On November 15, 2021 Senhwa Biosciences, Inc. (TPEx: 6492), a drug development company focusing on first-in-class therapeutics for oncology, rare diseases, and novel coronaviruses, reported that an abstract highlighting clinical design for their lead drug candidate, Pidnarulex (CX-5461), in patients with solid tumors and BRCA2 and/or PALB2 mutation, has been accepted for trial in progress poster presentation at the upcoming American Society of Clinical Oncology (ASCO) (Free ASCO Whitepaper) Gastrointestinal Cancers Symposium (2022 ASCO (Free ASCO Whitepaper) GI) in San Francisco, 20-22 January, 2022 (Press release, Senhwa Biosciences, NOV 15, 2021, View Source [SID1234595651]).

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Inherited mutations in BRCA genes predispose to various early onset cancers. Approximately 10% and 19% of pancreatic cancer patients harboring BRCA1 and BRCA2 mutations respectively and FDA has approved Lynparza (olaparib), the first poly ADP-ribose polymerase inhibitor (PARPi) as frontline maintenance in pancreatic cancer in late 2019. Unfortunately, resistance to PARPi associated with multiple mechanisms can be observed over time, suggesting a prominent unmet need for the development of new treatment options.

"Pidnarulex alone, has shown efficacy in tumor cells resistant to PARPi in the preclinical studies. When Pidnarulex was in combination with other chemotherapeutics, it even delayed the development of PARPi resistance. Therefore, we believe Pidnarulex demonstrates great potential as a treatment for pancreatic or other cancer patients who have acquired resistance to PARPi or other chemotherapies," said Tai-Sen Soong, Chief Executive Officer of Senhwa Biosciences.

The full abstract will be made available online via View Source at 5:00 PM (EST) on 18 January, 2022.

About Pidnarulex (CX-5461)

Specific mutations within the Homologous Recombination (HR) pathway may be exploited by Pidnarulex through a "synthetic lethality" approach by targeting the DNA repair defects in HR Deficient tumors. Specifically, Pidnarulex is designed to stabilize DNA G-quadruplexes of cancer cells, which leads to disruption of the cell’s replication fork. While acting in concert with HR pathway deficiencies, such as BRCA1/2 mutations, replication forks stall and cause DNA breaks, ultimately resulting in cancer cell death. On the other hand, PMCC postulates a different mechanism of action. Specifically, it is thought that Pidnarulex acts as a RNA Pol I Inhibitor.

On November 15, 2021 PACT Pharma, Inc., a clinical-stage company developing transformational personalized neoTCR-T cell therapies for the eradication of solid tumors, reported that new data related to its PACTImmune Database were presented at the Society for Immunotherapy of Cancer (SITC) (Free SITC Whitepaper)’s (SITC) (Free SITC Whitepaper) 36th Annual Meeting (Press release, PACT Pharma, NOV 15, 2021, View Source [SID1234595650]). The results were featured in a poster presentation (#820) entitled, "Machine learning significantly improves neoantigen-HLA predictions utilizing > 26,000 data points from the PACTImmune Database," at the SITC (Free SITC Whitepaper) conference, which was held November 10-14, 2021.

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The presented results reported findings from a study in which PACT applied machine learning to more than 26,000 manufactured polypeptides consisting of the initially predicted neoE peptide together with Beta-2-Microglobulin and the HLA heavy chain for 62 different HLA alleles. Data demonstrated that PACT’s approach significantly improved neoE-HLA predictions, resulting in a 22% improvement in success rates on prospective data as compared to the widely used netMHCpan4.1 predictions. Additionally, the presentation outlined key elements of PACT’s strategy for continued enhancements to its approach to further improve its predictive power.

"The PACTImmune Database enables us to tune and continue to learn from our platform and its growing data assets. Based on retrospective analysis we know that higher predicted neoE-HLA success corelates with more TCRs captured per patient. Ultimately, these improved predictions should give us more actionable neoTCR options for patients in our clinical trial," said Eric Stawiski, Vice President of Bioinformatics at PACT and presenter of the SITC (Free SITC Whitepaper) poster.

The abstract related to this presentation is available on the SITC (Free SITC Whitepaper) website and can be accessed at: View Source

About PACTImmune Database
PACT has developed a proprietary approach to validate predicted neoepitopes (neoEs) and their cognate T cell receptors (neoTCRs) by capturing neoepitope-specific T cells from peripheral blood. This neoTCR discovery and validation process is being applied in a clinical trial (NCT03970382) evaluating personalized neoTCR-T cell therapy to treat patients across eight solid tumor types. Extensive pre-, on- and post-treatment data related to this trial has been accumulated in the PACTImmune Database (PIDB) which represents a growing data asset for patient-specific tumor immunogenicity in solid tumors.

