- XCE853 is Oregon Therapeutic’s first-in-class, and potentially
best-in-class PDI inhibitor, exhibiting potent preclinical efficacy
across multiple solid and hematological cancers, and is ready to
advance to Investigational New Drug (IND)-enabling
development.
- The AI-enabled collaboration aims to refine and expand the
positioning of XCE853, a novel protein disulfide isomerase (PDI)
inhibitor, in new and targeted oncology indications, including for
drug-resistant tumors.
- The collaboration is leveraging RADR®’s AI-based capabilities,
including 200+ machine learning (ML) algorithms and foundational
models for oncology drug development to uncover biomarkers and
molecular correlates of efficacy and define potential combination
regimens to sharpen XCE853’s drug development strategy.
- Lantern Pharma is receiving equal IP co-ownership and drug
development rights in newly discovered biomarkers, novel
indications, and use for new pharmacological strategies for
XCE853.
Lantern Pharma Inc. (NASDAQ: LTRN), a leading artificial
intelligence (AI) oncology drug discovery and development company,
today announced a strategic AI-driven collaboration with French
biotechnology company, Oregon Therapeutics to optimize the
development of its first-in-class protein disulfide isomerase
(PDI)(1) inhibitor drug candidate XCE853 in novel and targeted
cancer indications. Lantern will be leveraging its proprietary
RADR® AI platform to uncover biomarkers and efficacy-associated
signatures of XCE853 across solid tumors that can aid in precision
development. Collaborative efforts are expected to identify
biomarker signatures that can be used to stratify tumors most
responsive to XCE853 and guide potential future clinical
development and patient selection. Oregon Therapeutics is
developing XCE853 in various cancer indications, including
drug-resistant ovarian and pancreatic cancer, certain hematological
cancers and several pediatric cancers including CNS cancers.
PDIs are promising targets for cancer therapy raising clinical
interest recently2 notably for their potential in cancers of poor
prognosis like breast cancer3 or ovarian cancer. Up-regulated
expression of PDIs was found to be associated with worse clinical
outcome in numerous cancers such as hepatocellular carcinoma(4), as
well as breast and ovarian cancers(5). PDIs are protein chaperones
and are central to maintaining cancer cell metabolism, additionally
PDI inhibitors can cause cancer cell death through the accumulation
of impaired proteins and dysregulated cellular stress responses. A
combination of these effects is known as proteotoxicity, a unique
and promising therapeutic strategy that may be especially effective
in targeting cancers that are resistant to therapy.
In the US, nearly 612,000 people(6) are projected to die from
cancer in 2024 and, resistance to anticancer drugs will be
implicated in 90% of those deaths(7). To date, no PDI inhibitor has
reached the clinic due to the complexities related to selecting and
mapping the molecules that will most accurately target the right
PDI enzymes. There are more than 20 PDI enzymes, with each playing
a slightly different and often biologically redundant role. Oregon
Therapeutic’s lead drug-candidate XCE853 is known to target PDIs of
specific interest for cancer. Lantern Pharma and Oregon
Therapeutics believe that computational tools, including
foundational models, machine learning and large-scale molecular
analysis can offer an ideal and streamlined pathway for breaking
through these data and decision complexities – making RADR® the
perfect platform for better informing the role XCE853 can play in
effective cancer treatment. (8, 9)
“To date, our first-in-class metabolic inhibitor, XCE853, has
exhibited robust preclinical efficacy in both in vitro and in vivo
models across multiple cancer types,” said Marc-Henry PITTY,
MD, CEO of Oregon Therapeutics. “Lantern’s RADR® AI platform
will leverage the in vitro and in vivo data to potentially advance
XCE853 development in a highly targeted manner and will help inform
disease indications and biomarker signatures that can aid in the
design of future clinical trials and in the pursuit of combination
therapies with other approved cancer drugs. Our team is looking
forward to efficiently selecting among the landscape of ideal
development options and efficiently de-risking future clinical
development decisions.” Oregon Therapeutics has previously
performed preclinical studies indicating that in addition to
ovarian and pancreatic cancer, XCE853 may also be particularly
active in renal, prostate, lung, breast, and head and neck cancers,
and leukemia based on preclinical cell-line studies. Oregon project
leader, Sandrine Courtès PhD, who has been developing the
collaboration with Lantern Pharma, stated: “PDIs Inhibitors have
a great potential, since this molecular target is highly expressed
in several cancer types, supports tumor growth and is associated
with clinical outcomes.”
