posted on 2013-12-13, 00:00authored byKhalid O. Alfarouk, Muntaser E. Ibrahim, Robert A. Gatenby, Joel S. Brown
Intratumoral evolution produces extensive genetic heterogeneity in clinical cancers.
This is generally attributed to an increased mutation rate that continually
produces new genetically defined clonal lineages. Equally important are the interactions
between the heritable traits of cancer cells and their microenvironment
that produces natural selection favoring some clonal ‘species’ over others. That is,
while mutations produce the heritable variation, environmental selection and cellular
adaptation govern the strategies (and genotypes) that can proliferate within
the tumor ecosystem. Here we ask: What are the dominant evolutionary forces in
the cancer ecosystem? We propose that the tumor vascular network is a common
and primary cause of intratumoral heterogeneity. Specifically, variations in blood
flow result in variability in substrate, such as oxygen, and metabolites, such as
acid, that serve as critical, but predictable, environmental selection forces. We
examine the evolutionary and ecological consequences of variable blood flow by
drawing an analogy to riparian habitats within desert landscapes. We propose
that the phenotypic properties of cancer cells will exhibit predictable spatial variation
within tumor phenotypes as a result of proximity to blood flow. Just as rivers
in the desert create an abrupt shift from the lush, mesic riparian vegetation along
the banks to sparser, xeric and dry-adapted plant species in the adjacent drylands,
we expect blood vessels within tumors to promote similarly distinct communities
of cancer cells that change abruptly with distance from the blood vessel. We propose
vascular density and blood flow within a tumor as a primary evolutionary
force governing variations in the phenotypic properties of cancer cells thus providing
a unifying ecological framework for understanding intratumoral
heterogeneity.