On June 27, 2019 The Multiple Myeloma Research Foundation (MMRF) reported that it is piloting a new precision medicine research initiative called the Immune Atlas (Press release, Multiple Myeloma Research Foundation, JUN 27, 2019, View Source [SID1234537309]). The objectives of this Immune Atlas pilot are to develop a ‘gold standard’ immune profiling platform for myeloma research studies and to generate robust immune data that is fundamental to the delivery of precision medicine. The Immune Atlas is a critical part of the organization’s bold three-year plan, which focuses, in part, on generating robust immune data to advance precision immuno-oncology efforts.

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"Immunotherapy has transformed outcomes for patients with many kinds of cancers that previously had few effective options," said the MMRF President and Chief Executive Officer Paul Giusti. "Progress in immunotherapy in myeloma has been gradual because of the complexity of the disease and a fragmented research effort. As the leader in precision medicine, we are now seeking to accelerate immune agents into the clinic for myeloma patients and ensure that each patient receives treatment that is specific for their immune profile."

The MMRF has partnered with leading academic centers that will employ cutting edge analytical technologies to comprehensively characterize the immune repertoire and activity of key immune cell populations in myeloma patients. The five centers involved in the pilot are from the Multiple Myeloma Research Consortium (MMRC): Beth Israel Deaconess Medical Center, Emory University, Mayo Clinic Rochester, Mount Sinai School of Medicine, and Washington University.

"The great strength of the MMRF is the ability to bring partners together to collaborate on efforts that advance cures for myeloma patients," said the MMRF Chief Scientific Officer Daniel Auclair, PhD. "We are so fortunate to have these five best-in-class institutions as members of our Multiple Myeloma Research Consortium (MMRC), who can bring cutting-edge scientific analysis to bear on the most pressing needs of our patients. Once this immune profiling platform is validated, it can be rolled out to bring the promise of precision immunotherapy to the entire myeloma community."

About Multiple Myeloma

Multiple myeloma (MM) is a cancer of the plasma cell. It is the second most common blood cancer. An estimated 30,770 adults (16,400 men and 14,730 women) in the United States will be diagnosed with MM in 2019 and an estimated 12,770 people are predicted to die from the disease. The five-year survival rate for MM is approximately 47%, versus 31% in 1999.

On June 27, 2019 SpringWorks Therapeutics, Inc., a clinical-stage biopharmaceutical company focused on developing life-changing medicines for patients with severe rare diseases and cancer, reported that the company has entered into a clinical trial collaboration agreement with GlaxoSmithKline to evaluate SpringWorks Therapeutics’ investigational gamma secretase inhibitor (GSI), nirogacestat, in combination with GlaxoSmithKline’s investigational anti-B-cell maturation antigen (BCMA) antibody-drug conjugate (ADC), belantamab mafodotin (formerly GSK2857916), in patients with relapsed or refractory multiple myeloma (Press release, SpringWorks Therapeutics, JUN 27, 2019, View Source [SID1234537308]).

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Gamma secretase is an enzyme that cleaves multiple transmembrane proteins, including BCMA. As evidenced in publications and preclinical experiments, treatment with a GSI, including nirogacestat, can increase BCMA cell surface expression levels on multiple myeloma cells1, potentially improving the activity of BCMA-targeted therapies, including BCMA ADCs.

"While significant advances have been made in treating multiple myeloma over the past decade, a significant unmet need remains for patients who have relapsed or are refractory to available treatments," said Saqib Islam, Chief Executive Officer of SpringWorks Therapeutics. "We are delighted to enter into this agreement with GlaxoSmithKline, who also invested in our recent Series B financing, and we look forward to exploring the potential benefit of nirogacestat and belantamab mafodotin for multiple myeloma patients. With this collaboration, we are pleased to further expand on our strategy in building our targeted oncology portfolio with another industry leader."

Under the terms of the agreement, GlaxoSmithKline will sponsor and conduct the adaptive Phase 1b study to evaluate the safety, tolerability and preliminary efficacy of the combination, and will assume all development costs associated with the study. GlaxoSmithKline and SpringWorks Therapeutics will also form a joint development committee to manage the clinical study.

About Nirogacestat

Nirogacestat is an investigational, oral, selective, small molecule gamma-secretase inhibitor in Phase 3 clinical development for desmoid tumors, which are rare and often debilitating and disfiguring soft-tissue tumors. Gamma secretase cleaves multiple transmembrane protein complexes, including Notch, which is believed to play a role in activating pathways that contribute to desmoid tumor growth. In June 2018, the FDA granted Orphan Drug designation for nirogacestat for the treatment of desmoid tumors, and in November 2018, the FDA granted Fast Track designation for nirogacestat for the treatment of adult patients with progressive, unresectable, recurrent or refractory desmoid tumors or deep fibromatosis.

