New GroEL-like chaperonin of bacteriophage OBP Pseudomonas fluorescens suppresses thermal protein aggregation in an ATP-dependent manner.

Recently, we discovered and studied the first virus-encoded chaperonin of bacteriophage EL Pseudomonas aeruginosa, gene product (gp) 146. In the present study, we performed bioinformatics analysis of currently predicted GroEL-like proteins encoded by phage genomes in comparison with cellular and mitochondrial chaperonins. Putative phage chaperonins share a low similarity and do not form a monophyletic group; nevertheless, they are closer to bacterial chaperonins in the phylogenetic tree. Experimental investigation of putative GroEL-like chaperonin proteins has been continued by physicochemical and functional characterization of gp246 encoded by the genome of Pseudomonas fluorescens bacteriophage OBP. Unlike the more usual double-ring architecture of chaperonins, including the EL gp146, the recombinant gp246 produced by Escherichia coli cells has been purified as a single heptameric ring. It possesses ATPase activity and does not require a co-chaperonin for its function. In vitro experiments demonstrated that gp246 is able to suppress the thermal protein inactivation and aggregation in an ATP-dependent manner, thus indicating chaperonin function. Single-particle electron microscopy analysis revealed the different conformational states of OBP chaperonin, depending on the bound nucleotide.

Bacteriophage-encoded chaperonins stimulate prion protein fibrillation in an ATP-dependent manner.

The pathogenesis of the various prion diseases is based on the conformational conversion of the prion protein from its physiological cellular form to the insoluble scrapie isoform. Several chaperones, including the Hsp60 family of group I chaperonins, are known to contribute to this transformation, but data on their effects are scarce and conflicting. In this work, two GroEL-like phage chaperonins, the single-ring OBP and the double-ring EL, were found to stimulate monomeric prion protein fibrillation in an ATP-dependent manner. The resulting fibrils were characterised by thioflavin T fluorescence, electron microscopy, proteinase K digestion assay and other methods. In the presence of ATP, chaperonins were found to promote the conversion of prion protein monomers into short amyloid fibrils with their further aggregation into less toxic large clusters. Fibrils generated with the assistance of phage chaperonins differ in morphology and properties from those formed spontaneously from monomeric prion in the presence of denaturants at acidic pH.

Structural and functional diversity of novel and known bacteriophage-encoded chaperonins.

A bioinformatics analysis of the currently predicted GroEL-like proteins encoded by bacteriophage genomes was carried out in comparison with the phage double-ring EL and single-ring OBP chaperonins, previously described by us, as well as with the known chaperonins of group I and group II. A novel GroEL-like protein predicted in the genome of phage AR9 Bacillus subtilis was expressed in E. coli cells, purified and characterised by various physicochemical methods. As shown by native electrophoresis, analytical ultracentrifugation and single-particle electron microscopy analysis, the putative AR9 chaperonin is a single-ring heptamer. Like the EL and OBP chaperonins, the new AR9 chaperonin possesses chaperone activity and does not require co-chaperonin to function. It was shown to prevent aggregation and provide refolding of the denatured substrate protein, endolysin, in an ATP-dependent manner. A comparison of its structural and biochemical properties with those of the EL and OBP chaperonins suggests outstanding diversity in this group of phage chaperonins.