Protein Folding Activity of the Ribosome and Its Implication in Prion Processes

Sammanfattning: How the linear protein chains fold into their three-dimensional active conformation is one of the remaining puzzles of modern science. Other than molecular chaperones, ribosome - the cellular protein synthesis machinery, has also been implicated in protein folding. The active site of protein folding activity of the ribosome (PFAR) is in the domain V of the main RNA component of the large ribosomal subunit, which also constitutes the peptidyl transferase center.We have characterized the mechanism of PFAR using ribosomes or ribosome-borne folding modulators (RFMs) and human carbonic anhydrase I (HCA) as a model system. RFMs from all three kingdoms of life showed PFAR.  By multiple addition of the denatured protein in the refolding assay we demonstrate that the RFMs can recycle efficiently to assist refolding of a new batch of denatured protein. The turnover of the RFMs, which includes release of the protein substrate, takes milliseconds. Furthermore, fast kinetics of HCA refolding suggests that an early folding intermediate is the substrate for PFAR. Our results demonstrate for the first time that PFAR is catalytic.It was shown that two anti-prion drugs 6AP and GA specifically inhibit PFAR by binding to the domain V of the 23S / 25S rRNA. Using UV-crosslinking followed by primer extension we have identified the interaction sites of 6AP on domain V of 23S rRNA, which overlap with the protein binding sites, and are sensitive to mutagenesis. We find that 6AP and GA inhibit PFAR by direct competition with the substrate protein for the binding sites. Also, 6AP derivatives inhibit PFAR in the same order as their antiprion activity, 6AP8CF3 > 6AP8Cl > 6AP > 6APi. These results suggest involvement of PFAR in prion processes.To clarify the role of PFAR in prion processes, we studied HET-s prion aggregation in the presence of domain V/ IV/II of rRNA. The rRNAs, especially domain V rRNA not only reduced HET-s aggregation, but also changed the morphology of the HET-s fibrils, which became shorter and less compact. These results show that PFAR actively prevents large amyloid aggregation and thus, possibly influence prion propagation.