The collaboration focuses on the integration and interrogation
of molecular, genetic and transcriptomic data pertaining to XCE853.
This analysis will be powered by RADR® and its growing library of
over 60 billion data points from many diverse types of biological
measurements and oncology experiments, as well as more than 200 ML
algorithms focused on problems that are central to real-world
cancer drug development. The initial objectives of the
collaboration are to:
1) uncover biomarkers and efficacy-associated gene signatures to
guide in the eventual stratification and selection of patients for
future clinical trials,
2) identify tumor-based response and resistance mechanisms to
XCE853 and strategies to overcome treatment resistance, and
3) expand the use of XCE853 in additional therapeutic cancer
indications for XCE853.
“Drug development teams have found significant data and
modeling challenges in regard to tackling the complexities
associated with PDI inhibitors given the challenges with creating
meaningful models, and accumulating and deciphering the data,”
said Panna Sharma, CEO and President of Lantern Pharma. “Our AI
platform, RADR®, can increase the confidence, insights, and comfort
levels in developing data-driven development paths by modeling
highly complex scenarios at a scale that only has become possible
recently. It’s an ideal approach for Oregon Therapeutics, which has
executed a series of highly targeted in vivo and in vitro
experiments and is poised to make incredibly important and
patient-centric decisions about the clinical future of the
molecule. That's where RADR® can play a highly essential and market
defining role.”
Under the terms of the collaboration, Lantern Pharma is
receiving equal IP co-ownership and drug development rights in
newly discovered biomarkers, novel indications, and/or new
pharmacological use strategies for XC853 and related analogues.
Oregon Therapeutics is entitled to financial benefits resulting
from the out licensing of the background IP to Lantern Pharma.
Lantern Pharma and Oregon Therapeutics are both entitled to
additional financial benefits resulting from the out licensing of
any collaboration IP to a third party. No further financial details
regarding the collaboration were disclosed.
References
- Prevost G.P. et al. Abstract 3760: XCE853 is a promising
protein disulfide isomerase (PDI) inhibitor exhibiting a strong
inhibitory activity in preclinical tumor models. Cancer Res. (2016)
76 (14_Supplement): 3760.
https://doi.org/10.1158/1538-7445.AM2016-3760
- Shili Xu, Saranya Sankar, Nouri Neamati, Protein disulfide
isomerase: a promising target for cancer therapy, Drug Discovery
Today, Volume 19, Issue 3, 2014, Pages 222-240, ISSN 1359-6446,
https://doi.org/10.1016/j.drudis.2013.10.017.
(https://www.sciencedirect.com/science/article/pii/S135964461300384X)
- Powell LE, Foster PA. Protein disulphide isomerase inhibition
as a potential cancer therapeutic strategy. Cancer Med. 2021
Apr;10(8):2812-2825. doi: 10.1002/cam4.3836. Epub 2021 Mar 20.
PMID: 33742523; PMCID: PMC8026947.
- Yu, Won et al. 2014, Korean J Intern Med 29(5): 580-587), brain
tumors (Zou et al. 2018, Oncol Rep. Feb;39(2):501-510.)
- Samanta et al. 2017, Oncotarget. Nov 28; 8(61):
103543–103556
- Siegel R.L., Giaquinto A.N., and Jemal A. Cancer statistics
2024. CA: A Cancer Journal for Clinicians. (Jan/Feb 2024) 74 (1):
12-49. https://doi.org/10.3322/caac.21820
- Longley D.B. and Johnston P.G. Molecular mechanisms of drug
resistance. The Journal of Pathology. (Jan 2005) 205 (2): 275-292.
https://doi.org/10.1002/path.1706
- Rutkevich L.A., Cohen-Doyle M.F., Brockmeier U., Williams D.B.
