Early fibrotic niches establish tumour-permissive microenvironments

Pathologic transformation represents a critical yet poorly defined window during which mutant epithelial stem cells actively construct the microenvironment that enables tumour initiation. Here, using integrated single-cell, spatial, and functional analyses, we define the earliest multicellular events that license this transition following oncogenic activation in the lung. KrasG12D-mutant alveolar type II cells rapidly adopt regenerative-like states that act as signalling hubs, orchestrating coordinated stromal and immune reprogramming while enhancing epithelial plasticity. Through secretion of Amphiregulin (Areg), mutant epithelial cells activate EGFR signalling in adjacent fibroblasts, inducing a fibrotic, injury-like programme. Reprogrammed fibroblasts, in turn, expand and reprogramme alveolar macrophages, amplifying inflammatory signalling and reinforcing epithelial plasticity. These reciprocal interactions establish a self-sustaining epithelial–stromal–immune circuit that generates a tumour-permissive niche prior to malignant outgrowth. Disruption of the Areg–EGFR axis prevents early niche formation and abrogates tumour initiation. Conservation of this programme in KRASG12D-inducible human alveolar organoids and early-stage lung adenocarcinoma tissues identifies epithelial–microenvironment communication as a therapeutically actionable vulnerability and suggests that intercepting niche formation may prevent progression to treatment-resistant disease. Overall design: Human AT2 cell–derived lung organoids from healthy transplant donors were analysed under two conditions: SITTE11 (Control organoids) and SITTF11 (KRASG12D-transduced organoids). Single-cell RNA sequencing using the 10x Genomics Chromium platform was performed to compare gene expression profiles and identify early fibrotic niche formation and cross-compartmental remodelling induced by KRASG12D activation.