Early Pulmonary Fibrosis is Defined by Niche- and Cell-Specific Molecular Programs

Rationale: Preclinical familial pulmonary fibrosis (FPF) represents an early stage of fibrotic lung disease, yet the compartment- and cell-specific molecular programs preceding fibrosis remain poorly understood. Objective: To define spatially organized molecular signatures associated with preclinical FPF and identify tissue-informed circulating biomarkers linked to early fibrotic remodeling. Methods: We performed integrated multi-omic profiling of histologically preserved and remodeled lung regions from subjects with preclinical FPF, Idiopathic Pulmonary Fibrosis (IPF), and controls using spatial transcriptomics, single-nucleus RNA sequencing (snRNAseq), and blood proteomics. Differential expression and pathway enrichment analyses were performed across spatial compartments and epithelial cell states. Results: Histologically preserved lung regions in preclinical FPF demonstrated transcriptional abnormalities including stress-response, ciliary, and extracellular matrix-associated programs despite minimal architectural distortion. Spatial analyses identified alterations in alveolar niche molecular programs accompanied by increasing profibrotic signaling across preserved and tissue remodeled lung compartments. Compared with advanced IPF, preclinical FPF retained epithelial repair and surfactant-associated signatures. Integration with snRNAseq demonstrated enrichment of alveolar and airway epithelial cell dysregulated states associated with transitional phenotypes previously implicated in IPF. Compartment- and epithelial-associated transcriptional signatures identified in lung tissue were partially represented in the peripheral blood. Conclusion: Preclinical FPF is characterized by compartment- and cell-specific molecular programs that precede established fibrosis. We identified distinct alveolar, airway, and vascular molecular signatures and epithelial remodeling states represented in the peripheral blood. These findings provide an initial framework for molecular classification of early stages of pulmonary fibrosis and support future studies evaluating minimally invasive approaches for disease stratification and precision therapeutics.