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

A biosensor molecule comprises: a protease amino acid sequence; at least one sensor comprising at least one sensor amino acid sequence which is responsive to at least one target molecule; and an inhibitor of the protease activity of said protease amino acid sequence; wherein the biosensor is switchable from a protease active to a protease inactive state, or from a protease inactive to a protease active state when said sensor responds to said target molecule. The biosensor protease may be a protease of a virus such as a Potyvirus or a Flavivirus wherein the inhibitor is an autoinhibitory peptide derived from the virus. The biosensor may respond to the target molecule allosterically or may be cleaved by a target protease molecule.

Provided is a proteolysis-targeting virus, wherein one or more proteolysis-targeting molecules that can be recognized by the ubiquitin-proteasome system are comprised at one or more different sites of protein thereof, and the viral protein is linked to the proteolysis-targeting molecules by one or more linkers that can be selectively cleaved. Also provided are a nucleic acid molecule encoding the proteolysis-targeting virus, a nucleic acid vector expressing the proteolysis-targeting virus, a preparation method for the proteolysis-targeting virus, methods for the preparation of an attenuated live virus, replication-incompetentlive virus, replication-controllable live virus, and a relevant vaccine and medication for preventing and treating virus infections, a vaccine or pharmaceutical composition comprising the proteolysis-targeting virus, and a system for preparing the proteolysis-targeting virus.

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.

Compositions, systems and methods are provided for conferring disease resistance to plant pathogens that use proteases to target plant substrate proteins inside plant cells. Briefly, the compositions, systems and methods are based upon plant substrate proteins that are targeted by pathogen-specific proteases and that activate nucleotide binding site-leucine rich repeat (NB-LRR) disease resistance proteins when cleaved by the protease. These substrate proteins are modified such that the endogenous protease recognition sequence is replaced by a protease recognition sequence specific to a different pathogen protease (i.e., a heterologous protease recognition sequence). The modified plant substrate protein therefore can be used in connection with its corresponding NB-LRR protein to activate resistance in response to cleavage by the heterologous pathogen-specific protease. When activated by the plant pathogen-specific protease, the pair initiates host defense responses thereto, including programmed cell death.

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.

The present invention provides systems and methods for performing forward genetic screens in cells and methods of treating disease through inhibiting targets identified in a forward genetic screen as involved in a pathway associated with the disease. The invention involves the use of multiple tandem fluorescent reporter molecules separated by cleavage sites under the control of a single promoter to enhance the fluorescent readout from a cell screen.

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.