Some embodiments of the present disclosure are directed to methods that include delivering to a subject a nucleic acid encoding an antigen, wherein the nucleic acid is delivered via a tumor-selective vehicle or via intratumoral injection, and delivering to the subject an immune cell expressing a receptor that binds to the antigen.

Provided herein is a method of producing a protein comprising a target-specific extravesicular domain (TED) of an extracellular vesicle (EV) surface protein comprising modifying a polynucleotide comprising a nucleotide sequence encoding the extravesicular domain (ED) of an EV surface protein by a mutagenesis method within at least one modified region within the ED amino acid sequence with a length of 3-20 contiguous amino acids flanked by regions of the wild-type ED sequence at its N-terminus and C-terminus, to incorporate a target binding site within the ED, thereby producing a repertoire of polynucleotides encoding a variety of TEDs, each comprising a different target binding site, and selecting a TED specifically recognizing a predetermined target, and producing the protein comprising the selected TED.

A therapeutic agent comprising a nucleic acid and a TCR modified immune cell and use thereof. The therapeutic agent comprises a first composition comprising a first active ingredient and a second composition comprising a second active ingredient. The first active ingredient includes or contains a nucleic acid having a labeling polypeptide coding sequence for being introduced into a tumor cell and/or a cancer cell. The labeling polypeptide has one or more epitope polypeptides which can be presented on a surface of the tumor cell and/or cancer cell by MHC class I molecules. The second composition comprises a second active ingredient in a second pharmaceutically acceptable carrier and the second active ingredient comprises a T cell receptor modified immune cell which can specifically recognize and bind to the epitope polypeptide presented by MHC class I molecules. The therapeutic agent achieves synergistic treatment effect and provides a new route for tumor treatment.

The present disclosure relates to methods for profiling subject specific and personalized T cell receptor (TCR) repertoires using a single-cell sequencing method. More particularly, disclosed are methods for determining binding of T cell receptors to subject specific neoantigens. In addition, the techniques herein may identify the antigenic targets of T cell receptors in the context of tumor neoantigens. Moreover, the present disclosure enables the discovery of T cell targets in numerous diseases, with implications for understanding the basic mechanisms of the mammalian immune response and for developing antigen-specific diagnostic markers and therapies. Finally, cloned TCRs can be used to formulate personalized immunotherapies for those inflicted with a disease, such as cancer.

In some aspects, the present disclosure provides compositions comprising an N4-based MMC ligand, a cell targeting group, and a fluorophore or a therapeutic compound comprising a formula: ##STR00001##
wherein the variables are as defined herein. In some embodiments, these compositions may be used in the imaging techniques or in the treatment of a disease or disorder such as cancer.

The present disclosure provides an allogeneic whole cell cancer vaccine platform that includes compositions and methods for treating and preventing cancer. Provided herein are compositions containing a therapeutically effective amount of cells from one or more cancer cell lines, some or all of which are modified to (i) inhibit or reduce expression of one or more immunosuppressive factors by the cells, and/or (ii) express or increase expression of one or more immunostimulatory factors by the cells, and/or (iii) express or increase expression of one or more tumor-associated antigens (TAAs), including TAAs that have been mutated, and which comprise cancer cell lines that natively express a heterogeneity of tumor associated antigens and/or neoantigens. Also provided herein are methods of making the vaccine compositions, methods of preparing, and methods of use thereof.

The present invention relates to specific binding members which bind to lymphocyte-activation gene 3 (LAG-3). The specific binding members preferably comprise a LAG-3 antigen-binding site which may be located in two or more structural loops of a CH3 domain of the specific binding member. The specific binding members of the invention find application, for example, in cancer therapy.

The invention relates generally to a composition for rapid and sustained delivery of one or more biologically active agents, and uses thereof, wherein the composition comprises short biocompatible polymer fibres (SPF) having an average length in the range of from about 1 pm to about 3 mm, and an average diameter in the range of from about 15 nm to about 5 μm, wherein the SPF are loaded with one or more biologically active agents, and wherein, when administered, the composition provides rapid and sustained release of the one or more biologically active agents from the SPF.

Disclosed are a bacteriologically-modified whole-cell tumor vaccine and a method of making the same. The method includes: lysing bacteria at logarithmic growth phase to obtain a bacterial lysate; mixing the bacterial lysate with an excessive amino compound solution to aminate the bacterial lysate in the presence of EDC; mixing the aminated bacterial lysate with the tumor cells for a certain period of time to produce bacteriologically-modified tumor cells; and inactivating the bacteriologically-modified tumor cells to produce the bacteriologically-modified whole-cell tumor vaccine. The bacteriologically-modified whole-cell tumor vaccine has been demonstrated to have desirable therapeutic effect in tumor model mice.

Autologous anti-cancer vaccines and methods of manufacture and treatment are provided, including expansion of individual patient-derived tumor cells in an immune-compromised animal(s) to attain, quantitatively and qualitatively, sufficient material for efficacious vaccine production and utilization, to elicit an immune response against micrometastases and/or recurrence in the individual patient following tumor excision.