Single-cell transcriptome profiling reveals intra-tumoral heterogeneity in human chordomas

Chordoma is a rare and aggressive bone tumor. An accurate investigation of tumor heterogeneity is necessary for the development of effective therapeutic strategies. This study aims to assess the poorly understood tumor heterogeneity of chordomas and identify potential therapeutic targets. Single-cell RNA sequencing was performed to delineate the transcriptomic landscape of chordomas. Six tumor samples of chordomas were obtained, and 33,737 cells passed the quality control test and were analyzed. The main cellular populations identified with specific markers were as follows: chordoma cells (16,052 [47.6%]), fibroblasts (6945 [20.6%]), mononuclear phagocytes (4734 [14.0%]), and T/natural killer (NK) cells (3944 [11.7%]). Downstream analysis of each cell type was performed. Six subclusters of chordomas exhibited properties of an epithelial-like extracellular matrix, stem cells, and immunosuppressive activity. Although few immune checkpoints were detected on cytotoxic immune cells such as T and NK cells, a strong immunosuppressive effect was exerted on the Tregs and M2 macrophages. In addition, the cellular interactions were indicative of enhancement of the TGF-beta signaling pathway being the main mechanism for tumor progression, invasion, and immunosuppression. These findings, especially from the analysis of molecular targeted therapy and tumor immune microenvironment, may help in the identification of therapeutic targets in chordomas.

Automated summary

This study used single-cell RNA sequencing to explore the transcriptomic landscape of chordomas, revealing the heterogeneity of chordomas and identifying the characteristics of epithelial-like extracellular matrix, stem cells, and immunosuppressive activity. The enhancement of the TGF-beta signaling pathway was found to be the main mechanism for tumor progression, invasion, and immunosuppression in chordomas.