[eng] The reprogramming of energy metabolism represents an important hallmark
of cancer. The main cause of this alteration is represented by the presence
of hypoxic areas. The decreased availability of oxygen activates the Hypoxia
Inducible Factor (HIF) pathway which regulates the switch from an aerobic to
an anaerobic metabolism, as well as an increased uptake of glucose.
The aim of this thesis is multiple. In the first part we study and we numerically
simulate a mathematical model consisting of four ordinary differential equations
(ODEs): one for cancer cells with HIF inactivated, one for cancer cells with
HIF activated and two for the metabolites cancer cells can consume in order
to produce ATP. We model the dynamics of the transition between the two
different behaviors, of cancer growth under normoxic and hypoxic conditions
and of cancer progression in a hostile environment; furthermore we compare the
behaviour of cancer cells in highlanders and lowlanders.
In the second part we introduce a simple mathematical model to analyse the
link between angiogenesis and the Warburg effect in cancer cells.
We show that the the increased expression of glucose receptor is an important
factor in the transition from initiation to cancer progression . We also show
that the genetic polymorphism considered in highlanders does not provide useful
information on cancer growth in the long term behaviour.
The second model, despite only introduced, will let us formulate new questions
concerning the role of the angiogenesis in cancer progression and fascinating
links among different aspect of cancer metabolism.