[Problem] Provided are a production method for a multi-input/multi-output-type genetic switch or a transcription factor, and a multi-input/multi-output-type genetic switch or a transcription factor. [Solving Means] The inventors of the present invention have completed a production method for a multi-input/multi-output-type genetic switch or a transcription factor, essentially including the steps of “fusing two or more transcription factor genes to each other” and “introducing mutations into the fusion-type transcription factor gene,” and have further succeeded in obtaining a multi-input/multi-output-type genetic switch or a transcription factor by the method.

Provided is an rtTA and single chain rtTA variants and uses thereof for inducible expression of a nucleic acid of interest. Nucleic acid molecules comprising an improved rtTA and/or sc rtTA sequence according to the invention are also provided, as well as vectors, replicons and cells comprising such nucleic acid molecules.

A living engineered glue system for performing autonomous mechanical repairs comprises a biofilm of microbial cells embedded in an extracellular matrix and operably linked in an environmentally-inducible, cell-cell communication genetic circuit to control gene expression.

Provided is a bacteria for targeting tumors and treating cancer, a drug delivery composition, and methods of using same for treating cancer.

The present disclosure provides expression constructs designed to provide for expression of therapeutic proteins from engineered cells. The engineered cells may be encapsulated into implantable elements that allow for the therapeutic protein to be released into from the capsule while protecting the cell from the immune system of a patient into which the capsule is implanted.

The present invention provides compositions and methods for regulated gene expression. In certain aspects, the invention relates to an inducible synthetic promoter that can be used for regulated gene expression or to generate mutations in one or more bacterial cells of the gut microbiota.

The present invention relates to the preparation of mesenchymal stem cells, which are for the proliferation of viral vectors and viruses, and enable virus production and release timing control such that tumor targeting can be improved and viruses can be mass-produced. In addition, the tumorigenesis of mesenchymal stem cells of the present invention can be fundamentally blocked, safety is secured by enabling virus production and release to be controlled at desired time points, and antitumor effects can be maximized.

Disclosed is a technique for constructing optogenetic amplifier and inverter circuits utilizing transcriptional activator/repressor pairs, in which expression of the transcriptional activator or repressor, respectively, is controlled by light-controlled transcription factors. This system is demonstrated utilizing the quinic acid regulon system from Neurospora crassa, or Q System, a transcriptional activator/repressor system. This is also demonstrated utilizing the galactose regulon from Saccharomyces cerevisiae, or GAL System. Such optogenetic amplifier circuits enable multi-phase microbial fermentations, in which different light schedules are applied in each phase to dynamically control different metabolic pathways for the production of proteins, fuels or chemicals. The orthogonal nature of the Q and GAL systems enable the co-expression of amplifier and inverter circuits to simultaneously amplify and invert the response of light-controlled transcriptional controls over different sets of genes in the same cell.

Disclosed herein are polynucleotides encoding ligand-inducible gene switch polypeptides, and systems comprising gene switch polypeptides for modulating the expression of a heterologous gene and an interleukin in a host cell. The compositions, methods and systems described herein facilitate ligand dependent expression of polypeptides including but not limited to cytokines and antigen binding polypeptides.

Methods of expressing an expression product of interest are provided. Accordingly there is provided a method comprising introducing into a cell a polynucleotide comprising an AimR responsive element operatively linked to a nucleic acid sequence encoding the expression product of interest, and contacting said cell with an AimP peptide comprising an amino acid sequence of XXXXGG/A, wherein said AimP peptide is capable of binding said AimR polypeptide and dissociating said AimR polypeptide from said AimR responsive element. Also provided are articles of manufacture, isolated peptides, polynucleotides and nucleic acid constructs.