The present invention relates to A multicomponent system wherein a first component is an engineered antigen-presenting cell (eAPC) designated component A and a second component is a genetic donor vector, designated component C, for delivery of one or more ORFs encoding an analyte antigen-presenting complex (aAPX) and/or an analyte antigenic molecule (aAM), wherein component A a. Lacks endogenous surface expression of at least one family of aAPX and/or aAM and b. Contains at least two genomic receiver GO sites, designated component B and component D, each for integration of at least one ORF encoding at least one aAPX and/or aAM, and component C is matched to a component B, and wherein component C is designed to deliver c. A single ORF encoding at least one aAPX and/or aAM or d. Two or more ORF encoding at least one aAPX and/or aAM, wherein the genomic receiver sites B and D are synthetic constructs designed for re-combinase mediated exchange (RMCE).

Provided herein are neuroprotective molecules containing a sequence of 25-35 contiguous nucleotides between nucleotide 1 and nucleotide 50 of a mature human tRNA and at least four contiguous guanosine-containing nucleotides, where the sequence of 25-35 contiguous nucleotides contains a D-loop stem structure, the at least four contiguous guanosine-containing nucleotides are located at the 5 end of the neuroprotective molecule, and the neuroprotective molecule contains at least one deoxyribonucleotide. Also provided are neuroprotective molecules containing a sequence of 25-35 contiguous nucleotides between nucleotide 1 and nucleotide 50 of a mature human tRNA.sup.CYS; and at least four contiguous guanosine-containing nucleotides, where the sequence of 25-35 contiguous nucleotides contains a D-loop stem structure and the at least four contiguous guanosine-containing nucleotides are located at the 5 end of the neuroprotective molecule.

This invention discloses a nucleic acid aptamer AS1411 modified DNA tetrahedron. The preparation method includes the steps of (1) binding an AS1411 sequence to the 5 terminal of any DNA single-strand in a DNA tetrahedron, synthesizing the DNA, dissolving obtained DNA powder with ddH.sub.2O; (2) measuring an absorbance of the DNA and then calculating a total volume of the four single strands; (3) pipetting the DNA obtained in step (1) according to the calculation results in step (2), mixing the DNA with a TM buffer, mixing the mixture uniformly with vortex vibration, and performing a PCR progress. The preparation method is simple. The produced product can effectively solve the problem that the unmodified DNA tetrahedron cannot enter the nucleus and the problem that the AS1411 cannot carry drugs directly.

Provided are an expression inhibitor of an inflammation promoting factor based on the discovery of a new factor influencing the expression amount/level of an inflammation promoting factor, and a development tool therefor. Provided are also a diagnostic agent and a diagnosis method for immune diseases, inflammatory diseases, painful conditions and similar. More specifically provided are: an expression inhibitor of an inflammation promoting factor containing at least one kind of inhibitor selected from the group consisting of RBMS2 expression inhibitor and RBMS2 function inhibitor; a screening method using as an indicator the expression or the function of RBMS2; an expression cassette useful for the method; as well as a diagnostic agent containing a product detection agent for RBMS2 gene expression and disease detection method using as an indicator RBMS2 gene expression amount/level.

The present invention relates to processes for producing compositions comprising (i) a virus-like particle of an RNA bacteriophage, and (ii) aggregated oligonucleotides, wherein said aggregated oligonucleotides are packaged into said virus-like particle. The invention further provides processes for producing nucleotide compositions comprising aggregated oligonucleotides suitable for use in the aforementioned processes before. Moreover, the invention further provides nucleotide compositions comprising aggregated oligonucleotides. Furthermore, the invention further provides compositions comprising (i) a virus-like particle of an RNA bacteriophage, and (ii) aggregated oligonucleotides, wherein said aggregated oligonucleotides are packaged into said virus-like particle.

The present invention relates to new nucleic acid molecules of therapeutic interest, in particular for use in the treatment of cancer.

Provided herein are cell penetrating conjugates. The conjugates include non-cell penetrating proteins connected through a phosphorothioate nucleic acid, wherein the phosphorothioate nucleic acid enhances intracellular delivery of the non-cell penetrating proteins. Also provided are methods and kits including the conjugates provided herein.

Double-stranded and single-stranded RNA molecules, and their use in methods for inducing interferon are provided. The interferon induction provides anti-viral and other medically useful effects, such as anti-cancer effects. Also provided are methods for reducing or inhibiting interferon induction exhibited by such molecules, particularly siRNA and shRNA molecules produced in vitro.

Some embodiments of the methods and compositions provided herein relate to treating a subject suffering from hypertension, a cardiac injury, or a metabolic disorder. Some embodiments include administering an exosome to a subject. Some embodiments include administering an oligonucleotide to the subject. In some embodiments, the oligonucleotide comprises a Y-RNA or Y-RNA fragment such as EV-YF1 or EV-YF1-U16. In some embodiments, the oligonucleotide or exosome also has a therapeutic effect on the subject.

Methods for capturing a target nucleic acid from a sample by using a capture probe that binds nonspecifically to the target nucleic acid and binds specifically to an immobilized probe via a specific binding pair that has one member on the capture probe and one member on the immobilized probe are disclosed. Compositions that include a capture probe that binds nonspecifically to a target nucleic acid and specifically to an immobilized probe via binding of members of a specific binding pair in a solution phase of a reaction mixture are disclosed.