We report the X-ray analysis at 2.0 A resolution for crystals of the aspartic proteinase endothiapepsin (EC 3.4.23.6) complexed with a potent difluorostatone-containing tripeptide renin inhibitor 282). The scissile bond surrogate, an electrophilic ketone, is hydrated in the complex. The pro-(R) (statine-like) hydroxyl of the tetrahedral carbonyl hydrate is hydrogen-bonded to both active-site aspartates 32 and 215 in the position occupied by a water in the native enzyme. The second hydroxyl oxygen of the hydrate is hydrogen-bonded only to the outer oxygen of Asp 32. These experimental data provide a basis for a model of the tetrahedral intermediate in aspartic proteinase-mediated cleavage of the amide bond. This indicates a mechanism in which Asp 32 is the proton donor and Asp 215 carboxylate polarizes a bound water for nucleophilic attack. The mechanism involves a carboxylate (Asp 32) that is stabilized by extensive hydrogen bonding, rather than an oxyanion derivative of the peptide as in serine proteinase catalysis.
Comparison of the three-dimensional structures of native endothiapepsin (EC 3.4.23.6) and 15 endothiapepsin oligopeptide inhibitor complexes defined at high resolution by X-ray crystallography shows that endothiapepsin exists in two forms differing in the relative orientation of a domain comprising residues 190-302. There are relatively few interactions between the two parts of the enzyme; consequently, they can move as separate rigid bodies. A translational, librational, and screw analysis of the thermal parameters of endothiapepsin also supports a model in which the two parts can move relative to each other. In the comparison of different aspartic proteinases, the rms values are reduced by up to 47% when the two parts of the structure are superposed independently. This justifies description of the differences, including those between pepsinogen and pepsin (EC 3.4.34.1), as a rigid movement of one part relative to another although considerable distortions within the domains also occur. The consequence of the rigid body movement is a change in the shape of the active site cleft that is largest around the S3 pocket. This is associated with a different position and conformation of the inhibitors that are bound to the two endothiapepsin forms. The relevance of these observations to a model of the hydrolysis by aspartic proteinases is briefly discussed.
The conformation of the synthetic renin inhibitor CP‐69,799, bound to the active site of the fungal aspartic proteinase endothiapepsin (EC 3.4.23.6), has been determined by X‐ray diffraction at 1.8 A resolution and refined to the crystallographic R factor of 16%. CP‐69,799 is an oligopeptide transition‐‐state analogue inhibitor that contains a new dipeptide isostere at the P1‐P1′ position. This dipeptide isostere is a nitrogen analogue of the well‐explored hydroxyethylene dipeptide isostere, wherein the tetrahedral P1′ C alpha atom has been replaced by trigonal nitrogen. The inhibitor binds in the extended conformation, filling S4 to S3′ pockets, with hydroxyl group of the P1 residue positioned symmetrically between the two catalytic aspartates of the enzyme. Interactions between the inhibitor and the enzyme include 12 hydrogen bonds and extensive van der Waals contacts in all the pockets, except for S3′. The crystal structure reveals a bifurcated orientation of the P2 histidine side chain and an interesting relative rotation of the P3 phenyl ring to accommodate the cyclohexyl side chain at P1. The binding of the inhibitor to the enzyme, while producing no large distortions in the enzyme active site cleft, results in small but significant change in the relative orientation of the two endothiapepsin domains. This structural change may represent the action effected by the proteinase as it distorts its substrate towards the transition state for proteolytic cleavage.
The molecular structure of interleukin-1 beta, a hormone-like cytokine with roles in several disease processes, has been determined at 2.0 A resolution and refined to a crystallographic R-factor of 0.19. The framework of this molecule consists of 12 antiparallel beta-strands exhibiting pseudo-3-fold symmetry. Six of the strands make up a beta-barrel with polar residues concentrated at either end. Analysis of the three-dimensional structure, together with results from site-directed mutagenesis and biochemical and immunological studies, suggest that the core of the beta-barrel plays an important functional role. A large patch of charged residues on one end of the barrel is proposed as the binding surface with which IL-1 interacts with its receptor.
