New dosing regimens for treating muscular dystrophy in a patient suffering from Duchenne muscular dystrophy (DMD) with an antisense oligonucleotide conjugate that causes skipping of an exon in the human dystrophin gene are described. Also described is a method of treating a patient with an antisense oligomer CPP conjugate and a magnesium supplement.

The present disclosure relates to RNA amidates and thioamidates useful for RNA interference applications. The RNA amidates and thioamidates contain at least one internucleoside linkage chosen from ribo-N3′.fwdarw.P5′ phosphoramidate (NP) and ribo-N3′.fwdarw.P5′ thiophosphoramidate (NPS) linkages, and optionally further containing at least one covalently conjugated lipid moiety. Compositions comprising the amidates and thioamidates are disclosed, as are methods for their use in modulating gene expression.

The present disclosure provides a solid phase method of making oligonucleotides via sequential coupling cycles including at least one coupling of a dinucleotide dimer subunit to a free 3′-terminal group of a growing chain. The oligonucleotides include at least two nucleoside subunits joined by a N3′.fwdarw.P5′ phosphoramidate linkage. The method may include the steps of (a) deprotecting the protected 3′ amino group of a terminal nucleoside attached to a solid phase support, said deprotecting forming a free 3′ amino group; (b) contacting the free 3′ amino group with a 3′-protected amino-dinucleotide-5′-phosphoramidite dimer in the presence of a nucleophilic catalyst to form an internucleoside N3′.fwdarw.P5′ phosphoramidite linkage; and (c) oxidizing (e.g., sulfurizing) the linkage. The compositions produced by the subject methods may include a reduced amount of one or more (N−x) oligonucleotide products. Also provided are pharmaceutical compositions including the subject oligonucleotide compositions.

The present disclosure provides a solid phase method of making oligonucleotides via sequential coupling cycles including at least one coupling of a dinucleotide dimer subunit to a free 3′-terminal group of a growing chain. The oligonucleotides include at least two nucleoside subunits joined by a N3′.fwdarw.P5′ phosphoramidate linkage. The method may include the steps of (a) deprotecting the protected 3′ amino group of a terminal nucleoside attached to a solid phase support, said deprotecting forming a free 3′ amino group; (b) contacting the free 3′ amino group with a 3′-protected amino-dinucleotide-5′-phosphoramidite dimer in the presence of a nucleophilic catalyst to form an internucleoside N3′.fwdarw.P5′ phosphoramidite linkage; and (c) oxidizing (e.g., sulfurizing) the linkage. The compositions produced by the subject methods may include a reduced amount of one or more (N−x) oligonucleotide products. Also provided are pharmaceutical compositions including the subject oligonucleotide compositions.

Methods of using B2 or Alu nucleic acids, or antisense oligonucleotides that modulate the EZH2/B2 or EZH2/Alu interaction and have the capacity to alter cleavage of B2 and Alu RNA, for increasing or decreasing cell and organismal viability.

The present disclosure provides a solid phase method of making oligonucleotides via sequential coupling cycles including at least one coupling of a dinucleotide dimer subunit to a free 3′-terminal group of a growing chain. The oligonucleotides include at least two nucleoside subunits joined by a N3′.fwdarw.P5′ phosphoramidate linkage. The method may include the steps of (a) deprotecting the protected 3′ amino group of a terminal nucleoside attached to a solid phase support, said deprotecting forming a free 3′ amino group; (b) contacting the free 3′ amino group with a 3′-protected amino-dinucleotide-5′-phosphoramidite dimer in the presence of a nucleophilic catalyst to form an internucleoside N3′.fwdarw.P5′ phosphoramidite linkage; and (c) oxidizing (e.g., sulfurizing) the linkage. The compositions produced by the subject methods may include a reduced amount of one or more (N−x) oligonucleotide products. Also provided are pharmaceutical compositions including the subject oligonucleotide compositions.

The present disclosure provides a solid phase method of making oligonucleotides via sequential coupling cycles including at least one coupling of a dinucleotide dimer subunit to a free 3′-terminal group of a growing chain. The oligonucleotides include at least two nucleoside subunits joined by a N3′.fwdarw.P5′ phosphoramidate linkage. The method may include the steps of (a) deprotecting the protected 3′ amino group of a terminal nucleoside attached to a solid phase support, said deprotecting forming a free 3′ amino group; (b) contacting the free 3′ amino group with a 3′-protected amino-dinucleotide-5′-phosphoramidite dimer in the presence of a nucleophilic catalyst to form an internucleoside N3′.fwdarw.P5′ phosphoramidite linkage; and (c) oxidizing (e.g., sulfurizing) the linkage. The compositions produced by the subject methods may include a reduced amount of one or more (N−x) oligonucleotide products. Also provided are pharmaceutical compositions including the subject oligonucleotide compositions.

The present disclosure relates to antisense oligomers and related compositions and methods for inducing exon inclusion as a treatment for glycogen storage disease type II (GSD-II) (also known as Pompe disease, glycogenosis II, acid maltase deficiency (AMD), acid alpha-glucosidase deficiency, and lysosomal alpha-glucosidase deficiency), and more specifically relates to inducing inclusion of exon 2 and thereby restoring levels of enzymatically active acid alpha-glucosidase (GAA) protein encoded by the GAA gene.

Treatment of prostate cancer by regional and prolonged release of one or more nucleotide-based RNAi agents is provided.

Disclosed herein are oligonucleotide conjugates and pharmaceutical compositions for inducing multi-exon skipping. In some instances, also disclosed herein are methods of treating a muscular dystrophy, including treating Duchenne muscular dystrophy or Becker muscular dystrophy.