Cell type-resolved long-read transcriptomics of the human cortex reveals pervasive alternative splicing and disease-relevant isoforms

Alternative splicing generates extensive transcriptomic diversity in the human brain, but the full cell type-resolved landscape of isoform variation remains unresolved due to the constraints of short-read sequencing. Here, we integrated fluorescence-activated nuclei sorting with long-read (PacBio Iso-Seq) and short-read (Illumina) RNA sequencing to generate isoform-resolved transcriptomes of five major cortical cell types, including MGE-derived GABAergic neurons, glutamatergic neurons, oligodendrocytes, astrocytes, and microglia from adult dorsolateral and orbitofrontal cortex. We identified more than 220,000 unique full-length isoforms, 35-56% of which were previously unannotated depending on cell type and region. These novel isoforms were longer, contained more exons, and displayed greater coding potential than annotated transcripts. Glial populations, particularly oligodendrocytes and microglia, exhibited the greatest isoform diversity, with more than half of all isoforms displaying strong cell type-specific expression. Differential transcript usage revealed pervasive cell-specific splicing, including in genes central to neuronal and glial function such as SLC5A6 and TWF1. Many newly discovered isoforms intersected with genetic risk variants for neurological disorders, including for POGZ, FOXP1, and DYRK1A, suggesting that isoform diversification may contribute to disease risk. This resource provides a comprehensive, cell type-resolved atlas of isoform diversity in the human cortex and establishes a foundation for mechanistic studies of RNA regulation and disease vulnerability in the brain.