On November 15, 2021 ImmunoGenesis, a clinical-stage biotechnology company developing science-driven immune therapies, reported that preclinical data from its lead development programs were presented in six scientific posters at the Society for Immunotherapy of Cancer (SITC) (Free SITC Whitepaper) 36th Annual Meeting (SITC 2021), which was held November 10-14, 2021, in Washington, DC. The preclinical results presented advance the development of ImmunoGenesis’ immunotherapy programs (Press release, ImmunoGenesis, NOV 15, 2021, View Source [SID1234595649]).

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"We are very pleased to have data from our programs presented at SITC (Free SITC Whitepaper)," said James Barlow, ImmunoGenesis President and CEO. "These strong study findings support our development programs focused on creating therapies that target cold cancers—including pancreatic cancers—refractory to currently available immunotherapy. We look forward to further building upon these successful results with the advancement of our drug candidates as we look to enter clinical trials next year."

Posters Related to IMGS-001: PD-L1/PD-L2 Dual-Specific Antibody with Effector Function

Human PD-L2 triggers a unique T cell inhibitory program through PD-1 engagement distinct from that of PD-L1

Using a T cell line with an NFAT reporter, this study validated that human PD-L2, unlike murine PD-L2, generates a purely co-inhibitory signal in human T cells, albeit with a reduced inhibitory potential relative to PD-L1. Further, preliminary data in a syngeneic murine model of EL4 showed that antibody dependent cellular cytotoxicity capable PD-L2 blocking antibodies are therapeutically superior to PD-L1 or PD-L2 blockade alone. The study was the first demonstration of T cell immunoregulatory functions of PD-L2, which are distinct from those of PD-L1, and demonstrate that the more tumor-selective expression pattern of PD-L2 relative to PD-L1 provides a therapeutic advantage to effector-function capable PD-L2 antibodies.

Dual-specific antibodies blocking both PD-L1 and PD-L2 engagement of PD-1 restore anti-tumor immunity

This study investigated the capacity of monoclonal antibodies capable of bivalent binding to both PD-L1 and PD-L2 to restore the function of PD-1-suppressed T cells in vitro. The study also evaluated whether enhancing the cytotoxic effector function of these bispecific antibodies might further enhance their efficacy through the depletion of tumor cells and supportive stroma. Results indicated that these bispecific antibodies restore the function of PD-1-suppressed T cells with equivalent efficiency to pembrolizumab. ADCC-capable PD-Ligand bispecific antibodies suppress the growth of U2940 lymphoma in immunodeficient mice more efficiently than Rituximab, and in a syngeneic model of PD-L1/PD-L2 double positive colon carcinoma, these antibodies demonstrate superiority to PD-1 blocking antibodies to limit tumor growth and increase survival. This study showed that ADCC-capable PD-Ligand bispecific antibodies display higher therapeutic potential than existing anti-PD-1 antibodies and represent a new class of PD-1 pathway therapeutics with significant potential for the treatment of a variety of human cancers.

Posters Related to IMGS-501: STING Immune Stimulating Antibody Conjugate (STING-ISAC)

High-potency synthetic STING agonists rewire the myeloid stroma in the tumor microenvironment to amplify immune checkpoint blockade efficacy in refractory pancreatic ductal adenocarcinoma

This study profiled myeloid-derived suppressor cell (MDSC) and M2 macrophage function following stimulation with cyclic dinucleotides (CDNs) of ascending potency using RNA sequencing and protein arrays to uncover molecular and cellular mechanisms by which stimulator of interferon genes (STING) agonists reprogram the suppressive myeloid stroma to drive proinflammatory conversion of tumor myeloid stroma to sensitize tumors to immune checkpoint blockade. For the first time, this study concluded that synthetic CDN STING agonists affect MDSC and M2 macrophage repolarization, in part through altering metabolism and c-Myc signaling. Lastly, the study demonstrated the potential for high-potency STING agonists to overcome resistance to checkpoint blockade in an aggressive orthotopic tumor model of pancreatic ductal adenocarcinoma.

