Disclosed herein are multi-way oligonucleotide junctions for delivering one or more cargo molecules to a biological target and method of making such junctions. The oligonucleotide junctions are formed by two or more oligonucleotides and are stable outside the cell and easily dissociate inside the cell to release the cargo molecule(s). One or more cargo molecules as well as delivery ligand can be loaded to the junctions for targeted delivery. Also disclosed are nanostructures including one or more junctions attached to each other for delivering two or more cargo molecules.

The present invention includes bivalent or multivalent nucleic acid molecules or complexes of nucleic acid molecules having two or more target-specific regions, in which the target-specific regions are complementary to a single target gene at more than one distinct nucleotide site, and/or in which the target regions are complementary to more than one target gene or target sequence. Also included are compositions comprising such nucleic acid molecules and methods of using the same for multivalent RNA interference and the treatment of a variety of diseases and infections.

This invention discloses a method for preparing TDNs-AS1411-nucleic acid drug nanocomposite based drug delivery system, which includes the following steps: binding AS1411 and nucleic acid drug to a tetrahedral DNA nanostructure respectively; selecting four DNA single strands that respectively carry AS1411 and nucleic acid drug; mixing the four DNA single strands; mixing the DNA single strands and the TM buffer uniformly; putting the mixture into a PCR apparatus; raising the temperature to 95 C. quickly and maintaining for 10 min; and next cooling down to 4 C. and maintaining for 20 min to obtain the TDNs-AS1411-nucleic acid drug nanocomposite based drug delivery system. This drug delivery system can directly act on cell nucleus and will not be degraded by lysosomal. The targeting specificity is good. The drug can take a good efficacy and the pertinency is high.

The present invention relates to a pharmaceutical composition for preventing or treating atopic dermatitis, the pharmaceutical composition including, as an active ingredient, X-shaped DNA (X.sub.L-DNA) formed by complementary binding of oligonucleotides having nucleotide sequences of SEQ ID NO: 1 to SEQ ID NO: 4. When the pharmaceutical composition is subcutaneously injected into an animal model of atopic dermatitis, effects of easing skin lesions, such as erythema, bleeding and edema, and the like, and ear edema, and reducing expression of immunoglobulin E (IgE) are exhibited. In this regard, the composition can be used as a pharmaceutical composition, a health food, or a cosmetic for atopic dermatitis.

The present disclosure provides engineered polynucleotide sequences that form scaffolds and nucleoprotein complexes comprising such engineered polynucleotide sequences that form scaffolds and nucleic acid binding proteins. Nucleic acid sequences encoding the engineered polynucleotide sequences that form scaffolds, as well as expression cassettes, vectors and cells comprising such polynucleotide sequences, are described. A variety of methods for making and using the engineered polynucleotide sequences that form scaffolds are also disclosed.

Provided herein are methods, compounds, and compositions for reducing expression of transthyretin mRNA and protein in an animal. Such methods, compounds, and compositions are useful to treat, prevent, delay, or ameliorate transthyretin amyloidosis, or a symptom thereof.

Novel oligonucleotides that enhance silencing of the expression of a gene containing a single nucleotide polymorphism (SNP) relative to the expression of the corresponding wild-type gene are provided. Methods of using novel oligonucleotides that enhance silencing of the expression of a gene containing a SNP relative to the expression of the corresponding wild-type gene are provided.

This disclosure relates to novel HTT-1A targeting sequences. Novel HTT-1A targeting oligonucleotides for the treatment of neurodegenerative diseases are also provided.

Provided herein are branched oligonucleotides exhibiting efficient and specific tissue distribution, cellular uptake, minimum immune response and off-target effects, without formulation.

The present disclosure provides engineered polynucleotide sequences that form scaffolds and nucleoprotein complexes comprising such engineered polynucleotide sequences that form scaffolds and nucleic acid binding proteins. Nucleic acid sequences encoding the engineered polynucleotide sequences that form scaffolds, as well as expression cassettes, vectors and cells comprising such polynucleotide sequences, are described. A variety of methods for making and using the engineered polynucleotide sequences that form scaffolds are also disclosed.