Recent research has demonstrated that neoantigen-specific T-cell receptors (TCRs) can be isolated from a cancer patient’s lymphocytes. These TCRs may be used to engineer populations of tumor-reactive T cells for cancer immunotherapies. Obtaining sequences of these functional TCRs is a critical initial step in preparing this type of personalized cancer treatment; however, current methods are time-consuming and labor-intensive. Scientists at the National Cancer Institute (NCI) have developed a rapid and robust method of isolating the sequences of mutation-specific TCRs to alleviate these issues; they seek licensing and/or co-development research collaborations for the development of a method for isolating the sequences of tumor-reactive TCRs. For collaboration opportunities, please contact Steven A. Rosenberg, M.D., Ph.D. at firstname.lastname@example.org.
Adoptive cell therapy uses cancer reactive T-cells to effectively treat cancer patients. Producing many persistent T-cells is critical for successful treatments. Researchers at the NCI seek licensing and/or co-development research collaborations for a novel method of producing effective T-cell populations using Akt inhibitors.
Scientists at the National Cancer Institute (NCI) have developed the Cytokine Signaling Analyzer (CytoSig), a software-based platform that provides both a database of target genes modulated by cytokines and a predictive model of cytokine signaling cascades from transcriptomic profiles. NCI seeks collaborators or licensees to advance the development of CytoSig for research, target discovery, or as a Clinical Decision Support System (CDSS).
Researchers at the National Cancer Institute (NCI) developed a novel mouse for the detection of TGF-ß signaling. This mouse provides the opportunity to study TGF-ß signaling in vivo and may be a useful model for preclinical pharmacology studies. The NCI seeks licensees for the TGF-ß reporter mouse.
Recombinant human tissue inhibitors of metalloproteinases (rhTIMP-2) have been shown to suppress tumor growth and tumor-associated angiogenesis. NCI Radiation Oncology Branch (ROB) researchers have developed a unique HEK-293F cell line which stably expresses rhTIMP-2, increasing the production of TIMP-2 to quantities sufficient to be used for testing and development as a therapeutic for various cancers, ischemic diseases (myocardial infarct and cerebrovascular infarct), and neurodegenerative diseases.
Researchers at the National Cancer Institute (NCI) have developed an improved class of heptamethine cyanine fluorophore dyes useful for imaging applications in the near-IR range (750-850 nm). A new chemical reaction has been developed that provides easy access to novel molecules with improved properties. Specifically, the dyes display greater resistance to thiol nucleophiles, and are more robust while maintaining excellent optical properties. The dyes have been successfully employed in various in vivo imaging applications and in vitro labeling and microscopy applications. The NCI seek co-development or licensees to develop them as targetable agents for optical-guided surgical interventions.
Researchers at the National Cancer Institute (NCI) have developed a bioluminescent MB49-luciferase bladder cancer cell line that can be used in preclinical studies to evaluate anti-cancer agents in bladder cancer. NCI seeks parties to non-exclusively license this research material.
The National Cancer Institute (NCI) seeks licensees for an SLC46A3 knockout mouse line. SLC46A3 is a solute carrier of the Major Facilitator Superfamily (MFS) and is thought to have roles in multiple diseases including nonalcoholic fatty liver disease, liver cancer and obesity.
Researchers at the National Cancer Institute (NCI) developed orthotopic allograft models for pancreatic cancer that utilize cells or tumor fragments implanted into the cancer-free pancreata of recipient immunocompetent mice. NCI seeks licensees to commercialize this invention.
The Hippo signaling pathway is one of the most frequently altered pathways in human cancer. Researchers at the National Cancer Institute (NCI) have developed a genetically encoded peptide inhibitor of the Hippo signaling pathway members YAP1/TAZ-TEAD, to dissect and study the specific TEAD-downstream regulatory gene expression networks of cell proliferation, tissue homeostasis, and stem cell functions in different cell types and pathologies. The DNA construct encoding this inhibitor may be delivered to cells using lentivirus, adenovirus, or adeno-associated virus, and is a valuable research tool. NCI seeks licensees for this peptide inhibitor and the encoding DNA construct.
Impairment of cell motility and membrane trafficking can result in enhanced cell proliferation and survival and increased migration and invasion leading to cancer. Several proteins involved in cell motility and membrane trafficking have been shown to be dysregulated in various cancers. Animal models that facilitate the study of roles of these proteins in vivo are therefore required. The National Cancer Institute (NCI) seeks licensees for Mouse Lines with Fluorescently Labelled Membrane Proteins Regulating Cellular Motility and Membrane Trafficking
The National Cancer Institute (NCI) has a novel mouse model of autoimmunity based on chronic interferon-gamma expression (ARE-Del). This mouse can be used as an in vivo model to study female-biased autoimmune diseases, including: Systemic Lupus Erythematosus, Primary Biliary Cholangitis, and Ovarian Failure Syndrome.
NCI's Center for Advanced Preclinical Research (CAPR) has developed a Serous Epithelial Ovarian Cancer (SEOC) genetically engineered mouse model (GEM), GEM-derived SEOC orthotopic mouse model, and biological materials derived therefrom, with several key histopathologic, immunophenotypical, and genetic features of human SEOC. NCI CAPR seeks licensees for this technology.
The National Cancer Institute Cancer Genetics Branch is seeking statements of capability or interest from parties interested in collaborative research to further develop, evaluate, or commercialize mouse epithelial cancer cell lines.
NIH scientists created and characterized an excellent mouse model for TNBC that shares important molecular characteristics of human TNBC making it highly useful for preclinical testing of drugs and novel therapies. This model may provide a valuable means of identifying new drugs and therapies that could be translated to human clinical trials.The NCI seeks parties interested in licensing this mouse model of prostate and triple-negative breast cancers to study cancer biology and for preclinical testing.