Methods and compositions for regulating activity of a poxvirus viral polymerase by modulating the assembly and/or interaction of one or more subunits of the viral polymerase are described.

Disclosed are nucleic acid oligomer compounds and to their use in compositions and methods for inhibiting proliferation, survival or viability of cancer cells including prostate, lung, pancreatic, breast, cervical and bone cancer cells.

The present disclosure relates to methods for the inhibition of proteins involved in the assembly and or secretion of HBV SVP by inhibiting the activity of casein kinase 1 isoform delta, DNAJB12, and/or microtubule-actin crosslinking factor 1.

The present disclosure relates to nucleic acid-peptide-nucleic acid conjugate molecules and to methods for synthesizing nucleic acid-peptide-nucleic acid conjugate molecules. In some embodiments, a method for synthesizing a nucleic acid-peptide-nucleic acid conjugate molecule using proximity-enhanced synthesis includes covalently linking a peptide with a first nucleic acid strand via a first reaction, hybridizing the first nucleic acid strand with a second nucleic acid strand to bring the second nucleic acid strand in proximity to the peptide, and covalently linking the peptide with the second nucleic acid strand via a second reaction to provide the nucleic acid-peptide-nucleic acid conjugate molecule. In some embodiments, the peptide of the nucleic acid-peptide-nucleic acid conjugate molecule is a substrate for cleavage by an enzyme, such as matrix metalloproteinase-8 (MMP-8). Exemplary applications of the nucleic acid-peptide-nucleic acid conjugate molecule for drug delivery, molecular assembly of hybrid structures, and constraining the peptide to a biologically active conformation are also disclosed.

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.

Disclosed is an oligonucleotide-modified nucleic acid containing at least one 1-β-D-arabinofuranosylcytosine as a modified nucleic acid having therapeutic efficacies and guanosine. More particularly, a novel oligonucleotide-modified nucleic acid containing at least one modified nucleic acid (N) having therapeutic efficacies and being rich in guanosine (G) is synthesized and the fact that the novel oligonucleotide-modified nucleic acid has excellent apoptotic activities on blood cancer cells and drug-resistant blood cancer cells is identified. Based on this, provided is a composition for preventing, ameliorating or treating blood cancer, containing the novel oligonucleotide-modified nucleic acid, and the novel oligonucleotide-modified nucleic acid or a pharmaceutically acceptable salt thereof as an active ingredient.

This disclosure describes, in one aspect, a composition that generally includes an xNA molecule comprising at least six nucleotides, in an amount effective to improve at least one indicator of myocyte function and a pharmaceutically acceptable carrier. In another aspect, this disclosure describes a method of treating cardiac disease. Generally, the method includes administering to a subject a composition that includes an xNA molecule having at least six nucleotides, in an amount effective to improve at least one indicator of myocyte function, and a pharmaceutically acceptable carrier. In another aspect, this disclosure describes a method for evaluating the efficacy of treatment of cardiac disease. Generally, the method includes administering to a subject a composition that includes a first xNA molecule comprising a predetermined length in an amount effective to increase myocyte relaxation, then selecting a predetermined length of a second xNA molecule for at least one subsequent treatment. If treatment with the first xNA results in more myocyte relaxation than is desired, then the predetermined length of the second xNA molecule is shorter than the predetermined length of the first xNA. If, on the other hand, treatment with the first xNA results in less myocyte relaxation than is desired then the predetermined length of the second xNA molecule is longer than the predetermined length of the first xNA.

Biologically active nucleotide molecules are configured, with the nucleotide sequence thereof, to be able to trigger several, in particular a plurality of “off-target” effects to cause cell-killing stress by means of binding of same, by means of which off-target effects cells are so massively influenced that the cells die off or programmed cell death (apoptosis) is induced in the cells.

Nucleic acids (DNA and RNA) provide a versatile platform for engineering synthetic biology in a variety of technology areas including medicine, science, agriculture, and energy. In many settings, degradation of nucleic acid molecules poses a significant engineering challenge as the molecules do not function if they have been degraded. In some embodiments, nucleic acid protective elements (PELs) are used to protect chemically synthesized or expressed nucleic acid molecules from degradation. PELs may be derived from all or part of a viral xrRNA sequence and/or structural motif, PELs may include rationally designed sequences and/or structural motifs, PELs may be engineered using directed evolution, and in some embodiments, PELs comprise a mixture of biologically derived, rationally designed sequence and/or structural motifs, and/or sequences and/or structural motifs that are engineered by directed evolution. In some embodiments, PELs significantly enhance the performance of nucleic acid synthetic biology, protecting nucleic acid regulatory and/or structural elements from degradation to increase regulatory dynamic range, fractional dynamic range, fold-change, and/or other performance metrics. In some embodiments, PELs that reduce nucleic acid degradation provide a platform technology for enhancing the performance of synthetic biology, with applications including therapeutics, diagnostics, biological research tools, vaccines, crop protection, molecular manufacturing, sustainable energy production, and other areas involving nucleic acids.

A non-specific-binding inhibitor enables, in detection of a target nucleic acid by hybridization, effective inhibition of cross-hybridization between the target nucleic acid and complementary strands of sequences similar thereto, which non-specific-binding inhibitor has a stable quality among production lots, and a hybridization method for nucleic acid uses the inhibitor. The non-specific-binding inhibitor for nucleic acid includes a nucleic acid which has a base length of 2 to 11 bases and in which the content of a guanine base(s) and/or methylated guanine base(s) in the entire base sequence is not less than 70%.