The present invention relates to a novel peptide or a partial sequence thereof for enhancing expression efficiency of a target protein, and a fusion protein comprising the same. The novel peptide according to the present invention can enhance expression efficiency of a target protein, and furthermore, the peptide can also be applied to a solubility-enhancing fusion protein in order to enhance solubility of the target protein, so that solubility as well as expression efficiency of the target protein is enhanced, which allows such a peptide to be usefully used for production of a recombinant target protein.

The present invention relates to a novel peptide or a partial sequence thereof for enhancing expression efficiency of a target protein, and a fusion protein comprising the same. The novel peptide according to the present invention can enhance expression efficiency of a target protein, and furthermore, the peptide can also be applied to a solubility-enhancing fusion protein in order to enhance solubility of the target protein, so that solubility as well as expression efficiency of the target protein is enhanced, which allows such a peptide to be usefully used for production of a recombinant target protein.

Provided is a mutant lysyl-tRNA synthetase. Compared with a wild-type lysyl-tRNA synthetase, the mutant lysyl-tRNA synthetase of the present invention can increase the amount of non-natural amino acids inserted and the amount of a protein of interest containing non-natural amino acids, and can also improve the stability of the protein of interest, thereby making same less prone to fragmentation.

Provided by the present invention is a mutant lysyl-tRNA synthetase that has a deletion mutation at one or more sites selected from the group corresponding to the amino acid sequence of wild-type aminoacyl-tRNA synthetase: 102nd, 128th-140th, and 159th-179th amino acid residues. Compared with wild-type lysyl-tRNA synthetase, the mutant lysyl-tRNA synthetase according to the present invention has high activity, a high level of expression and good solubility, and may significantly increase the amount of an inserted unnatural amino acid and the level of expression of a target protein containing an unnatural amino acid.

The present invention relates to a mouse (Mus musculus) in which expression and site-specific modification of a target protein is temporally and spatially controlled, and a method for producing the same and the use thereof, and more particularly to a transgenic mouse in which expression of a target protein having a modification attached to a specific position is temporally and spatially controlled as a result of incorporation of an unnatural amino acid. In the mouse according to the present invention, in which site-specific modification of a target protein is temporally and spatially controllable, expression of the target protein having the site-specific modification attached thereto is controllable depending on the timing and/or position of introduction of an unnatural amino acid. Thus, the mouse according to the present invention is useful for studies on the in vivo functions of cellular proteins, various human diseases including cancers and neurodegenerative disorders, new drug discovery, and the like.

The present invention relates to a mouse (Mus musculus) in which expression and site-specific modification of a target protein is temporally and spatially controlled, and a method for producing the same and the use thereof, and more particularly to a transgenic mouse in which expression of a target protein having a modification attached to a specific position is temporally and spatially controlled as a result of incorporation of an unnatural amino acid. In the mouse according to the present invention, in which site-specific modification of a target protein is temporally and spatially controllable, expression of the target protein having the site-specific modification attached thereto is controllable depending on the timing and/or position of introduction of an unnatural amino acid. Thus, the mouse according to the present invention is useful for studies on the in vivo functions of cellular proteins, various human diseases including cancers and neurodegenerative disorders, new drug discovery, and the like.

The present invention relates to a novel function of lysyl tRNA synthetase, that is, lysyl tRNA synthetase interacts with 67LR through translocation of KRS into plasma membrane, and so enhances tumor (or cancer) cell migration, thereby having an effect on cancer metastasis. More specifically, it relates to method for controlling cancer metastasis or cancer cell migration by modulating an cellular level of lysyl tRNA synthetase, an use of an expression vector comprising a construct inhibiting KRS expression for preventing or treating cancer, an use of an agent inhibiting KRS activity for preventing or treating cancer, a method for screening an agent which modulates cancer metastasis or cancer cell migration, a method for screening an agent inhibiting an interaction between KRS and 67LR. Accordingly, cancer metastasis and cancer cell migration may be controlled using the inventive KRS, further the cellular metabolism related to laminin receptor (67LR) of plasma membrane may be controlled. The relationship between KRS and laminin receptor disclosed in the present invention may be very useful for treatment, prevention and/or diagnosis of various disease related to thereof.

The present invention relates to: a lysyl tRNA synthetase (KRS) fragment which comprises an amino acid sequence represented by SEQ ID NO: 1 and is secreted from cancer cells; microvesicles comprising the KRS fragment; and a method for providing information necessary for cancer diagnosis and screening a cancer metastasis inhibiting agent using the same. The present invention can be favorably used in the development of a diagnostic kit for providing information necessary for cancer diagnosis or the development of a cancer metastasis inhibiting agent, and thus is highly industrially applicable.

The present invention provides: ferritin; a single-chain variable fragment bound to the N-terminus of the ferritin; and a fusion protein self-assembling nanoparticle structure in which an N-terminus RNA-interaction domain (RID) in a human-derived lysyl-tRNA synthetase is bound to the N-terminus of the single-chain variable fragment by means of a novel fusion partner. Therefore, the present invention provides: a fusion protein having enhanced water solubility; nanoparticles; a vector coding same; a host cell transformed by means of the vector, and a pharmaceutical composition, for treating a disease, using the same.

Provided by the present invention is a mutant lysyl-tRNA synthetase that has a deletion mutation at one or more sites selected from the group corresponding to the amino acid sequence of wild-type aminoacyl-tRNA synthetase: 102nd, 128th-140th, and 159th-179th amino acid residues. Compared with wild-type lysyl-tRNA synthetase, the mutant lysyl-tRNA synthetase according to the present invention has high activity, a high level of expression and good solubility, and may significantly increase the amount of an inserted unnatural amino acid and the level of expression of a target protein containing an unnatural amino acid.