The present invention relates to nanoparticles complexed with biomacromolecule agents configured for treating, preventing or ameliorating various types of disorders, and methods of synthesizing the same. In particular, the present invention is directed to compositions comprising nanoparticles (e.g., synthetic high density lipoprotein (sHDL)) carrying biomacromolecule agents (e.g., nucleic acid, peptides, glycolipids, etc.), methods for synthesizing such nanoparticles, as well as systems and methods utilizing such nanoparticles (e.g., in diagnostic and/or therapeutic settings).

Provided herein are methods, compositions and uses involving immunotherapies, such as adoptive cell therapy, e.g., T cell therapy, and inhibitors of a TEK family kinase, such as BTK or ITK. The provided methods, compositions and uses include those for combination therapies involving the administration or use of one or more such inhibitor in conjunction with another agent, such as an immunotherapeutic agent targeting T cells, such as a therapeutic antibody, e.g., a multispecific (e.g., T cell engaging) antibody, and/or genetically engineered T cells, such as chimeric antigen receptor (CAR)-expressing T cells. Also provided are methods of manufacturing engineered T cells, compositions, methods of administration to subjects, nucleic acids, articles of manufacture and kits for use in the methods. In some aspects, features of the methods and cells provide for increased or improved activity, efficacy, persistence, expansion and/or proliferation of T cells for adoptive cell therapy or endogenous T cells recruited by immunotherapeutic agents.

Materials and methods useful for generating highly mannosylated pseudotyped lentiviral vector particles comprising a Vpx protein are provided.

Disclosed are immunotherapeutic compositions and the concurrent use of combinations of such compositions for the improved induction of therapeutic immune responses and/or for the prevention, amelioration and/or treatment of disease, including, but not limited to, cancer and infectious disease.

Provided are isolated TCRs, TCR-like molecules, and portions thereof that bind to phosphopeptide-HLA-A2 complexes. The isolated TCRs, TCR-like molecules, or portions are optionally soluble TCRs, TCR-like molecules, or portions. Also provided are isolated nucleic acids encoding the disclosed TCRs, TCR-like molecules, or portions; host cells that contain the disclosed TCRs, TCR-like molecules, or portions; pharmaceutical compositions that include the disclosed TCRs, TCR-like molecules, portions, nucleic acids, and/or T cells; kits; and methods of using the same.

Compositions, e.g., therapeutic agents, and methods are provided for modulating gene and protein expression of Forkhead Box protein 1 (Foxp1). The therapeutic agents include short nucleic acid molecules that modulate gene and protein expression of Forkhead Box protein 1 (Foxp1) expression, viral vectors containing such molecules, T cells transduced with these viruses for adoptive therapies, and any small molecules that bind to and inactivate Foxp1. These compounds and methods have applications in cancer therapy either alone or in combination with other therapies that stimulate the endogenous immune system in the environment of the cancer, e.g., tumor.

What is described is a novel genetic screen, involving recombinant technology and class I antigen cross-presentation, to search for supraoptimal superagonists of the 27L MART-1 mutant selecting for single amino acid substitution mutants of 27L that activate human antigen-specific CTL clones recognizing the wild-type MART-1.sub.26-35 epitope. Three novel mutant epitopes are identified with superagonist properties that are functionally superior to 27L. The ability of a given analog to act as superagonist varies among patients. Also described is the use of methods to establish panels of potential superagonist APLs to individualize tumor peptide vaccines among patients. The methodology is replicated to identify APL to NYESO-1.sub.157-165 and NYESO-1.sub.157-170 tumor epitopes. A general method is described that is useful to produce a tumor vaccine to any tumor epitope.

In some embodiments, described herein is a method of tumor treatment or tumor vaccination. The method generally comprises applying to a human being in need thereof a tumor therapeutic composition or tumor vaccine defined herein. The tumor therapeutic composition or tumor vaccine can be produced by protein transfer of glycosyl-phosphatidylinositol (GPI)-anchored immunostimulatory or costimulatory molecules.

The present invention comprises compositions, methods, and devices for enhancing an endogenous immune response against a cancer. Devices and methods provide therapeutic immunity to subjects against cancer.

This document relates to methods and materials involved in treating cancer (e.g., melanoma). For example, methods and materials involved in using an anti-chronic inflammation treatment (e.g., chemotherapy) in combination with a cancer treatment agent (e.g., a cancer vaccine) to treat cancer are provided.