The disclosure provides programmable methylation “writers” and demethylation “erasers” for editing the methylation state of RNA targets, e.g., an RNA transcriptome. In particular, the disclosure provides RNA methylation editor polynucleotide contracts and vectors comprising (i) an RNA programmable RNA binding domain (RNApRNAbd); and (ii) an effector domain, wherein the effector domain is capable of adding or removing a methyl group in an RNA. The disclosed RNA methylation editor constructs are capable of achieving limited off-target modifications in RNA molecules. Further, the disclosure provides methods for making and using the programmable methylation editors to modifying the methylation state of RNA. The disclosure further provides complexes comprising a methylation writer protein and a guide RNA molecule and complexes comprising a demethylation eraser protein and a guide RNA molecule. The disclosure further provides pharmaceutical compositions and cells comprising the disclosed fusion proteins and complexes.

This invention is related to a therapeutic agent for treating chronic kidney disease comprising a substance which inhibits the enzymatic activity of NNMT or suppresses NNMT gene expression, or a method for screening a therapeutic agent for treating chronic kidney disease which targets the NNMT enzyme or NNMT gene.

This invention is related to a therapeutic agent for treating chronic kidney disease comprising a substance which inhibits the enzymatic activity of NNMT or suppresses NNMT gene expression, or a method for screening a therapeutic agent for treating chronic kidney disease which targets the NNMT enzyme or NNMT gene.

The disclosure provides programmable methylation writers and demethylation erasers for editing the methylation state of RNA targets, e.g., an RNA transcriptome. In particular, the disclosure provides RNA methylation editor polynucleotide contracts and vectors comprising (i) an RNA programmable RNA binding domain (RNApRNAbd); and (ii) an effector domain, wherein the effector domain is capable of adding or removing a methyl group in an RNA. The disclosed RNA methylation editor constructs are capable of achieving limited off-target modifications in RNA molecules. Further, the disclosure provides methods for making and using the programmable methylation editors to modifying the methylation state of RNA. The disclosure further provides complexes comprising a methylation writer protein and a guide RNA molecule and complexes comprising a demethylation eraser protein and a guide RNA molecule. The disclosure further provides pharmaceutical compositions and cells comprising the disclosed fusion proteins and complexes.

The disclosure provides programmable methylation writers and demethylation erasers for editing the methylation state of RNA targets, e.g., an RNA transcriptome. In particular, the disclosure provides RNA methylation editor polynucleotide constructs and vectors comprising (i) an RNA programmable RNA binding domain (RNApRNAbd); and (ii) an effector domain, wherein the effector domain is capable of adding or removing a methyl group in an RNA. The disclosed RNA methylation editor constructs are capable of achieving limited off-target modifications in RNA molecules. Further, the disclosure provides methods for making and using the programmable methylation editors to modifying the methylation state of RNA. The disclosure further provides complexes comprising a methylation writer protein and a guide RNA molecule and complexes comprising a demethylation eraser protein and a guide RNA molecule. The disclosure further provides pharmaceutical compositions and cells comprising the disclosed fusion proteins and complexes.