Reversible transitions between noradrenergic and mesenchymal tumor identities define cell plasticity in neuroblastoma

Noradrenergic and mesenchymal identities have been characterized in neuroblastoma cell lines according to their epigenetic landscapes and core regulatory circuitries. However, their relationship and relative contribution in patient tumors remain poorly defined. We now document spontaneous and reversible plasticity between the two identities, associated with epigenetic reprogramming, in several neuroblastoma models. Interestingly, xenografts with cells from each identity eventually harbor a noradrenergic phenotype suggesting that the microenvironment provides a powerful pressure towards this phenotype. Accordingly, such a noradrenergic cell identity is systematically observed in single-cell RNA-seq of 18 tumor biopsies and 15 PDX models. Yet, a subpopulation of these noradrenergic tumor cells presents with mesenchymal features that are shared with plasticity models, indicating that the plasticity described in these models has relevance in neuroblastoma patients. This work therefore emphasizes that intrinsic plasticity properties of neuroblastoma cells are dependent upon external cues of the environment to drive cell identity. Noradrenergic and mesenchymal cell states have been proposed in neuroblastoma, but their contributions to the tumour are not clearly understood. Here, the authors used in vitro and in vivo models, as well as single-cell RNA-seq, to characterise noradrenergic and mesenchymal cells and their phenotypic plasticity in neuroblastoma.

Automated summary

Noradrenergic and mesenchymal identities have been characterized in neuroblastoma cell lines. However, their relationship and contribution in patient tumors remain unclear. This study documents spontaneous and reversible plasticity between the two identities, associated with epigenetic reprogramming. The microenvironment plays a role in driving cell identity, as xenografts eventually harbor a noradrenergic phenotype.