Activation of retinal neurons triggers tumour formation in cancer-prone mice

[Cancer Neuroscience]

The nervous system integrates and processes information to act as master regulator of various vital, biological processes. However, increasing data suggest that the nervous system is also a key player in the initiation of cancer and cancer progression. Following the tenet that oncology follows ontogeny, it has been shown that brain tumors follow neural developmental processes. Incurable gliomas form neurite-like membrane tubes called tumor microtubes and are controlled by neurodevelopmental pathways. Tumor microtubes are used for invasion, proliferation and interconnection with other tumor cells, forming a tumor network that is therapeutically resistant. Additionally, neurons can activate tumor cells via glutamatergic synapses to drive tumor invasion and growth. The most recent knowledge of brain cancer neuroscience presented here with a focus on brain tumours has already led to new approaches for antitumour treatment.

Disconnecting multicellular networks in brain tumours

Cancer cells can organize and communicate in functional networks. Similarly to other networks in biology and sociology, these can be highly relevant for growth and resilience. In this Perspective, we demonstrate by the example of glioblastomas and other incurable brain tumours how versatile multicellular tumour networks are formed by two classes of long intercellular membrane protrusions: tumour microtubes and tunnelling nanotubes. The resulting networks drive tumour growth and resistance to standard therapies. This raises the question of how to disconnect brain tumour networks to halt tumour growth and whether this can make established therapies more effective. Emerging principles of tumour networks, their potential relevance for tumour types outside the brain and translational implications, including clinical trials that are already based on these discoveries, are discussed.