Long-read RNA-seq resolves isoform-level and context-specific regulatory architecture of complex traits in cattle

Traditional short-read RNA-seq lacks the resolution to fully capture full-length isoforms and complex alternative splicing, leaving a "missing regulation" gap in existing molecular atlases. Here, we present a population-scale, multi-omics dissection of bovine complex traits using matched deep whole-genome sequencing (30), long-read (ONT) and short-read RNA-seq, as well as metabolome data from 432 dairy cows across four distinct lactation stages. We expanded the bovine transcript atlas with 13,177 novel isoforms and fine-mapped 1,088,900 regulatory effects across 11 diverse molecular phenotypes. Notably, long-read mapping uncovered 606 genes with isoform expression quantitative trait loci (12.8%, eQTL) and 1,116 genes with detailed splicing QTL (sQTL) (31.8%) that were missed by conventional short-read mapping. We further showed that lactation-specific regulation was profoundly mediated by the metabolic microenvironment (46.8%) and cellular composition (4.3%). Across genome-wide associations (GWAS) of 90 bovine complex traits, isoform-level and context-specific regulatory effects captured GWAS loci missed by short-read eQTL and sQTL analyses, increasing colocalized loci from 35.2% to 60.3%. These regulatory variants also exhibited evolutionary constraints with human immune and metabolic loci. Our study establishes an invaluable resource (https://cattleblr.farmgtex.org) demonstrating that long-read transcriptomics is essential for resolving the complexity of regulatory mechanisms underlying mammalian physiology.