On March 4, 2026 Denovicon Therapeutics, Inc. reported the discovery of DNT-1569, a small molecule inhibitor of poly(ADP-ribose) polymerase 7 (PARP7) designed as a potential oral immunomodulatory therapy for solid tumors. To the best of our knowledge, no small molecule immuno-oncology drug has reached the market — the entire immunotherapy revolution to date relies on biologics. DNT-1569 is designed to change that. The compound demonstrates potent PARP7 inhibition with approximately 2,000-fold selectivity over PARP1 and 2,500-fold selectivity over PARP2 — a selectivity profile that distinguishes it from all known PARP7 inhibitors, including the clinical compound RBN-2397 (atamparib).

Schedule your 30 min Free 1stOncology Demo!
Discover why more than 1,500 members use 1stOncology™ to excel in:

Early/Late Stage Pipeline Development - Target Scouting - Clinical Biomarkers - Indication Selection & Expansion - BD&L Contacts - Conference Reports - Combinatorial Drug Settings - Companion Diagnostics - Drug Repositioning - First-in-class Analysis - Competitive Analysis - Deals & Licensing

                  Schedule Your 30 min Free Demo!

Why PARP7 — and Why Selectivity Matters
After nearly 25 years in drug discovery — including 17 years at Johnson & Johnson, where I co-led seven clinical candidates — one pattern stands out: good mechanisms fail when the molecules carrying them aren’t clean enough to dose properly.

PARP7 is a compelling immuno-oncology target. Inhibiting PARP7 restores type I interferon signaling in tumor cells, activating the innate immune system and potentially converting immunologically "cold" tumors — the ones that don’t respond to checkpoint inhibitors like Keytruda — into "hot" tumors that the immune system can recognize and attack. PARP7 is dysregulated across multiple solid tumor types, including lung, breast, ovarian, head and neck, pancreatic, and colorectal cancers.

The clinical precedent exists. Ribon Therapeutics’ RBN-2397 entered Phase 1 trials and demonstrated preliminary antitumor activity, establishing proof of concept that PARP7 inhibition produces clinical benefit. But RBN-2397 is not a selective PARP7 inhibitor — it potently inhibits PARP1 and PARP2 as well, which creates the same hematological toxicities seen with traditional PARP inhibitors. This likely resulted in tox-limited dosing and, consequently, the achievable efficacy.

The mechanism is validated. The selectivity problem was not.

DNT-1569: Solving the Selectivity Problem
DNT-1569 was designed to be the PARP7 inhibitor that RBN-2397 was not — one that inhibits the intended target without carrying off-target PARP1/2 liabilities.

Biochemical Profile:

DNT-1569 (Denovicon) RBN-2397 (Ribon)
PARP7 4 nM 3 nM
PARP1 8,000 nM 37 nM
PARP2 10,000 nM 17 nM
PARP1 Selectivity ~2,000× ~12×
PARP2 Selectivity ~2,500× ~6×
Scaffold Novelty Tanimoto = 0.14 vs. RBN-2397 —
Virtual Design Time < 2 days Years (traditional)
DNT-1569 matches RBN-2397’s PARP7 potency while pushing PARP1 and PARP2 activity into the micromolar range. This selectivity profile is designed to enable full therapeutic dosing of PARP7 without the PARP1/2-driven toxicities that likely constrained RBN-2397’s clinical performance.

Importantly, DNT-1569 sits on a novel chemical scaffold — a Tanimoto similarity of 0.14 relative to RBN-2397 confirms that this is not an analogue or derivative of existing PARP7 chemistry. The compound emerged from an entirely different design process, not from iterating on a known scaffold.

How We Got Here
DNT-1569 was designed using Denovicon’s computational drug discovery platform, which uses physics-based machine learning to design molecules with druglike properties built in from the start — not optimized after the fact.

Rather than starting with target affinity and then spending years trying to engineer in druglike properties — the traditional break-fix cycle that accounts for the majority of preclinical program failures — our approach optimizes across ADMET, pharmacokinetic, toxicity, and affinity properties from the outset. Every design decision maps to real chemical features that medicinal chemists can interrogate — no black boxes.

The entire virtual design phase for DNT-1569 was completed in under two days. The program from inception to the selectivity data reported here took under one year.

