The present invention relates to novel regulatory T cell proteins. One protein, designated PD-L3, resembles members of the PD-L1 family, and co-stimulates αCD3 proliferation of T cells in vitro. A second, TNF-like, protein has also been identified as being upregulated upon αCD3/αGITR stimulation. This protein has been designated T.sup.reg-sTNF. Proteins, antibodies, activated T cells and methods for using the same are disclosed.

In particular methods of using these proteins and compounds, preferably antibodies, which bind or modulate (agonize or antagonize) the activity of these proteins, as immune modulators and for the treatment of cancer, autoimmune disease, allergy, infection and inflammatory conditions, e.g. multiple sclerosis is disclosed

The invention is directed to a Conjugate for labelling a target moiety on a cell, characterized by general formula (II): X.sub.o-P-Y.sub.m, with Y: MHC-complex targeting TCR molecules, P: enzymatically degradable spacer, X: detection moiety, o: integer between 5 and 25, m: integer between 2 and 1000, wherein X and P; P and Y are covalently bound to each other and Y is bound to P via the C-terminus.

Disclosed are methods of identifying a secretome from a subject cell within a heterogeneous cell population when the subject cell contacts a target cell (e.g. a subject immune cell contacts a target cancer cell) or a stimulatory agent and methods of using the identified secretome to identify cells that are safe and efficacious for cellular therapies, including adoptive CAR T-cell therapies.

An antibody having a higher function targeting a CD73 antigen, and more specifically, an antibody for cancer treatment having a higher activity. The antibody or a human-type antibody derivative that has a binding activity to a CD73 antigen and activates T cells having a toxic activity to cancer cells, and includes complementarity determining regions of any combination of heavy and light chains each having a specific amino acid sequence.

Methods for identifying cancer patients amenable to anti-cancer immunotherapy are provided along with methods of monitoring cancer therapy. Also provided are methods of treating cancer patients amenable to anti-cancer immunotherapy. The methods involve determining the level of CD127 <low> PD-1 <low> T cells. The patients are treated with an immune checkpoint inhibitor, such as an anti-CTLA-4 antibody, e.g. ipilimumab.

Present invention is related to a tumor microenvironment on chip or a biochip for cell therapy having a carrier, a first cell or tissue culture area and a second cell or tissue area imbedded within the carrier. The present invention provides a biochip successfully cooperating micro fluidic technology and cell culture achieving the goal for detecting or testing the function of cell therapy for cancer or tumor.

An object is to elucidate the immune response mechanism of IL-17-producing cells which causes a pathological condition such as psoriasis, and to provide an immune response suppressant for suppressing the immune response of IL-17-producing cells, a medicament for treating or preventing a disease or a pathological condition involving the immune response of an IL-17-producing cell, a method for inducing immune response in γδT cells, and a method for evaluating a medicament (candidate substance) and a method for producing IL-17 by use of the method. The present invention provides an immune response suppressant for an IL-17-producing cell, including a substance that inhibits the binding of CD96 to at least one protein selected from CD155 and CD111, a medicament including the immune response suppressant for an IL-17-producing cell, a method having a step (A) of culturing at least one of a γδT cell and a CD4-positive T cell together with IL-23, an anti-CD3 antibody capable of stimulating a TCR/CD3 complex and an anti-CD96 antibody capable of stimulating CD96, and a method for evaluating a medicament (candidate substance) and a method for producing IL-17, including a method having the step (A).

Provided are methods for determining or predicting attributes of therapeutic cell compositions in connection with cell therapy. The cells of the therapeutic cell composition express recombinant receptors such as chimeric receptors, e.g. chimeric antigen receptors (CARs) or other transgenic receptors such as T cell receptors (TCRs). The methods provide for the identification of correlations between input composition (e.g., starting material derived from subjects for producing a cell therapy) attributes and therapeutic cell composition attributes.

This invention provides for a fusion protein between an IL2αβγ Selective Agonist protein (IL2 Selective Agonist) and a IgG Fc protein using a linker. The IL2 Selective Agonist moiety provides a therapeutic activity by selectively activating the IL2αβγ form of the receptor, thus selectively stimulating Tregs. The Fc moiety provides a prolonged circulating half-life compared to the circulating half-life of IL-2 or an IL2SA protein.

The present disclosure provides T-cell modulatory multimeric polypeptides that comprise an immunomodulatory polypeptide, an epitope-presenting peptide, and class I MHC polypeptides. A T-cell modulatory multimeric polypeptide is useful for modulating the activity of a T cell, and for modulating an immune response in an individual.