Background: The Tibetan pig, a highland breed with exceptional adaptability to harsh environments (cold, hypoxia, coarse feed) but poor growth/reproductive traits, was studied to uncover genetic mechanisms and support breeding improvements. Methods: We conducted de novo genome assembly of a male Tibetan pig using stLFR sequencing, supplemented with ONT data, and compared the assembly to the Duroc pig genome (v11.1). Results: The assembled genome (2.25 Gb, contig N50 = 136.5 Mb, GC content = 41.74%, 94.16× coverage) showed 96.9% BUSCO completeness. Structural variant (SV) analysis identified 22,008 insertions and 27,639 deletions, with an SV genotyping accuracy of 0.9735. Selective sweep analysis highlighted adaptive genes: XIRP2 (cardiac function), KSR2/CACNA1A (fat metabolism), COL11A1 (cartilage), and ADORA2A (vascular regulation). Tibetan pigs exhibited the fewest and shortest runs of homozygosity (ROHs) among four breeds, with ROH-linked SNPs implicating lipid catabolism genes (LIPE, PNPLA2, MGLL, DGAT1). An SNP-based GWAS revealed reproductive trait associations: immune gene IL2RB, energy metabolism genes PRKAG2, ADGRA1, and PTPRN2, and growth genes SLIT2 and BMP6. SV analysis identified additional candidates: energy metabolism genes HAO2 and NRG4, growth genes MTUS2 and FGF12, and immune genes SCGB1A1 and C8A. Conclusions: This study provides a chromosome-level genome assembly of a male Tibetan pig (generated from stLFR and ONT data), and, through whole-genome resequencing of 124 Tibetan sows, identifies key genetic factors underlying Tibetan pigs’ environmental adaptability and reproductive limitations, enabling genomic strategies to enhance breeding efficiency while preserving adaptive traits.
Duan et al. (Thu,) studied this question.