Provided herein is a reporter system for identifying a cytokine receptor modulator and uses thereof.

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.

[Problem to be Solved] It is intended to provide a fusion polypeptide that regulates the transcription of a target gene.

[Solution] The present inventors have provided a fusion polypeptide comprising: a cell-penetrating peptide; a DNA-binding polypeptide; and a transcriptional regulator.

Disclosed herein include methods, compositions, and kits suitable for robust and tunable control of payload gene expression. Some embodiments provide rationally designed circuits, including miRNA-level and/or protein-level incoherent feed-forward loop circuits, that maintain the expression of a payload at an efficacious level. The circuit can comprise a promoter operably linked to a polynucleotide encoding a fusion protein comprising a payload protein, a protease, and one or more self-cleaving peptide sequences. The payload protein can comprise a degron and a cut site the protease is capable of cutting to expose the degron. The circuit can comprise a promoter operably linked to a polynucleotide comprising a payload gene, a silencer effector cassette, and one or more silencer effector binding sequences.

Polynucleotide constructs that express an engineered foot-and-mouth disease (FMDV) P1 precursor protein and a non-FMDV TEV protease and methods for safe and efficient recombinant production of FMDV antigens and immunogens. Recombinant production of FMDV antigens avoids the need to culture highly-infectious FMDV, while conventional culture methods for producing FMDV antigens rely on the native FMDV 3C protease which exerts toxic effects on host cells. The inventors have developed a new system that efficiently and safely processes FMDV P1 precursor without the FMDV 3C protease, thus avoiding the toxic effects associated with use of the 3C protease. The invention is also directed to the FMDV antigens and virus-like particles produced by this system as well as to FMDV vaccines, diagnostics and other biologics.

Polynucleotide constructs that express an engineered foot-and-mouth disease (FMDV) P1 precursor protein and a non-FMDV TEV protease and methods for safe and efficient recombinant production of FMDV antigens and immunogens. Recombinant production of FMDV antigens avoids the need to culture highly-infectious FMDV, while conventional culture methods for producing FMDV antigens rely on the native FMDV 3C protease which exerts toxic effects on host cells. The inventors have developed a new system that efficiently and safely processes FMDV P1 precursor without the FMDV 3C protease, thus avoiding the toxic effects associated with use of the 3C protease. The invention is also directed to the FMDV antigens and virus-like particles produced by this system as well as to FMDV vaccines, diagnostics and other biologics.

The present disclosure relates to a method for expressing, water-solubilizing, and purifying protein by using a calsequestrin-tag (CSQ-tag). Also provided are: a recombinant expression vector containing a CSQ-tag and a target protein; a host cell transformed using the recombinant expression vector; and a method for expressing and purifying a target protein by using a CSQ tag.

The invention relates to a combination preparation containing a selective cell death-inducing binary enzyme system for use in the therapy and/or treatment of cancer and tumors in humans and animals, a process, and its use.

Polynucleotide constructs that express an engineered foot-and-mouth disease (FMDV) P1 precursor protein and a non-FMDV TEV protease and methods for safe and efficient recombinant production of FMDV antigens and immunogens. Recombinant production of FMDV antigens avoids the need to culture highly-infectious FMDV, while conventional culture methods for producing FMDV antigens rely on the native FMDV 3C protease which exerts toxic effects on host cells. The inventors have developed a new system that efficiently and safely processes FMDV P1 precursor without the FMDV 3C protease, thus avoiding the toxic effects associated with use of the 3C protease. The invention is also directed to the FMDV antigens and virus-like particles produced by this system as well as to FMDV vaccines, diagnostics and other biologics.

The present disclosure provides a light-activated, calcium-gated polypeptide; and a system comprising: a) the light-activated, calcium-gated polypeptide; and b) a fusion protein comprising a calcium responsive polypeptide and a protease that cleaves a proteolytically cleavable linker present in the light-activated, calcium-gated polypeptide. The present disclosure provides nucleic acids encoding the light-activated, calcium-gated polypeptide or the system, and cells comprising the nucleic acids. The present disclosure provides methods of detecting a change in intracellular calcium ion concentration. The present disclosure provides methods of controlling or modulating an activity of a cell.