Since the DNT-1569 program, Denovicon’s platform has evolved into a quantum physics-driven generative AI architecture that extends these capabilities to trillion-molecule chemical spaces, enabling simultaneous multi-objective optimization in a single computational step. The core principle remains the same: build druglikeness in by design. The scale and speed at which we can now do it has fundamentally changed.

Clinical Implications
The immuno-oncology landscape is dominated by biologics — checkpoint inhibitors, CAR-T therapies, bispecific antibodies — all of which require infusion, cold chain logistics, specialized administration, and carry substantial cost. To the best of our knowledge, there is no marketed small molecule immuno-oncology drug. DNT-1569 is designed to address that gap: an oral small molecule that modulates the immune system’s ability to recognize and attack tumors.

A truly selective small molecule PARP7 inhibitor opens two therapeutic paths.

Monotherapy: If PARP7 inhibition alone is sufficient to drive antitumor immunity in selected patient populations — as early evidence in squamous cell lung cancer and head and neck cancers suggests — a selective oral PARP7 inhibitor could offer meaningful clinical benefit without the toxicity burden of pan-PARP inhibition. As a small molecule, it reaches compartments that antibodies cannot — including the central nervous system — and can be manufactured and distributed at a fraction of the cost of biologics.

Combination therapy: The greater opportunity may lie in combining a selective PARP7 inhibitor with existing immune checkpoint inhibitors. Approximately 70% of cancer patients do not respond to checkpoint inhibitors alone, largely because their tumors are immunologically cold. A selective PARP7 inhibitor that activates the type I interferon pathway — turning cold tumors hot — could serve as an oral immunomodulatory backbone for checkpoint inhibitor combinations. Critically, this combination is viable only if the PARP7 inhibitor does not add significant toxicity to the regimen. DNT-1569’s selectivity profile is designed to make that combination feasible.

An oral, well-tolerated small molecule immunomodulator would represent a new therapeutic modality — one with implications not just for efficacy, but for global patient access.

What Comes Next
Immune biomarker assays for DNT-1569 are underway. These data will provide the first readout on whether the selectivity advantage observed in biochemical assays translates to the expected immunomodulatory activity in cellular systems. Denovicon is actively engaging pharmaceutical partners for proof-of-concept collaborations around the PARP7 program and the broader quantum physics-driven generative AI platform.

(Press release, Denovicon Therapeutics, MAR 4, 2026, View Source [SID1234663214])

On March 3, 2026 Persevere Therapeutics, Inc. ("Persevere"), a Delaware-incorporated, clinical-stage oncology biotechnology company, reported its official launch following a period of stealth operations. The company is emerging with a Phase 1b/2a-ready clinical asset and the first close of its Seed financing.

Schedule your 30 min Free 1stOncology Demo!
Discover why more than 1,500 members use 1stOncology™ to excel in:

Early/Late Stage Pipeline Development - Target Scouting - Clinical Biomarkers - Indication Selection & Expansion - BD&L Contacts - Conference Reports - Combinatorial Drug Settings - Companion Diagnostics - Drug Repositioning - First-in-class Analysis - Competitive Analysis - Deals & Licensing

                  Schedule Your 30 min Free Demo!

As part of its launch, Persevere has acquired the clinical-stage program and related assets for misetionamide (GP-2250) from Geistlich Pharma AG. Misetionamide is a novel, first-in-class dual inhibitor of c-MYC and NFκB with clinical activity in a Phase 1 trial.

Persevere has closed on a first tranche of a Seed round and is actively engaging prospective investors for the remaining allocation. The company is prepared to share equity round terms with qualified investors.

The Seed financing proceeds will be used to complete a Phase 1b/2a proof-of-concept clinical trial evaluating misetionamide in patients with platinum-resistant ovarian cancer (PROC), an area of significant unmet medical need.

"We named the company Persevere as an enduring reminder that we must ‘Never Give Up’ on behalf of cancer patients, who persevere every day," said Greg Bosch, Founder and CEO. "Persevere Therapeutics’ mission is the unwavering pursuit of improved clinical outcomes for cancer patients with our novel therapeutic, misetionamide."