Different crystal forms of bovine pancreatic ribonuclease A and hen egg white lysozyme, 2Zn insulin, 4Zn insulin and crystals of concanavalin A were examined under controlled environmental humidity in the relative humidity (r.h.) range of 100 to 75%. Many of them, but not all, undergo reversible structural transformations as evidenced by discontinuous changes in the diffraction pattern, the unit-cell dimensions and the solvent content. Tetragonal, orthorhombic and monoclinic lysozyme and a new crystal form of ribonuclease A show transformations at r.h.'s above 90%. Monoclinic lysozyme transforms at low r.h. to another monoclinic form with nearly half the original cell volume. The well known monoclinic form of ribonuclease A grown from aqueous ethanol solution undergoes two transformations while the same form grown from 2-methyl-2,4-pentanediol (MPD) solution in phosphate buffer does not transform at all. Soaking experiments involving alcohol solutions demonstrate that MPD has the effect of decreasing the r.h. at which the transformation occurs. Triclinic lysozyme, 2Zn insulin, 4Zn insulin and the crystals of cancanavalin A do not transform in the 100 to 75% r.h. range before losing crystallinity. The results obtained so far indicate that the crystal structure has a definite influence on water-mediated transformations. The transformations do not appear to depend critically on the amount of solvent in the crystals but the r.h. at which they occur is influenced by the composition of the solvent. The transformations appear to involve changes in crystal packing as well as conformational transitions in protein molecules. The present investigations and other related studies suggest that water-mediated transformations in protein crystals could be very useful in 0108-7681/85/060431-06501.50 exploring conformational transitions in and the hydration of proteins.
H-189, a synthetic human renin inhibitor, and pepstatin A, a naturally occurring inhibitor of aspartic proteinases, have been co-crystallized with the fungal aspartic proteinase endothiapepsin (EC 3.4.23.6). H-189 [Pro-His-Pro-Phe-His-Sta-(statyl)-Val-Ile-His-Lys] is an analogue of human angiotensinogen. Pepstatin A [Iva(isovaleryl)-Val-Val-Sta-Ala-Sta] is a blocked pentapeptide which inhibits many aspartic proteinases. The structures of the complexes have been determined by X-ray diffraction and refined to crystallographic R-factors of 0.15 and 0.16 at resolutions of 0.18 nm (1.8 A) and 0.2 nm (2.0 A) respectively. H-189 is in an extended conformation, in which the statine residue is a dipeptide analogue of P1 and P'1 as indicated by the conformation and network of contacts and hydrogen bonds. Pepstatin A has an extended conformation to the P'2 alanine residue, but the leucyl side chain of the terminal statine residue binds back into the S'1 subsite, and an inverse gamma-turn occurs between P'1 and P'3. The hydroxy moiety of the statine at P1 in both complexes displaces the solvent molecule that hydrogen-bonds with the catalytic aspartate residues (32 and 215) in the native enzyme. Solvent molecules originally present in the native structure at the active site are displaced on inhibitor binding (12 when pepstatin A binds; 16 when H-189 binds).
Joint refinement of macromolecules against crystallographic and nuclear magnetic resonance (NMR) observations is presented as a way of combining experimental information from the two methods. The model of interleukin-1 beta derived by the joint x-ray and NMR refinement is shown to be consistent with the experimental observations of both methods and to have crystallographic R value and geometrical parameters that are of the same quality as or better than those of models obtained by conventional crystallographic studies. The few NMR observations that are violated by the model serve as an indicator for genuine differences between the crystal and solution structures. The joint x-ray-NMR refinement can resolve structural ambiguities encountered in studies of multidomain proteins, in which low- to medium-resolution diffraction data can be complemented by higher resolution NMR data obtained for the individual domains.
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