In addition, gamma secretase has been shown to directly cleave membrane-bound BCMA, resulting in the release of the BCMA extracellular domain, or ECD, from the cell surface. By inhibiting gamma secretase, membrane-bound BCMA can be preserved, increasing target density while reducing levels of soluble BCMA ECD, which may serve as decoy receptors for BCMA-directed therapies.2 Nirogacestat’s ability to enhance the activity of BCMA-directed therapies has been observed in preclinical models of multiple myeloma.

About belantamab mafodotin (GSK2857916)

Belantamab mafodotin is an investigational anti-B-cell maturation antigen (BCMA) antibody-drug conjugate in Phase 2 clinical development for patients with relapsed/refractory multiple myeloma and other advanced hematologic malignancies expressing BCMA.

In 2017, belantamab mafodotin was awarded Breakthrough Therapy designation from the U.S. Food and Drug Administration and PRIME designation from the European Medicines Agency; these designations are intended to facilitate development of investigational medicines that have shown clinical promise for conditions where there is significant unmet need.

On June 27, 2019 OncoSec Medical Incorporated (OncoSec) (NASDAQ:ONCS), a company developing late-stage intratumoral cancer immunotherapies, reported that it has entered into a collaboration with Dana-Farber Cancer Institute, a world-leading cancer research and treatment institution, and The Marasco Laboratory, a cutting-edge CAR T-cell research laboratory led by Wayne Marasco, M.D., Ph.D., a renowned cancer immunology researcher, to develop CAR T-cell therapies for triple-negative breast cancer and other solid tumor cancers (Press release, OncoSec Medical, JUN 27, 2019, View Source [SID1234537305]).

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Under the terms of the agreement, OncoSec has acquired an exclusive option to licensing rights to the CAR T-cell product candidates and associated IP resulting from the research being conducted at The Marasco Laboratory using engineered single-chain variable fragment (scFv) antibodies in a dual-targeted bi-specific CAR T-cell approach. Previous research conducted by The Marasco Laboratory suggests their proprietary CAR T-cell technology has the potential to be effective against numerous solid tumor indications, while minimizing the toxicity that current CAR T-cell technologies exhibit when applied beyond liquid tumor indications.

"This partnership has the potential to deliver novel, next-generation, dual-targeted CAR T-cell therapy for solid tumors, an achievement that has eluded researchers due to the toxicity of current CAR-T cell therapies. Prior research suggests that Dr. Marasco’s approach may hold the key to unlocking the safe and effective use of CAR T-cell therapies in solid tumors," said Daniel J. O’Connor, President and Chief Executive Officer of OncoSec. "CAR T-cell treatment of solid tumors is an early stage market with no approved products at the present time, and thus represents a considerable unrealized market opportunity. We believe the barriers preventing the advancement of CAR T-cell technology in the solid tumor setting are surmountable by Dr. Marasco and his team’s expertise. Further, combination with OncoSec’s intratumoral TAVO (IL-12) by electroporation may further enhance the efficacy of CAR T-cell therapy in solid tumors."

"The structure of our agreement with Dana-Farber provides for the greatest upside for our shareholders, while significantly de-risking our modest initial investment. Our financial contribution for the research is spread over several years and coincides with the generation of product candidates and data. We also have the flexibility to cease contribution should we opt to do so," continued Mr. O’Connor.

The Company plans to begin clinical trials with the TNBC CAR T-cell therapy in 2020, both as a monotherapy and in combination with OncoSec’s TAVO (IL-12).

Dr. Marasco, Professor, Department of Cancer Immunology at Dana-Farber and Professor of Medicine, Department of Medicine at Harvard Medical School, is a renowned antibody engineering expert who specializes in designing and engineering CAR T-cell therapies. Dr. Marasco and his team have a proven track record of developing monoclonal antibodies that attach to important proteins highly expressed in many common types of solid cancers, which is critical to developing an effective CAR T-cell therapy.

Importantly, the collaboration with Dana-Farber contemplates a vertically integrated development program, with the intent of conducting the CMC and clinical formulation work, as well as the clinical manufacturing of the drug product, at the Dana-Farber Core Manipulation Cell Facility (CMCF). The CMCF is an impressive GMP manufacturing facility located at Dana-Farber. Additionally, OncoSec plans to conduct the initial clinical trials within the Harvard University network of hospitals.

