Abstract
BACKGROUND: Atopic dermatitis (AD), food sensitization (FS), and food allergy (FA) frequently co-occur in infancy, but the factors driving distinct atopic phenotypes remain unclear. While FLG null mutations are major genetic risk factors for AD, they explain only a fraction of disease heritability, suggesting a potential role for the skin microbiome. OBJECTIVE: To determine how early-life skin microbiome composition and its interaction with host genetics contribute to distinct atopic phenotypes in infancy. METHODS: We analyzed >1,000 skin swabs from 429 infants in the VITALITY cohort using deep shotgun metagenomic sequencing at 2-3 months (pre-diagnosis) and 12 months (post-diagnosis). Differential abundance, strain-level, and microbial genome-wide association analyses were performed to identify taxonomic and functional features associated with AD, FS, FA, and their co-occurrence, as well as with FLG mutation status. RESULTS: Within AD, microbial signatures differed by co-occurring FA or FS. At 12 months, Staphylococcus epidermidis was enriched in infants with AD alone, whereas infants with AD and FA exhibited decreased Staphylococcus hominis and Lactococcus species, along with increased Dermacoccus nishinomiyaensis and Malassezia slooffiae. At 2-3 months, early skin dysbiosis characterized by enrichment of Staphylococcus species was associated with subsequent development of AD with FS or FA, but not AD alone. Among infants with AD, FLG mutation carriers exhibited additional microbial shifts, including reduced Streptococcus species and increased Malassezia slooffiae. Strain-level analyses revealed mother-infant sharing of skin microbial taxa associated with AD, and microbial genome-wide association analyses identified species-specific genes linked to AD severity. CONCLUSIONS: Infant atopic phenotypes are associated with distinct, phenotype-specific features of the skin microbiome that emerge both before and after clinical disease onset. By resolving microbial differences within AD according to allergic co-occurrence, host genetics, and early-life timing, this study highlights the infant skin microbiome as a potential target for early risk stratification.