Intratumoral delivery of high potency STING agonists modulates the immunosuppressive myeloid compartment and induces curative responses in checkpoint-refractory glioblastoma models

This study utilized the synthetic cyclic di-nucleotide STING agonists IACS-8803 (8803) and ML-RR-S2-CDA (MLRR) to assess survival and tumor immune infiltrate functional reprogramming in two orthotopic transplantable human and murine glioblastoma tumor models, U87 and the recently developed QPP8 (QKi-/- Pten-/- P53-/-). The study concluded that STING agonists prolong survival in human and murine orthotopic models of glioblastoma. This prolonged survival is associated with a decrease in immunosuppressive M2 functional markers in human tumor infiltrating myeloid populations. Additionally, M2-polarized microglia demonstrated a reduction in M2 functional markers and upregulation of proinflammatory M1 markers following treatment with STING agonists. Together these results indicate that delivery of STING agonists can induce proinflammatory repolarization of the glioblastoma myeloid stroma, including both infiltrating myeloid populations and brain-resident microglia, to drive prolonged survival in refractory models of glioblastoma.

Posters Related to Evofosfamide Hypoxia-Reversal Agent in Combination with Checkpoint Inhibitors

Disrupted oxygen supply and tumor hyper-oxygen consumption contribute independently to prostate cancer immune privilege

This study investigated the capacity of two mitochondrial complex I inhibitors to reduce tumor oxidative metabolism, diminish myeloid suppressive capacity, and improve anti-tumor T cell immunity, alone and in combination with evofosfamide and checkpoint blockade to sensitize unresponsive tumors to immunotherapy. This study found that while evofosfamide or inhibition of oxidative metabolism alone did not significantly impact tumor regression, dual combination and triple combination with checkpoint blockade led to a significant reduction in tumor burden. Conclusions indicate that tumor hypoxia and associated immune suppressive programming can be reduced through both local tissue remodeling and limitation of tumor oxygen metabolism. Complex I inhibition selectively inhibits tumor and myeloid cell function, while sparing T cells. This provides opportunities to craft synergistic immuno-metabolic therapies with the potential to treat cold tumor patients refractory to current FDA approved immunotherapeutics.

Hypoxia reduction in tandem with anti-angiogenic therapy remodels the PDAC microenvironment and potentiates CD40 agonist therapy

In this study, evofosfamide (TH-302, IMGS-101) and a vascular endothelial growth factor receptor-2 (VEGFR-2) blocking antibody were used to treat several syngeneic murine models, including orthotopic pancreatic cancer and a transplantable model of prostate cancer. The researchers concluded that evofosfamide and DC101 utilize unique yet complementary mechanisms to improve the survival of mice challenged with pancreatic or prostate tumors. This combination relieves hypoxic stress and simultaneously reinvigorates T cell function and reduces macrophage mediated immunosuppression. In this setting, CD40 agonist therapy provides an additive benefit in prolonging mouse survival. Put together, these data indicate that targeted reduction of hypoxia with anti-angiogenic therapy remodels the tumor microenvironment and enhances immunotherapy responses in PDAC.

About IMGS-001 PD-L1/PD-L2
ImmunoGenesis’ lead program is IMGS–001, a PD-L1/PD-L2 dual-specific inhibitor with an engineered cytotoxic effector function. As the first molecule to target PD-L2 in addition to PD-L1, IMGS-001 has the potential to shut down the entire PD-1 pathway, potentially providing superior blockade compared to other PD-1 or PD-L1 inhibitors. The built-in engineered effector function allows IMGS-001 to kill immunosuppressive cells that express PD-L1 and/or PD-L2. Preclinical data showed that IMGS–001 offered five times the response rate in cold tumors than currently available immunotherapies. Additionally, IMGS–001 can provide a foundation for add-on therapies.

About IMGS-501 STING-ISAC
STING-ISAC builds on ImmunoGenesis’ novel platform PD-L1/PD-L2 inhibitor by conjugating a STING agonist to the antibody, combining an optimal PD-1 pathway blockade with a powerful immune agonist. ImmunoGenesis is developing this agent to effectively and systemically transport the intravenously delivered STING agonist to all tumor sites and targets within the tumor microenvironment. This therapeutic advance pushes through an important barrier seen with traditional STING agonists, which consistently produce an effect only at the site of the intratumoral injection. ImmunoGenesis’ STING-ISAC, delivered intravenously, could precisely target where it is most effective across tumor sites.