Persevere benefits from the solid foundation already established by the significant effort and investment to-date in the development of misetionamide. These advancements include a broad preclinical program and the completion of a successful Phase 1 clinical trial where 56 cancer patients were treated. Persevere’s investors have a unique opportunity to leverage this prior investment as the company now advances the program into its next stage of clinical development. In addition to the multi-center Phase 1 which demonstrated excellent safety and encouraging efficacy profile of misetionamide, significant milestones have already been achieved including all CMC, toxicology and regulatory hurdles with two open INDs as well as 16 scientific publications and an extensive patent estate.

"Platinum resistant ovarian cancer remains one of the most challenging and underserved areas in gynecologic oncology, leaving patients with limited effective options and a poor prognosis," noted Dr. Robert Coleman, MD, gynecologic oncologist with Texas Oncology and Chief Medical Officer at Vaniam Group. "Persevere’s misetionamide offers a much-needed therapeutic innovation, not only as a differentiated alternative to the growing number of antibody drug conjugates [ADCs] in development, but also as a potential option for patients whose disease has been exposed to, and/or progressed on prior ADC therapy."

(Press release, Persevere Therapeutics, MAR 3, 2026, View Source [SID1234663276])

On March 3, 2026 T-knife Therapeutics, Inc., a biopharmaceutical company developing next-generation T cell therapies to fight cancer, reported the authorization of its Clinical Trial Application (CTA) to begin the Phase 1 ATLAS trial of TK-6302 in Europe. TK-6302 is a multi-armored PRAME-targeted T cell therapy specifically engineered to overcome the challenges associated with treating solid tumor cancers. The ATLAS trial, which is poised to begin this year, is an adaptive, first-in-human, open-label, Phase 1 trial of TK-6302 in patients with advanced PRAME-positive solid tumors.

Schedule your 30 min Free 1stOncology Demo!
Discover why more than 1,500 members use 1stOncology™ to excel in:

Early/Late Stage Pipeline Development - Target Scouting - Clinical Biomarkers - Indication Selection & Expansion - BD&L Contacts - Conference Reports - Combinatorial Drug Settings - Companion Diagnostics - Drug Repositioning - First-in-class Analysis - Competitive Analysis - Deals & Licensing

                  Schedule Your 30 min Free Demo!

"We are proud to achieve this important milestone, which enables the initiation of the Phase 1 ATLAS clinical trial and our transition to becoming a clinical-stage company," stated Thomas M. Soloway, President and Chief Executive Officer of T-knife. "TK-6302 is a highly differentiated therapy, engineered for greater potency against PRAME, a clinically validated target with attractive commercial potential. PRAME is highly prevalent across multiple high unmet-need solid tumor indications, including squamous non-small cell lung, ovarian, endometrial, skin, and triple-negative breast cancers. Today’s announcement reflects the dedication, expertise, and urgency our team brings to transforming innovative science into life-changing therapies."

Peggy Sotiropoulou, Ph.D., Chief Scientific Officer of T-knife, added, "The CTA was supported by a comprehensive and compelling preclinical data package demonstrating TK-6302’s best-in-class anti-tumor efficacy. By bolstering T-cell fitness and persistence while overcoming challenging tumor mediated immune barriers, TK-6302 has the potential to deliver meaningful clinical benefit, including deep, durable responses across a range of solid tumor cancers. Bringing a first-of-its-kind multi-armored, CRISPR gene-edited T cell therapy into the clinic underscores our commitment to pushing scientific boundaries in the service of delivering transformative therapies to patients."

About TK-6302
TK-6302 is a PRAME-targeted T cell therapy that has been "supercharged" by the inclusion of multiple armoring innovations: a high affinity PRAME targeting receptor to enhance cytotoxicity; a costimulatory CD8 coreceptor to engage CD4 T cells and enhance T cell fitness and persistence; and a FAS-based checkpoint converter designed to boost engraftment and promote T cell survival in the hostile tumor micro-environment. Preclinical data with TK-6302 demonstrated sustained serial killing and cytokine secretion in a model mirroring the inhibitory ligand expression in PRAME-expressing tumors. In a complex 3-dimensional (3D) spheroid tumor model, TK-6302 eliminated multiple rounds of tumors and demonstrated superior anti-tumor activity compared to controls. TK-6302 is manufactured with a non-viral gene editing process for improved T cell receptor expression, and it has been successfully manufactured at-scale using the clinical process.