(2010). Molecular Biology of the Cell. 21:3093–105.
https://doi.org/10.1091/mbc.e10-04-0356
- Watanabe M.W., Laurindo, F.R.M, Fernandes, D.C. Frontiers in
Chemistry. (2014). Methods of measuring protein disulfide isomerase
activity: a critical overview. 2, 73.
https://www.frontiersin.org/articles/10.3389/fchem.2014.00073/full
About RADR®
RADR® is Lantern Pharma’s proprietary integrated AI platform for
large-scale biomarker and drug-tumor interaction data analytics
that leverages machine learning. It is used to provide mechanistic
insights about drug-tumor interactions, predict the potential
response of cancer types and subtypes to existing drugs and drug
candidates, and uncover patient groups that may respond to
potential therapies being developed by Lantern Pharma and its
collaborators.
RADR® uses an ensemble-based approach to apply its library of
algorithms to statistical, correlative, and inferential problems in
drug-tumor interactions. This allows the platform to rapidly
analyze large amounts of complex data and predict how both patients
and tumors will respond to therapeutic combinations. RADR® also
evolves as new datasets are added, which improves and sharpens the
insights generated from the algorithms.
RADR's highly scalable machine-learning methods are designed to
guide drug development and yield new biological insights, while
also having the potential to increase response rates and improve
outcomes in clinical trials. The robustness and growing number of
datasets powering RADR® is anticipated to continue to improve
machine-learning results, accelerate automation of other features
and aid oncology drug development for Lantern and its partners with
an ultimate focus on benefitting cancer patients.
About LANTERN PHARMA
Lantern Pharma (NASDAQ: LTRN) is an AI company transforming the
cost, pace, and timeline of oncology drug discovery and
development. Our proprietary AI and machine learning (ML) platform,
RADR®, leverages over 60 billion oncology-focused data points and a
library of 200+ advanced ML algorithms to help solve
billion-dollar, real-world problems in oncology drug development.
By harnessing the power of AI and with input from world-class
scientific advisors and collaborators, we have accelerated the
development of our growing pipeline of therapies that span multiple
cancer indications, including both solid tumors and blood cancers
and an antibody-drug conjugate (ADC) program. On average, our newly
developed drug programs have been advanced from initial AI insights
to first-in-human clinical trials in 2-3 years and at approximately
$1.0 - 2.5 million per program.
Lantern’s lead development programs include a Phase 2 clinical
program and multiple Phase 1 clinical trials. We have also
established a wholly-owned subsidiary, Starlight Therapeutics, to
focus exclusively on the clinical execution of our promising
therapies for CNS and brain cancers, many of which have no
effective treatment options. Our AI-driven pipeline of innovative
product candidates is estimated to have a combined annual market
potential of over $15 billion USD and have the potential to provide
life-changing therapies to hundreds of thousands of cancer patients
across the world.
Please find more information at:
- Website: www.lanternpharma.com
- LinkedIn: https://www.linkedin.com/company/lanternpharma/
- X: @lanternpharma
About XCE853
XCE853 is Oregon Therapeutic’s proprietary late preclinical
stage drug candidate developed for multiple drug resistant cancers.
XCE853 is a synthetic small molecule displaying an excellent
docking and inhibition activity on the main human PDIs playing a
key role in cancer. XCE853 displays cytotoxic activity at the
nanomolar range on a large panel of cancer cells (80+ models) and
is most interestingly, even more potent on a panel of multiple drug
resistant models. XCE853 showed promising ex vivo activity on
patients’ sample. XCE853 displayed excellent oral bioavailability
in mice and was able to completely and irreversibly block the
growth of several human cancers in vivo xenograft models.
Preliminary toxicity package in rats and mice displayed an
acceptable safety profile. This extensive preclinical package with
transcriptomic and mechanism of action data will be augmented by
insights powered by Lantern’s AI platform, RADR®, to position the
XCE853 drug-candidate for an optimized clinical development path
focused on patient needs.
About OREGON THERAPEUTICS
Oregon Therapeutics is a French preclinical biotech developing
PDI inhibitors issued from groundbreaking drug discovery programs.
