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Novogen's NV-128 Is a Unique Inhibitor of mTOR Dephosphorylation Leading to Caspase Independent Death in Chemoresistant Cancer Cells
| Quelle: Novogen, Limited
SAN DIEGO, CA--(Marketwire - April 15, 2008) - Pre-clinical studies reviewed during an oral
presentation here today at the annual meeting of the American Association
for Cancer Research demonstrate that the Novogen drug candidate NV-128
engages a novel mode of cell death targeting the akt-mTOR pathway in
multi-drug resistant ovarian cancer cells. The data were presented by Dr.
Ayesha Alvero, MD, and Associate Professor Gil Mor, MD, Department of
Obstetrics and Gynecology, Yale University School of Medicine.
NV-128 is unique in that it does not induce caspase-mediated apoptosis
which can be non-functional in chemoresistant cancer cells due to
accumulated mutations in tumor suppressor/promoter genes and
over-expression of anti-apoptotic proteins. Rather, NV-128 uncouples the
akt-mTORP70S6K signal transduction cascade which has a key role in driving
protein translation and uncontrolled cancer cell proliferation. Further,
NV-128 induces mitochondrial depolarization via a novel pathway involving
the autophagy protein Beclin-1 and Bcl-2, thereby resulting in endonuclease
G translocation to the nucleus and cell death.
"We consider that the capacity of NV-128 to trigger mTOR dephosphorylation
leading to caspase-independent cell death, in otherwise chemoresistant
ovarian cancer cells, opens new possibilities for the use of NV-128 as a
potential addition to conventional chemotherapy targeting ovarian cancer
cells," said Dr. Mor.
In the context of developing therapies indicated against late stage ovarian
cancer, Dr. Mor said, "The demonstration of a functional
caspase-independent cell death pathway in apoptotic-resistant ovarian
cancer cells is a key step to the development of alternative targeted
therapy for refractory patients."
Structurally, NV-128 is an analogue of triphendiol (NV-196) and
phenoxodiol, both of which are investigational drugs that have been
licensed by Novogen to Marshall Edwards, Inc. Phenoxodiol is currently in
a multinational, multi-center Phase III clinical trial for patients with
late stage ovarian cancer. Triphendiol has recently been granted orphan
drug status by the FDA for pancreatic and bile duct cancers, and late stage
melanoma.
"The ability of our suite of analogues to invoke discreet modes of cell
death suggests that they have potential to be used synergistically, thereby
inhibiting alternative modes of cancer cell survival which may be invoked
post therapy. This could lower the incidence of residual disease
clinically," said Professor Alan Husband, Group Director of Research,
Novogen, Ltd.
Unlike analogues of rapamycin, like temsirolimus and everolimus, which
target only mTORC1, NV-128's capacity to dephosphorylate mTOR enables it to
inhibit both mTORC1 and mTORC2 activity. This blocks growth factor driven
activation of AKT and the potential for development of chemoresistance.
Further, unlike NV-128, rapalogs invoke caspase-mediated apoptosis making
them less effective in those cancer cells that have developed
rapalog-resistance and have a dysfunctional apoptotic cascade.
Also presented in Dr. Alvero's paper was a proof of concept study in an
animal model of drug resistant ovarian cancer, where it has been
demonstrated that NV-128 not only significantly retards tumor
proliferation, but is more efficacious than other standard of care drugs.
It was also reported that phosphorylated p70s6K was decreased, and
endonucelase G was increased in tumors taken from mice dosed with NV-128
thereby confirming that the NV-128 mechanism of action in vivo is the same
as that observed in vitro, and that both proteins can be employed as
markers of NV-128 efficacy.
"We are just now beginning to realize the depth of oncology drug candidates
that our technology will uncover," said Professor Husband. "We anticipate
that refinement of our proprietary molecular scaffold driven by
computer-based molecular modeling, will continue to yield novel derivatives
not only indicated as oncology leads, but also for cardiovascular and
inflammatory diseases."
About NV-128:
In contrast to phenoxodiol and triphendiol, NV-128 has been shown to induce
caspase-independent DNA degradation and cancer cell death. It appears that
in conjunction with autophagy induction, NV-128 induces caspase independent
cell death via the AKT-mTOR pathway resulting in beclin sequestration of
Bcl-2, Bax up-regulation and mitochondrial depolarization. As a
consequence, endonuclease G translocates to the nucleus where it initiates
DNA degradation and cell death. This offers an opportunity for use as a
monotherapy in chemoresistant cancers and enhanced efficacy against cancer
targets less susceptible to phenoxodiol. The option for co-administration
of combinations of these drugs is also under investigation to extend the
potential therapeutic range of this unique class of oncology compounds.
About Novogen Limited:
Novogen Limited (ASX : NRT ) (NASDAQ : NVGN ) is an Australian biotechnology
company that has patented isoflavone technology for the treatment and
prevention of degenerative diseases and disorders. Over the past ten years,
Novogen has conducted the largest and most comprehensive isoflavone
clinical testing programs in the world. Novogen is involved in drug
discovery and product development for a range of degenerative disorders
including cancer, cardiovascular diseases and inflammatory diseases. The
Company coordinates an international clinical research and development
program with external collaborators, hospitals and universities. For more
information, visit www.novogen.com.
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