(Press release, T-Knife, MAR 3, 2026, View Source [SID1234663274])

On March 3, 2026 Tempus AI, Inc. (NASDAQ: TEM), a technology company leading the adoption of AI to advance precision medicine, and Merck, known as MSD outside of the United States and Canada, reported an expanded, multi-year collaboration aimed at accelerating the discovery and development of precision medicine biomarkers and supporting Merck’s oncology and potentially broader therapeutic portfolios.

Schedule your 30 min Free 1stOncology Demo!
Discover why more than 1,500 members use 1stOncology™ to excel in:

Early/Late Stage Pipeline Development - Target Scouting - Clinical Biomarkers - Indication Selection & Expansion - BD&L Contacts - Conference Reports - Combinatorial Drug Settings - Companion Diagnostics - Drug Repositioning - First-in-class Analysis - Competitive Analysis - Deals & Licensing

                  Schedule Your 30 min Free Demo!

"This collaboration builds on our existing relationship and reflects our shared commitment to harnessing the power of multimodal datasets with AI to deliver better options for patients," said Ryan Fukushima, CEO, Data & Apps at Tempus. "We’ve spent years configuring our Lens Platform to seamlessly leverage our library of de-identified multimodal data with the necessary AI computing power to train and fine-tune specific models for healthcare. Working with the great scientists at Merck, we have exciting opportunities to translate the insights from AI models into precision medicine strategies and improve patient outcomes across oncology and beyond."

Under the terms of the agreement, Merck will use Tempus’ de-identified data along with Tempus’ Lens Platform and Workspaces environment, which offers an advanced computational configuration powered by one of the industry’s largest GPU infrastructures, which enables researchers to efficiently conduct complex analyses on training-ready multimodal datasets, generating novel insights to accelerate the development and optimization of candidate therapies at scale.

"The combination of new AI technologies and large curated multimodal data sets are transforming the way we conduct discovery research," said George Addona, Senior Vice President, Discovery, Preclinical Development and Translational Medicine, Merck Research Laboratories. "This collaboration with Tempus positions Merck to advance our precision oncology strategy through the application of the latest AI/ML capabilities to discover novel precision biomarkers, identify mechanisms of cancer cell resistance, and inform rational combinations for drugs in our early pipeline."

(Press release, Tempus, MAR 3, 2026, View Source [SID1234663269])

On March 3, 2026 AN2 Therapeutics, Inc. (Nasdaq: ANTX), a clinical-stage biopharmaceutical company developing novel small molecule therapeutics derived from its boron chemistry platform, reported its plans to expand the development of oral epetraborole into a Phase 2 proof-of-concept clinical study in adults with phlebotomy-dependent polycythemia vera (PV). PV is a blood cancer characterized by overproduction of red blood cells in the bone marrow. This overproduction increases hematocrit which can lead to serious medical complications, including arterial and venous thromboembolic events.

Schedule your 30 min Free 1stOncology Demo!
Discover why more than 1,500 members use 1stOncology™ to excel in:

Early/Late Stage Pipeline Development - Target Scouting - Clinical Biomarkers - Indication Selection & Expansion - BD&L Contacts - Conference Reports - Combinatorial Drug Settings - Companion Diagnostics - Drug Repositioning - First-in-class Analysis - Competitive Analysis - Deals & Licensing

                  Schedule Your 30 min Free Demo!

The Company’s decision to pursue PV is supported by data from multiple clinical trials of oral epetraborole in healthy volunteers and non-PV patients in which the drug consistently demonstrated early, controlled, sustained, and dose-dependent reductions in hematocrit at potentially clinically meaningful levels for PV.

Epetraborole’s effects were characterized by the following pharmacodynamic and clinical observations:

Consistent hematocrit reductions across multiple clinical populations, including healthy volunteers and nontuberculous mycobacterial (NTM) lung disease patients, with effects sustained over a six-month treatment period
Early onset of hematocrit reduction after dose initiation with durable, stable control and reversibility at treatment cessation
No clinically relevant change in white blood cell counts and minimal change in platelet counts
Demonstrated durable hematocrit reduction in 9-month chronic non-human primate studies
A potentially differentiated mechanism of action, likely acting on globin synthesis rather than directly on heme synthesis
Epetraborole has been generally well tolerated in clinical trials to date at doses anticipated for the treatment of PV.

