Abstract
As the main theory of carcinogenesis, the Somatic Mutation Theory, increasingly presents difficulties to explain some experimental observations, different theories are being proposed. A major alternative approach is the Tissue Organization Field Theory, which explains cancer origin as a tissue regulation disease instead of having a mainly cellular origin. This work fits in the latter hypothesis, proposing the bioelectric field, in particular the cell membrane polarization state, and ionic exchange through ion channels and gap junctions, as an important mechanism of cell communication and tissue organization and regulation. Taking into account recent experimental results and proposed bioelectric models, a computational model of cancer initiation was developed, including the propagation of a cell depolarization wave in the tissue under consideration. Cell depolarization leads to a change in its state, with the activation and deactivation of several regulation pathways, increasing cell proliferation and motility, changing its epigenetic state to a more stem cell-like behavior without the requirement of genomic mutation. The intercellular communication via gap junctions leads, in certain circumstances, to a bioelectric state propagation to neighbor cells, in a chain-like reaction, till an electric discontinuity is reached. However, this is a reversible process, and it was shown experimentally that, by implementing a therapy targeted on cell ion exchange channels, it is possible to reverse the state and repolarize cells. This mechanism can be an important alternative way in cancer prevention, diagnosis and therapy, and new experiments are proposed to test the presented hypothesis.
Highlights
Using the Xenopus laevis model, that gap junctions are important in long-range regulation of tumor formation. In14 the authors report on relationships between ion channel dysfunction and cancer hallmarks
It should be stressed that Somatic Mutation Theory (SMT) and Tissue Organization Field Theory (TOFT) are not mutually exclusive, on the contrary, they are complementary and can both contribute to explain the different circumstances and factors involved in a hugely complex event that is carcinogenesis
Dedicated experiments should be pursued on the association between bioelectricity, in particular the membrane electric potential and its relation with cell regulation pathways, and cancer inception
Summary
Using the Xenopus laevis model, that gap junctions are important in long-range regulation of tumor formation. In14 the authors report on relationships between ion channel dysfunction and cancer hallmarks. This initiates a change of the tissue cells’ bioelectric polarization state, a depolarization or polarization wave which propagates across the domain. Hereditary cancers can be explained by transmitted variability, which drive cells to exhibit different electrical properties, in particular in the number, conductivity and efficiency of ion channels, ion pumps and gap junctions.
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