Biologia da proteína prion celular / Cellular prion protein biology

Kil Sun Lee

30 December 2002

O prion celular (PrPc) é uma glicoproteína ligada à membrana plasmática por uma âncora de GPI (glycosylphosphatidylinositol). A sua isoforma anormal (PrPsc) é uma molécula infecciosa que causa várias doenças neurodegenerativas em mamíferos. A etiologia dessas doenças está associada a uma mudança conformacional pós-traducional de PrPc que ocorre após sua internalização (Prusiner, 1998). Na tentativa de desvendar as funções fisiológicas de PrPc, nosso grupo tem identificado e caracterizado as interações celulares que PrPc participa. A primeira delas é a interação entre PrPc e STI1 (Stress Inducible Protein 1). Essa interação transduz sinalização por cAMP e PKA levando a neuroproteção contra morte celular programada (Chiarini e cols, 2002; Zanata e cols, 2002). A segunda é a interação específica que existe entre PrPc e as proteínas da matriz extracelular, laminina e vitronectina, contribuindo para os processos neuronais, tais como crescimento, manutenção (Graner e cols., 2000 a e b) e regeneração dos neuritos (Hajj e cols., submetido), além da formação de memória de curta e longa duração (Coitinho e cols., submetido). Na primeira parte deste trabalho, procuramos investigar os genes regulados pelos sinais resultantes dessas interações e também pela remoção de PrPc usando a técnica de \"differential display\'\' RT-PCR. Na segunda parte do trabalho, caracterizamos que a interação PrPc - laminina é capaz de induzir uma sinalização transitória de cálcio, a qual ocorre mesmo na ausência de cálcio do meio extracelular. PrPc é uma molécula que cicla continuamente entre a membrana plasmática e os compartimentos intracelulares. Estudos recentes têm correlacionado o processo de internalização de PrPc com alguns dos seus papeis fisiológicos, tais como, homeostase de Cu2 + (Brown, 2001 ), interação com receptor de laminina (Gauczynski e cols, 2001) e até na conversão de PrPc para PrPsc (McKinley e cols, 1991; Arnold e cols, 1995). Portanto, na terceira parte deste trabalho, caracterizamos a localização e o tráfego celular de PrPc mostrando que PrPc está localizado na membrana plasmática e em compartimentos intracelulares e que trafega pelo Golgi, membrana plasmática, endossomos iniciais e de reciclagem. Foram mapeados ainda domínios na região amino-terminal responsáveis pela internalização de PrPc e na região carboxi-terminal como participantes da via secretora. Este trabalho contribuiu para o esclarecimento de alguns eventos biológicos relacionados à sinalização e ao tráfego de PrPc. Estes achados são de grande importância para a determinação das funções celulares de PrPc e ainda dos mecanismos envolvidos com as doenças relacionadas com esta molécula. / The cellular prion protein (PrPc) is a glycoprotein anchored to the plasma membrane by GPI (Glycosyl-phosphatidylinositol). Its abnormal isoform (PrPsc) is the infectious protein responsible for several neurodegenerative diseases. The main etiology of the prion diseases is related to conformational changes in the PrPc molecule, which occur after its internalization (Prusiner, 1998). In order to elucidate the physiological functions of PrPc, our group identified and characterized interactions between PrPc and other cellular molecules. The first is the interaction between PrPc and STI 1 (Stress Inducible Protein 1). This interaction has an important role in the neuroprotection against apoptosis through cAMP and PKA signaling (Chiarini et al., 2002; Zanata et al., 2002). PrPc also interacts with proteins of the extracellular matrix such as laminin and vitronetin. These interactions contribute for neurite outgrowth, maintenance and regeneration (Graner et al., 2000 a and b; Hajj et al., submitted) and also in memory formation (Coitinho et al., submitted). In the first part of this work we have applied the differential dysplay RTPCR technique in order to identify genes that are regulated by PrPc - STI 1 interaction and also by the deletion of PrPc. In the second part we have demonstrated that PrPc-laminin interaction induces transient calcium signaling in neuronal cells, which occurs even in the absence of extracellular calcium. PrPc cycles continuously between the plasma membrane and intracellular compartments. This mechanism is associated with some of the physiological function of PrPc, such as Cu2+ homeostasis (Brown, 2001 ), interaction with laminin receptor (Gauczynski et al., 2001 ), and PrPc conversion into PrPsc (McKinley et al., 1991; Arnold et al., 1995). Thus, in the third part of this project, we have characterized the PrPc localization at the cell surface and in intracellular compartments. The protein trafficking through Golgi apparatus, plasma membrane, early and recycling endosomes was also defined. Moreover, we have determinated that N-terminus PrPc domain is responsible for its internalization while C-terminus participates in PrPc delivery. Therefore, this work has contributed to elucidate biological events related to the cell signaling and trafficking of PrPc, which are important for the characterization of PrPc physiological functions and to understand the pathological mechanisms related to this molecule.

