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Institute
Prion diseases or transmissible spongiform encephalopathies (TSEs) are rare neurological disorders that may be of genetic or infectious origin, but most frequently occur sporadically in humans. Their outcome is invariably fatal. The infectious agent has been defined as prion (from proteinaceous infectious only) in 1992 by Stanley B. Prusiner and represent mainly, if not solely, an abnormal, protease-resistant isoform (PrPSc) of a cellular protein, the prion protein or PrPC. According to the “protein only” hypothesis, the prion is devoid of informational nucleic acids and consists of an “infectious” protein that is capable of converting the normal host protein PrPC into a likeness of itself. TSEs can be distinguished from other neurodegenerative diseases because of their infectivity and transmission capability. The only organ system in which severe histopathological damage can be demonstrated as a consequence of infection with prions is the nervous system. The communal lesions are neuronal loss, spongiosis and astrogliosis, accompanied by an intra- and extracellular accumulation of PrPSc, occasionally in form of amyloid plaques. Even if a strong activation of microglia and astrocytes occurs, no immunological response is usually detectable as consequence of prion infection. Despite the considerable attention for its involvement in TSEs, the physiological role of the cellular, nonpathogenic isoform of PrPC, has not yet been determined. In the last years, several putative cellular functions have been attributed to PrPC: its localization in “lipid rafts” is consistent with a possible role in cell adhesion, transmembrane signalling or as a recognition molecule. Furthermore, PrPC has been implicated in protection against oxidative stress, copper metabolism, apoptosis, cell proliferation and in the regeneration of blood precursors stem cells in the adult. It has also been shown that PrPC interacts with the neuronal cell adhesion molecule NCAM, promoting neurite outgrowth. However, both the PrPC-mediated effects and the role of PrPC-dependent pathways on neuronal differentiation are still not elucidated. First objective of this Ph.D thesis was the establishment of a novel in vitro cellular model for the study of the role of PrPC in neuronal differentiation and neurite outgrowth. Furthermore, an additional goal of this project was the indentification of the PrPC domains responsible for the induction of neuronal differentiation. A novel PrPC-depleted cell line (PrP0/0 ML) was derived from murine primary PrP-knockout neuronal cells by SV40 large T antigen-mediated immortalization. A temperature sensitive form of this oncogenic protein was used, allowing a temperature-mediated regulation of its expression. This cell line was then characterised for its growth potential, for the expression of specific cellular markers and for its ability to differentiate. It was found that, under culture conditions promoting the expression of the temperature-sensitive SV40 large T antigen, the cells expressed nestin, a specific marker of neuronal precursor cells. Therefore, the PrP0/0 ML cell line was identified as a potential neuronal stem cell line. In fact, under nonpermissive culture conditions when the expression of the temperature-sensitive SV40 large T antigen is downregulated, the PrP0/0 ML cells differentiated into neurons. Noteworthy, maintenance of the cells in conditions that promote cell differentiation induced a progressive reduction in the expression levels of nestin, an event that strongly correlated with the appearance of the specific neuronal markers MAP-2b and NeuN. In order to investigate the role of PrPC in the process of neuronal differentiation, the PrP0/0 ML cells were then reconstituted for the expression of either the full-length PrP or a N-terminal truncated PrPC form (PrPdel32-134). The differentiation potential of both reconstituted cell lines under nonpermissive culture conditions was then compared with that of the parenteral PrP0/0 ML cells. This in vitro study clearly highlights that PrPC expression in the PrP0/0 ML cell line accelerates neuronal differentiation and that the N-terminal domain of the prion protein is not necessary for this PrP-mediated function. Prion diseases like BSE, vCJK, Kuru and the majority of iatrogenic cases of CJK are caused by a peripheral infection. Infectious prions accumulate in the central and peripheral nervous system as well as in extracerebral tissues, such as the secondary lymphoid organs and muscles. The prion pathogenesis is a dynamic process which can be defined temporary and spatially in different phases: i) infection and peripheral replication, ii) neuroinvasion, transport of prions from the periphery to the central nervous system (CNS), and iii) neurodegeneration. In the last years, progresses in the elucidation of the peripheral prion pathogenesis were achieved. The identification of the cell types involved in the lymphoreticular prion replication phase and the recognition of the role of the peripheral nervous system in the process of prion spread from the periphery to the CNS have elucidated some of the cellular mechanisms that are involved in prion uptake, replication and propagation. However, relatively little information is available about the mechanism(s) underlying intercellular prion transfer and tissue-to tissue prion spread. Microvesicles (MVs) are submicron vesicles (0,03-1 microm.) with a single membrane and are shed from most eukaryotic cells undergoing activation or apoptosis. The segregation of specific proteins is followed by blebbing of the membrane surface, leading to the formation of MVs and their release in the extracellular environment. MVs can be also secreted upon fusion of multivesicular endosomes with the plasma membrane (exosomes). The secretion of MVs is the result of a complex cellular process involving changes in the metabolism of lipids and proteins. The functional role of MVs is still largely unknown. However, there is evidence showing that they are important modulators of cell-to-cell communication, participate in a variety of intracellular adhesion processes and are able to induce cellular response(s). The release of PrPC and infectious PrPSc by prion infected epithelial, neuroglial and neuronal cells in association with exosomes has recently been highlighted. Furthermore, it has been shown that exosomes can propagate prion infectivity both in vitro and in vivo, suggesting that PrPSc-bearing exosomes may provide a mechanism for intercellular transmission of infectious prions in addition to cell-to-cell contact. Second objective of this Ph.D thesis was to determine the possible role of plasma membrane-derived microvesicles in the propagation and transmission of prions. The release of MVs was first studied in different murine neuronal cell lines. Here it is shown for the first time that neurons also shed plasma membrane derived MVs, in addition to exosomes. Immunoelectron microscopy and immunoblot analyses clearly demonstrated the presence of PrPC on the membrane of MVs released from PrPC-expressing cells. Characterization of lipid rafts components in MVs highlighted the presence of the ganglioside GM2, the tyrosine kinase p59Fyn, flotillin-2 and the neuronal protein GAP-43. In order to investigate whether MVs are involved in the intercellular transmission of prions, MVs were first isolated from two prion infected murine neuronal cell lines, namely the Neuro-2a PK1 and the N2a58 cells, and then used for in vitro and in vivo infection assays. Immunoblot analyses after proteinase K treatment demonstrated the association of PrPSc with the secreted MVs. The PrPSc-bearing MVs were then used to perform infection experiments on noninfected cells. By the use of cell blot assay, a method that allows the detection of PrPSc-amplification and -accumulation in cultured cells, the kinetic of prion infection in the de novo infected cells was followed. Noteworthy, it was found that PrPSc-bearing MVs were capable to transmit prions in vitro and to stably infect the recipient cells. In order to investigate the role of MVs in the transmission of infectivity in vivo, PrPSc-bearing MVs as well as MVs isolated from noninfected cells (as negative control) were injected intracerebrally in PrPC-overexpressing indicator mice (tga20). The development of clinical disease was followed in a time-dependent manner. Clinical symptoms could be observed only in the group of indicator mice inoculated with the PrPSc-bearing MVs, which then succumbed to desease. These findings clearly demonstrated that MVs are biological carriers of both PrPSc and prion infectivity. MVs could therefore participate in vivo in the processes of intercellular prion transmission and propagation.