On October 13, 2020 IONTAS Limited (IONTAS), an innovative biotechnology company focused on antibody discovery and cutting-edge technology development, reported that it has entered into a licensing agreement with Bristol Myers Squibb Company regarding the Company’s proprietary mammalian display (Press release, Iontas, OCT 13, 2020, View Source [SID1234568378]).

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!

Under the terms of this agreement, IONTAS will receive an upfront payment for accessing the technology platform and will work with Bristol Myers Squibb in establishing the platform within its facilities. Additional near-term payments include maintenance fees, the achievement of development milestones, and eventual royalty payments on all antibodies derived from the platform.

IONTAS’ proprietary mammalian display technology enables large libraries of full-length antibodies to be expressed on the surface of mammalian cells, in a way that allows selection for optimal binding properties and optimal biophysical properties. These benefits can significantly reduce the risk of antibodies failing during the expensive manufacturing stages. Effectively the platform allows the right lead antibodies to be selected early in the discovery process, reducing the requirement for any potential costly re-engineering to correct developability issues.

John McCafferty, Chief Scientific Officer of IONTAS and inventor of the platform, commented: "We are excited to have Bristol Myers Squibb, one of the global leading biopharmaceutical companies, as our licensing partner. Our mammalian display system not only allows the screening of tens of millions of clones directly for binding but also has a unique advantage to detect developability issues. This allows us to ’fix’ problematic antibodies and identify them during early drug discovery. This can save the industry significant time and money by generating developable products faster."

On October 13, 2020 Targovax ASA (OSE: TRVX), a clinical stage immuno-oncology company developing oncolytic viruses to target hard-to-treat solid tumors, reported that the colorectal cancer cohort in part 1 of the ONCOS-102 and durvalumab trial in colorectal and platinum-resistant ovarian cancer that has spread to the peritoneum has met the pre-defined efficacy threshold of patients without progression at the end of week 24 (Press release, Targovax, OCT 13, 2020, View Source [SID1234568350]). The second part of the colorectal expansion cohort is now open for recruitment.

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 study is an open label, exploratory phase I/II trial assessing the combination of intra-peritoneally delivered ONCOS-102 in combination with systemically administered durvalumab, an anti-PD-L1 checkpoint inhibitor, in patients with colorectal (CRC) or platinum-resistant ovarian (OC) cancers that have metastasized to the peritoneal cavity. The trial is designed with a dose-escalation phase assessing three different dosing levels, followed by an expansion phase split into separate CRC and OC cohorts. The expansion phase is divided into two parts, where the second part is opened only if a pre-defined efficacy threshold is met in the first part. The efficacy threshold in the CRC cohort is 1 out of 13 patients and 5 out of 18 patients in the OC cohort without progression at week 24.

Ludwig Cancer Research, the trial sponsor, and the investigators have reviewed the available data in part 1 of the expansion phase and concluded that the threshold has been met in the CRC cohort. The second part of the CRC cohort has therefore been opened for recruitment with the aim of enrolling 14 additional patients. For OC, threshold was not met, and this cohort has been closed for further recruitment.

Dr. Dmitriy Zamarin, Medical Oncologist at Memorial Sloan Kettering Cancer Center (MSK), Investigator at the Ludwig Center at MSK and Principal Investigator of the study, said: "Chemotherapy-resistant microsatellite-stable colorectal cancer is a challenging disease to treat, with a response rate to immune checkpoint inhibitor monotherapy of less than 5%. We are hopeful that the immune activation by ONCOS-102 in peritoneal cavity may sensitize these tumors to immune checkpoint inhibition and improve this response rate."

Dr. Magnus Jäderberg, Chief Medical Officer of Targovax, said: "The first part of the trial has allowed us to determine which primary cancer holds most promise for future development of ONCOS-102 in the intra-peritoneal setting. We are very pleased to see that the efficacy threshold has been met for the CRC cohort, and will now focus exclusively on this patient population of primary, platinum-resistant CRC with peritoneal metastases for the second part of the trial. This is a large patient group with no effective available treatment alternatives today, and we are hopeful that this novel combination of immunotherapies can deliver benefit in this disease with very high unmet medical need."

The trial is a collaboration between Targovax, AstraZeneca (LSE/STO/Nasdaq: AZN), Cancer Research Institute (CRI) and Ludwig Cancer Research.