CAR T-cell therapies have been unable to achieve meaningful clinical results in solid tumors due to toxicity, specifically, the "on-target, off-tumor" side effects, which can trigger lethal immune pathology. The Marasco Lab has developed a proprietary strategy to limit off-tumor toxicity through the use of a bispecific CAR system in which both single-chain variable fragment (scFv) are strategically linked to drive the intracellular signaling sufficient for T cell activation/killing. Importantly, this activation/killing is triggered only if and when both targets are engaged simultaneously on a tumor.

The remarkable success of CAR T-cell therapies in hematological malignancies has propelled its development in solid tumors. However, unlike the great strides made in liquid tumors, the clinical success of CAR T-cell therapies in solid tumors has been limited in large part due to the associated immunosuppressive elements of the tumor microenvironment (TME). Intratumoral TAVO (IL-12) has a proven ability to alter the immunosuppressive TME by eliciting a productive pro-inflammatory immune response.

This TAVO induced pro-inflammatory response both limits immune suppression while driving immunogenicity, thereby providing a strong rationale for the combination of this CAR T-cell therapy with OncoSec’s TAVO immunotherapy.

"We are excited to be partnering with OncoSec to work to bring new therapies to cancer patients in need," said Dr. Marasco. "The Marasco Labs are dedicated to using cutting edge science to develop new targeted CAR T therapies that can address the challenges associated with successfully treating solid tumors. This support from OncoSec will enhance our efforts."

DNA electroporation is already used as a method to make a CAR T-cell therapy. Levering OncoSec’s deep expertise in electroporation, the Company also intends to investigate DNA electro-transfection for the intratumoral in vivo generation of functional CAR-T cells, with the goal of making CAR T-cell therapy more affordable and accessible to patients.

Dr. Marasco studied at the University of Connecticut’s School of Medicine, where he received his Ph.D. in 1980. He completed his postdoctoral training at the University of Michigan Medical School, where he also earned a M.D. in 1986. He received his subspecialty training in infectious diseases at Harvard Medical School, where he is currently a professor, and he joined the Dana- Farber Cancer Institute in 1989. In 1992, he also joined the Division of Infectious Diseases at Brigham and Women’s Hospital. In 1980 and 1981, Dr. Marasco won the Biomedical Research Council Award and the National Research Service Award from the University of Connecticut School of Medicine, and the University of Michigan awarded him the United States Public Health Service Award in 1981, the Dean’s Award for Research Excellence in 1986 and the Lung Immunopathology Training Grant Award in 1987 and 1988.

In 2009, U.S. News & World Report listed Dr. Marasco as a "Medical Pioneer" and a top scientist in his field. In the same year, Dr. Marasco was selected as a Distinguished Speaker by the Walter Reed Army Institute of Research. For cancer, as well as HIV/AIDS and other infectious diseases, one possible treatment involves the use of human monoclonal antibodies (Mabs) – which are proteins that are produced to bind to only one substance. For cancer treatments, Mabs bind only to cancer cells and produce immunological responses against the cancer cells. There is great promise with Mabs because their tumor-fighting effects can be less harmful to normal cells than that of traditional cancer treatments.

The Marasco Laboratory, located in the Department of Cancer Immunology and Virology at Dana-Farber Cancer Institute, conducts research in the field of targeted immunotherapy. The Lab’s work has made major scientific advances in the treatment of infectious diseases and cancer. Specifically, the Lab’s research interests are in human monoclonal antibody (mAb) immunotherapy.

In 2003, Dr. Marasco became the Director of the National Foundation for Cancer Research (NFCR) Center for Therapeutic Antibody Engineering to expand the use of human monoclonal antibodies in the treatment of cancer.

Dr. Marasco has had great success developing Mabs that attach to an important protein – carbonic anhydrase IX (CAIX) – that is highly expressed in renal cell carcinoma, the most common type of kidney cancer. Most recently, his team at the NFCR Center developed a combination immunotherapy treatment that holds promise for treating metastatic kidney cancer more effectively. The immunotherapy they have engineered includes not only the CAIX antibody that detects and binds to CAIX growth-promoting proteins on cancerous kidney cells, but also unblocks T cells to enable more rigorous attacks against cancer. The OncoSec / Dana- Farber collaboration will capitalize on Dr. Marasco’s prior success using the double treatment approach, adapting it to triple negative breast cancer and other difficult-to-treat solid cancers using different antibodies.

