Ation of the trimeric protease.SBP has optimum volume and contacts available including maximum hydrogen donor and acceptor groups that are crucial for interacting with peptides. The size of the site is very important since the binding peptides have 6? residues and the site needs to be large enough to accommodate them. It also has highest hydrophobicity which makes it the best interaction site and hence used in our studies. Although sites 1 and 3 have scores closer to that of SBP, taking into account all the above-mentioned parameters, SBP was chosen for further docking and MDS studies.Peptide Docking Show Similar Interacting ResiduesHere, we have used a holistic approach in designing activator peptides where different techniques were applied in parallel so as to conduct a MedChemExpress tert-Butylhydroquinone comprehensive search for a signature pattern that would dock at SBP. In one method, replicas for functional groups were chosen based on sequence and structural complementarities with hydrophobic SBP which were used for generating small molecular fragments. Scores obtained from docking these small molecules (Table S1) provided the framework for designing different combinations of tetrapeptides as shown in Table S2. With leads from literature and in silico structure-guided design, Gly and Val residues were added at N- and C-termini respectively of some peptides which subsequently increased the docking scores from 26 to 210 kcal/mol. Similarly, two peptides previously reported in the literature as well peptides designed from the putative binding sites in pea-15 and Hax-1 also interacted well with SBP. Analysis of docking results with all these different peptides show interaction with similar residues of SBP as observed in ligplot (Figure S1). However, the control peptide KNNPNNAHQN, which has quite a few asparagine residues, is an ideal sequence to act as negative peptide for the pocket due to its stereochemical properties [19], did not bind to SBP demonstrating the specificity of designed peptides. From the above extensive docking analysis, N216, S217, S219, E292 and E296 in SBP were found to be common for most of the peptide interactions (Figures 2a ). Of these residues, N216, S217, S219 belong to the linker region while E292 and E296 to the PDZ domain that were either involved in hydrogen bond formation or Van der Waals interaction with the peptides. This result suggests that SBP might be the possible binding site and therefore a 18325633 prospective putative allosteric site. The role of some of these important residues in allostery if any and its subsequent effect on catalytic activity and substrate turnover was further probed by enzymology studies as described later in the text.Results Identification of Selective Binding Pocket (SBP)The high resolution crystal 223488-57-1 site structure of HtrA2 [4] (Figure 1a) that lacked flexible loops, linkers and some N-terminal residues was the target protein for our studies. These regions were modelled and energy minimised as described under Methods section. Comparison of refined model with unrefined structure showed significant movements of the loops defining new binding sites on the protein surface. The linker at SPD-PDZ interface moved towards a7 of PDZ domain whereas the linker in the protease domain moved closer to the SPD-PDZ linker so as to form a groove (Figure 1b). Among the five possible putative binding sites that were identified, Site2 or SBP (Figure 1c) that encompasses the groove generated by SPD-PDZ linker, protease and PDZ domains attain.Ation of the trimeric protease.SBP has optimum volume and contacts available including maximum hydrogen donor and acceptor groups that are crucial for interacting with peptides. The size of the site is very important since the binding peptides have 6? residues and the site needs to be large enough to accommodate them. It also has highest hydrophobicity which makes it the best interaction site and hence used in our studies. Although sites 1 and 3 have scores closer to that of SBP, taking into account all the above-mentioned parameters, SBP was chosen for further docking and MDS studies.Peptide Docking Show Similar Interacting ResiduesHere, we have used a holistic approach in designing activator peptides where different techniques were applied in parallel so as to conduct a comprehensive search for a signature pattern that would dock at SBP. In one method, replicas for functional groups were chosen based on sequence and structural complementarities with hydrophobic SBP which were used for generating small molecular fragments. Scores obtained from docking these small molecules (Table S1) provided the framework for designing different combinations of tetrapeptides as shown in Table S2. With leads from literature and in silico structure-guided design, Gly and Val residues were added at N- and C-termini respectively of some peptides which subsequently increased the docking scores from 26 to 210 kcal/mol. Similarly, two peptides previously reported in the literature as well peptides designed from the putative binding sites in pea-15 and Hax-1 also interacted well with SBP. Analysis of docking results with all these different peptides show interaction with similar residues of SBP as observed in ligplot (Figure S1). However, the control peptide KNNPNNAHQN, which has quite a few asparagine residues, is an ideal sequence to act as negative peptide for the pocket due to its stereochemical properties [19], did not bind to SBP demonstrating the specificity of designed peptides. From the above extensive docking analysis, N216, S217, S219, E292 and E296 in SBP were found to be common for most of the peptide interactions (Figures 2a ). Of these residues, N216, S217, S219 belong to the linker region while E292 and E296 to the PDZ domain that were either involved in hydrogen bond formation or Van der Waals interaction with the peptides. This result suggests that SBP might be the possible binding site and therefore a 18325633 prospective putative allosteric site. The role of some of these important residues in allostery if any and its subsequent effect on catalytic activity and substrate turnover was further probed by enzymology studies as described later in the text.Results Identification of Selective Binding Pocket (SBP)The high resolution crystal structure of HtrA2 [4] (Figure 1a) that lacked flexible loops, linkers and some N-terminal residues was the target protein for our studies. These regions were modelled and energy minimised as described under Methods section. Comparison of refined model with unrefined structure showed significant movements of the loops defining new binding sites on the protein surface. The linker at SPD-PDZ interface moved towards a7 of PDZ domain whereas the linker in the protease domain moved closer to the SPD-PDZ linker so as to form a groove (Figure 1b). Among the five possible putative binding sites that were identified, Site2 or SBP (Figure 1c) that encompasses the groove generated by SPD-PDZ linker, protease and PDZ domains attain.