An integrated single-cell RNA-seq map of human neuroblastoma tumors and preclinical models uncovers divergent mesenchymal-like gene expression programs.
Richard H ChappleXueying LiuSivaraman NatarajanMargaret I M AlexanderYuna KimAnand G PatelChristy W LaFlammeMin PanWilliam C WrightHyeong-Min LeeYinwen ZhangMeifen LuSelene C KooCourtney LongJohn HarperChandra SavageMelissa D JohnsonThomas ConferWalter J AkersMichael A DyerHeather S SheppardJohn EastonPaul GeeleherPublished in: bioRxiv : the preprint server for biology (2024)
Neuroblastoma is a common pediatric cancer, where preclinical studies suggest that a mesenchymal-like gene expression program contributes to chemotherapy resistance. However, clinical outcomes remain poor, implying we need a better understanding of the relationship between patient tumor heterogeneity and preclinical models. Here, we generated single-cell RNA-seq maps of neuroblastoma cell lines, patient-derived xenograft models (PDX), and a genetically engineered mouse model (GEMM). We developed an unsupervised machine learning approach ('automatic consensus nonnegative matrix factorization' (acNMF)) to compare the gene expression programs found in preclinical models to a large cohort of patient tumors. We confirmed a weakly expressed, mesenchymal-like program in otherwise adrenergic cancer cells in some pre-treated high-risk patient tumors, but this appears distinct from the presumptive drug-resistance mesenchymal programs evident in cell lines. Surprisingly however, this weak-mesenchymal-like program was maintained in PDX and could be chemotherapy-induced in our GEMM after only 24 hours, suggesting an uncharacterized therapy-escape mechanism. Collectively, our findings improve the understanding of how neuroblastoma patient tumor heterogeneity is reflected in preclinical models, provides a comprehensive integrated resource, and a generalizable set of computational methodologies for the joint analysis of clinical and pre-clinical single-cell RNA-seq datasets.
Keyphrases
- rna seq
- single cell
- gene expression
- machine learning
- bone marrow
- stem cells
- high throughput
- case report
- cell therapy
- mouse model
- dna methylation
- public health
- quality improvement
- chemotherapy induced
- endothelial cells
- deep learning
- squamous cell carcinoma
- artificial intelligence
- radiation therapy
- locally advanced
- replacement therapy
- neural network