Distinct Transdifferentiation Trajectories and Transcriptional Regulators Differentiate Aneurysmal Remodeling from Atherogenesis

Introduction: Phenotype switching, a pathological process involving dedifferentiation, migration, and transdifferentiation into other cell types—particularly fibrochondrocytes—plays a critical role in both aneurysm formation and atherogenesis. However, the molecular mechanisms that distinguish aneurysmal remodeling from atherogenic progression remain poorly understood.

Methods: To investigate the molecular distinctions between aneurysmal formation and atherogenesis, we integrated the largest single-cell meta-analysis of thoracic aortic aneurysms to date with well-characterized coronary atherosclerosis data. This combined dataset underwent Level 1 annotation followed by manual Level 2 refinement. Pseudotime analysis was employed to trace trajectories and VIPER was utilized to assess differentially upregulated and downregulated regulon that drive each pathological process

Results: Our manual annotation identified distinct fibro chondrocyte-like cell populations that emerged in aneurysmal and atherosclerotic tissues, highlighting separate transdifferentiation trajectories. Pseudotime analysis revealed divergent lineage progression VIPER analysis identified key transcription factors that were differentially regulated between the two conditions, suggesting distinct molecular drivers underlying aneurysmal remodeling versus atherogenic progression. Notably, aneurysm-specific regulons were enriched for pathways related to extracellular matrix degradation whereas atherosclerosis-specific regulons were associated with fibrosis and lipid metabolism

Conclusion: In conclusion, this transcriptomic meta-analysis reveals distinct transdifferentiation trajectories and transcriptional regulatory networks that differentiate aneurysmal remodeling from atherogenic progression. The identification of unique fibrochondrocyte-like populations and their divergent pseudotime trajectories highlights fundamental differences in cellular plasticity between these two vascular pathologies.