Crystallographic study of mechanism of ribonuclease T1-catalysed specific RNA hydrolysis

Ribonuclease T1 (RNase T1) cleaves the phosphodiester bond of RNA specifically at the 3'-end of guanosine. 2'-guanosinemonophosphate (2'-GMP) acts as inhibitor for this reaction and was cocrystallized with RNase T1. X-Ray analysis provided insight in the geometry of the active site and in the parts of the enzyme involved in the recognition of guanosine. RNase T1 is globular in shape and consists of a 4.5 turns alpha-helix lying "below" a four-stranded antiparallel beta-sheet containing recognition center as well as active site. The latter is indicated by the position of phosphate and sugar residues of 2'-GMP and shows that Glu58, His92 and Arg77 are active in phosphodiester hydrolysis. Guanine is recognized by a stretch of protein from Tyr42 to Tyr45. Residues involved in recognition are peptide NH and C = O, guanine O6 and N1H which form hydrogen bonds and a stacking interaction of Tyr45 on guanine. Although, on a theoretical basis, many specific amino acid-guanine interactions are possible, none is employed in the RNase T1.guanine recognition.     

Three-dimensional structure of ribonuclease T1 complexed with an isosteric phosphonate substrate analogue of GpU: alternate substrate binding modes and catalysis

The X-ray crystal structure of a complex between ribonuclease T1 and guanylyl(3'-6')-6'-deoxyhomouridine (GpcU) has been determined at 2. 0 A resolution. This ligand is an isosteric analogue of the minimal RNA substrate, guanylyl(3'-5')uridine (GpU), where a methylene is substituted for the uridine 5'-oxygen atom. Two protein molecules are part of the asymmetric unit and both have a GpcU bound at the active site in the same manner. The protein-protein interface reveals an extended aromatic stack involving both guanines and three enzyme phenolic groups. A third GpcU has its guanine moiety stacked on His92 at the active site on enzyme molecule A and interacts with GpcU on molecule B in a neighboring unit via hydrogen bonding between uridine ribose 2'- and 3'-OH groups. None of the uridine moieties of the three GpcU molecules in the asymmetric unit interacts directly with the protein. GpcU-active-site interactions involve extensive hydrogen bonding of the guanine moiety at the primary recognition site and of the guanosine 2'-hydroxyl group with His40 and Glu58. On the other hand, the phosphonate group is weakly bound only by a single hydrogen bond with Tyr38, unlike ligand phosphate groups of other substrate analogues and 3'-GMP, which hydrogen-bonded with three additional active-site residues. Hydrogen bonding of the guanylyl 2'-OH group and the phosphonate moiety is essentially the same as that recently observed for a novel structure of a RNase T1-3'-GMP complex obtained immediately after in situ hydrolysis of exo-(Sp)-guanosine 2',3'-cyclophosphorothioate [Zegers et al. (1998) Nature Struct. Biol. 5, 280-283]. It is likely that GpcU at the active site represents a nonproductive binding mode for GpU [Steyaert, J., and Engleborghs (1995) Eur. J. Biochem. 233, 140-144]. The results suggest that the active site of ribonuclease T1 is adapted for optimal tight binding of both the guanylyl 2'-OH and phosphate groups (of GpU) only in the transition state for catalytic transesterification, which is stabilized by adjacent binding of the leaving nucleoside (U) group.     

Removing a hydrogen bond in the dimer interface of Escherichia coli manganese superoxide dismutase alters structure and reactivity

Among manganese superoxide dismutases, residues His30 and Tyr174 are highly conserved, forming part of the substrate access funnel in the active site. These two residues are structurally linked by a strong hydrogen bond between His30 NE2 from one subunit and Tyr174 OH from the other subunit of the dimer, forming an important element that bridges the dimer interface. Mutation of either His30 or Tyr174 in Escherichia coli MnSOD reduces the superoxide dismutase activity to 30--40% of that of the wt enzyme, which is surprising, since Y174 is quite remote from the active site metal center. The 2.2 A resolution X-ray structure of H30A-MnSOD shows that removing the Tyr174-->His30 hydrogen bond from the acceptor side results in a significant displacement of the main-chain segment containing the Y174 residue, with local rearrangement of the protein. The 1.35 A resolution structure of Y174F-MnSOD shows that disruption of the same hydrogen bond from the donor side has much greater consequences, with reorientation of F174 having a domino effect on the neighboring residues, resulting in a major rearrangement of the dimer interface and flipping of the His30 ring. Spectroscopic studies on H30A, H30N, and Y174F mutants show that (like the previously characterized Y34F mutant of E. coli MnSOD) all lack the high pH transition of the wt enzyme. This observation supports assignment of the pH sensitivity of MnSOD to coordination of hydroxide ion at high pH rather than to ionization of the phenolic group of Y34. Thus, mutations near the active site, as in the Y34F mutant, as well as at remote positions, as in Y174F, similarly affect the metal reactivity and alter the effective pK(a) for hydroxide ion binding. These results imply that hydrogen bonding of the H30 imidazole N--H group plays a key role in substrate binding and catalysis.     

