Analysis of galectin-3 expression in glioma cells exposed to hypoxic conditions and its role in tumor development in vivo

Galectin-3 (gal-3) belongs to a family of proteins with beta-galactoside binding domains and is related to various tumoral aspects, such as cell proliferation and adhesion, angiogenesis and protection against cell death. Studies show its relationship with the hypoxia phenomenon, a characteristic of many solid tumors that have high cell proliferation rates. The adaptation to hypoxia is mainly mediated by Hypoxia Induced Factor (HIF-1), which acts in the induction of several survival genes in environments with low oxygen concentrations. In addition to HIF, other factors are important in this process, such as NF-kB, for example, which is a transcription factor responsive to various cellular stresses, including hypoxia. Some tumor models are ideal for studying the effects of hypoxia in the tumor microenvironment, e.g. glioblastomas. These central nervous system tumors with high mortality rates are refractory to the main treatment methods due to their plasticity, heterogeneity and infiltrative growth. Histologically, these tumors exhibit nuclear atypia, high mitotic rates and pseudopalisading areas. It is postulated that these areas are composed of migrating cells out of necrotic microenvironments, which are also hypoxic due to their distance from the blood vessels and it is shown that these cells express both HIF-1alfa and gal-3. In vitro assays performed by our group demonstrated that gal-3 is positively regulated by hypoxia in a hybrid glioma cell line, NG97ht, and demonstrated that this protein is a key factor in protecting these cells against cell death induced by oxygen and nutrient deprivation conditions mimicking necrotic pseudopalisading areas in vivo, highlighting the pro-survival abilities of this protein. Although one of its possible functions has been elucidated, gal-3 mechanisms of action and induction are still unclear. Thus, this project aims to explore the gal-3 pro-tumoral effects, which may make it a possible target for anti-neoplastic therapies, better understanding the mechanisms of protection against cell death and expression in hypoxic environments, and also study its possible functions in vivo, extending these studies to other glioma cell lines. Our results demonstrated that gal-3 is located within the mitochondria in these glioma cell lines and may undergo posttranslational modifications in hypoxia, such as phosphorylation and that there is accumulation of nuclear HIF-1alfa in these cells under hypoxia. We have also seen that gal-3 in the NG97ht cell line presents two different alleles and that intermediate factors must be expressed previously by the cell before gal-3 induction in hypoxia. We also demonstrated that there is dependence on the NF-kB transcriptional factor for the gal-3 induction under these conditions. These experiments also demonstrated that exposure of cells to hypoxia and nutrient deprivation is capable of inducing reactive oxygen species and increased autophagy in these cells, which are important factors in the induction of cell death. In addition, we demonstrated that the induction of the NG97ht cell death in these conditions is due to necrosis. We expanded this theory of the participation of gal-3 as a protective molecule against cell death in hypoxia and nutrient deprivation to another human glioma cell line, T98G. And finally, we demonstrated that decreased expression of gal-3 in the U87MG glioma cell line leads to lower tumor establishment rates and decreased growth in vivo (AU)