About Evofosfamide
ImmunoGenesis has extended its program to include the hypoxia-reversal agent evofosfamide. Hypoxia predicts poor outcomes in patients across tumor types, as it suppresses T-cell immunity in the tumor microenvironment. Evofosfamide reduces hypoxia by a tissue-remodeling process that includes replacement of disrupted tumor vasculature with fully functional new vessels, allowing for restoration of T-cell infiltration into previously hypoxic zones. Prior Phase 1 data of evofosfamide in combination with ipilimumab resulted in an overall response rate of 17% and a disease control rate of 83% across four dose levels in 21 heavily pre-treated patients with advanced cancer. While not the primary target, this hypoxia-reversal agent sensitizes tumors for checkpoint inhibition and is on target to be in clinic in combination with immune checkpoint blockades in 2022.

On November 15, 2021 Benitec Biopharma Inc. (NASDAQ: BNTC) ("Benitec" or "the Company"), a development-stage, gene therapy-focused, biotechnology company developing novel genetic medicines based on the proprietary DNA-directed RNA interference ("ddRNAi") platform, reported the financial results for its Fiscal Year Q1 ended September 30, 2021 (Press release, Benitec Biopharma, NOV 15, 2021, View Source [SID1234595648]). The Company has filed its quarterly report on Form 10-Q for the quarter ended September 30, 2021, with the U.S. Securities and Exchange Commission.

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Operational Updates

The key milestones related to the investigational agents under development by the Company and other corporate updates are outlined below:

BB-301 (Oculopharyngeal Muscular Dystrophy Program)

On September 8, 2021, Benitec provided three key updates related to the progress of the BB-301 development program, including: updated results for the BB-301 Pilot Dosing Study in large animals, updates on European and North American regulatory interactions for the BB-301 development program, and a comprehensive overview of the design of, and key primary and secondary endpoints for, the Phase 1b/2a clinical trial which is planned for initiation in 2022. All of the updates were positive and demonstrated the significant progress that has been achieved for the BB-301 development program; below is a summary of each update:
BB-301 Pilot Dosing Study in Large Animals: On September 8th the Company disclosed updated analyses for the animal subjects dosed with BB-301 in the Pilot Dosing Study. The updated data continued to demonstrate dose-dependent transduction of the target pharyngeal muscle tissues by BB-301, dose-dependent gene expression for the three distinct components of the therapeutic BB-301 transgene, and biologically significant levels of gene silencing ("knock-down") of the target PABPN1 protein. These updated data provide continued support for the planned advancement of BB-301 into the Phase 1b/2a clinical study in 2022.
Regulatory Interactions in Europe: Following the disclosure in February 2021 of the positive interim data from the BB-301 Pilot Dosing Study in large animals, Benitec completed a Scientific Advice Meeting with The National Agency for the Safety of Medicines and Health Products in France (L’Agence nationale de sécurité du médicament et des produits de santé or "ANSM") in the first half of 2021. At the conclusion of the meeting:
The BB-301 Pilot Dosing Study in large animals was viewed as an appropriate dose range finding study.
The design of the ongoing GLP Toxicology and Biodistribution study was viewed as appropriate to support Phase 1b/2a testing of BB-301.
The manufacturing plan for clinical grade BB-301 drug product can be conducted under GMP conditions with a production process analogous to that employed in prior large-scale production runs for BB-301.
The design of the Phase 1b/2a clinical trial can support the evaluation of BB-301 safety and clinical efficacy in key populations of OPMD patients.
Regulatory Interactions in the United States: Benitec has been granted a Type C Meeting with the U.S. Food and Drug Administration ("FDA") in the fourth quarter of 2021.
Regulatory Interactions in Canada: Benitec has been granted a Pre-CTA Consultation Meeting with Health Canada in the fourth quarter of 2021.
BB-301 Phase 1b/2a Clinical Study Design: On September 8th the Company provided a comprehensive overview of the key design elements of the upcoming BB-301 Phase 1b/2a clinical trial. The Phase 1b/2a study is planned for 2022. In addition to the determination of the safety and tolerability profiles of BB-301, the secondary endpoints of the trial will facilitate the accurate and reproducible characterization of the key physiological processes underlying the successful completion of the pharyngeal phase of swallowing. The core analytical tools and methods that will be employed during the clinical study will focus on functional measures of swallowing efficiency for OPMD patients during the pharyngeal phase of swallowing.
Financial Highlights

Total Revenues for the quarter ended September 30, 2021 were $0 compared to fifty-five thousand dollars in total revenue for three months ended September 30, 2020. The decrease in revenues from customers is due to the decrease in licensing and royalty revenues in the current period.

