Progesterone actions in protein phosphorylation in the central nervous system

O presente trabalho propõe-se esclarecer o papel que a progesterona e os seus metabolitos exercem no sistema nervoso central. Nos últimos anos, com a descoberta da síntese local de esteróides no cérebro, a progesterona, assim como outras hormonas sexuais, ganharam uma relevância crescente em fenómenos tais como plasticidade neuronal e neuroprotecção. Ainda que já se comece a entender o papel de muitas hormonas no cérebro, tal como o estrogénio, o papel da progesterona continua menos conhecido. Deste modo, o nosso trabalho centrou-se na elucidação dos efeitos da progesterona em fenómenos de sobrevivência celular, plasticidade neuronal/sináptica. Graças à colaboração com um grupo pioneiro em estudos sobre hormonas sexuais neuroactivas, o presente trabalho fornece uma importante contribuição ao entendimento do papel desta hormona no sistema nervoso central. Este trabalho fornece novos dados, relativamente ao papel da progesterona e dos seus metabolitos reduzidos na regulação de vias de sinalização associadas com sobrevivência celular, tal como Akt/PI3K e ERK. Também é analisado o efeito do tratamento hormonal na expressão e estado de fosforilação da proteína Tau, sendo ainda motivo de estudo cinases e fosfatases envolvidas nestes mecanismos.

Sinalização celular e a resposta a estrogénios do epitélio mamário

Estrogens, such as 17β-estradiol (E2) are essential for normal growth and differentiation of the mammary gland. There are two estrogen receptors (ERs), ERα and ERβ which are ligand activated transcription factors. ERα stimulates proliferation and is the single most powerful predictor of breast cancer prognosis and since 70% of breast cancers express ERα, strategies to block this receptor are the primary breast cancer treatment. Unlike ERα, the role of ERβ in breast cancer and its potential as alternative therapeutic target remains controversial, mainly due to the lack of correlation between results obtained in vitro and epidemiological studies. The aim of this thesis was to increase our understanding of the molecular and cellular mechanisms of estrogen signaling in normal and cancerous cells, in different cellular contexts and with focus on ERβ. In Paper I we characterized the effect of the flavone PD098059 - which is a commonly used MEK1 inhibitor - on activation of transcription by ERα and ERβ. We found that the estrogenic effect of PD098059 is dose dependent in concentrations ranging from 1 – 10 μM and that activation of transcription by ER is suppressed by the inhibitory effect of PD98059 on MEK1 at concentrations above 50 μM. In agreement with its flavone nature, PD098059 had a much stronger effect on ERβ than on ERα transcriptional activity. Therefore, use of this compound for the study of signalling events in cells expressing ER should be carefully considered. In Paper II we assessed the effect of ERβ agonists in vivo and administered under different conditions in vitro. In basal conditions, ERβ induced apoptosis; however, in vivo ERβ agonists stimulated proliferation and inhibited apoptosis. In vivo effects were reproduced in culture, by activation of MAPK/ERK½ pathway with epidermal growth factor or basement membrane extract. In addition, insulin signalling and PI3-K/AKT activation was necessary for stimulation of proliferation. These results suggest that the cellular context modulates ERβ activity. Manuscript presents preliminary work aimed at the set-up of a methodological strategy to isolate ERs and to identify interacting proteins in different cellular contexts and which could modulate the bi-phased effects of ERβ in cell growth. In conclusion, the studies presented in this thesis contribute to clarify the apparent contradictory information regarding ERβ function in normal and cancerous mammary epithelium and suggest that the cellular context should be considered when ERβ effects are studied.