Abstract: Disclosed herein are high Tm RNA nanostructures that can be composed of one or more modules or motifs to build RNA nanostructures with or without layers. The RNA nanostructures can have a core domain and three or more double-stranded arms and formulations thereof to conjugate high copy numbers of therapeutics, pH responsive or enzyme cleavable drug cargo. Also described herein is a design strategy for generation of synthetic RNA oligonucleotides that can self assemble into highly thermostable RNA structures. Also described herein are uses of the RNA nanostructures described herein.

Abstract: The presently-disclosed subject matter relates to RNA-based composition and method to treat breast cancer in a subject. More particularly, the presently disclosed subject matter relates to a RNA nanostructure and composition containing a multiple branched RNA nanoparticle, a breast cancer targeting module, and an effective amount of a breast cancer therapeutic agent. Further, the presently disclosed subject matter relates to a method of using the RNA nanoparticle composition to treat breast cancer in a subject having or at risk of having breast cancer.

Abstract: A method is described for the identification of multi-subunit biocomplex drug targets. The method includes identifying a target that performs a biological function, wherein the target comprises one or more subunits, wherein a minimum number of the one or more subunits is inactivated to inhibit the biological function. The method includes selecting a drug that binds specifically to each subunit of the one or more subunits with a target probability. The method describes a relationship between inhibition efficiency of the drug and total number of the one or more subunits using a binomial distribution, wherein the inhibition efficiency comprises a probability that the delivered drug blocks the biological function. The method includes confirming empirically the relationship using an experimental target. The method includes administering the drug to the target to treat a multi-drug resistant disease, wherein the target comprises a biological complex in a mammalian subject.

Abstract: The presently-disclosed subject matter relates to RNA-based composition and method to treat gastric cancer in a subject. More particularly, the presently disclosed subject matter relates to a RNA nanostructure and composition containing a multiple branched RNA nanoparticle, a gastric cancer targeting module, and an effective amount of a therapeutic agent. Further, the presently disclosed subject matter relates to a method of using the RNA nanoparticle composition to treat gastric cancer in a subject having or at risk of having gastric cancer.

Abstract: The presently-disclosed subject matter relates to RNA-based composition and method to treat breast cancer in a subject. More particularly, the presently disclosed subject matter relates to a RNA nanostructure and composition containing a multiple branched RNA nanoparticle, a breast cancer targeting module, and an effective amount of a breast cancer therapeutic agent. Further, the presently disclosed subject matter relates to a method of using the RNA nanoparticle composition to treat breast cancer in a subject having or at risk of having breast cancer.

Abstract: The presently-disclosed subject matter relates to RNA-based composition and method to treat gastric cancer in a subject. More particularly, the presently disclosed subject matter relates to a RNA nanostructure and composition containing a multiple branched RNA nanoparticle, a gastric cancer targeting module, and an effective amount of a therapeutic agent. Further, the presently disclosed subject matter relates to a method of using the RNA nanoparticle composition to treat gastric cancer in a subject having or at risk of having gastric cancer.

Abstract: A method is described for the identification of multi-subunit biocomplex drug targets. The method includes identifying a target that performs a biological function, wherein the target comprises one or more subunits, wherein a minimum number of the one or more subunits is inactivated to inhibit the biological function. The method includes selecting a drug that binds specifically to each subunit of the one or more subunits with a target probability. The method describes a relationship between inhibition efficiency of the drug and total number of the one or more subunits using a binomial distribution, wherein the inhibition efficiency comprises a probability that the delivered drug blocks the biological function. The method includes confirming empirically the relationship using an experimental target. The method includes administering the drug to the target to treat a multi-drug resistant disease, wherein the target comprises a biological complex in a mammalian subject.

Abstract: A polyvalent multimeric complex formed from a plurality of circularly permuted chimeric pRNA molecules, each carrying a stabilized biologically active moiety.

Abstract: A circularly permuted chimeric pRNA molecule carrying a stabilized biologically active RNA, such as a ribozyme.

Abstract: A circularly permuted chimeric pRNA molecule carrying a stabilized biologically active RNA, such as a ribozyme.

Abstract: A polyvalent multimeric complex formed from a plurality of circularly permuted chimeric pRNA molecules, each carrying a stabilized biologically active moiety.

Abstract: A circularly permuted chimeric pRNA molecule carrying a stabilized biologically active RNA, such as a ribozyme.