In alternative embodiments, provided are compositions, including recombinant expression systems and vectors, products of manufacture and kits, and methods, for remotely-controlled and non-invasive manipulation of intracellular nucleic acid expression, genetic processes, function and activity in live cells such as T cells in vivo, for example, activating, adding functions or changing or adding specificities for immune cells, for monitoring physiologic processes, for the correction of pathological processes and for the control of therapeutic outcomes. In alternative embodiments, provided are blue-light-mediated light-inducible nuclear translocation and dimerization (LINTAD) systems for gene regulation to control cell activation based on the integration of light-sensitive LOV2-based nuclear localization, light-induced active transportation via the biLINuS motif, and CRY2-CIB1 dimerization that feature high spatiotemporal control to control or alter cell activities in vivo, for example, to limit CAR T cell activity to the tumor site for immunotherapy applications.

Provided in the present disclosure are a bifunctional protein which can bind to PD-1 (programmed death receptor-1) and TGF-β (transforming growth factor-β), the medical use of the bifunctional protein, and a preparation method therefor.

A humanized CD 19 antibody, and a chimeric antigen receptor thereof, an immune cell thereof and the use thereof are provided. The humanized CD19 antibody is based on a FMC63 chimeric antibody, which is subjected to humanization modification. A CAR-T and a dual CAR-T cell constructed based on the humanized antibody and the related use thereof are also provided. Compared with a CAR-T cell constructed by using FMC63, the CAR-T cell constructed based on the humanized antibody has higher killing effect and tumor removal ability.

The present disclosure relates to methods for enhancing the efficiency of therapies involving immune effector cells such as T cells engineered to express antigen receptors such as T cell receptors (TCRs) or chimeric antigen receptors (CARs). It is demonstrated herein that such antigen receptor-engineered immune effector cells, even when provided to a subject in sub-therapeutic amounts, are extremely effective in the treatment of cancer diseases, even those cancer diseases that are known to be difficult to treat with antigen receptor-engineered immune effector cells, such as solid tumors or cancers, if additionally target antigen for the antigen receptor is provided to the subject. Immune effector cells may be engineered ex vivo or in vitro and subsequently the immune effector cells may be administered to a subject in need of treatment, or immune effector cells may be engineered in vivo in a subject in need of treatment.

Provided herein are compositions, systems, and methods for delivering an effector protein into a cell. The present disclosure, in some aspects, provide novel proteins delivering an effector protein into a cell. The novel proteins are supernegatively charged proteins derived from highly anionic proteins identified from the proteome (e.g., human proteome). The novel protein tags can be associated (e.g., covalently or nocovalently) with the protein to be delivered to facilitate delivery of the effector protein into a cell.

Provided herein are engineered IL2 polypeptides and fusion proteins thereof. Also provided are methods of modulating an immune response by administering an engineered IL2 polypeptide or a fusion protein thereof. The engineered IL2 polypeptides and fusion proteins thereof demonstrate increased binding to IL2Rβ, decreased binding to IL2Rα, or both.

A genetically modified phototrophic cell for in-vivo production of hydrogen. The phototrophic cell has been genetically modified to the effect that a) at least one of the native photosystem I components has been deleted, b) the native hydrogenase has been deleted, and c) at least one fusion protein is expressed, comprising i. a hydrogenase or hydrogenase component and ii. at least one PSI component, with the proviso that the PSI is complemented by expression of the at least one fusion protein, and the hydrogenase component itself, or together with at least one further hydrogenase component expressibly introduced into the cell, has hydrogenase activity.

The present disclosure provides in vitro modified cytotoxic T cells (CTLs) that comprise: a) a T-cell receptor (TCR) specific for a preselected antigen in a human; and b) a nucleic acid(s) encoding a chimeric antigen receptor (CAR) specific for a cancer-associated antigen. The present disclosure provides methods of producing the modified CTLs. The present disclosure provides of treating cancer, comprising administering the modified CTLs to an individual in need thereof.

The present invention provides a system for providing a T cell product, including a T cell master cell bank and/or a T cell working cell bank.

An object of the present invention is to provide an evaluation system capable of detecting an extracellular purinergic receptor ligand minimally invasively, chronologically and systemically, and the present invention provides a genetically modified non-human animal expressing a first fusion protein and a second fusion protein for detecting an extracellular purinergic receptor ligand, in which the first fusion protein comprises a membrane protein that binds to a purinergic receptor ligand, and a first reporter protein, and the second fusion protein comprises a protein that binds to the membrane protein bound to the ligand, and a second reporter protein; and a cell thereof.