The present specification provides a drug that causes highly-efficient skipping of exon 51 in the human dystrophin gene. The present specification provides an antisense oligomer having an activity to induce skipping of exon 51 in the human dystrophin gene.

Disclosed herein are nucleic acid molecules, polypeptides, cells, vectors, and pharmaceutical compositions relating to miniaturized dystrophin. Methods of production and methods of therapeutic use of the miniaturized dystrophin are also disclosed.

The invention relates to compositions and methods for improving a dystrophic phenotype in a human subject having myopathies, such as Duchenne Muscular Dystrophy (DMD). In one embodiment, the invention relates to compositions comprising an adenoviral vector targeting the let-7c miRNA binding sequence in 3′-UTR genome editing of the utrophin gene and methods of treatment comprising administration thereof.

A duchenne muscular dystrophy-related exonic splicing enhancer, sgRNA and gene editing tool can be applied in the preparation of drugs for treating duchenne muscular dystrophy. The gene editing tool designed on the basis of cytosine deaminase AID mutants and Cas9 mutants can perform site-specific modification on a mammalian genome by using an adeno-associated virus (AAV) as a vector. By optimizing an encoding nucleic acid sequence and an element composition structure of the editing tool, site-specific targeted modification of mammalian genetic material DNA can be efficiently achieved; and by performing targeted genetic manipulation on the nucleic acid sequence carrying disease mutations, a pathogenic mutation cannot be retained in a mature protein amino acid sequence or the pathogenic mutation cannot perform its function, so that the purpose of treating various gene mutation type genetic rare diseases is achieved, and the advantages of high efficiency, safety and stability are achieved.

The present invention concerns a novel short promoter characterized by a high activity in the skeletal muscles and a low activity in the heart. It then constitutes a valuable candidate especially for driving the expression of transgenes encoding proteins useful for the treatment of muscular dystrophies.

The present disclosure encompasses engineered meganucleases that bind and cleave recognition sequences within a dystrophin gene. The present disclosure also encompasses methods of using such engineered meganucleases to make genetically modified cells. Further, the disclosure encompasses pharmaceutical compositions comprising engineered meganuclease proteins, or polynucleotides encoding engineered meganucleases of the disclosure, and the use of such compositions for the modification of a dystrophin gene in a subject, or for treatment of Duchenne Muscular Dystrophy.

The present invention provides an oligomer which efficiently enables to cause skipping of the 53rd exon in the human dystrophin gene. Also provided is a pharmaceutical composition which causes skipping of the 53rd exon in the human dystrophin gene with a high efficiency.

The present invention relates to recombinant adeno-associated virus (rAAV) delivery of polynucleotides for treating Duchenne Muscular Dystrophy resulting from the duplication of DMD exon 2. The invention provides rAAV products and methods of using the rAAV in the treatment of Duchenne Muscular Dystrophy.

The invention provides for recombinant AAV vectors comprising a polynucleotide sequence comprising the guide strand of miR-29c and methods of using the recombinant vectors to reduce or prevent fibrosis in subjects suffering from dystrophinopathy or muscular dystrophy. The invention also provides for combination therapies comprising expressing both miR-29 and micro-dystrophin to reduce and prevent fibrosis in patients suffering from dystrophinopathy or muscular dystrophy.

An in vitro electrical conductor is provided. The in vitro electrical conductor may include a plurality of Calsequestrin (CSQ) protein molecules. The CSQ protein molecules may be connected to form a tendril, a network structure, or a biological tunnel structure. An electrical device including the in vitro electrical conductor is provided. An ionic transistor including the in vitro electrical conductor is provided. An in vitro method of conducting ions from an ion source to an ion sink is further provided. The method may include providing an electrical conductor including a plurality of CSQ protein molecules and conducting ions through the electrical conductor to the ion sink. The CSQ protein molecules may be connected to form a tendril, a network structure, or a biological tunnel structure.