Molecular modeling and analysis of hepatitis E virus (HEV) papain-like cysteine protease

The biochemical or biophysical characterization of a papain-like cysteine protease in HEV ORF1-encoded polyprotein still remains elusive. Very recently, we have demonstrated the indispensability of ORF1 protease-domain cysteines and histidines in HEV replication, ex vivo (Parvez, 2013). In this report, the polyprotein partial sequences of HEV strains and genetically-related RNA viruses were analyzed, in silico. Employing the consensus-prediction results of RUBV-p(150) protease as structural-template, a 3D model of HEV-protease was deduced. Similar to RUBV-p150, a 'papain-like beta-barrel fold' structurally confirmed the classification of HEV-protease. Further, we recognized a catalytic 'Cys434-His443' dyad homologue of RUBV-p(150) (Cys1152-His1273) and FMDV-L-pro (Cys51-His148) in line with our previous mutational analysis that showed essentiality of 'His443' but not 'His590' in HEV viability. Moreover, a RUBV 'Zn2+ binding motif' (Cys1167,Cys1175-Cys1178-Cys1225-Cys1227) equivalent of HEV was identified as 'Cys457-His458-Cys459 and Cys481-Cys483' residues within the 'beta-barrel fold'. Notably, unlike RUBV, 'His458' also clustered therein, that was in conformity with the consensus cysteine protease 'Zn2+-binding motif. By homology, we also proposed an overlapping 'Ca2+-binding site' D-X-[DNS]-[ILVFYW]-[DEN]-G-[GP]-XX-DE' signature, and a 'proline-rich motif interacting 'hyptophan (W437-W472)' module in the modeled structure. Our analysis of the predicted model therefore, warrants critical roles of the 'catalytic dyad' and 'divalent metal-binding motifs' in HEV protease structural-integrity, ORF1 self-processing, and RNA replication. This however, needs further experimental validations. (C) 2013 Elsevier B.V. All rights reserved.