Novel Strategy for In Vitro Validation of Babesia orientalis Heat Shock Proteins Chaperone Activity and Thermostability.

Background: Babesia orientalis is an intra-erythrocytic protozoan parasite that causes babesiosis in water buffalo. The genome of B. orientalis has been reported and various genes have been accurately annotated, including heat shock proteins (HSP). Three B. orientalis HSPs (HSP90, HSP70 and HSP20) have been previously identified as potential antigenic targets. Here, a new validation strategy for the chaperone activities and cell protection characteristics of the three HSPs was developed in vitro. Methods: BoHSP20, BoHSP70 and BoHSP90B were amplified from cDNA, followed by cloning them into the pEGFP-N1 vector and transfecting the vector plasmid separately into 293T and Hela mammalian cells. Their expression and localization were determined by fluorescence microscopy. The biological functions and protein stability were testified through an analysis of the fluorescence intensity duration. Their role in the protection of cell viability from heat-shock treatments was examined by MTT assay (cell proliferation assay based on thiazolyl blue tetrazolium bromide). Results: Fusion proteins pEGFP-N1-BoHSP20, pEGFP-N1-BoHSP70, and pEGFP-N1-BoHSP90B (pBoHSPs: pBoHSP20; pBoHSP70 and pBoHSP90B) were identified as 47 kDa/97 kDa/118 kDa with a 27 kDa GFP tag, respectively. Prolonged fluorescent protein half-time was observed specifically in pBoHSPs under heat shock treatment at 55 °C, and BoHSP20 showed relatively better thermotolerance than BoHSP70 and BoHSP90B. Significant difference was found between pBoHSPs and controls in the cell survival curve after 2 h of 45 °C heat shock. Conclusion: Significant biological properties of heat stress-associated genes of B. orientalis were identified in eukaryote by a new strategy. Fusion proteins pBoHSP20, pBoHSP70 and pBoHSP90B showed good chaperone activity and thermo-stability in this study, implying that BoHSPs played a key role in protecting B. orientalis against heat-stress environment during parasite life cycle. In conclusion, the invitro model explored in this study provides a new way to investigate the biological functions of B. orientalis proteins during the host–parasite interaction. [ABSTRACT FROM AUTHOR]