Modes of binding of 2'-AMP to RNase T1. A computer modeling study.

The modes of binding of adenosine 2'-monophosphate (2'-AMP) to the enzyme ribonuclease (RNase) T1 were determined by computer modelling studies. The phosphate moiety of 2'-AMP binds at the primary phosphate binding site. However, adenine can occupy two distinct sites--(1) The primary base binding site where the guanine of 2'-GMP binds and (2) The subsite close to the N1 subsite for the base on the 3'-side of guanine in a guanyl dinucleotide. The minimum energy conformers corresponding to the two modes of binding of 2'-AMP to RNase T1 were found to be of nearly the same energy implying that in solution 2'-AMP binds to the enzyme in both modes. The conformation of the inhibitor and the predicted hydrogen bonding scheme for the RNase T1-2'-AMP complex in the second binding mode (S) agrees well with the reported x-ray crystallographic study. The existence of the first mode of binding explains the experimental observations that RNase T1 catalyses the hydrolysis of phosphodiester bonds adjacent to adenosine at high enzyme concentrations. A comparison of the interactions of 2'-AMP and 2'-GMP with RNase T1 reveals that Glu58 and Asn98 at the phosphate binding site and Glu46 at the base binding site preferentially stabilise the enzyme-2'-GMP complex.     

Computer modeling studies on the subsite interactions of ribonuclease T1.

The modes of binding of pGp,ApG,CpG and UpG to the enzyme ribonuclease T1 were determined by computer modeling. Essentially two binding modes are possible for all the four ligands--one with the 3'-phosphate group occupying the phosphate binding site (substrate mode of binding) and the second with the 5'-phosphate group occupying the phosphate binding site (inhibitor mode of binding). The latter binding mode is energetically favoured over the former and in this mode the base (G) and the 5'-phosphate moieties occupy the same sites on the enzyme as 5'-GMP when bound to RNase T1. The ribose moiety of pGp adopts a C3'-endo pucker form when bound to the enzyme and the glycosyl torsion angle will be in -syn range as 5'-GMP in the RNase T1-5'-GMP complex. Based on these results, a mechanism for the release of the product subsequent to cleavage of the substrate by the enzyme has been proposed. The amino acid residues Asn98 and Tyr45 are shown to form the subsites for the phosphate and the base respectively on the 5'-side of the guanine occupying the primary binding site. These studies also provide a stereochemical explanation for the specificity of the 1N subsite for adenine.     

X-ray crystal structures of active site mutants of the vanadium-containing chloroperoxidase from the fungus Curvularia inaequalis

The X-ray structures of the chloroperoxidase from Curvularia inaequalis, heterologously expressed in Saccharomyces cerevisiae, have been determined both in its apo and in its holo forms at 1.66 and 2.11?Å resolution, respectively. The crystal structures reveal that the overall structure of this enzyme remains nearly unaltered, particularly at the metal binding site. At the active site of the apo-chloroperoxidase structure a clearly defined sulfate ion was found, partially stabilised through electrostatic interactions and hydrogen bonds with positively charged residues involved in the interactions with the vanadate in the native protein. The vanadate binding pocket seems to form a very rigid frame stabilising oxyanion binding. The rigidity of this active site matrix is the result of a large number of hydrogen bonding interactions involving side chains and the main chain of residues lining the active site. The structures of single site mutants to alanine of the catalytic residue His404 and the vanadium protein ligand His496 have also been analysed. Additionally we determined the structural effects of mutations to alanine of residue Arg360, directly involved in the compensation of the negative charge of the vanadate group, and of residue Asp292 involved in forming a salt bridge with Arg490 which also interacts with the vanadate. The enzymatic chlorinating activity is drastically reduced to approximately 1% in mutants D292A, H404A and H496A. The structures of the mutants confirm the view of the active site of this chloroperoxidase as a rigid matrix providing an oxyanion binding site. No large changes are observed at the active site for any of the analysed mutants. The empty space left by replacement of large side chains by alanines is usually occupied by a new solvent molecule which partially replaces the hydrogen bonding interactions to the vanadate. The new solvent molecules additionally replace part of the interactions the mutated side chains were making to other residues lining the active site frame. When this is not possible, another side chain in the proximity of the mutated residue moves in order to satisfy the hydrogen bonding potential of the residues located at the active site frame.     

