Mapping PTBP2 binding in human brain identifies SYNGAP1 as a target for therapeutic splice switching.
Jennine M Dawicki-McKennaAlex J FelixElisa A WaxmanCongsheng ChengDefne A AmadoPaul T RanumAlexey BogushLea V DunganJean Ann MaguireAlyssa L GagneElizabeth A HellerDeborah L FrenchBeverly L DavidsonBenjamin L ProsserPublished in: Nature communications (2023)
Alternative splicing of neuronal genes is controlled partly by the coordinated action of polypyrimidine tract binding proteins (PTBPs). While PTBP1 is ubiquitously expressed, PTBP2 is predominantly neuronal. Here, we define the PTBP2 footprint in the human transcriptome using brain tissue and human induced pluripotent stem cell-derived neurons (iPSC-neurons). We map PTBP2 binding sites, characterize PTBP2-dependent alternative splicing events, and identify novel PTBP2 targets including SYNGAP1, a synaptic gene whose loss-of-function leads to a complex neurodevelopmental disorder. We find that PTBP2 binding to SYNGAP1 mRNA promotes alternative splicing and nonsense-mediated decay, and that antisense oligonucleotides (ASOs) that disrupt PTBP binding redirect splicing and increase SYNGAP1 mRNA and protein expression. In SYNGAP1 haploinsufficient iPSC-neurons generated from two patients, we show that PTBP2-targeting ASOs partially restore SYNGAP1 expression. Our data comprehensively map PTBP2-dependent alternative splicing in human neurons and cerebral cortex, guiding development of novel therapeutic tools to benefit neurodevelopmental disorders.
Keyphrases
- endothelial cells
- induced pluripotent stem cells
- genome wide
- spinal cord
- end stage renal disease
- gene expression
- poor prognosis
- drug delivery
- high resolution
- spinal cord injury
- dna methylation
- high density
- oxidative stress
- peritoneal dialysis
- brain injury
- machine learning
- genome wide identification
- cancer therapy
- white matter
- artificial intelligence
- single cell
- transcription factor
- congenital heart disease
- prognostic factors
- african american