Description

Tumors of the central nervous system affect 21 people per 100,000 every year, a figure that refers to countries with advanced economies, with an increase in incidence over time. Among tumors of the central nervous system, Glioblastoma (GBM) is the most frequent and aggressive malignant tumor with an average life expectancy of approximately 12 months and a survival of less than 5% in the following 5 years to the diagnosis. The growth and progression of GBM are dependent on a specialized subpopulation of tumor cells called "cancer stem cells" (CSCs). CSCs are chemo- and radio-resistant, are responsible for relapses and therefore should constitute an important target of therapeutic strategies, but the mechanisms underlying their biology are still poorly understood. Hypoxia, through the hypoxia-inducible factor (HIF) and sphingolipid pathway, plays a key role in the control of tumor growth and angiogenesis and represents, perhaps, the most effective adaptation mechanism of the tumor itself. Indeed, The hypoxic microenvironment of solid tumors gives them greater aggressiveness, an increase in the expression of proteins linked to angiogenesis, anaerobic energy metabolism and adaptation to oxidative stress which facilitates the onset and proliferation of CSCs.

This study supports the evidence that the hypoxic microenvironment regulates the state of CSCs, and therefore influencing the response to the current pharmacological treatments.

Although S1P can act as an intracellular second messenger, most of its effects are exerted as an extracellular mediator, through binding to specific G protein-coupled receptors, originally known as EDGs and now called S1P receptors (S1PRs). Our group has previously demonstrated that acquired modifications in the metabolism of sphingolipids, in particular in the regulation of S1P, are able to confer stem-like and chemo-resistance properties to CSCs in patients with GBM.

The project aims to identify new molecular and metabolic targets involved in the survival and chemo-resistance of tumor stem cells in relation to the tumor microenvironment.

Through the study of sphingolipid metabolism, new markers and inhibitors will be identified to be delivered to inhibit CSC proliferation and tumor progression.

With this approach the investigators will be able to evaluate how the tumor microenvironment and the molecular and metabolic characteristics of the tumor influence cellular communication and whether this process can be influenced by new pharmacological treatments. This study could highlight new pathways and tumor-specific alterations to stratify new therapeutic strategies and to identify new potential biomarkers in diagnosis and monitoring, thus improving the prognosis of patients suffering from brain tumors.