The present disclosure provides methods for genetically modifying lymphocytes and methods for performing adoptive cellular therapy that include transducing T cells and/or NK cells. The methods can include inhibitory RNA molecule(s) and/or engineered signaling polypeptides that can include a lymphoproliferative element, and/or a chimeric antigen receptor (CAR), for example a microenvironment restricted biologic CAR (MRB-CAR). Additional elements of such engineered signaling polypeptides are provided herein, such as those that drive proliferation and regulatory elements therefor, as well as replication incompetent recombinant retroviral particles and packaging cell lines and methods of making the same. Numerous elements and methods for regulating transduced and/or genetically modified T cells and/or NK cells are provided, such as, for example, those including riboswitches, MRB-CARs, recognition domains, and/or pH-modulating agents.

The present invention relates to a vaccine composition comprising an effective amount of a replication-competent controlled herpesvirus expressing an antigen of a pathogen other than a herpesvirus. Encompassed are uses in immunization and methods of immunization employing the vaccine compositions, wherein transient activation of the replication of the herpesvirus at the site of vaccine administration to a subject enhances systemic immune responses to the antigen.

The present disclosure relates to a DNA construct, and a strain into which a recombinant vector comprising the DNA construct has been introduced. The DNA construct according to the present disclosure allows the expression levels of genes, operably linked downstream of first and second promoters, in a host strain or cell, to be balanced, so that cancer diagnosis and treatment may be performed simultaneously. In addition, the DNA construct of the present disclosure completely does not allow the anticancer protein and the reporter protein to be expressed at all in the absence of doxycycline, and thus it allows the anticancer protein to be expressed at an appropriate dose for cancer treatment by controlling whether or not treatment with doxycycline is performed, and at the same time, enables the size of the cancer to be monitored in real time depending on the expression level of the reporter protein.

The presently disclosed subject matter relates to targeted integration (TI) host cells suitable for the expression of recombinant proteins wherein those TI host cells have been subjected to supertransfection resulting in the random integration (RI) of exogenous nucleic acids encodes into their genome, as well as methods of producing and using said supertransfected TI host cells.

Control Devices are disclosed including RNA destabilizing elements (RDE), and RNA control devices, combined with transgenes, including Chimeric Antigen Receptors (CARs) in eukaryotic cells. RDEs can be combined with RNA control devices to make RDEs that include ligand mediated control. These smart RDEs and other RDEs can be used to optimize expression of transgenes, e.g., CARs, in the eukaryotic cells so that, for example, effector function is optimized. CARs and transgene payloads can also be engineered into eukaryotic cells so that the transgene payload is expressed and delivered at desired times from the eukaryotic cell.

Disclosed herein are improved methods for treatment of brain cancer (such as glioma/glioblastoma) via ligand-inducible gene-switch controlled in vivo expression of an immunomodulator (i.e., IL-12) in combination with one or more other immunomodulators (i.e., an immune cell check point inhibitor; e.g., such as a PD-1 inhibitor or a PD-1 binder.

A method and vectors for controlling blood glucose levels in a mammal are disclosed. In one embodiment, the method comprises the steps of: treating the hepatocyte cells of a patient with a first, second or third vector, wherein the first vector comprises a promoter enhancer, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase and an albumin 3′UTR and lacks an HGH intron, wherein the second vector comprises an HGH intron, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase site and an albumin 3′UTR and lacks a promoter enhancer, wherein the third vector comprises an HGH intron, glucose inducible regulatory elements, a liver-specific promoter, a gene encoding human insulin with modified peptidase site, an albumin 3′UTR and a promoter enhancer and observing the patient's insulin levels, wherein the patient's insulin levels are controlled.

Disclosed herein are contiguous DNA sequences encoding highly compact multi-input genetic logic gates for precise in vivo cell targeting, and methods of treating disease using a combination of in vivo delivery and such contiguous DNA sequences.

The present invention provides expression vectors for use in an inducible coexpression system, capable of controlled induction of expression of each gene product.

The present invention relates to regulatable adeno-associated virus (AAV) vectors as well as to their use in gene therapy. It further relates to corresponding nucleic acid molecules, host cells, non-human transgenic animals, pharmaceutical compositions and kits.