Abstract
Perineural invasion (PNI) is a pivotal prognostic factor in pancreatic cancer associated with aggressive tumor behavior and adverse patient outcomes. The recognized clinical impact of PNI highlights the need to better understand the molecular mechanisms underlying PNI-induced phenotypes. In this study, we isolated PNI-associated cancer-associated fibroblasts (pCAFs), which demonstrated a markedly enhanced capacity to promote neural invasion in pancreatic cancer compared to non-perineural invasion-associated CAFs (npCAFs). Single-cell, high-throughput sequencing and metabolomics data showed a significant upregulation of glycolysis in pCAFs, fostering a high-lactate tumor microenvironment conducive to cancer progression. pCAF-derived lactate was absorbed by tumor cells, facilitating histone H3K18 lactylation. The lactate-induced epigenetic modification activated the transcription of neural invasion-associated genes, such as L1CAM and SLIT1, thereby driving PNI in pancreatic cancer. Further exploration of metabolic reprogramming in pCAFs revealed enhanced acetylation of the glycolytic enzyme GAPDH, which correlated with increased enzymatic activity and glycolytic flux. Targeting of GAPDH and lactylation modifications significantly inhibited neural invasion in a genetically engineered mouse model. Clinical data suggested that high levels of H3K18 lactylation correlate with severe PNI and poorer patient prognosis. Together, these findings provide critical insights into the role of CAFs in promoting PNI of pancreatic cancer, highlighting glycolytic reprogramming and lactate-driven histone modifications as potential therapeutic targets for PDAC.
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