00 Wavelength (Å) 1.5418 Resolution (Å)1 20-2.30 (2.42-2.30) R merge (%) 12.4 (55.5) I/σI 18.8 (2.6) Completeness (%) 99.6 (98.3) Redundancy 8.9 (6.1) Refinement Resolution (Å) 20-2.30 (2.42-2.30) No. reflections 54135 R work/R free 0.199/0.233 No. atoms Protein 7274 Ligand/ion 69 Compound 40 Water 468 B-factors Protein 24.081 Ligand/ion 38.819 Water 29.006 Compound 42.133 R.m.s deviations Bond lengths (Å) 0.008 Bond angles (°) 1.4
1Numbers in parentheses represent statistics in highest resolution Vactosertib shell In the complex structure, HpFabZ hexamer displayed a classical “”trimer of dimers”" organization similar to the native HpFabZ structure (PDB code 2GLL). Six monomers of the hexamer arranged a ring-like contact topology (A-B-F-E-C-D-A), and every two monomers (A/B, C/D and E/F) formed dimer each other through hydrophobic interactions. Two L-shaped substrate-binding tunnels with the entrance protected by a door residue Tyr100 were located in the interface of a dimer and ~20 Å away from each other. see more Tyr100 adopted two different conformations. The open conformation, in which the side chain of Tyr100 pointed towards Ile64′ (the prime indicated the residue from the other subunit in the dimer), allowed the chains of substrates to enter
the tunnel. While the closed conformation, in which the side chain of Tyr100 flopped ~120° around the
Cα-Cβ bond and pointed towards residue Pro112′, blocked the entrance of the tunnel and stopped the substrate chain from reaching the catalytic site. The catalytic site in the tunnel was formed by two highly conserved residues, His58 and Glu72′ that were located in the middle kink of the tunnel. Emodin inhibited HpFabZ activity by either binding to Tyr100 or embedding into the middle of the tunnel C appropriately with favorable shape of complementary, thus preventing the substrate from accessing the active site. It bound to tunnels B and C of HpFabZ hexamer with two distinct Liothyronine Sodium interaction models, similar to the binding feature of HpFabZ-compound 1 complex (PDB code: 2GLP) [8] (Fig. 3). The two binding models were shown in Fig. 4. In one model (designated hereinafter as model A in Fig. 4A), Emodin bound to the entrance of tunnel B linearly (Tyr100 of the tunnel came from monomer B). Different from the open and close conformations, the phenol ring of door residue Tyr100 flopped ~120° to a third conformation and paralleled the pyrrolidine ring of Pro112′. Ring A of Emodin was then stacked between the phenol ring and pyrrolidine ring forming a sandwich structure, while 3′-methyl of ring A also interacted with residues Arg110 and Ile111 via hydrophobic interactions.