Combination therapies that include (i) an immune cell that expresses a chimeric antigen receptor (CAR) or similar molecule and (ii) a compound that preserves or potentiates the in vivo actions of tumor necrosis factor alpha (TNFα) against cancer cells are described. The combination therapies result in the killing of antigen-negative cells in the vicinity of immunotherapy targeted-antigen-positive cells reducing the survivability of escape variants and providing other benefits.

Combination therapies that include (i) an immune cell that expresses a chimeric antigen receptor (CAR) or similar molecule and (ii) a compound that preserves or potentiates the in vivo actions of tumor necrosis factor alpha (TNFα) against cancer cells are described. The combination therapies result in the killing of antigen-negative cells in the vicinity of immunotherapy targeted-antigen-positive cells reducing the survivability of escape variants and providing other benefits.

Described herein are methods for treating rheumatoid arthritis by determining whether a subject having rheumatoid arthritis will respond to an anti-TNF-alpha therapy based on the number of innate and adaptive immune cells in a sample from the subject prior to treatment.

There is described herein, a method for inducing Tc22 lineage T cells from a population of CD8+ T cells, the method comprising: a) providing a population of CD8+ T cells; b) activating the population; and c) culturing or contacting the population of CD8+ T cells with Coenzyme A.

A column is disclosed for removal of sTNF-R2 from a body fluid. The column has a compartment, an inlet coupled to the compartment and configured to receive the body fluid, and a substrate disposed within the compartment. A capture ligand is coupled to the substrate and has a modified sequence with an amino acid substitution in a reference sequence that includes a portion of a natural TNF sequence. The modified sequence has an affinity for the sTNF-R2 that is greater than an affinity of the reference sequence for the sTNF-R2.

This invention provides for a fusion protein between a single chain TNFR2 Selective Agonist protein (scTNFR2 Selective Agonist) and a dimerization domain, such as an IgGFc protein. The single chain TNFR2 Selective Agonist moiety provides a therapeutic activity by selectively activating the TNFR2 form of the TNF-α receptor, thus selectively stimulating Tregs and/or increasing myelin deposition.

This invention provides for a fusion protein between a single chain TNFR2 Selective Agonist protein (scTNFR2 Selective Agonist) and a dimerization domain, such as an IgGFc protein. The single chain TNFR2 Selective Agonist moiety provides a therapeutic activity by selectively activating the TNFR2 form of the TNF-α receptor, thus selectively stimulating Tregs and/or increasing myelin deposition.

Provided in the present invention are a specific antibody of BCMA and a BCMA-targeting immune effector cell, and also provided are a chimeric antigen receptor-modified T cell prepared using the antibody and the use thereof.

Provided in the present invention are a specific antibody of BCMA and a BCMA-targeting immune effector cell, and also provided are a chimeric antigen receptor-modified T cell prepared using the antibody and the use thereof.

The present invention relates to tumour necrosis factor (TNF) muteins with improved properties, and in particular to TNF muteins which are agonists of, and bind selectively to, tumour necrosis factor receptor 1 (TNFR1). Compositions comprising said TNF muteins, which may additionally comprise appropriate anticancer agents or imaging agents are provided. The use of the muteins of the invention in methods of treating or detecting a tumour are also provided. The invention also provides nucleic acids (e.g. vectors) encoding the TNF muteins and host cells comprising said nucleic acids.