On June 27, 2019 Propanc Biopharma, Inc. (OTC: PPCBD) ("Propanc"), a biopharmaceutical company developing new cancer treatments for patients suffering from recurring and metastatic cancer, reported that Propanc’s intellectual property ("IP") portfolio has undergone rapid growth recently, with sixty-five patents currently either in force or pending in most major countries and regions around the world (Press release, Propanc, JUN 27, 2019, View Source [SID1234537304]). The IP covers Propanc’s underlying anti-cancer technology in development. In the past year, three additional patent families entered national phase, where a patent application is filed in individual countries and regions, in order to achieve grant status.

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"Our IP portfolio is a world leader in the field of administration of proenzymes for the treatment and prevention of metastatic cancer. IP is the cornerstone of any biotech company, and places us in a strong position to unlock significant value, as we plan to progress into a First-In-Human study and then hopefully towards proof of concept in a specific cancer indication, where we will then look at possible licensing opportunities," said Dr. Julian Kenyon, Propanc’s Chief Scientific Officer. "We are firmly of the opinion that our current market value does not truly reflect the advancement of our lead product, PRP, or its true potential as a breakthrough, long term treatment for aggressive and fast spreading cancers from solid tumors by targeting and eradicating cancer stem cells."

Propanc has a total of four patent families covering the use of proenzymes for treating cancer via a combination of trypsinogen and/or chymotrypsinogen pancreatic proenzymes, which includes Propanc’s lead product candidate, PRP. The IP portfolio includes composition of matter claims and a method of treatment to eradicate cancer stem cells. Further applications are also expected relating to the formulation and methods of use, as well as research programs with its joint research partners designed to further optimize the quality, safety and performance of PRP.

On June 27, 2019 Advaxis, Inc. (NASDAQ:ADXS), a clinical-stage biotechnology company focused on the discovery, development and commercialization of immunotherapy products, reported that it is increasing its focus on neoantigen-directed immunotherapies and closing the AIM2CERV Phase 3 clinical trial with axalimogene filolisbac (AXAL) in high-risk locally advanced cervical cancer (Press release, Advaxis, JUN 27, 2019, View Source [SID1234537303]). Advaxis intends to continue to support the clinical development of AXAL, its single-antigen construct, in other HPV-related cancers while redirecting resources towards advancing its neoantigen-directed programs. Specifically, the company plans to continue developing ADXS-NEO, currently in a Phase 1 clinical trial, in patients with several types of advanced or metastatic solid tumors including melanoma, lung, colorectal, head and neck and bladder cancers, and ADXS-HOT, currently in a Phase 1/2 clinical trial, for non-small cell lung cancer. The company anticipates advancing additional drug constructs from its ADXS-HOT program into the clinic over the next 18 months.

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"We remain firmly committed to our Lm Technology platform, including our personalized and off-the-shelf approaches for neoantigen-directed therapies, and the development of AXAL against HPV-related cancers," said Kenneth A. Berlin, President and Chief Executive Officer of Advaxis. "While closing the AIM2CERV trial was a difficult decision due to the efforts of many individuals including the investigators and patients, the delays we incurred as a result of the recent FDA partial clinical hold and the estimated cost and time to completion for AIM2CERV led us to believe the best path forward for the company is to focus on our neoantigen programs. We believe this increased focus will enable a quicker and more cost-effective approach to demonstrate the strength and versatility of our Lm platform, thereby enhancing shareholder value."

The estimated remaining cost to complete the AIM2CERV trial ranges from $80 million to $90 million, and initial efficacy data is not anticipated for at least three years. Therefore, results from the clinical trial were not the basis for the decision to close the study, nor was safety as the trial recently underwent its third Independent Data Monitoring Committee (IDMC) review with no safety issues noted. The company plans to unblind the AIM2CERV clinical data generated to date and anticipates submitting these data for publication. In addition, Advaxis will continue to pursue monetization opportunities for AXAL.

"The emerging data from our neoantigen programs look very promising, and therefore these programs merit an increased focus of the company’s resources," stated Mr. Berlin. "With this redirection of resources to our neoantigen programs, we anticipate our cash usage for the next 12 months will be in the range of $33 million to $37 million, which includes $8 million to $9 million in non-recurring costs associated with prior AXAL studies including AIM2CERV. This reduction in our cash burn is a significant improvement over the past several years and also betters the goal we set of $45 million at the beginning of our fiscal year 2019." He concluded, "We believe these changes will enable us to pursue a leadership position in the neoantigen field by building upon the early and exciting data from our ADXS-NEO and ADXS-HOT programs."