On October 13, 2020 EdiGene, Inc., which develops genome editing technologies to accelerate drug discovery and develop novel therapeutics for a broad range of diseases, reported the successful completion of a RMB 450 million (approximately USD 67 million) Series B financing (Press release, EdiGene, OCT 13, 2020, View Source [SID1234568346]). 3H Health Investment led the round and other new investors included Sequoia Capital China, Alwin Capital and Kunlun Capital, along with continued support by previous investors, including IDG Capital, Lilly Asia Venture, Huagai Capital and Green Pine Capital Partners. Proceeds from the financing will be used to advance the company’s pipeline into clinics and to expand the team.

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!

Minchuan Wang, Ph.D., Partner of 3H Health Investment commented: "As one of the most disruptive biomedical technologies, gene editing is rapidly moving toward clinics globally. EdiGene is leading the wave in China, as they have established outstanding research and development capabilities, and more importantly, they have developed an impressive portfolio of proprietary gene editing tools and product candidates. We are pleased to lead the Series B financing, and are excited to join force with EdiGene and other investors to bring life-changing innovative gene-editing therapies to patients in China and globally. We look forward to contributing our clinical, business, and policy resources to further strengthen the company’s capabilities, and are confident that EdiGene is well-positioned to be a leader in gene-editing therapeutics."

"We have raised approximately RMB 700 million (USD 100 million) in the past two years. We are delighted to add these top tier investors in closing of our Series B financing, and are grateful for the continuous support from the current investors," said Dong Wei, Ph.D.，CEO of EdiGene, "The round enables us to further scale up and transform our pipeline into clinical-stage, which is also a big step forward in building a globally competitive gene editing company. More importantly, we are closer to realizing our mission of bringing innovative and high-quality gene-editing therapies to patients in need."

"We are very pleased to have the support and partnership from our investors, which propels the company to an exciting new stage," said Wensheng Wei, Scientific Founder of EdiGene, "Together with the investors, we look forward to translating cutting-edge gene editing technologies into innovative therapies, bringing hope and health to patients and their families."

Founded in 2015, EdiGene has established four gene editing based platforms and is advancing its early stage programs into clinical development for patients with genetic diseases and cancer. The four platforms are ex vivo genome-editing platforms for hematopoietic stem cells and T cells, in vivo therapeutic platform based on RNA base editing, and high-throughput genome-editing screening to discover novel targeted therapies. In addition, EdiGene has launched GMP manufacturing facility in 2018 in Guangdong Province.

On October 12, 2020 Baylor College of Medicine reported that Natural killer T (NKT) cells, a type of immune cells known for their potent anti-cancer properties in murine tumor models, have been developed into a novel form of immunotherapy to treat patients with cancer (Press release, Baylor College of Medicine, OCT 12, 2020, View Source [SID1234568607]).

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!

Researchers at Baylor College of Medicine and the University of North Carolina at Chapel Hill have genetically modified human NKT cells with a chimeric antigen receptor (CAR) that enables them to specifically recognize and attack neuroblastoma, a form of childhood cancer. Expressed with the CAR is interleukin-15 (IL-15), a natural protein that supports NKT cell survival.

In the study, appearing in Nature Medicine, researchers present interim results from an ongoing clinical trial showing that the modified cells are safe, localize to tumors, and, in one of three patients, induced an objective response with regression of bone metastatic lesions.

Enhancing the tumor-fighting capabilities of NKT cells

The earliest CAR-modified cells were immune T cells. CAR T cells have been proven to be effective in treating certain types of leukemia and lymphoma. However, a number of challenges have been encountered in attempts to treat solid tumors with CAR T cells. Preclinical studies have demonstrated that NKT cells offer a novel approach that may enhance CAR-directed cancer immunotherapy.

"In addition to being able to effectively combat tumors in mouse models, the presence of NKT cells within solid tumors is associated with favorable outcomes in cancer patients," said co-corresponding author Dr. Leonid Metelitsa, professor of pediatric oncology at Baylor and Texas Children’s Hospital and member of Baylor’s Dan L Duncan Comprehensive Cancer Center.

Previous work has shown that NKT cells have a spectrum of anti-tumor activities. For instance, these cells migrate to tumor sites where they kill tumor-associated macrophages, a type of immune cell that can promote tumor growth and metastasis. Moreover, NKT cell activation indirectly promotes an anti-tumor response mediated by two other types of immune cells, NK and T cells.

"We think that NKT cells have substantial potential to serve as valuable contributors to the fight against cancer," said co-corresponding and first author Dr. Andras Heczey, assistant professor of pediatric oncology at Baylor and Texas Children’s and member of the Dan L Duncan Comprehensive Cancer Center. "For the last 10 years, we have been focused on enhancing these cells’ tumor-fighting abilities with the ultimate goal of bringing them to the clinic."

