The present disclosure relates to cells capable of co-expressing T cell receptors (“TCR”) together with membrane-bound IL-15 polypeptides and/or CD8 polypeptides and the use thereof in adoptive cellular therapy. The present disclosure further provides for modified IL-15, IL-15Rα, IL-15/IL-15Rα fusion polypeptide, and IL-15Rα/IL-15 fusion polypeptide sequences, vectors, and associated methods of making and using the same. The present disclosure further provides for modified CD8 sequences, vectors, and associated methods of making and using the same.

Provided are novel fusion proteins, nucleic acids encoding said proteins, vectors comprising said nucleic acids, compositions comprising said nucleic acids or vectors, host cells comprising said nucleic acids, vectors or compositions or pharmaceutical compositions. Provided are methods of reducing (down regulating) a target membrane-bound protein (MBP) level in a cell, methods of producing a cell having a reduced target membrane-bound protein level, or methods of treating a disease, or methods of reducing or preventing GvHD in a subject associated with the administration of one or more CAR T-cells to the subject.

Composition and methods for ex vivo expansion of natural killer (NK) cells, and methods for cell-based cancer immunotherapy are disclosed. Leukemic cell-derived dendritic cells and anti-PD-L1 antibodies, and certain embodiments with addition of PBMCs are used for in vivo administration for cancer treatment. Leukemic cell-derived dendritic cells and anti-PD-L1 antibodies are also used for ex vivo expansion of NK cells.

This disclosure relates to compositions and methods for treating cancer using armored chimeric antigen receptor cells.

The present invention relates to a method and system for identifying and validating pairs of candidate antigens and their cognate antigen-specific T lymphocytes that are useful for validating the immunogenic activity of paired antigen and TCR sequences. The method includes, inter alia, steps of determining one or more splice variants that are more highly transcribed in a sample obtained e from cohort of patients compared to a reference sample, determining one or more amino acid sequences that occur in an amino acid translation of said one or more splice variants but not in the corresponding splice variant in the reference sample, and predicting HLA binding of the amino acid sequences in order to identify candidate shared antigen. The present invention also relates to methods of characterising and/or treating a medical condition, including cancer.

Disclosed are treatments for cancer that enhance a patient immune systems' ability to detect and attack cancer. The present disclosure provides methods for treating cancer in a subject in need thereof comprising administering to the subject an effective amount of a pregnancy specific glycoprotein (PSG) inhibitor.

The present disclosure provides methods and compositions that include a polynucleotide that includes nucleic acids that encode an anti-idiotype polypeptide, as well as polypeptides that are encoded by the same, and cells that include and express the polypeptide. Disclosed methods include methods that utilize the anti-idiotype polypeptides as safety switches when they are used in combination with antibodies, include approved biologic antibodies, that include the recognized idiotype. Certain embodiments include anti-idiotype polypeptides and nucleotides encoding the same, that include an internal domain. This internal domain in some embodiments has functional domains that can induce proliferation or cell death upon binding of the anti-idiotype polypeptide by its target antibody.

Immune cells, including T cells, expressing a chimeric antigen receptor targeted to CD45 are described. In some cases, the immune cells lack a functional CD45 gene. In some cases, the immune cells also include a modification (a suicide sequence) that allows the cells to be killed in vivo. The immune cells are useful for treating a variety of cancers.

The present disclosure describes systems and methods for immunotherapies Immune cells can be engineered to exhibit enhanced half-life as compared to control cell (e.g., a non-engineered immune cell). Immune cells can be engineered to exhibit enhanced proliferation as compared to a control cell. Immune cells can be engineered to effectively and specifically target diseased cells (e.g., cancer cells) that a control cell otherwise is insufficient or unable to target. The engineered Immune cells disclosed herein can be engineered ex vivo, in vitro, and in some cases, in vivo. The engineered Immune cells that are prepared ex vivo or in vitro can be administered to a subject in need thereof to treat a disease (e.g., myeloma or solid tumors). The engineered Immune cells can be autologous to the subject. Alternatively, the engineered immune cells can be allogeneic to the subject.

Provided are a tandem epitope polypeptide vaccine for novel coronavirus and use thereof. Specifically, a vaccine polypeptide for novel coronavirus pneumonia is provided on the basis of analysis and study of the RBD sequence and structural information of the S protein of SARS-CoV-2. Said vaccine polypeptide comprises the following elements connected in series: a generic Th epitope sequence, a B cell epitope sequence and a T cell epitope sequence. The B cell epitope and the T cell epitope have an amino acid sequence from the RBM region of the S protein of SARS-CoV-2. Provided are a vaccine composition containing said vaccine polypeptide and use thereof. Experiments show that the vaccine polypeptide of the present invention can enable cynomolgus monkeys to initiate strong cellular and humoral immunity, and to generate neutralizing antibodies that block the binding of RBD and ACE2, and can be used for preventing and treating novel coronavirus pneumonia.