded proteins. We propose that other cell
types, tumor or non tumour, that are already under ER stress,
or its equivalent, maybe particularly susceptible to proteasome
inhibitors.
[Back to top]
Tumor Necrosis Factor: Renaissance as a Cancer Therapeutic?
D. Daniel and N.S. Wilson
Since the discovery of tumor necrosis factor (TNF)-alpha,
researchers have pursued many approaches to harness the potency
of TNF-alpha and TNF superfamily members to treat human cancers.
Several ligands of the TNF superfamily, including TNF-alpha,
lymphotoxin, FAS ligand (FasL), and APO2 ligand/TNF-related
apoptosis-inducing ligand (Apo2L/TRAIL) have been tested in
various stages of clinical research for their anti-tumor efficacy.
Moreover, several antibodies to TNF receptor (TNFR) superfamily
members are now being explored as cancer therapeutics. Due
to the toxicity associated with delivering TNF-alpha systemically
at clinically relevant doses, more targeted methods are now
seen as a likely alternative to provide a localized therapeutically
effective dose of TNF-alpha. In this review we revisit historical
attempts to use TNF-alpha to treat human cancer, and put this
into the context of more recent targeted strategies to circumvent
TNF-alpha’s systemic toxicity. We will attempt to integrate
the results of pre-clinical and clinical trials with a concise
synopsis of the TNF-alpha signaling network, with the goal
of reconciling our understanding of how the cell biology and
tumor biology mechanistically relate.
[Back to top]
Modulation of TRAIL-Induced Apoptosis by HDAC Inhibitors
Simone Fulda
Triggering apoptosis, the cell’s intrinsic death
program, is a promising approach for cancer therapy. TNF-related
apoptosis-inducing ligand (TRAIL), a member of the TNF superfamily
of death inducing ligands, is of special interest for cancer
therapy, since TRAIL has been shown to predominantly kill
cancer cells, while sparing normal cells. However, since many
cancers fail to undergo apoptosis in response to TRAIL treatment,
TRAIL-based combination therapies have been developed for
cancer-cell specific sensitization towards TRAIL. Chromatin
remodelling plays an important role in gene regulation and
aberrant architecture of the chromatin has been implicated
in tumor formation and progression. In recent years, HDAC
inhibitors (HDACI) that reverse aberrant epigenetic changes
have emerged as a potential strategy to sensitize cancer cells
for TRAIL-induced apoptosis. Synergistic tumor cell death
has been reported in a variety of human cancers using different
HDACI together with TRAIL. Here, recent advances in the understanding
of the molecular events that underlie the synergistic interaction
of HDACI and TRAIL are discussed as well as how this knowledge
can be translated into the design of cancer-selective novel
therapeutics.
[Back to top]
Application of Proteome Analysis to the Assessment
of Prognosis and Response Prediction in Clinical Oncology
Christoph Röcken, Ralf Ketterlinus and Matthias P.A.
Ebert
In Europe more than 3 million individuals develop a malignancy
annually. Despite recent progress in screening, diagnosis
and therapy of most cancers, prognosis remains poor and only
a minority of patients are cured. This owes to the fact that
most cancers are diagnosed in advanced stages and due to the
fact that treatment options for most cancers are limited.
While there has been a substantial improvement in systemic
therapy for many cancers it remains difficult to assess the
potential responsiveness of the cancers towards these newly
developed drugs, which include small molecules and monoclonal
antibodies. Therefore various strategies have been developed
in order to assess the prognosis and predict the expected
tumor response in order to individualize the treatment, thereby
offering the patient a tailored therapy which accounts for
the tumor- and patient-specific morphological and molecular
characteristics of the disease. This review summarizes recent
efforts, challenges and limitations of proteome analysis in
the assessment of prognosis and response-prediction in human
cancers.