"We believe epetraborole may offer a differentiated hematological profile that combines hematocrit control via red-cell selectivity, early onset, titratability and oral delivery, attributes that could address key treatment objectives in polycythemia vera and offer patients a new therapeutic option where current approaches fall short," said Eric Easom, Co-Founder, Chairman, President and CEO of AN2 Therapeutics. "This program creates additional, near-term value inflection points within our current runway and broadens our pipeline, which now includes three Phase 2 studies initiating in 2026, and two preclinical oncology compounds that are expected to move into development this year."

"While current therapies are effective for some patients, many continue to have inadequately controlled hematocrit levels and rely on repeated phlebotomy or injectable treatments," said Stan Gerson, M.D., Hematologist and Oncologist at University Hospitals Cleveland Medical Center and Dean and Professor of Medicine at Case Western Reserve University School of Medicine. "As a chronic illness with no cure, PV carries a persistent risk of thrombosis and a substantial symptom burden. There remains a clear need for additional oral treatment options, including those with novel mechanisms of action, that can help manage hematocrit while minimizing treatment burden and long-term tolerability concerns."

The Company is currently proceeding through the regulatory clearance process and anticipates initiating the Phase 2 trial in the third quarter of 2026. The Company expects to provide periodic public data updates as early as the fourth quarter of 2026, subject to regulatory clearance and enrollment progress.

About Polycythemia Vera (PV)

PV is a blood cancer characterized by overproduction of red blood cells in the bone marrow. This overproduction increases hematocrit which can lead to serious medical complications, including arterial and venous thromboembolic events. If untreated, PV can be life-threatening. Despite available therapies, many patients experience uncontrolled hematocrit levels and persistent symptom burden, requiring long term management to maintain adequate disease control. PV is estimated to affect approximately 155,000 people in the U.S.

Webcast Information

AN2 will host a live webcast presentation on Wednesday, March 4, 2026 at 9:30am ET to provide an overview of the PV program. The event will feature Dr. Aaron Gerds, alongside members of the AN2 team. Dr. Gerds is the Associate Professor of Medicine at the Cleveland Clinic Lerner College of Medicine of Case Western Reserve University and serves as Deputy Director for Clinical Research at the Cleveland Clinic Taussig Cancer Institute. He is also Deputy Associate Director for Clinical Research at the Case Comprehensive Cancer Center.

The live webcast of the presentation can be accessed by registering under "Events" in the investors section of the Company’s website at View Source or View Source Upon registration, all participants will receive an email confirmation with a link that will log you in automatically and the option to add it to your calendar. It is recommended that participants log into the webcast approximately 10 minutes prior to the webcast. An archived replay will be available for 30 days following the presentation. The replay will be available on this same link beginning approximately two hours after the event.

About the Phase 2 Study of Epetraborole in PV

This planned Phase 2 study consists of an open-label epetraborole sentinel cohort, an open-label dose optimization cohort for dose selection (Part 1), followed by a double-blind, randomized, placebo-controlled cohort (Part 2), and an optional open-label extension cohort (Part 3). The study is designed to assess the efficacy of oral epetraborole in phlebotomy-dependent adults with PV and its effect on key hematological variables, to optimize a dose regimen on a by-patient level, to assess safety and tolerability, to assess patient-reported outcomes (PROs) using validated PRO instruments, and to assess other key hematological parameters.

About Epetraborole

Epetraborole is a boron-containing, orally available, small molecule that has shown dose and exposure-dependent decreases in hematocrit. Evidence suggests that it operates by reducing production of early-stage erythrocytes (red blood cells) while sparing other cell lineages in the marrow, including white blood cells and platelets. Epetraborole’s clinical data package supporting evaluation in PV is comprehensive, including 10 Phase 1 studies, two Phase 2 studies, and a Phase 2/3 study in NTM lung disease. The drug has been generally well tolerated in prior trials at doses anticipated for PV and, to date, no tolerability barriers to long-term use have been identified. Epetraborole, if approved, would represent a distinct chemical class in both PV and anti-infectives.

(Press release, AN2 Therapeutics, MAR 3, 2026, View Source [SID1234663268])