Non-canonical ALK7 pathways promote pancreatic cancer metastasis through ß-catenin/MMP-mediated basement membrane breakdown and intravasation

Breaching the vascular barrier is a critical step in pancreatic ductal adenocarcinoma (PDAC) metastasis, yet the mechanisms enabling this process to remain incompletely understood. This study identifies two distinct but interconnected ALK7-driven non-canonical pathways that promote PDAC dissemination. The ALK7–ß-catenin–EMT axis enhances intrinsic tumor cell motility, driving epithelial–mesenchymal transition (EMT) and cytoskeletal remodeling. In parallel, the ALK7–ß-catenin–MMP axis facilitates metastatic invasion by upregulating MMP production, leading to ECM degradation and invadosome formation, which promote vascular barrier breakdown. An orthotopic PDAC metastasis model reveals that both pharmacological and genetic ALK7 inhibition suppresses lung metastasis, emphasizing its role in facilitating tumor invasion. A 3D microfluidic vessel-on-chip platform further demonstrates that ALK7 inhibition preserves basement membrane (BM) integrity, limiting intravasation without affecting extravasation. While MMP inhibition effectively blocks BM breakdown and intravasation, extravasation remains unaffected, highlighting distinct molecular requirements for different metastatic stages. These findings establish ALK7 as a dual-function pro-metastatic regulator that orchestrates both tumor cell plasticity and ECM remodeling, positioning ALK7 inhibition as a promising strategy to target early metastatic dissemination in PDAC. Overall design: To minimize the risk and determine the exact roles of ALK7 in PDAC cells, we performed short hairpin RNA (shRNA) mediated ALK7 knockdown (KD) in PDAC cells prior to inoculating them into animals. We then performed gene expression profiling analysis using data obtained from RNA-seq of 2 different cells. Comparative gene expression profiling analysis of RNA-seq data for PDAC cells and its KD derivative shALK7