Preparing NKT for clinical trials

The journey to develop NKT cells into a form of immunotherapy involved finding solutions for a number of challenges. For example, NKT cells represent a low percentage of the cells in the blood, so Metelitsa, Heczey and their colleagues developed methods to grow NKT cell populations to clinical scale with high purity.

Although NKT cells can combat tumors in several ways, they all seem to be indirect. "Working with Dr. Gianpietro Dotti at UNC, we gave NKT cells a tool – the CAR – that enables them to attack tumors directly," Metelitsa said. "We also equipped them with IL-15, an additional tool to help them survive in the patient while they fight the tumor."

"The field of CAR cellular immunotherapy for cancer has been focused to date primarily on the manipulation of T lymphocytes," said Dotti, professor and director of cancer cellular immunotherapy at UNC Lindberger Comprehensive Cancer Center. "Based on previous clinical evidence that NKT infiltration within the tumor correlates with favorable clinical outcomes, we decided to leverage this intrinsic property of NKTs and to arm them with an additional bullet – the so-called CAR – to further potentiate their capacity to destroy the tumor."

With all these innovations in hand, the researchers moved on to test CAR NKT cells in patients with neuroblastoma in a clinical trial.

Clinical results

The clinical trial is ongoing, and results from the first three patients with heavily pre-treated, relapsed/refractory metastatic neuroblastoma are presented in this study. The patients were treated with CAR NKT cells, engineered from the patient’s own white blood cells at the Center for Cell and Gene Therapy at Baylor and Texas Children’s. Researchers engineered 95 percent pure NKT cells, a portion of which was armed with CAR-IL15.

"Our initial results show that NKT cells can be expanded to clinical scale with high purity, genetically engineered to express a CAR and IL15, and used to safely treat patients with advanced neuroblastoma," Metelitsa said.

"In addition, we found that CAR-IL15 NKT cells can be detected in the peripheral blood, where they expand postinfusion, traffic to bone metastases and the bone marrow, and exert anti–tumor activity," Heczey said. "We observed an objective response, elimination of at least 50 percent of metastases, in one of the patients."

Dr. Antonio Montalbano and other co-authors from Immunai, a company specializing in single-cell technologies and AI approaches for immunology, applied its state-of-the-art technology platform that allows for the analysis of all genes at the single-cell level in the CAR-NKT patient products. These analyses revealed new information about the heterogeneity of human NKT cells and molecular details of their therapeutic modifications. The researchers discovered nine subsets of NKT cells, and that the CAR receptor seemed to go preferentially to one set identified as cluster 3. Further studies will help understand the implications of these findings.

"Our study shows that it is possible to employ immune cells with natural anti-tumor capabilities and enhance their tumor fighting power with designer synthetic receptors, opening the possibility of applying this strategy to combat hard-to-treat solid tumors," Metelitsa said.

"By leveraging Immunai’s end-to-end platform of artificial intelligence and computational analysis, we were able to zero in on CAR engineered NKT cells from the patients at the single-cell level. The findings from this study are critical toward developing more precise and effective therapies for cancer patients," said Montalbano, genomics technologies lead at Immunai. "We’re looking forward to continuing our research with Baylor with the goal of advancing therapeutic discoveries, accelerating drug development and improving patient outcomes."

The NKT platform developed in this research at Baylor has been licensed to Kuur Therapeutics to advance clinical development.

"The Baylor-Kuur Therapeutics relationship is generating exactly the type of outcomes that we had envisioned at the outset," said Shawn Davis, vice president and chief ventures officer at Baylor. "The modified NKT platform developed in the Metelitsa laboratory is differentiated from other cell therapy platforms, offering novel routes for the treatment of cancers that have posed challenges for immunotherapeutic approaches. The encouraging findings announced today support the potential of NKT platform to provide promising alternatives, particularly for the treatment of solid tumors."

Other contributors to this work include Amy N. Courtney, Simon Robinson, Ka Liu, Mingmei Li, Nisha Ghatwai, Olga Dakhova, Bin Liu, Tali Raveh-Sadka, Cynthia N. Chauvin-Fleurence,Xin Xu, Ho Ngai, Erica J. Di Pierro and Barbara Savoldo. The authors are affiliated with one or more of the following institutions: Baylor College of Medicine, Texas Children’s Hospital, Immunai Inc. and the University of North Carolina at Chapel Hill.