Oregon has developed XCE853 up to regulatory preclinical stage
entry and demonstrated XCE853’s disruptive potential as “first in
class” and “best in class” candidate in oncology. Oregon
Therapeutics’ first objective is to bring XCE853 into Clinical
Phase for the treatment of cancers in collaboration with Lantern
Pharma. Based on the scientific rationale to exploit metabolic
vulnerability of some cancers, the two priority indications are
ovarian cancer and advanced pancreatic cancer. Potential additional
indications include liver, prostate, head and neck and several
orphan cancers.
Please find more information at:
- Website: www.oregon-therapeutics.com
- Contact: CEO, Marc-Henry PITTY, PhD MD:
oregontherapeutics@gmail.com
Forward-looking Statements:
This press release contains forward-looking statements within
the meaning of Section 27A of the Securities Act of 1933, as
amended, and Section 21E of the Securities Exchange Act of 1934, as
amended. These forward-looking statements include, among other
things, statements relating to: future events or Lantern’s future
financial performance; the potential advantages of Lantern’s RADR®
platform in identifying drug candidates and patient populations
that are likely to respond to a drug candidate; Lantern’s strategic
plans to advance the development of its drug candidates and
antibody drug conjugate (ADC) development program; estimates
regarding the development timing for Lantern’s drug candidates and
ADC development program; expectations and estimates regarding
clinical trial timing and patient enrollment; the research and
development efforts of Lantern’s internal drug discovery programs
and the utilization of the RADR® platform to streamline the drug
development process; Lantern’s intention to leverage artificial
intelligence, machine learning and genomic data to streamline and
transform the pace, risk and cost of oncology drug discovery and
development and to identify patient populations that would likely
respond to a drug candidate; estimates regarding patient
populations, potential markets and potential market sizes; sales
estimates for Lantern’s drug candidates and its plans to discover
and develop drug candidates and to maximize their commercial
potential by advancing such drug candidates itself or in
collaboration with others. Any statements that are not statements
of historical fact (including, without limitation, statements that
use words such as "anticipate," "believe," "contemplate," "could,"
"estimate," "expect," "intend," "seek," "may," "might," "plan,"
"potential," "predict," "project," "target," “model,” "objective,"
"aim," "upcoming," "should," "will," "would," or the negative of
these words or other similar expressions) should be considered
forward-looking statements. There are a number of important factors
that could cause Lantern’s actual results to differ materially from
those indicated by the forward-looking statements, such as (i) the
risk that Lantern’s research and the research of our collaborators
may not be successful, (ii) the risk that promising observations in
preclinical studies do not ensure that later studies and
development will be successful, (iii) the risk that Lantern’s may
not be successful in licensing potential candidates or in
completing potential partnerships and collaborations, (iv) the risk
that none of Lantern’s product candidates has received FDA
marketing approval, and Lantern may not be able to successfully
initiate, conduct, or conclude clinical testing for or obtain
marketing approval for its product candidates, (v) the risk that no
drug product based on Lantern’s proprietary RADR® AI platform has
received FDA marketing approval or otherwise been incorporated into
a commercial product, and (vi) those other factors set forth in the
Risk Factors section in Lantern’s Annual Report on Form 10-K for
the year ended December 31, 2023, filed with the Securities and
Exchange Commission on March 18, 2024. You may access Lantern’s
Annual Report on Form 10-K for the year ended December 31, 2023
under the investor SEC filings tab of our website at
www.lanternpharma.com or on the SEC's website at www.sec.gov. Given
these risks and uncertainties, Lantern can give no assurances that
the forward-looking statements contained in this press release will
prove to be accurate, or that any other results or events projected
or contemplated by the forward-looking statements contained in this
press release will in fact occur, and Lantern cautions investors
not to place undue reliance on these statements. All of Lantern’s
forward-looking statements in this press-release represent
Lantern’s judgment as of the date hereof, and, except as otherwise
required by law, Lantern disclaims any obligation to update any
forward-looking statements to conform the statement to actual
results or changes in its expectations.
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