A Fc-CD80 fusion protein has a CD80 extracellular domain (ECD) linked to a C-terminal of an immunoglobulin Fc domain. The Fc-CD80 fusion protein can be used for the preparation of a conjugate, the conjugate including the Fc-CD80 fusion protein as a first component, and a second component containing a second effector molecule, the second component being located at an N-terminal of the first component. In addition, a conjugate including the Fc-CD80 fusion protein, a pharmaceutical composition including the Fc-CD80 fusion protein and/or the conjugate are effective for the treatment or prevention of cancerous diseases in individuals.

The present invention relates to a method of isolating exosomes. Specifically, the invention relates to a method comprising the steps of providing a sample including exosomes; identifying a cell-surface polypeptide on the exosomes; and isolating the exosomes using the cell-surface polypeptide on the exosomes. The exosomes isolated from by the methods of the invention can be studied for the purposes of biomarker identification, for the understanding of biological function and disease, and to find ways to target them with therapeutics.

A pharmaceutical composition for enhancing radiation therapy, containing a fusion protein dimer is disclosed. The fusion protein dimer includes an IL-2 protein and a CD80 protein. A method of radiation therapy for cancer, using the composition is also disclosed. The composition for enhancing radiation therapy may increase the effect of radiation therapy in cancer treatment.

Disclosed herein are ACE2-Fc fusion polypeptides that contain at least one binding site for a spike protein of a coronavirus and methods of using such for therapeutic and/or diagnostic purposes. Also provided herein are methods for producing such fusion polypeptides.

Disclosed herein are ACE2-Fc fusion polypeptides that contain at least one binding site for a spike protein of a coronavirus and methods of using such for therapeutic and/or diagnostic purposes. Also provided herein are methods for producing such fusion polypeptides.

Disclosed is a dTAG system comprising small molecule degraders of mutant BET family protein-tagged proteins via recruitment of an E3 ubiquitin ligase and uses thereof.

Provided herein are immunoresponsive cells having IL-1 superfamily activities with spatiotemporal restriction. The immunoresponsive cells can further express a protease for regulating the IL-1 superfamily activities, and a chimeric antigen receptor (CAR) or a parallel CAR. Also provided herein are methods of preparing the immunoresponsive cells and methods of directing T cell mediated immune response using the immunoresponsive cells.

The present disclosure provides compositions and methods for cell transplantation therapy based on forced expression of an exogenous HLA-F protein in donor cells to be transplanted into a subject. In some embodiments, the donor cells express an exogenous chimeric HLA-F protein comprising an extracellular region comprising an HLA-F alpha 1 domain, an HLA alpha 2 domain, an HLA-F alpha 3 domain, a linker and a β2m protein.

Nucleic acid constructs and compositions that allow insertion and/or expression of a retinoschisin coding sequence are provided. Nuclease agents targeting RS1 loci are provided. Compositions and methods of using such constructs for integration into a target genomic locus and/or expression in a cell are also provided. Methods of treating X-linked juvenile retinoschisis using the nucleic acid constructs and compositions are also provided.

Use of 2-pentanone and specific receptor thereof in a manufacture of a product regulating a cell function, a regulation of cell function, a manufacture of a product promoting an increase in an intracellular calcium ion concentration, or a manufacture of a product promoting an increase in a neuronal firing rate is provided. In the present disclosure, the specific receptor of 2-pentanone is expressed in cultured cells or animals, and its specific binding to 2-pentanone opens ligand-gated cation channels, resulting in an increase of intracellular calcium ion concentration, depolarization of cell membranes, and generation of electrical activity or endocrine activity, thereby finally achieving precise regulation of tissue cells and organ functions. After being treated, cells can be activated rapidly, producing effects with a rapid onset; once the treatment is stopped, the experimental effect can be quickly terminated to allow the cells to return to their original state quickly.