In this review we summarize our recent efforts in trying to understand the
role of heterogeneity in cancer progression by using neural networks to
characterise different aspects of the mapping from a cancer cells genotype and
environment to its phenotype. Our central premise is that cancer is an evolving
system subject to mutation and selection, and the primary conduit for these
processes to occur is the cancer cell whose behaviour is regulated on multiple
biological scales. The selection pressure is mainly driven by the
microenvironment that the tumour is growing in and this acts directly upon the
cell phenotype. In turn, the phenotype is driven by the intracellular pathways
that are regulated by the genotype. Integrating all of these processes is a
massive undertaking and requires bridging many biological scales (i.e.
genotype, pathway, phenotype and environment) that we will only scratch the
surface of in this review. We will focus on models that use neural networks as
a means of connecting these different biological scales, since they allow us to
easily create heterogeneity for selection to act upon and importantly this
heterogeneity can be implemented at different biological scales. More
specifically, we consider three different neural networks that bridge different
aspects of these scales and the dialogue with the micro-environment, (i) the
impact of the micro-environment on evolutionary dynamics, (ii) the mapping from
genotype to phenotype under drug-induced perturbations and (iii) pathway
activity in both normal and cancer cells under different micro-environmental
conditions