This work was supported by grants/contracts from Alex’s Lemonade Stand Foundation for Childhood Cancer, Kuur Therapeutics, American Cancer Society, Cookies for Kids’ Cancer Foundation, and the Cancer Prevention and Research Institute of Texas (BCM Comprehensive Cancer Center Training Program, RP160283).

On October 12, 2020 Prescient Therapeutics reported that attention for its remarkable progress on the development of a broad pipeline for personalised cancer treatments (Press release, Prescient Therapeutics, OCT 12, 2020, View Source;utm_medium=rss&utm_campaign=shedding-light-on-prescient-therapeutics-ptx-personalised-cancer-treatments [SID1234568605]).

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!

Personalised cancer treatments of PTX comprises CAR-T and targeted therapies spanning several challenging cancers. Prescient Therapeutics has licensed technologies and collaborations with world-leading cancer centres in the U.S.

Let us deep dive and discuss product pipeline of Prescient Therapeutics-

Universal immune receptor platform, OmniCAR

OmniCAR is a universal immune receptor platform creating next-generation CAR-T therapies. Whilst CAR-T has represented a paradigm-shift in treating cancer, current generation CAR-T is faced with many limitations including safety and flexibility in targeting other cancers.

This is where OmniCAR comes in, creating next-genreation CAR-T that addresses the limitations of current generation CAR-T. OmniCARenables controllable T-cell activity & multi-antigen targeting with a single cell product. The modular CAR system of OmniCAR decouples antigen recognition from the T-cell signalling domain. This platform is based on technology licensed from the University of Pennsylvania and Oxford University.

The universal immune receptor platform allows extraordinary control and flexibility over the current generation CAR-T approaches. With OmniCAR, Prescient will enable its in-house development of next-generation engineered cell therapies. OmniCAR also creates opportunities in collaboration and business development for cell therapy area of Prescient.

Prescient is working with the goal of harnessing innate adaptability and control of OmniCAR for developing novel CAR-T products for new indications. OmniCAR platform improves the cost, time as well as the effectiveness of delivering CAR-T therapies across the world.

READ MORE: Prescient Collaborates With Peter MacCallum Cancer Centre

Moreover, Prescient has several other programs underway to develop new cell therapy methods.

First-in-class drug candidate, PTX-100
PTX-100 disrupts the oncogenic Ras pathway by preventing the activation of Rho, Rac and Ral, leading to cancer cells death. PTX-100 is under clinical development for hematological and solid malignancies under Phase 1b PK/PD basket study.

Currently, PTX is conducting its Phase 1b basket study of PTX-100 at a dose of 2,000 mg/m2.

In this study, Prescient is finding the mutational status of malignancies of each patient and aims to compare this status with any clinical activity. Moreover, the Company is investigating several cancer biomarkers with the objective of identifying patients who may be most likely to respond to PTX-100 therapy.

Novel PH domain inhibitor, PTX-200
A novel PH domain inhibitor PTX-200 inhibits Akt tumor survival pathway. This pathway has a significant role in the development of numerous cancers, including breast & ovarian cancer, along with acute myeloid leukemia (AML). With its novel mechanism of action, PTX-200 specifically inhibits Akt while being comparatively safe. Currently, Prescient is conducting Phase 1b study of PTX-200 & cytarabine in AML patients.

On 3 August 2020, the Company disclosed that it had completed the Phase 1b study for the first cohort at a dose of 25 mg/m2 PTX-200 under the revised study protocol. Currently, Prescient is conducting the Phase 1b study at the increased dose level of 35 mg/m2 PTX-200.

World-renowned leukemia expert Professor Jeffrey Lancet (H. Lee Moffitt Cancer Center, Florida) is leading the AML study.

COVID-19 Antiviral Testing Program
Addition to its personalised cancer treatments Prescient’s two assets are under evaluation against the deadly SARS-CoV-2. On 21 July 2020, Prescient Therapeutics disclosed that its two assets had been nominated as Group 1 priority candidates by Doherty Institute for a COVID-19 antiviral testing program. Both the assets of Prescient are selected on the basis of their potential antiviral properties.

On 12 October 2020, PTX share was trading at A$0.066, with a market capitalisation of A$41.64 million.

To know more about Prescient Therapeutics Limited, click here.

To stay updated with PTX company activities and announcements, please update your details on their investor centre.

Resilient Healthcare Stocks to Beat the Pandemic Heat
With the pandemic continuing to affect the globe, healthcare companies are evaluating their lead compounds for COVID-19 treatment. Future revenue for these stocks depends on the probability of launching an approved treatment in the market.