posted on 2025-04-09, 13:20authored byPaola Peinado, Marco Stazi, Claudio Ballabio, Michael-Bogdan Margineanu, Zhaoqi Li, Caterina I Colón, Min-Shu Hsieh, Shreoshi Pal Choudhuri, Victor Stastny, Seth Hamilton, Alix Le Marois, Jodie Collingridge, Linus Conrad, Yinxing Chen, Sheng Rong Ng, Margaret Magendantz, Arjun Bhutkar, Jin-Shing Chen, Erik Sahai, Benjamin J Drapkin, Tyler Jacks, Matthew G Vander Heiden, Maksym V Kopanitsa, Hugh PC Robinson, Leanne Li
Elevated or ectopic expression of neuronal receptors promotes tumour progression in many cancer types1,2; neuroendocrine (NE) transformation of adenocarcinomas has also been associated with increased aggressiveness3. Whether the defining neuronal feature, namely electrical excitability, exists in cancer cells and impacts cancer progression remains mostly unexplored. Small-cell lung cancer (SCLC) is an archetypal example of a highly aggressive NE cancer and comprises two major distinct subpopulations: NE cells and non-NE cells4,5. Here we show that NE cells, but not non-NE cells, are excitable, and their action potential firing directly promotes SCLC malignancy. However, the resultant high ATP demand leads to an unusual dependency on oxidative phosphorylation in NE cells. This finding contrasts with the properties of most cancer cells reported in the literature, which are non-excitable and rely heavily on aerobic glycolysis. Additionally, we found that non-NE cells metabolically support NE cells, a process akin to the astrocyte-neuron metabolite shuttle6. Finally, we observed drastic changes in the innervation landscape during SCLC progression, which coincided with increased intratumoural heterogeneity and elevated neuronal features in SCLC cells, suggesting an induction of a tumour-autonomous vicious cycle, driven by cancer cell-intrinsic electrical activity, which confers long-term tumorigenic capability and metastatic potential.
Funding
Crick (Grant ID: CC2165, Grant title: Li, L CC2165)
European Research Council (Grant ID: CancerNeuroscience, Grant title: ERC - CancerNeuroscience)
European Research Council (Grant ID: 101019366 - CAN_ORGANISE, Grant title: ERC 101019366 - CAN_ORGANISE)
Crick (Grant ID: CC2040, Grant title: Sahai CC2040)