1.72 A resolution refinement of the trigonal form of bovine pancreatic phospholipase A2.

The trigonal crystal structure of the recombinant bovine pancreatic phospholipase A2 has been re-refined at a slightly higher resolution (1.72 A). The crystals are trigonal, space group P3121, unit-cell parameters a = b = 46.78 and c = 102.89 A and are isomorphous to the previous structure. The structure was refined to a final crystallographic R value of 19.5% (Rfree = 28.4%) using 10 531 reflections. A total of 106 solvent molecules were included in the refinement compared with the earlier refinement which contains only 85 water molecules and 8 925 reflections at 1.8 A resolution. The root-mean-square deviation from the ideal bond lengths and bond angles is considerably better in the present refinement. The active site is extended ( approximately 14 A) from Ala1 to the calcium. The three catalytic residues (Asp99, His48 and the catalytic water) are connected by the conserved structural water and the N-terminal Ala1 on one side, and by the calcium through an equatorial water on the other. The water molecules play a role in the activity of the enzyme PLA2. The Ala1 end of the extended active site performs the activation of the phospholid membranes while the opposite end performs the hydrolysis of the monomeric phospholids.

Structure of the purine-pyrimidine alternating RNA double helix, r(GUAUAUA)d(C), with a 3'-terminal deoxy residue.

The crystal structure of the purine-pyrimidine alternating octameric RNA helix, r(GUAUAUA)d(C), carrying a 3'-terminal deoxycytidine residue, has been determined at 2.2 A resolution. The molecule crystallizes in the rhombohedral space group R3 (hexagonal cell constants: a = b = 43.07,c = 59.36 A;alpha = beta = 90,gamma = 120 degrees )with one duplex in an asymmetric unit. The structure was solved by molecular replacement and refined with 83 and 2/3 solvent molecules and 2/3 sodium ions to a final R factor of 15.6% using 1775 reflections (86%). The duplexes are approximately linear, their global helix axes are inclined by 10 degrees with respect to the 3(2)-screw axes, and they are stacked on top of each other in a head-to-tail fashion. The twist between the junction base pairs of the stacked duplexes is negligible resulting in a discontinuity of the helix backbones and grooves. The sodium ions on the threefold axis play a significant role in the organization of the packing network. The helical parameters, particularly the twist and the roll, of this alternating sequence are in accord with Calladine's rules. Almost all the 2'-hydroxyl groups are involved in specific hydrogen-bonding interactions, either directly to the sugar ring oxygens O4' on the 3' side, or, through water bridges, to the sugars, phosphates, or bases. This hydrogen bonding of the 2'-hydroxyl groups restrains the conformation of the sugar-phosphate backbone and the glycosidic torsion angles of this RNA fragment. The lack of intermolecular packing contacts in the grooves provides a clear picture of the groove solvation.

X-ray structures of the B-DNA dodecamer d(CGCGTTAACGCG) with an inverted central tetranucleotide and its netropsin complex.

The crystal structures of the B-DNA dodecamer d(CGCGTTAACGCG) duplex (T2A2), with the inverted tetranucleotide core from the duplex d(CGCGAATTCGCG) [A2T2, Dickerson & Drew (1981). J. Mol. Biol. 149, 761-768], and its netropsin complex (T2A2-N) have been determined at 2.3 A resolution. The crystals are orthorhombic, space group P2(1)2(1)2(1), unit-cell dimensions of a = 25.7, b = 40.5 and c = 67.0 A, for T2A2 and a = 25.49, b = 40.87, c = 67.02 A for T2A2-N and are isomorphous with A2T2. The native T2A2 structure, with 70 water molecules had a final R value of 0.15 for 1522 reflections (F > 2sigma), while for the netropsin complex, with 87 water molecules, the R value was 0.16 for 2420 reflections. In T2A2, a discontinuous string of zig-zagging water molecules hydrate the narrow A.T minor groove. In T2A2-N, netropsin binds in one orientation in the minor groove, covering the TTAA central region, by displacing the string of waters, forming the majority of hydrogen bonds with DNA atoms in one strand, and causing very little perturbation of the native structure. The helical twist angle in T2A2 is largest at the duplex center, corresponding to the cleavage site by the restriction enzymes HpaI and HincII. The sequence inversion AATT-->TTAA of the tetranucleotide at the center of the molecule results in a different path for the local helix axis in T2A2 and A2T2 but the overall bending is similar in both cases.

