Single-cell RNA-seq reveals breast cancer heterogeneity and identifies TCP1 as a therapeutic target in breast cancer.
Houman Wu, Haiyang Du, Gao Si, Xuejie Song, Fuchun Si
Abstract
Open AccessBreast cancer is composed of diverse cell populations, and this intratumoral heterogeneity profoundly affects clinical behavior. Here, we leveraged single cell RNA sequencing (scRNA-seq) of 68 breast cancer specimens to dissect tumor heterogeneity at high resolution. Unsupervised clustering identified all major cell types of the tumor microenvironment (TME)-including malignant epithelial cells, fibroblasts, T cells, macrophages, endothelial cells, and others-with striking variability in their proportions across molecular subtypes. For example, a BRCA1-mutant triple-negative breast cancer (TNBC) sample showed dense immune infiltration, whereas an estrogen receptor (ER)-positive tumor was mostly epithelial, consistent with known subtype differences in immunogenicity. We applied inference of copy number variations (inferCNV) to distinguish malignant epithelial cells, identifying ~90,000 tumor cells with significant copy-number aberrations enriched for cancer hallmark pathways. Re-clustering of these malignant cells revealed five discrete subpopulations. Notably, a KRT17-positive subcluster displayed the highest stemness score and a distinctive ETS-family transcription factor (ERG) regulon, suggesting a stem-like phenotype. Using The Cancer Genome Atlas (TCGA) cohort, we found that genes upregulated in this KRT17+ subpopulation, particularly NFKBIA, PDLIM4, and TCP1 stratified patient survival. An 8-gene risk signature derived from the KRT17 program segregated patients into high- and low-risk groups with markedly different outcomes. High-risk tumors were characterized by an immunosuppressive TME enriched in M2-like macrophages, whereas low-risk tumors more often harbored lymphocyte-predominant infiltrates. Focusing on TCP1, a chaperonin subunit upregulated in high-risk tumors, we demonstrate that TCP1 knockdown in breast cancer cell lines substantially impairs cell migration (~50% reduction in wound closure) and invasion (P < 0.01). These findings reveal functionally distinct malignant cell states within breast cancer and identify TCP1 as a promising therapeutic target to disrupt aggressive, stem-like tumor cell programs, ultimately guiding more personalized treatment strategies.