This invention provides the field of therapeutics. Most specifically present invention provides methods of generating in vitro engineered dendritic cells conditionally expressing interleukin-12 (IL-12) under the control of a gene expression modulation system in the presence of activating ligand and uses for therapeutic purposes in animals including human.

This invention provides the field of therapeutics. Most specifically present invention provides methods of generating in vitro engineered dendritic cells conditionally expressing interleukin-12 (IL-12) under the control of a gene expression modulation system in the presence of activating ligand and uses for therapeutic purposes in animals including human.

Provided are antibodies, fragments thereof, chimeric antigen receptors (CARs) and T cell receptors (TCRs) comprising one or more of the anti-PMCA antigen binding domains disclosed herein. SynNotch receptors that comprise an anti-PSCA binding domain Provided are polynucleotides encoding antibodies, fragments thereof, CARs, T cell receptors (TCR) and SynNotch receptors. Provided are compositions, cells and cell therapies comprising the same. Further provided are methods of treatment.

The technology described herein is directed to regulated synthetic gene expression systems. In one aspect described herein are synthetic transcription factors (synTFs) comprising a DNA binding domain, a transcriptional activator domain, a transcriptional effector domain (TED), and optionally a regulator protein. In other aspects described herein are gene expression systems comprising said synTFs and methods of treating diseases and disorders using said synTFs.

Provided herein is a molecular switch and a variety of feedback and feed-forward circuits that employ a split protein (e.g., a split transcription factor) and monomers from designed heterodimers In some embodiments, the cell may contain a first polypeptide comprising a first part of a split protein and a monomer of a designed heterodimer; (b) a second polypeptide comprising a second part of a split protein and a monomer of a designed heterodimer; and (c) a third polypeptide comprising a monomer of a designed heterodimer, not containing the first or second parts of the split protein. In these embodiments, (a) and (b) bind to each other, and (c) binds to (a) or (b), thereby inactivating the reconstituted split protein. Expression of (c) is regulated by the activity of the reconstituted split protein. Various circuits are also provided.

The present disclosure is broadly concerned with the field of cancer immunotherapy. For example, the present invention generally relates to an immune cell comprising a genetically engineered antigen receptor that specifically binds to a target antigen and a genetic disruption agent that reduces or is capable of reducing the expression in the immune cell of a gene that weakens the function of the immune cell.

The present invention relates to gene therapy systems designed for the delivery of a therapeutic product to a subject using replication-defective virus composition(s) engineered with a built-in safety mechanism for ablating the therapeutic gene product, either permanently or temporarily, in response to a pharmacological agentpreferably an oral formulation, e.g., a pill. The invention is based, in part, on the applicants' development of an integrated approach, referred to herein as PITA (Pharmacologically Induced Transgene Ablation), for ablating a transgene or negatively regulating transgene expression. In this approach, replication-deficient viruses are used to deliver a transgene encoding a therapeutic product (an RNA or a protein) so that it is expressed in the subject, but can be reversibly or irreversibly turned off by administering the pharmacological agent; e.g., by administration of a small molecule that induces expression of an ablator specific for the transgene or its RNA transcript.

The present disclosure provides engineered immune cells and methods for their creation and use. The immune cells comprise activating and blocking receptors, in which the blocking receptor provides a signal that dominates a signal from the activating receptor.

The instant disclosure provides chimeric polypeptides which modulate various cellular processes following a cleavage event induced upon binding of a specific binding member of the polypeptide with its binding partner. Methods of using chimeric polypeptides to modulate cellular functions, including e.g., induction of gene expression, are also provided. Nucleic acids encoding the subject chimeric polypeptides and associated expression cassettes and vectors as well as cells that contain such nucleic acids and/or expression cassettes and vectors are provided. Also provided, are methods of treating a subject using the described components and methods as well as kits for practicing the subject methods.

The instant disclosure provides chimeric polypeptides which modulate various cellular processes following a cleavage event induced upon binding of a specific binding member of the polypeptide with its binding partner. Methods of using chimeric polypeptides to modulate cellular functions, including e.g., induction of gene expression, are also provided. Nucleic acids encoding the subject chimeric polypeptides and associated expression cassettes and vectors as well as cells that contain such nucleic acids and/or expression cassettes and vectors are provided. Also provided, are methods of treating a subject using the described components and methods as well as kits for practicing the subject methods.