Some embodiments of the systems, methods and compositions provided herein relate to a compound protease. In some embodiments, the compound protease includes a protease domain and a cut site for another enzyme. In some embodiments, the compound protease includes an association domain. In some embodiments, the compound protease is part of a protein circuit.

Provided herein are cells, e.g., T cells expressing artificial cell death polypeptides that cause death of a cell, e.g., cells (e.g., T lymphocytes) expressing the cell death polypeptide, when the cell death polypeptide is multimerized or dimerized. Also provided herein is use of such cells, e.g., T lymphocytes, to treat diseases such as cancer.

The disclosure provides compositions and methods for inducing programmed cell death, such as necroptosis. Compositions may comprise fusion proteins comprising a death inducing domain and a multimerization domain; nucleic acids encoding fusion proteins; and cells comprising fusion proteins. The compositions may be used in methods such as cancer therapy, including in combination with additional immunotherapeutics.

The present invention relates to a novel polypeptide which displays IgG cysteine protease activity, and in vivo and ex vivo uses thereof. Uses of the polypeptide include methods for the prevention or treatment of diseases and conditions mediated by IgG, and methods for the analysis of IgG.

The present disclosure relates to systems, methods and compositions provided herein that include a compound protease. The compound protease can contain a protease domain, a cut site for another enzyme and an association domain. In some embodiments, the compound protease is part of a protein circuit.

Some embodiments of the systems, methods and compositions provided herein relate to a compound protease. In some embodiments, the compound protease includes a protease domain and a cut site for another enzyme. In some embodiments, the compound protease includes an association domain. In some embodiments, the compound protease is part of a protein circuit.

Provided herein are cells, e.g., T cells expressing artificial cell death polypeptides that cause death of a cell, e.g., cells (e.g., T lymphocytes) expressing the cell death polypeptide, when the cell death polypeptide is multimerized or dimerized. Also provided herein is use of such cells, e.g., T lymphocytes, to treat diseases such as cancer.

The present invention provides compositions and methods for targeting an extracellular matrix derived (EMD) peptide predominantly to an injured tissue, as opposed to an uninjured tissue in vivo. The targeted EMD peptide facilitates the repair and/or regeneration of the injured tissue by providing a surface for cells to attach and grow, thereby facilitating the repair and/or regeneration of the injured tissue.

Provided herein are cells, e.g., T cells expressing artificial cell death polypeptides that cause death of a cell, e.g., cells (e.g., T lymphocytes) expressing the cell death polypeptide, when the cell death polypeptide is multimerized or dimerized. Also provided herein is use of such cells, e.g., T lymphocytes, to treat diseases such as cancer.

Methods and constructs are provided for controlling processes in live animals, plants or microbes via genetically engineered near-infrared light-activated or light-inactivated proteins including chimeras including the photosensory modules of bacteriohytochromes and output modules that possess enzymatic activity and/or ability to bind to DNA, RNA, protein, or small molecules. DNA encoding these proteins are introduced as genes into live animals, plants or microbes, where their activities can be turned on by near-infrared light, controlled by the intensity of light, and turned off by near-infrared light of a different wavelength than the activating light. These proteins can regulate diverse cellular processes with high spatial and temporal precision, in a nontoxic manner, often using external light sources. For example, near-infrared light-activated proteins possessing nucleotidyl cyclase, protein kinase, protease, DNA-binding and RNA-binding activities are useful to control signal transduction, cell apoptosis, proliferation, adhesion, differentiation and other cell processes.