Browsing by Subject "Golgi retention"

Growth differentiation factor 15 (GDF15), a member of TGF-β super family is a soluble cytokine that is associated with different pathological conditions including cancer, cardiac and renal failure and obesity. Its high serum levels are linked with symptoms like cachexia/anorexia in cancer patients and can be used as a marker for these diseases. Its crucial role in weight regulation and energy homeostasis has been demonstrated by treating obese mice with GDF15, which results in weight lose along with improved glucose metabolism and increased insulin tolerance. It is now known that GDF15 exerts its metabolic effect by binding to a GDNF receptor -α-Like (GFRAL) receptor along with co-receptor RET. Interestingly, these two receptors co-localize only in the brain stem area of mice and humans indicating involvement of a neuronal circuit in GDF15 mediated effects. Despite its implications in major health disorders, little is known about the interaction of GDF15 with its receptors and how this interaction in turn modulates different cellular signalling and functions. The aim of the thesis was to study the mechanism and factors involved in endocytosis of GDF15. I employed high content imaging and flow cytometry techniques to visualize and analyse the internalization of ligand-receptor complex and investigate the role of actin, dynamin and phosphoinositide 3 kinase in the process. The results suggest that similar to the internalization of other cellular growth factors, the uptake of GDF15 is affected by disruption of the actin cytoskeleton. The role of dynamin is still unclear. I also discovered that the internalization of GDF15 was inefficient even in cells that expressed the receptor GFRAL, with large cell-to-cell variation. By following the intracellular localization of the receptor GFRAL, my results revealed that the receptor GFRAL is not efficiently exported to the plasma membrane and most of the protein is retained in the Golgi compartment of cells. This phenomenon was stronger in murine fibroblast cells, where the receptor was almost exclusively trapped in the secretory compartment, explaining why the uptake of the ligand GDF15 is so inefficient in these cells. The system developed during this project will now be used to analyse different factors involved in the uptake of GDF15 and eventually uncover the possible endocytic pathway. Moreover, the Golgi retention of the receptor opens up new questions to investigate like whether the physiological function of GDF15 is regulated by receptor export signals. This will help deciphering the complex and mysterious interaction of GDF15 with its receptor GFRAL.