Structure and function of the catalytic site mutant Asp 99 Asn of phospholipase A2: absence of the conserved structural water.

To probe the role of the Asp-99 ... His-48 pair in phospholipase A2 (PLA2) catalysis, the X-ray structure and kinetic characterization of the mutant Asp-99-->Asn-99 (D99N) of bovine pancreatic PLA2 was undertaken. Crystals of D99N belong to the trigonal space group P3(1)21 and were isomorphous to the wild type (WT) (Noel JP et al., 1991, Biochemistry 30:11801-11811). The 1.9-A X-ray structure of the mutant showed that the carbonyl group of Asn-99 side chain is hydrogen bonded to His-48 in the same way as that of Asp-99 in the WT, thus retaining the tautomeric form of His-48 and the function of the enzyme. The NH2 group of Asn-99 points away from His-48. In contrast, in the D102N mutant of the protease enzyme trypsin, the NH2 group of Asn-102 is hydrogen bonded to His-57 resulting in the inactive tautomeric form and hence the loss of enzymatic activity. Although the geometry of the catalytic triad in the PLA2 mutant remains the same as in the WT, we were surprised that the conserved structural water, linking the catalytic site with the ammonium group of Ala-1 of the interfacial site, was ejected by the proximity of the NH2 group of Asn-99. The NH2 group now forms a direct hydrogen bond with the carbonyl group of Ala-1.

Molecular dynamics investigations of DNA triple helical models: unique features of the Watson-Crick duplex.

We have built computer models of triple helical structures with a third poly(dT) strand Hoogsteen base paired to the major groove of a poly(dA).poly(dT) Watson-Crick (WC) base-paired duplex in the canonical A-DNA as well as B-DNA. For the A-DNA form, the sugar-phosphate backbone of the third strand intertwines and clashes with the poly(dA) strand requiring a radical alteration of the duplex to access the hydrogen bonding sites in the major groove. In contrast, when the duplex was in the canonical B-DNA form, the third strand was readily accommodated in the major groove without perturbing the duplex. The triple helical model, with the duplex in the B-DNA form, was equilibrated for 400ps using molecular dynamics simulations including water molecules and counter-ions. During the entire simulations, the deoxyriboses of the adenine strand oscillate between the S-type and E-type conformations. However, 30% of the sugars of the thymine strands-II & III switch to the N-type conformation early in the simulations but return to the S-type conformation after 200ps. In the equilibrium structure, the WC duplex portion of the triplex is unique and its geometry differs from both the A- or B-DNA. the deoxyriboses of the three strands predominantly exhibit S-type conformation. Besides the sugar pucker, the major groove width and the base-tilt are analogous to B-DNA, while the X-displacement and helical twist resemble A-DNA, giving a unique structure to the triplex and the Watson & Crick and Hoogsteen duplexes.

A model for the calmodulin-peptide complex based on the troponin C crystal packing and its similarity to the NMR structure of the calmodulin-myosin light chain kinase peptide complex.

In the crystal structure of troponin C, the holo C-domain is bound in a head-to-tail fashion to the A-helix of the apo N-domain of a symmetry-related molecule. Using this interaction, we have proposed a model for the calmodulin-peptide complex. We find that the interaction of the C-domain with the A-helix is similar to that observed in the NMR structure of the calmodulin-myosin light chain kinase (MLCK) peptide complex. This similarity in binding has enabled us to make a precise sequence alignment of the target peptides in the calmodulin-binding cleft and to rationalize the amino acid sequence-dependent binding strengths of various peptides. Our model differs from that proposed by Strynadka and James (Proteins Struct. Funct. Genet. 7, 234-248, 1990) in that the peptides are rotated by 100 degrees in the calmodulin binding cleft.

Crystal structure of the Y52F/Y73F double mutant of phospholipase A2: increased hydrophobic interactions of the phenyl groups compensate for the disrupted hydrogen bonds of the tyrosines.