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Natural and Synthetic Agents Targeting Inflammation and Angiogenesis
for Chemoprevention of Prostate Cancer
Elena M.V. Araldi, Isabella Dell’Aica, Ilaria Sogno,
Girieca Lorusso, Spiridione Garbisa and Adriana Albini
Prostate cancer is the most common cancer in men and
one of the leading causes of cancer-related deaths in Western
countries. The extraordinary biological heterogeneity, the
increasing incidence of this disease, and the presence of
putative premalignant conditions make prostate cancer a crucial
pathology to study and test pharmacological or nutritional
chemopreventive strategies. It has been demonstrated that
the incidence of prostate cancer is lower in Asian people,
and that it increases in Asian men living in Western countries;
these data point to a pivotal role of diet in the onset of
prostate cancer. A large amount of work has been done in investigating
chemopreventive properties of dietary compounds widely used
in Asian countries (i.e. soy, soybeans, green tea, fish) in
respect of the oxidants- and meat-rich diet typical of Western
people, particularly of central and northern Europe. Some
dietary products appear promising as chemo-preventive agents
for prostate cancer, because they display both anti-oxidant
and anti-inflammatory activity – and inflammation is
crucial for the aetiology of adeno-carcinoma of the prostate.
There is increasing evidence for close correlation between
inflammation, the micro-environment and tumour-associated
neo-angiogenesis causing the adverse outcomes of prostate
cancer. It may thus be useful to develop new strategies to
couple the treatment of inflammation-related prostate cancer
and the generation of angiopreventive or antiinflammatory
molecules to prevent this disease. The search for compounds
with few or no adverse effects – particularly cardiovascular
– as compared with the agents currently in use is therefore
of greatest relevance.
This paper reviews the beneficial effects in this context
of the most promising compounds: β-carotene,
capsaicin, curcumin, daidzein, EGCG, genistein, hyperforin,
lycopene, N-acetyl-L-cysteine, reductase inhibitors, resveratrol,
selenium, silybinin, quercetin, vitamin-D and vitamin-E.
[Back to top]
Novel Monoclonal Antibodies for the Treatment of Chronic Lymphocytic
Leukemia
Tadeusz Robak
For many years, alkylating agents and purine nucleoside
analogs (PNA) have been considered the drug of choice for
treatment of chronic lymphocytic leukemia (CLL). More recently
the introduction of monoclonal antibodies (mAb), especially
rituximab directed against CD20 and alemtuzumab directed against
CD52, has renewed interest in CLL therapy. Over the last few
years, several new mAbs directed against lymphoid cells have
been developed and investigated in preclinical studies and
clinical trials. Some of them are highly active in CLL. New
mAbs directed against CD20 include human mAb ofatumumab (HuMax
CD20) , IMMU-106 (hA20) which has a >90% humanized framework
and GA-101, a novel third – generation fully humanized
and optimized mAb. These agents are highly cytotoxic against
B-cell lymphoid cells and are evaluated in CLL. Lumiliximab
(anti-CD23 mAb) is a genetically engineered macaque-human
immunoglobulin (Ig) A1. This antibody showed high activity
and good tolerability in phase I clinical trial and is evaluated
in phase I/II clinical trials as a single agent and in combination.
Epratuzumab is a humanized anti-CD22 mAb currently used in
clinical trials for treatment of non-Hodgkin lymphoma and
autoimmune disorders. Further studies are needed to elucidate
the role of this agent in CLL. Apolizumab (HU1D10) is a humanized
IgG1 antibody specific for a polymorphic determinant found
on the HLA-DR β
chain. Preclinical and early clinical studies suggest that
this mAb has some activity in CLL. HCD122 (CHIR-12.12) and
SGN-40 are anti-CD40 mAbs which induce cytotoxicity against
CLL cells. Phase I study has shown a favorable safety profile
and some activity of HCD122 in pretreated CLL patients. Immunotoxins,
especially BL22, LMP-2 and denileukin diftitox, are also being
evaluated in lymphoid malignancies and seem to be active in
CLL. Finally, antiangiogenic mAbs, especially bevacimzumab,
have a potential therapeutic role in this disease. In this
review, new mAbs, potentially useful in CLL are presented.
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