Spatiotemporal secondary hair follicle development in the Lanyu pig (Sus scrofa taivanus): a novel pelage hair follicle model

Large full-thickness (LFT) skin wounds remain a major clinical challenge, and progress in regenerative medicine has been limited by poor translation from animal models to humans. A key limitation is that commonly used species such as mice, rats, and rabbits are loose-skinned, whereas humans are tight-skinned with distinct skin architecture. Although pigs more closely resemble human skin, widely used breeds have lost secondary (vellus-like) hair follicles through artificial selection, restricting their utility for studying ectodermal organ regeneration. Here, we characterize the development, patterning, and molecular features of secondary hair follicles in the Lanyu pig (Sus scrofa taivanus), an indigenous breed that retains these structures. Whole-mount and histological analyses revealed two distinct follicle populations: primary follicles arranged in stable triplet clusters and smaller secondary follicles distributed interstitially. A developmental time course using alkaline phosphatase (ALP) staining identified sequential stages of secondary follicle morphogenesis--placode, hair germ, hair peg, and mature follicle--occurring after primary follicle establishment. Immunohistochemical analysis demonstrated conserved epithelial- mesenchymal interactions, progressive epithelial stratification, and dynamic {beta}-catenin signaling during secondary follicle development. Keratin expression patterns and follicular architecture closely resembled those of human vellus hair follicles, supporting the translational relevance of this model. Notably, secondary follicles were retained into adulthood, and genetic analyses of outcrossed animals suggest that this trait follows an autosomal dominant inheritance pattern. Together, these findings establish the Lanyu pig as a tight-skinned mammalian model that preserves vellus-like hair follicles, providing a platform for investigating hair follicle-mediated skin regeneration and improving translational relevance for human wound healing.