The present invention includes compositions and methods for treating atherosclerosis. In certain embodiments, atherosclerosis is treated using a chimeric antigen receptor (CAR) T cell specific for modified low-density lipoprotein.

Proteins comprising anti-GUCY2C scFvs and nucleic acid molecules that encode anti-GUCY2C scFvs are disclosed. Proteins comprising signal sequence linked to anti-GUCY2C scFvs linked to hinge, transmembrane and signal domain sequences are disclosed. Nucleic acid molecules that encode proteins comprising signal sequence linked to anti-GUCY2C scFvs linked to hinge, transmembrane and signal domain sequences are disclosed. T cells that comprise such proteins and such nucleic acid molecules that are disclosed. Methods of making the T cells and methods of using the T cells to treat or prevent cancer that has cancer cells that express GUCY2C are disclosed.

The present invention provides gene edited or gene silenced immune cells comprising an chimeric antigen receptor (CAR) such as an anti-CD2 CAR. In some embodiments, such engineered immune cells lack CD2 expression. Also, provided herein are methods of using such cells in cancer therapies.

The present invention provides engineered immune cells comprising an anti-CD2 protein expression blocker (PEBL) and an anti-CD2 chimeric antigen receptor (CAR). In some embodiments, such engineered immune cells lack surface expression CD2. Also, provided herein are methods of using such cells in cancer therapies.

The present disclosure provides modified immune cells or precursors thereof (e.g. modified T cells) comprising a chimeric cell surface sialidase or a variant sialidase precursor protein. Compositions and methods of treatment are also provided.

Various TnMUC1-specific chimeric antigen receptors (CARs), nucleic acids encoding the same, and methods of using the same, are provided. Compositions and methods comprising a TnMUC1-specific CAR for treating MUC1-associated cancer in a subject in need thereof are provided.

The present invention concerns providing chimeric natural killer cell receptor (CNK) constructs, genetically engineered T cells expressing such constructs (CNK-T), genetically engineered natural killer cells expressing such constructs (CNK-NK), and the use of CNK-T and CNK-NK to treat a variety of disease states. Specifically, the CNK are designed to target any types of infected, transformed, autoreactive, senescent and stressed cells overexpressing NKG2D ligands. Compared with native T cells and native natural killer cells, the CNK-T and CNK-NK are shown to have improved sensitivity in initiating cytotoxicity against the tumor cells and viral cells in absence or presence of the second genetically modification. Moreover, by incorporating the CNK into the chimeric antigen receptor (CAR) system, the genetically engineered T cells expressing such constructs (CNK/CAR-T) display enhanced sensitivity and superior cytotoxicity against tumor cells. Therefore, such CNK-T and CNK/CAR-T could be applied to the cellular therapy to treat tumor, virus infected diseases and autoimmune diseases directly.

The disclosure concerns a method for cancer treatment by in vivo priming and activation of natural killer cells for achieving tumor cell lysis. The method includes introducing into a patient a priming tumor cell preparation (PTCP) derived from a first tumor cell line, which is irradiated to inactivate the first tumor cells or a membrane preparation thereof, the first tumor cells having known priming ligands on the membrane surface thereof. The patient's rest NK cells are contacted by the PTCP in vivo, resulting in primed NK cells, which are characterized by upregulation of CD69, shedding of CD16, or a combination of CD69+ and CD16. These primed NK cells then contact second tumor cells, the cancer, and are configured to lyse and kill the second tumor cells.

The present disclosure relates to compositions and methods for compositions, methods, and kits for treating cancer using chimeric antigen receptor (CAR) modified cells. Some embodiments of the present disclosure relate to an isolated nucleic acid sequence encoding CAR. The CAR may include an antigen binding domain, a transmembrane domain, a costimulatory signaling region, and a CD3 zeta signaling domain. The antigen binding domain may bind to an antigen of a non-essential organ.

The disclosure concerns a method for cancer treatment by in vivo priming and activation of natural killer cells for achieving tumor cell lysis. The method includes introducing into a patient a priming tumor cell preparation (PTCP) derived from a first tumor cell line, which is irradiated to inactivate the first tumor cells or a membrane preparation thereof, the first tumor cells having known priming ligands on the membrane surface thereof. The patient's rest NK cells are contacted by the PTCP in vivo, resulting in primed NK cells, which are characterized by upregulation of CD69, shedding of CD16, or a combination of CD69+ and CD16. These primed NK cells then contact second tumor cells, the cancer, and are configured to lyse and kill the second tumor cells.