Green tea extracts interfere with the stress-protective activity of PrP and the formation of PrP.

A hallmark in prion diseases is the conformational transition of the cellular prion protein (PrP(C)) into a pathogenic conformation, designated scrapie prion protein (PrP(Sc)), which is the essential constituent of infectious prions. Here, we show that epigallocatechin gallate (EGCG) and gallocatechin gallate, the main polyphenols in green tea, induce the transition of mature PrP(C) into a detergent-insoluble conformation distinct from PrP(Sc). The PrP conformer induced by EGCG was rapidly internalized from the plasma membrane and degraded in lysosomal compartments. Isothermal titration calorimetry studies revealed that EGCG directly interacts with PrP leading to the destabilizing of the native conformation and the formation of random coil structures. This activity was dependent on the gallate side chain and the three hydroxyl groups of the trihydroxyphenyl side chain. In scrapie-infected cells EGCG treatment was beneficial; formation of PrP(Sc) ceased. However, in uninfected cells EGCG interfered with the stress-protective activity of PrP(C). As a consequence, EGCG-treated cells showed enhanced vulnerability to stress conditions. Our study emphasizes the important role of PrP(C) to protect cells from stress and indicate efficient intracellular pathways to degrade non-native conformations of PrP(C).

Destabilization of the non-pathogenic, cellular prion-protein by a small molecular drug.

The presence of the normal cellular prion-protein (PrPc) is a prerequisite for the development of fatal, neurodegenerative diseases called transmissible spongiform encephalopathies (TSEs). We discovered a new biological activity of the well-known coumarin antibiotic novobiocin; the treatment of eukaryotic cells with novobiocin induces the rapid depletion of PrPc. This activity is shared by coumermycin A1, another coumarin with a related molecular structure. Novobiocin's effects on the prion-protein are time- and dose-dependent. No permanent damage to the treated cells was observed, which continue to proliferate after cessation of drug exposure. Most of the cellular proteins are unaffected by novobiocin treatment. Pretreatment with geldanamycin, an inhibitor of the aminoterminal ATPase of heat-shock protein 90 (Hsp90) partially antagonizes novobiocin's depletory activity. Concurrent treatment with the protease inhibitor chymostatin completely prevents PrPc loss. Here we show that the stability of the normal cellular prion-protein may be targeted pharmacologically. These findings open up a hitherto unknown avenue to the study of TSEs in general and may have therapeutic implications.

Hyperbaric oxygen enhances the expression of prion protein and heat shock protein 70 in a mouse neuroblastoma cell line.

1. Cellular prion protein, PrP(C), is a ubiquitous glycoprotein strongly expressed in neurons with an as yet unknown biological function. In previous studies, we demonstrated that PrP(C) could be regulated by heat shock stress, implying that it might be a stress-responsive protein. Hyperbaric oxygen (HBO) administration is a well-defined model for the study of oxidative stress. 2. This study investigated the effect of HBO on PrP(C) and Hsp 70 expression in mouse neuroblastoma cell lines (N18), assessing the expression of PrP(C) and Hsp 70 using RT-PCR and Western blotting. HBO administration resulted in a time- and dose-dependent increase in PrP(C) and Hsp70 expression in N18 cells at both mRNA and protein levels, with a concomitant upregulation of c-Jun N-terminal kinase (JNK). 3. Under HBO treatment, luciferase reporter constructs of the rat PrP(C) promoter, containing the heat shock element (HSE) also present in Hsp70, expressed higher luciferase activity (3- to 10-fold) than those constructs without HSE. 4. In summary, these data suggest that PrP(C) and Hsp 70 may be regulated by HBO, through the activation of JNK. Thus, the activated heat shock transcriptional factor 1, phosphorylated by JNK interacted with HSE in the promoter of PrP(C) resulted in increased gene expression. These findings are vital for future therapeutic approaches in transmissible spongiform encephalopathies and the understanding of the function of the PrP(C).