The present invention relates to a technique capable of treating a retinal neurodegenerative disease through regeneration of a retinal nerve by targeting Prox1 in the mammalian retina using an inhibitor which inhibits Prox1 expression or migration. According to the present invention, inducing the regeneration of the damaged retina in mammals, and thus can be commonly applied to the treatment of various retinal neurodegenerative diseases causing vision loss, and furthermore, when combining with a selective retinal nerve differentiation method or the like, it is expected that the method can be used for the development of an innovative retinal regeneration method capable of selectively regenerating only specific degenerating retinal neurons.

A gene editing system comprising: (a) a Type V CRISPR nuclease polypeptide or a first nucleic acid encoding the Type V CRISPR nuclease polypeptide; (b) a reverse transcriptase (RT) polypeptide or a second nucleic acid encoding the RT polypeptide; (c) a guide RNA (gRNA) or a third nucleic acid encoding the gRNA, wherein the gRNA comprises one or more binding sites recognizable by the Type V CRISPR nuclease (CRISPR nuclease binding sites) and a spacer sequence specific to a target sequence within a genomic site of interest, the target sequence being adjacent to a protospacer adjacent motif (PAM); and (d) a reverse transcription donor RNA (RT donor RNA) or a fourth nucleic acid encoding the RT donor RNA, wherein the RT donor RNA comprises a primer binding site (PBS) and a template sequence.

The present disclosure provides methods of treating subjects having hypertension, coronary heart disease, and/or atrial fibrillation or at risk of developing hypertension, coronary heart disease, and/or atrial fibrillation, methods of identifying subjects having an increased risk of developing hypertension, coronary heart disease, and/or atrial fibrillation, and methods of detecting Solute Carrier Family 9 Isoform A3 Regulatory Factor 2 (SLC9A3R2) variant nucleic acid molecules and variant polypeptides.

The present disclosure provides methods of treating a subject having decreased bone mineral density or at risk of developing decreased bone mineral density, and methods of identifying subjects having an increased risk of developing decreased bone mineral density.

The present disclosure relates to methods for increasing telomere length in one or more human cells and/or increasing genome stability of one or more human cells, for example by contacting one or more human cells with an agent that increases expression of Zscan4 in the one or more human cells. Methods of treating a subject in need of telomere lengthening, treating a disease or condition associated with a genomic and/or chromosome abnormality, of rejuvenating one or more human cells, of rejuvenating tissues or organs, and of rejuvenating a subject in need thereof, for example by contacting one or more human cells in the subject with an agent that increases expression of Zscan4, or by administering to a subject in need thereof, an agent that increases expression of Zscan4 are also provided.

The present invention is directed to methods and compositions of RNA nanostructures for replication and/or subgenomic expression of gene modulating single-stranded RNA by RNA-directed RNA polymerase-like proteins and the use of such nanostructures for use in a variety of organisms.

The present invention is directed to methods and compositions of RNA nanostructures for replication and/or subgenomic expression of gene modulating single-stranded RNA by RNA-directed RNA polymerase-like proteins and the use of such nanostructures for use in a variety of organisms.

Provided herein is a method of reprogramming a non-neuronal cell to a neuron. Aspects of the present disclosure relate to using cell reprogramming agent suppresses the expression or activity of PTB to convert a non-neuronal cell into a neuron. Also provided herein is a method of treating neurodegenerative disease by reprogramming non-neuronal cells in vivo to functional neurons.

Methods for reactivating genes on the inactive X chromosome that include administering one or both of a DNA methyltransferase (DNMT) Inhibitor and/or a topoisomerase inhibitor, e.g., etoposide and/or 5′-azacytidine (aza), optionally in combination with an inhibitor of XIST RNA and/or an Xist-interacting protein, e.g., a chromatin-modifying protein, e.g., a small molecule or an inhibitory nucleic acid (such as a small inhibitory RNA (siRNAs) or antisense oligonucleotide (ASO)) that targets XIST RNA and/or a gene encoding an Xist-interacting protein, e.g., a chromatin-modifying protein.

Methods for reactivating genes on the inactive X chromosome that include administering one or both of a DNA methyltransferase (DNMT) Inhibitor and/or a topoisomerase inhibitor, e.g., etoposide and/or 5′-azacytidine (aza), optionally in combination with an inhibitor of XIST RNA and/or an Xist-interacting protein, e.g., a chromatin-modifying protein, e.g., a small molecule or an inhibitory nucleic acid (such as a small inhibitory RNA (siRNAs) or antisense oligonucleotide (ASO)) that targets XIST RNA and/or a gene encoding an Xist-interacting protein, e.g., a chromatin-modifying protein.