improved NK cell persistence and anti-tumor activity. In a research demonstration, the Feldan system has been used to introduce guide RNAs and CRISPR nucleases to NK cells to specifically knock-out genes expressing inhibitory receptors on the surface of NK cells. This engineering resulted in NK cells that remain active in the presence of certain inhibitory signals known to be produced by tumors.
Improving therapeutic NK cell persistence
Second, when infused into a patient, NK cells may be targeted for destruction by the patient’s immune system. Lymphodepleting chemotherapy is commonly given before cell therapy administration to prevent the patient’s immune system from rejecting the infused cells. However, this conditioning can result in adverse events in patients. The Feldan system, again in combination with specific guide RNAs and CRISPR nucleases, has been used to create engineered NK cells resistant to both T- cell- and NK- cell destruction by eliminating MHC expression while adding a gene for MHC class I antigen E, also known as histocompatibility antigen E or HLA-E.
We intend to further optimize and develop these NK gene editing systems and explore their utility in further improving the potential therapeutic benefit of our future NK cell product candidates.
Competition
The biopharmaceutical industry in general, and the cell therapy field in particular, is characterized by rapidly advancing and changing technologies, intense competition and a strong emphasis on intellectual property. We face substantial and increasing competition from large and specialty biopharmaceutical companies, as well as public and private medical research institutions and governmental agencies. Competitors may compete with us in hiring scientific and management personnel, establishing clinical study sites, recruiting patients to participate in clinical trials and acquiring technologies complementary to, or necessary for, our programs.
Our known biopharmaceutical competitors developing allogeneic non-CAR-NK cell, CAR-NK or CAR-T cell therapies currently include, among others, Acepodia, Allogene, Autolus, Caribou Biosciences, Cellectis, Celularity, CRISPR Therapeutics, Fate Therapeutics, Gamida Cell, Glycostem, Kiadis Pharma (acquired by Sanofi), Nkarta, NantKwest / ImmunityBio, Precision BioSciences, Poseida, Takeda (in collaboration with The University of Texas MD Anderson Cancer Center) and Wugen, each of which has clinical-stage allogeneic programs, as well as numerous other biopharmaceutical companies, including Astellas, Century Therapeutics, Cytovia, Editas Medicine, Gilead, Indapta Therapeutics, NK Gen, oNKo-Innate, ONK Therapeutics, Senti Bio and Shoreline Biosciences with earlier-stage allogeneic programs. Further, three companies have FDA-approved autologous CAR-T cell therapies indicated for certain hematological malignancies, Novartis, Bristol-Myers Squibb, and Gilead Sciences, Inc. A number of companies are seeking to harness NK or T cell biology through engagers which seek to direct a patient’s own NK or T cells to the site of a tumor. Such competitors include Affimed, Amgen, Dragonfly Therapeutics, Innate Pharma, Servier and other biopharmaceutical companies. Our competitors will also include companies that are or will be developing other targeted therapies, including small molecule or antibodies for the same indications that we are targeting.
In addition, research in immuno-oncology is one of the most active areas for the discovery and clinical development of new anticancer therapies in the biopharmaceutical industry. New approaches, such as bispecific antibodies, as well as refinements of existing modalities, such as immune checkpoint inhibitors, are constantly emerging.
Many of our current or potential competitors have significantly greater financial, technical and human resources, as well as more expertise in research and development, manufacturing, preclinical
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