The present disclosure relates to an exosome comprising a photocleavable protein and a use thereof, and the exosome according to the present disclosure contains a fusion protein comprising a blue fluorescent protein (TagBFP), a photocleavable protein (mMaple3), and an exosome-specific marker protein (CD9), and it has been found that when light of 405 nm is irradiated to the exosome, the photocleavable protein, mMaple3 is cleaved and thereby the blue fluorescent protein in the exosome can be delivered into a target cell. In addition, it has been found that Cre protein in the exosome can be delivered into an animal organ, when light of 405 nm is irradiated to an exosome containing Cre fusion protein (Cre-mMaple3-CD9). Therefore, the exosome containing the photocleavable protein according to the present disclosure is expected to be useful in the protein treatment field by safely and efficiently delivering various therapeutic proteins into cells.

The present disclosure relates to an exosome comprising a photocleavable protein and a use thereof, and the exosome according to the present disclosure contains a fusion protein comprising a blue fluorescent protein (TagBFP), a photocleavable protein (mMaple3), and an exosome-specific marker protein (CD9), and it has been found that when light of 405 nm is irradiated to the exosome, the photocleavable protein, mMaple3 is cleaved and thereby the blue fluorescent protein in the exosome can be delivered into a target cell. In addition, it has been found that Cre protein in the exosome can be delivered into an animal organ, when light of 405 nm is irradiated to an exosome containing Cre fusion protein (Cre-mMaple3-CD9). Therefore, the exosome containing the photocleavable protein according to the present disclosure is expected to be useful in the protein treatment field by safely and efficiently delivering various therapeutic proteins into cells.

The present invention relates to a targeted protease degradation (TED) platform, and specifically to a conjugate of target molecule-linker-E3 ligase ligand as shown in formula I, R.sub.T-L1-R.sub.E3 (formula I), wherein R.sub.T is a monovalent group of the target molecule, R.sub.E3 is a monovalent group of the E3 ligase ligand, L1 is the linker linking A and B, and L1 is as shown in formula II below: —W-L2-W.sup.2— (II).

The present invention relates to a targeted protease degradation (TED) platform, and specifically to a conjugate of target molecule-linker-E3 ligase ligand as shown in formula I, R.sub.T-L1-R.sub.E3 (formula I), wherein R.sub.T is a monovalent group of the target molecule, R.sub.E3 is a monovalent group of the E3 ligase ligand, L1 is the linker linking A and B, and L1 is as shown in formula II below: —W-L2-W.sup.2— (II).

A peptide vaccine complexed so that the peptide vaccine can be delivered specifically to the surface of specific immune cells and a method for delivering a peptide vaccine specifically to the surface of specific immune cells. The peptide vaccine is combined with an IgG binding peptide capable of binding to an IgG that is an agonist against molecules on the surface of specific immune cells such as dendritic cells.

A peptide vaccine complexed so that the peptide vaccine can be delivered specifically to the surface of specific immune cells and a method for delivering a peptide vaccine specifically to the surface of specific immune cells. The peptide vaccine is combined with an IgG binding peptide capable of binding to an IgG that is an agonist against molecules on the surface of specific immune cells such as dendritic cells.

Provided are compositions and methods useful in regenerating damaged tissue, especially cardiac tissue, by delivering to the site of injury an miRNA that can reduce, for example, the expression of phosphatase and tensin homolog (PTEN). The compositions and methods of the disclosure may be generally applied to deliver an miRNA to a cell or tissue such as, but not limited to, a neuron, a smooth muscle cell, or a tumor cell. The compositions comprise a transmembrane carrier peptide conjugated, optionally by a linker, to an oligonucleotide complementary to an miRNA. The carrier peptide facilitates the entry of the miRNA into cells and for delivery to a tissue of an animal or human may be mixed with an extracellular matrix-derived hydrogel carrier.

Provided are compositions and methods useful in regenerating damaged tissue, especially cardiac tissue, by delivering to the site of injury an miRNA that can reduce, for example, the expression of phosphatase and tensin homolog (PTEN). The compositions and methods of the disclosure may be generally applied to deliver an miRNA to a cell or tissue such as, but not limited to, a neuron, a smooth muscle cell, or a tumor cell. The compositions comprise a transmembrane carrier peptide conjugated, optionally by a linker, to an oligonucleotide complementary to an miRNA. The carrier peptide facilitates the entry of the miRNA into cells and for delivery to a tissue of an animal or human may be mixed with an extracellular matrix-derived hydrogel carrier.

A liquid formulation of a long-acting conjugate of a peptide having activities for a glucagon receptor and a GLP-1 receptor, and a method for preparing the liquid formulation are disclosed. The liquid formulation contains 18 nmol/mL to 940 nmol/mL of the long-acting conjugate, a buffering agent in an amount for maintaining the pH of the liquid formulation in the range of 4.5 to 7.5, and 1% (w/v) to 20% (w/v) of saccharide, and 0.001% (w/v) to 0.2% (w/v) of a nonionic surfactant.

A liquid formulation of a long-acting conjugate of a peptide having activities for a glucagon receptor and a GLP-1 receptor, and a method for preparing the liquid formulation are disclosed. The liquid formulation contains 18 nmol/mL to 940 nmol/mL of the long-acting conjugate, a buffering agent in an amount for maintaining the pH of the liquid formulation in the range of 4.5 to 7.5, and 1% (w/v) to 20% (w/v) of saccharide, and 0.001% (w/v) to 0.2% (w/v) of a nonionic surfactant.