Advancing precision health discovery in a genetically diverse health system
Summary
medRxiv. 2025 Jun 12:2025.06.11.25329386. doi: 10.1101/2025.06.11.25329386. Linking genetic data with electronic health records in hospital biobanks promises to advance precision medicine, but limited ancestral diversity constrains discovery and generalizability. We analyzed 93,936 participants from the UCLA ATLAS Community Health Initiative to inform disease prevalence and genetic risk across five continental and 36 fine-scale ancestry groups. We discovered numerous unreported gene-phenoty
Content
# Advancing precision health discovery in a genetically diverse health system
*Published: 2026 Apr 30*
medRxiv. 2025 Jun 12:2025.06.11.25329386. doi: 10.1101/2025.06.11.25329386.
Linking genetic data with electronic health records in hospital biobanks
promises to advance precision medicine, but limited ancestral diversity
constrains discovery and generalizability. We analyzed 93,936 participants from
the UCLA ATLAS Community Health Initiative to inform disease prevalence and
genetic risk across five continental and 36 fine-scale ancestry groups. We
discovered numerous unreported gene-phenotype associations, including FN3K with
intestinal disaccharidase deficiency in Europeans and admixed Americans.
Polygenic scores (PGS) robustly predicted common diseases, with effects markedly
diminished in non-Europeans. Furthermore, we reduced the pronounced European
bias in curated clinical variants using computational predictors, uncovering
unreported disease-gene associations, including ANKZF1 and peripheral vascular
disease in African Americans. Longitudinal data revealed that semaglutide
efficacy varies across ancestries, is associated with PGS for type 2 diabetes,
and is modulated by genetic variation in PTPRU. These findings illustrate how
ancestrally diverse biobanks from a single health system yield robust disease
associations and pharmacogenomic insights.
DOI: 10.1016/j.cell.2026.03.007