Avaliation of PrPc expression in neuron-glia crosstalk, in astrocytes and the mechanisms of STI1 secretion

The physiological functions of PrPc are under intense investigation and characterization, particularly those associated with brain development. In neurons, the association of PrPc with its ligand, STI1, induces neuritogenesis and neuroprotection via ERK and PKA signaling pathways, respectively. The present study evaluated whether PrPc expression in astrocytes modulates neuron-glia crosstalk and the autocrine role of STI1 in astrocytes. PrPc modulates neuron-glia interaction, the production and secretion of soluble factors, and the organization of the laminin in the extracellular matrix. PrPc expression in neurons and astrocytes is essential to neuritogenesis and neuronal survival. The autocrine role of STI1 in astrocytes was also demonstrated. The PrPc-STI1 interaction prevents cell death in a PKA-dependent manner, and induces astrocyte differentiation, from a flat to a process-bearing morphology in an ERK1/2 dependent manner. We showed that PrPccnull astrocytes presented a slower rate of astrocyte maturation than wild-type ones, with reduced expression of GFAP and increased vimentin and nestin expression. STI1 inhibited proliferation of both wild-type and PrPCnull astrocytes in a PKC-dependent manner. The mechanisms by which STI1 can be secreted by astrocytes was avaliated and we demonstrated that this secretion is independent on the classical secretory pathway mediated by the Golgi apparatus. Secreted STI1 is found in a soluble form and associated with lipidic compartments and we characterized by electron microscopy as vesicles that range from 20-200nm. Among the non-classical lipid-dependent secretory pathways, STI1 secretion by shedding was ruled out since STI1 was not secreted with lipoprotein fractions. On the other hand, STI1 is present in fractions that are positive for transferrin receptor, Hsp70, Hsp90 and PrPc, suggesting an exosome identity. Taken together, these data indicate that STI1 acts as a neurotrophic factor whose activity is dependent on the expression of PrP c at the neuronal surface, modulating differentiation and survival of both neurons and astrocytes (AU)