Biophysical and biochemical characterization of a thermostable archaeal cyclophilin from Methanobrevibacter ruminantium.

The archaeal protein folding machinery is quite similar to that found in eukaryotes, especially in terms of shared components like chaperones. Cyclophilins are chaperones found in both eukaryotes and archaea, which catalyze the reversible cis-trans isomerization around peptidyl-prolyl imide bond (PPIase activity). Eukaryotes possess multiple cyclophilin genes, many of which have acquired divergent functions. Archaea, having a single copy of this gene, may help better in comprehending the role of cyclophilins in maintaining cellular proteostasis. However, no cyclophilin homologs from archaea have been characterized as yet, limiting comparison with their eukaryotic counterparts. In the present work, we characterize in detail a cyclophilin from the archaea, Methanobrevibacter ruminantium (MrCyp). We explore the functional and structural characteristics of MrCyp using various biophysical techniques. MrCyp exhibits both the PPIase and aggregation prevention activity. Analysis of folding/unfolding data and measurement of ∆G and T suggest that the protein is thermodynamically stable. MrCyp helps in increasing cell viability of E. coli cells. These features imply that MrCyp could be a promising candidate for co-expression mediated enhancement in the yield and quality of over-expressed proteins in heterologous expression systems such as E. coli. This is the first study of its kind, reporting the detailed functional characterization of an archaeal cyclophilin.