Disruption of ADAMTSL4 Causes Ectopia Pupillae in Zebrafish via COL8A1-Driven Cell Migration

Congenital ectopia lentis (EL) poses a significant threat to visual outcomes in children. Although emerging causative genes have been identified, their biological functions remain poorly understood. In this study, we investigated the contribution of ADAMTSL4 variants to congenital EL in a cohort of 702 pedigrees. Pathogenic variants in ADAMTSL4 were identified in 23 probands (3.28%), comprising 29 distinct variants, with 14 being novel, making ADAMTSL4 the second most frequently mutated gene in the cohort. All affected individuals exhibited EL, and 26.09% also presented with ectopia pupillae (EP), also referred to as ectopia lentis et pupillae. To explore the functional consequences of ADAMTSL4 deficiency, we generated a CRISPR/Cas9-mediated adamtsl4 -knockout zebrafish model, that faithfully recapitulated cardinal human disease features with an incidence comparable to that observed in affected patients. Histological and ultrastructural analysis revealed disrupted zonular fiber anchorage at the lens capsule, even in mutated eyes without overt EL or EP. Transgenic overexpression of adamtsl4 successfully reversed the ocular phenotypes, confirming the gene’s essential role in ocular development. Single-cell RNA-sequencing and fluorescence in situ hybridization demonstrated enriched ADAMTSL4/adamtsl4 expression in the equatorial lens epithelium, retinal pigment epithelium (RPE), iris anterior pigmented epithelium, and choroid fibroblast. Functional assays using zebrafish and human RPEs revealed that ADAMTSL4 deficiency compromised cell adhesion and promoted cell migration. Transcriptomic profiling revealed significant enrichment of extracellular matrix organization and cell adhesion pathways, with cross-species validation identifying consistent upregulation of COL8A1/col8a1b . Notably, COL8A1 knockdown in ADAMTSL4 -deficient RPEs partially reversed the aberrant migratory phenotype, suggesting a functional interaction. Together, these findings establish ADAMTSL4 as a major causative gene in ectopia lentis et pupillae, highlight its role in orchestrating ocular integrity via regulation of extracellular matrix and cell behavior.