Provided nucleic acid-based expression construct for the target cell-specific production of a therapeutic protein, such as a pro-apoptotic protein, within a target cell, including a target cell that is associated with aging, disease, or other condition, in particular a target cell that is a senescent cell or a cancer cell. Also provided are formulations and systems, including fusogenic lipid nanoparticle (LNP) formulations and systems, for the delivery of nucleic acid-based expression constructs as well as methods for making and using such nucleic acid-based expression constructs, formulations, and systems for reducing, preventing, and/or eliminating the growth and/or survival of a cell, such as a senescent cell and/or a cancer cell, which is associated with aging, disease, or other condition as well as methods for the treatment of aging, disease, or other conditions by the in vivo administration of a formulation, such as a fusogenic LPN formulation, comprising an expression construct for the target cell-specific production of a therapeutic protein, such as a pro-apoptotic protein, in a target cell that is associated with aging, disease, or other condition, in particular a target cell that is a senescent cell or a cancer cell.

Disclosed are a gene expression cassette for expressing an N-terminal-methionine-truncated target protein comprising a nucleic acid encoding a target protein and a nucleic acid encoding a cysteine protease, in which a cysteine protease recognition sequence is inserted between methionine (Met), which is the first amino acid at the N-terminus of the target protein, and the second amino acid and N-terminal methionine is cleaved with the cysteine protease, and a method of producing an N-terminal-methionine-truncated target protein using the same.

Provided are a method of screening an inhibitor of caspase activity by lipopolysaccharide and a method of screening a therapeutic agent for inflammatory diseases or sepsis using the same. Accordingly, it is possible to develop a caspase-4-specific inhibitor.

Methods and materials for specific imaging of active enzyme in a live or intact cell are disclosed. The enzyme of interest tagged to reporter protein (donor) is exogenously expressed in a cell. The conversion of proenzyme to active enzyme (containing reporter protein) is achieved upon applying an appropriate stimulus to the target cells. The activated enzyme is labelled with an activity-based probe carrying a fluorophore (acceptor). The covalent labelling of active enzyme by the activity-based probe creates a FRET pair which provides the opportunity to exquisitely image the function of an “active enzyme”. This method is used for specific imaging of the function of active caspase-3,-7,-8,-9 and cathepsin-B and also for profiling of inhibitors of caspases and cathepsin B.

The present disclosure provides for conversion-resistant CAR regulatory T cells (Tregs) and bi-specific antibodies, and methods to use these Tregs and antibodies for the treatment of autoimmune diseases and for prevention of organ transplant rejection.

Provided nucleic acid-based expression construct for the target cell-specific production of a therapeutic protein, such as a pro-apoptotic protein, within a target cell, including a target cell that is associated with aging, disease, or other condition, in particular a target cell that is a senescent cell or a cancer cell. Also provided are formulations and systems, including fusogenic lipid nanoparticle (LNP) formulations and systems, for the delivery of nucleic acid-based expression constructs as well as methods for making and using such nucleic acid-based expression constructs, formulations, and systems for reducing, preventing, and/or eliminating the growth and/or survival of a cell, such as a senescent cell and/or a cancer cell, which is associated with aging, disease, or other condition as well as methods for the treatment of aging, disease, or other conditions by the in vivo administration of a formulation, such as a fusogenic LPN formulation, comprising an expression construct for the target cell-specific production of a therapeutic protein, such as a pro-apoptotic protein, in a target cell that is associated with aging, disease, or other condition, in particular a target cell that is a senescent cell or a cancer cell.

Provided are a method of screening an inhibitor of caspase activity by lipopolysaccharide and a method of screening a therapeutic agent for inflammatory diseases or sepsis using the same. Accordingly, it is possible to develop a caspase-4-specific inhibitor.

A method for in vitro transcription of a DNA template into RNA includes providing a mixture containing a buffer substance, ribonucleoside triphosphates (NTPs), one or more magnesium salts in a concentration of from about 2 mM to about 60 mM, the DNA template, and a recombinant RNA polymerase, and incubating the reaction mixture at from about 25 C. to about 40 C. for from about 1 hour to about 12 hours thereby producing the RNA. A method for in vitro transcription includes providing a DNA template and a cap analogue that binds to 1 and/or +1 nucleotides of promoter for in vitro transcription, thus producing more full length mRNAs, allowing for more flexibility on the choice of first mRNA base, and providing +2 position open for custom sequence.

A method for in vitro transcription of a DNA template into RNA includes providing a mixture containing a buffer substance, ribonucleoside triphosphates (NTPs), one or more magnesium salts in a concentration of from about 2 mM to about 60 mM, the DNA template, and a recombinant RNA polymerase, and incubating the reaction mixture at from about 25 C. to about 40 C. for from about 1 hour to about 12 hours thereby producing the RNA. A method for in vitro transcription includes providing a DNA template and a cap analogue that binds to 1 and/or +1 nucleotides of promoter for in vitro transcription, thus producing more full length mRNAs, allowing for more flexibility on the choice of first mRNA base, and providing +2 position open for custom sequence.

Methods and materials for specific imaging of active enzyme in a live or intact cell are disclosed. The enzyme of interest tagged to reporter protein (donor) is exogenously expressed in a cell. The conversion of proenzyme to active enzyme (containing reporter protein) is achieved upon applying an appropriate stimulus to the target cells. The activated enzyme is labelled with an activity-based probe carrying a fluorophore (acceptor). The covalent labelling of active enzyme by the activity-based probe creates a FRET pair which provides the opportunity to exquisitely image the function of an active enzyme. This method is used for specific imaging of the function of active caspase-3,-7,-8,-9 and cathepsin-B and also for profiling of inhibitors of caspases and cathepsin B.