Introduction

• – Self-sufficiency in growth signals. Cancer cells have the ability to grow without hormonal signals, likely by producing these signals by themselves (autocrine signaling), by constitutively activating signaling pathways associated to hormones, or by silencing termination signals.
• – Evading growth suppressors. Cancer cells resist to inhibitory signals that might otherwise stop their growth (an event occurring in normal proliferative cells), eliminating tight control of cell division through tumor suppressor genes. This allows cell division also if DNA is damaged or during contact with other neighboring cells.
• – Evading apoptosis. Cancer cells lose the ability to activate a programmed cell death, a process known as apoptosis. Nevertheless, cells may become completely abnormal, they do not undergo apoptosis. Cancer cells are able to do so by altering the mechanisms to detect damages and circumventing cell cycle, or nutrient and adhesion checkpoints.
• – Limitless replicative potential. Cancer cells indefinitely proliferate. Cancer cells escape natural senescence and undergo immortalization, being apparently capable of indefinite growth and division. Cancer cells bypass the senescence barrier by manipulating telomerases to increase the length of telomeres or by disabling their pRB and p53 tumor suppressor proteins, with the consequent emergence of a genome alterations, strongly correlated with DNA damage to multiple genes controlling cell division (oncogenes) and tumor suppressors.
• – Sustained angiogenesis. Cancer cells stimulate the growth of blood vessels to supply nutrients for themselves. As a growing tumor requires new blood vessels to receive adequate oxygen and nutrients, cancer cells acquire the ability to orchestrate the machinery needed for a new vasculature by activating the so-called angiogenic switch, unbalancing the net production of proangiogenic factors over the antiangiogenic ones.
• – Tissue invasion and metastasis. Cancer cells are able to invade local tissue and spread to distant sites. Malignant tumors undergo a multistep process allowing (i) local invasion of these cells from the primary site into the surrounding tissues, then (ii) the intravasation and the consequent facing the harsh environment of the circulatory system, (iii) the extravasation and engraftment into a distant organ. Cancer cell motility is enhanced through activation of epithelial-mesenchymal transition (EMT) or mesenchymal-amoeboid transition, two epigenetic pathways allowing adaptations of motility styles to different tissue microenvironment.
• – Metabolic deregulation. Most cancer cells exhibit abnormal metabolic demands, fluxes, and bioenergetics, as revealed in the early twentieth century in the Warburg hypothesis (i.e., massive upload of glucose, which is diverted into glycolytic collateral pathways as well as in lactate fermentation, even under aerobic conditions). Recent advances showed a peculiar metabolic plasticity of cancer cells, beyond the glycolytic pathway. Such metabolic deregulation showed by cancer cells spans from different nutrients exploitation in a restricted environment, to the nutrient competition, until the epigenetic regulation exerted by metabolites such as succinate, fumarate, and 2-hydroxyglutarate (namely, oncometabolites).
• – Evading the immune system. Cancer cells are able to avoid immune-surveillance, the natural mechanism of cancer detection by the immune system. Indeed, cancer cells elicit a complex response driving immune effector cells inhibition, while sustaining Treg activation, with the final outcome to be hidden to the immune system.
• – Sustained inflammation. Cancers have been described as “wounds that do not heal,” mainly due to sustained local chronic inflammation, caused by recruiting several accessory populations within the neoplasm. Chronic inflammation has been correlated with sustained angiogenesis and inhibition of functional immune response, thereby explaining the role of inflammation in sustaining cancer aggressiveness. ECM (extracellular matrix), hypoxia end acidity are all environmental factors enhancing tumor inflammation, thereby concurring to increase cancer aggressiveness (see below).

The role of tumor microenvironment