The enzyme phospholipase A2 (PLA2) catalyzes the hydrolysis of the sn-2 ester bond of membrane phospholipids. The highly conserved Tyr residues 52 and 73 in the enzyme form hydrogen bonds to the carboxylate group of the catalytic Asp-99. These hydrogen bonds were initially regarded as essential for the interfacial recognition and the stability of the overall catalytic network. The elimination of the hydrogen bonds involving the phenolic hydroxyl groups of the Tyr-52 and -73 by changing them to Phe lowered the stability but did not significantly affect the catalytic activity of the enzyme. The X-ray crystal structure of the double mutant Y52F/Y73F has been determined at 1.93 A resolution to study the effect of the mutation on the structure. The crystals are trigonal, space group P3(1)21, with cell parameters a = b = 46.3 A and c = 102.95 A. Intensity data were collected on a Siemens area detector, 8,024 reflections were unique with an R(sym) of 4.5% out of a total of 27,203. The structure was refined using all the unique reflections by XPLOR to a final R-factor of 18.6% for 955 protein atoms, 91 water molecules, and 1 calcium ion. The root mean square deviation for the alpha-carbon atoms between the double mutant and wild type was 0.56 A. The crystal structure revealed that four hydrogen bonds were lost in the catalytic network; three involving the tyrosines and one involving Pro-68. However, the hydrogen bonds of the catalytic triad, His-48, Asp-99, and the catalytic water, are retained. There is no additional solvent molecule at the active site to replace the missing hydroxyl groups; instead, the replacement of the phenolic OH groups by H atoms draws the Phe residues closer to the neighboring residues compared to wild type; Phe-52 moves toward His-48 and Asp-99 of the catalytic diad, and Phe-73 moves toward Met-8, both by about 0.5 A. The closing of the voids left by the OH groups increases the hydrophobic interactions compensating for the lost hydrogen bonds. The conservation of the triad hydrogen bonds and the stabilization of the active site by the increased hydrophobic interactions could explain why the double mutant has activity similar to wild type. The results indicate that the aspartyl carboxylate group of the catalytic triad can function alone without additional support from the hydrogen bonds of the two Tyr residues.

Phospholipase A2 engineering. X-ray structural and functional evidence for the interaction of lysine-56 with substrates.

Site-directed mutagenesis studies of bovine pancreatic phospholipase A2 (PLA2, overproduced in Escherichia coli) showed that replacement of surface residue Lys-56 by a neutral or hydrophobic amino acid residue resulted in an unexpected and significant change in the function of the enzyme. The kcat for phosphatidylcholine micelles increases 3-4-fold for K56M, K56I, and K56F and ca. 2-fold for K56N and K56T but does not change for K56R. These results suggest that the side chain of residue 56 has significant influence on the activity of PLA2. In order to probe the structural basis for the enhanced activity, the crystal structures of wild-type and K56M PLA2 were determined by X-ray crystallography to a resolution of 1.8 A. The results suggest that the mutation has not only perturbed the conformation of the side chain of Met-56 locally but also caused conformational changes in the neighboring loop (residues 60-70), resulting in the formation of a hydrophobic pocket by residues Met-56, Tyr-52, and Tyr-69. Docking of a phosphatidylcholine inhibitor analogue into the active site of K56M, according to the structure of the complex of cobra venom PLA2-phosphatidylethanolamine inhibitor analogue [White, S.P., Scott, D. L., Otwinowski, Z., Gleb, M. H., & Sigler, P. (1990) Science 250, 1560-1563], showed that the choline moiety [N(CH3)3]+ is readily accommodated into the newly formed hydrophobic pocket with a high degree of surface complementarity. This suggests a possible interaction between residue 56 and the head group of the phospholipid, explaining the enhanced activities observed when the positively charged Lys-56 is substituted by apolar residues, viz., K56M, K56I, and K56F. Further support for this interpretation comes from the 5-fold enhancement in kcat for the mutant K56E with a negatively charged side chain, where there would be an attractive electrostatic interaction between the side chain of Glu-56 and the positively charged choline moiety. Our results also refute a recent report [Tomasselli, A. G., Hui, J., Fisher, J., Zürcher-Neely, H., Reardon, I.M., Oriaku, E., Kézdy, F.J., & Heinrikson, R.L. (1989) J. Biol. Chem. 264, 10041-10047] that substrate-level acylation of Lys-56 is an obligatory step in the catalysis by PLA2.