Total Operating Expenses were $4.8 million for the quarter ended September 30, 2021 compared to $2.7 million for the comparable period in 2020. For the quarters ended September 30, 2021 and 2020, respectively, Benitec incurred $0 and $134 thousand in royalties and license fees. During the three months ended September 30, 2021 and 2020, respectively, the Company incurred $2.8 million and $0.8 million in research and development expenses. The increase in research and development expenses is primarily related to the commencement of the BB-301 GLP Toxicology and Biodistribution Study in large animals at Charles River Laboratories. Additionally, the Company incurred expenses related to the production of GMP-grade drug product to facilitate submissions of the Clinical Trial Applications outside of the United States and the Investigational New Drug Application in the United States, as these activities are critical to the planned initiation of the Phase 1b/2a clinical trial for BB-301 in 2022. General and administrative expenses were $2.0 million and $1.8 million for the three months ended September 30, 2021 and 2020, respectively. The increase during this three-month period was due to small increases in insurance costs, consultant fees, and legal and accounting fees.

Jerel A. Banks, M.D., Ph.D., Executive Chairman and Chief Executive Officer of Benitec Biopharma commented, "Our team continues to focus on the core development activities that will ensure the advancement of BB-301 into the first-in-human study. Our primary goal has been, and will continue to be, the improvement of the lives of patients suffering from genetic disorders for which no curative interventions exist. We believe that the initiation of the Phase 1b/2a study is critical for patients in the Oculopharyngeal Muscular Dystrophy community and represents an important milestone with respect to our long-term goals as a company."

On November 15, 2021 Athos Therapeutics, Inc., a late preclinical stage biotechnology company pioneering the development of first-in-class precision therapeutics for patients with autoimmune diseases and cancer, reported the completion of an oversubscribed $15MM Series A financing (Press release, Athos Therapeutics, NOV 15, 2021, View Source [SID1234595647]).

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The funding will be used to advance the company’s pre-clinical and clinical programs, including the initiation of a first in human phase I clinical trial of ATH-63 in 2022. Athos is developing ATH-63 for Inflammatory Bowel Disease, Lupus, other autoimmune disorders, and select cancer indications. Funding will also be used to develop additional novel targets for autoimmune diseases and two first-in-class small molecule inhibitors for solid cancers and AML. Additionally, Athos will further advance its proprietary artificial intelligence drug discovery platform, and substantially expand its patient biomaterial omics database through collaborations with large academic medical centers all over the world, including the Cleveland Clinic Foundation.

Athos Therapeutics completes an oversubscribed $15MM Series A financing

"I am delighted at the progress Athos has made since our Seed round of $4.25MM in March of 2020. Those seed funds enabled us to hire a stellar team, develop a powerful drug discovery engine, perform multi-omics analysis of annotated patient samples from key IBD centers around the world, file 8 patents, and create a medicinal chemistry platform that produced 100’s of highly selective and safe compounds with excellent pharmacologic profiles. The addition of more than $15MM in new funding will allow us to complete a Phase 1 human clinical trial with ATH-63 and progress our autoimmune and novel cancer programs towards the clinic," said Dimitrios Iliopoulos, PhD, MBA, President & Chief Executive Officer of Athos. "Furthermore, we are excited about the development of a new small molecule inhibitor that addresses the unmet needs of a subpopulation of AML patients," he added.

ATH-63 is a small molecule, first-in-class, approach to the massive unmet medical need of IBD. Medications currently prescribed for IBD are associated with limited efficacy, serious side effects, and were not developed for any specific IBD patient subtype. The development of ATH-63 was the result a meticulous systems biology approach where Athos was able to characterize IBD subtypes at the molecular level, using a proprietary biologic and network computational analysis of multi-omics data from highly annotated IBD patient samples.

"The field of IBD is in dire need of more precise, long-lasting, and far safer therapeutic options for millions of patients that suffer from the disease. In response to this need, we developed a highly targeted, precision medicine drug development platform to specifically identify compounds, like ATH-63, that we think will be game-changers for patients," said Allan J. Pantuck, MD, MS, Chairman and Chief Medical Officer of Athos. "Our entire team and Board want to extend our sincere thanks to our original seed funders, the many seed holders who also participated in the Series A, and our new Series A investors. We are honored to have all of you on Team Athos," he added.