Biologia celular

Biologia molecular

Construção de vetores de expressão

Glicoproteínas da membrana

Prion

Proteínas da membrana

Tráfego intracelular

Cell biology

Construction of expression vectors

Intracellular traffic

Membrane glycoproteins

Membrane proteins

Molecular biology

Prion

Rôle des petites protéines G de type Arf dans la morphogenèse et la virulence de Candida albicans / Role of Arf small GTPases in Candida albicans morphogenesis and virulence

Labbaoui, Hayet

16 May 2017

Candida albicans est une levure pathogène opportuniste de l’homme. La capacité de C. albicans à changer de forme en réponse à des stimuli externes, passant d’une croissance bourgeonnante à filamenteuse, est associée à sa virulence. Cette morphogenèse requiert une réorganisation du cytosquelette d’actine et un trafic membranaire ciblé. Chez Saccharomyces cerevisiae, les petites protéines G de type Arf jouent un rôle important dans le trafic membranaire et la polarité cellulaire. Le rôle de ces protéines chez C. albicans est largement méconnu. C. albicans a 3 protéines Arf, Arf1-Arf3 et 2 Arf-like, Arl1 et Arl3. Nos résultats indiquent que seule Arf2 est nécessaire à la viabilité et à la résistance aux antifongiques, et qu’Arf2 et Arl1 sont critiques pour la croissance filamenteuse hyphale; le mutant arl1/arl1 en particulier forme des hyphes 2 fois plus courtes que la souche sauvage. Les mutants Δ/pTetARF2 et arl1/arl1 ont un défaut de virulence dramatique et ARL1 est particulièrement critique pour la candidose oropharyngée. Nos résultats indiquent que les défauts du mutant Δ/pTetARF2 seraient dus à une altération du Golgi, et ceux d’arl1/arl1 de l’incapacité de ce mutant à restreindre sa croissance à un site unique. Ce défaut de croissance polarisée du mutant arl1/arl1 n’est pas lié à la mislocalisation de son effecteur Imh1, ni à une misrégulation de la phosphatidylsérine flippase Drs2. Par contre, nos données suggèrent que le défaut de croissance hyphale de ce mutant résulterait d’une hypersécrétion. Cette étude nous a permis d’identifier Arf2 et Arl1 comme protéines clés du trafic membranaire, critiques pour la croissance filamenteuse et la virulence de C. albicans. / The human fungal pathogen Candida albicans switches from budding to filamentous growth. This dramatic morphogenesis is critical for its virulence and requires sustained polarized growth, via exocytosis and endocytosis, as well as reorganization of intracellular compartments. In the yeast Saccharomyces cerevisiae, Arf G-proteins and their regulators function at the interface of membrane traffic and cell polarity. The roles of this class of proteins during the transition to filamentous growth and virulence in C. albicans are largely unknown. In C. albicans there are 3 Arf proteins, Arf1-Arf3 and 2 Arf-like proteins, Arl1 and Arl3. Our results reveal that only Arf2 is required for viability and sensitivity to antifungal drugs and that both Arf2 and Arl1 are required for hyphal growth, with arl1/arl1 hyphal filaments being 2-fold shorter than that of the wild-type strain. Furthermore, both Δ/pTetARF2 and arl1/arl1 mutants have drastically reduced virulence, with ARL1 particularly critical for oropharyngeal candidiasis. We show that the defects in Δ/pTetARF2 is due to an alteration of Golgi integrity, while the defects in the arl1 mutant are likely to result from the inability of this mutant to restrict growth to a single site. Further analyses of the arl1/arl1 mutant revealed that this defect does not result from a misregulation of the GRIP-domain golgin coiled-coil tethering protein Imh1 nor of the phosphatidylserine flippase Drs2. Rather, our results suggest that the arl1/arl1 hyphal growth defect results from increased secretion. Together our work identifies Arf2 and Arl1 as key regulators of membrane traffic, critical for hyphal growth and virulence.

Arf/Arl

Candida albicans

Trafic membranaire

Morphogenèse

Croissance filamenteuse

Virulence

Arf/Arl GTPase

Candida albicans

Intracellular traffic

Morphogenesis

Filamentous growth

Virulence