Single-cell long-read sequencing-based mapping reveals specialized splicing patterns in developing and adult mouse and human brain.
Anoushka JoglekarWen HuBei ZhangOleksandr NarykovMark E DiekhansJordan MarroccoJennifer BalaccoLishomwa C NdhlovuTeresa A MilnerOlivier FedrigoErich D JarvisGloria M SheynkmanDmitry KorkinMargaret Elizabeth RossHagen U TilgnerPublished in: Nature neuroscience (2024)
RNA isoforms influence cell identity and function. However, a comprehensive brain isoform map was lacking. We analyze single-cell RNA isoforms across brain regions, cell subtypes, developmental time points and species. For 72% of genes, full-length isoform expression varies along one or more axes. Splicing, transcription start and polyadenylation sites vary strongly between cell types, influence protein architecture and associate with disease-linked variation. Additionally, neurotransmitter transport and synapse turnover genes harbor cell-type variability across anatomical regions. Regulation of cell-type-specific splicing is pronounced in the postnatal day 21-to-postnatal day 28 adolescent transition. Developmental isoform regulation is stronger than regional regulation for the same cell type. Cell-type-specific isoform regulation in mice is mostly maintained in the human hippocampus, allowing extrapolation to the human brain. Conversely, the human brain harbors additional cell-type specificity, suggesting gain-of-function isoforms. Together, this detailed single-cell atlas of full-length isoform regulation across development, anatomical regions and species reveals an unappreciated degree of isoform variability across multiple axes.
Keyphrases
- single cell
- rna seq
- high throughput
- preterm infants
- cell therapy
- endothelial cells
- stem cells
- young adults
- white matter
- high resolution
- poor prognosis
- metabolic syndrome
- genome wide
- mental health
- type diabetes
- cerebral ischemia
- mesenchymal stem cells
- skeletal muscle
- blood brain barrier
- bone marrow
- body composition
- amino acid
- induced pluripotent stem cells