Recent advancements in LNA oligonucleotides include the use of amine linkers to link an LNA antisense oligonucleotide to a conjugate group. For example please see WO2014/I18267. The present invention originates from the identification of a problem when de-protecting LNA oligonucleotides which comprise an aliphatic amine group and DMF protected LNA G nucleoside, which results in the production of a +28 Da impurity. This problem is solved by using acyl protection groups on the exocyclic nitrogen of the LNA-G residue, rather than the standard DMF protection group.

Provided is a method of treating cancer cells localized in the lung by administering to such patients a therapeutically effective amount of a liposomal annamycin formulation (L-Ann).

The present disclosure relates to multimeric oligonucleotides comprising subunits, each of the subunits independently comprises a single-stranded or double-stranded oligonucleotide. Each of the subunits is joined to another subunit by a covalent linker, and at least one subunit comprises at least one partial single-stranded oligonucleotide. The present disclosure also relates to methods of synthesizing the multimeric oligonucleotides and the methods of using the multimeric oligonucleotides disclosed herein.

The present disclosure relates to methods of synthesizing moderate length RNAs by splint-mediated ligation of RNA fragments.

This application relates to therapeutic siRNA agents and methods of making and using the agents.

The invention provides an artificial sgRNA and a CRISPR/Cas9 system by combining the artificial sgRNA and Cas9. Activity of the sgRNA can be retained even when a nucleotide linker region for forming a single strand by linking the 3′-terminal of crRNA and the 5′-terminal of tracrRNA in sgRNA is substituted with an amino acid derivative linker, when the linker region existing between stem-loop 1 and stem-loop 2 of tracrRNA and/or the loop portion of stem-loop 2 are/is substituted with an amino acid derivative linker, or when an amino acid derivative linker is added/inserted into the vicinity of the 5′-terminal and/or the 3′-terminal of sgRNA. Stability in vivo can be improved by introducing one or more amino acid derivative linkers into the sgRNA.

The present disclosure provides a trinucleotide comprising the formula below or an oligomeric compound comprising the formula below:

##STR00001##

The present invention relates to ligand conjugates of oligonucleotides (e.g., iRNA agents) and methods for their preparation. The ligands are derived primarily from monosaccharides These conjugates are useful for the in vivo delivery of oligonucleotides.

The present disclosure falls within the field of biomedical technology, and in particular relates to modified oligonucleotides and a compound that can be used for synthesizing same and a method for modifying oligonucleotides. The present disclosure also relates to the use of the modified oligonucleotides for preventing and/or treating diseases associated with the liver in a subject.

The present disclosure provides polynucleotide guides for use in CRISPR-Cas systems wherein such polynucleotides contain at least one CRISPR abasic restricted nucleotide (CABRNT) and/or at least one CRISPR accuracy via analogs (CAVA) nucleotide. CRISPR guides that contain at least one abasic site and/or at least one base analog, as well as nucleoprotein complexes of CRISPR-Cas proteins and CABRNT, CAVA, and CABRNT-CAVA guides are also described. Also disclosed are methods for making and using the CABRNT, CAVA, and CABRNT-CAVA polynucleotides and guides and the CABRNT/Cas, CAVA/Cas, and CABRNT-CAVA/Cas nucleoprotein complexes of the present invention.