Crystal structure of ribonuclease T1 complexed with adenosine 2'-monophosphate at 1.8-A resolution.

Ribonuclease T1 was purified from an Escherichia coli overproducing strain and co-crystallized with adenosine 2'-monophosphate (2'-AMP) by microdialysis against 50% (v/v) 2-methyl-2,4-pentanediol in 20 mM sodium acetate, 2 mM calcium acetate, pH 4.2. The crystals have orthorhombic space group P2(1)2(1)2(1), with cell dimensions a = 48.93(1), b = 46.57(4), c = 41.04(2) A; Z = 4 and V = 93520 A3. The crystal structure was determined on the basis of the isomorphous structure of uncomplexed RNase T1 (Martinez-Oyanedel et al. (1991) submitted for publication) and refined by least squares methods using stereochemical restraints. The refinement was based on Fhkl of 7,445 reflections with Fo greater than or equal to 1 sigma (Fo) in the resolution range of 10-1.8 A, and converged at a crystallographic R factor of 0.149. The phosphate group of 2'-AMP is tightly hydrogen-bonded to the side chains of the active site residues Tyr38, His40, Glu58, Arg77, and His92, comparable with vanadate binding in the respective complex (Kostrewa, D., Choe, H.-W., Heinemann, U., and Saenger, W. (1989) Biochemistry 28, 7592-7600) and different from the complex with guanosine 2'-monophosphate (Arni, R., Heinemann, U., Tokuoka, R., and Saenger, W. (1988) J. Biol. Chem. 263, 15358-15368) where the phosphate does not interact with Arg77 and His92. The adenosine moiety is not located in the guanosine recognition site but stacked on Gly74 carbonyl and His92 imidazole, which serve as a subsite, as shown previously (Lenz, A., Cordes, F., Heinemann, U., and Saenger, W. (1991) J. Biol. Chem. 266, 7661-7667); in addition, there are hydrogen bonds adenine N6H . . . O Gly74 (minor component of three-center hydrogen bond) and adenosine O5' . . . O delta Asn36. These binding interactions readily explain why RNase T1 has some affinity for 2'-AMP. The molecular structure of RNase T1 is only marginally affected by 2'-AMP binding. Its "empty" guanosine-binding site features a flipped Asn43-Asn44 peptide bond and the side chains of Tyr45, Glu46 adopt conformations typical for RNase T1 not involved in guanosine binding. The side chains of amino acids Leu26, Ser35, Asp49, Val78 are disordered. The disorder of Val78 is of interest since this amino acid is located in a hydrophobic cavity, and the disorder appears to be correlated with an "empty" guanosine-binding site. The two Asp15 carboxylate oxygens and six water molecules coordinate a Ca2+ ion 8-fold in the form of a square antiprism.     

Role of histidine-40 in ribonuclease T1 catalysis: three-dimensionalstructures of the partially active His40Lys mutant.

Histidine-40 is known to participate in phosphodiester transesterification catalyzed by the enzyme ribonuclease T1. A mutant enzyme with a lysine replacing the histidine-40 (His40Lys RNase T1) retains considerable catalytic activity [Steyaert, J., Hallenga, K., Wyns, L., & Stanssens, P. (1990) Biochemistry 29, 9064-9072]. We report on the crystal structures of His40Lys RNase T1 containing a phosphate anion and a guanosine 2'-phosphate inhibitor in the active site, respectively. Similar to previously described structures, the phosphate-containing crystals are of space group P2(1)2(1)2(1), with one molecule per asymmetric unit (a = 48.27 A, b = 46.50 A, c = 41.14 A). The complex with 2'-GMP crystallized in the lower symmetry space group P2(1), with two molecules per asymmetric unit (a = 49.20 A, b = 48.19 A, c = 40.16 A, beta = 90.26). The crystal structures have been solved at 1.8- and 2.0-A resolution yielding R values of 14.5% and 16.0%, respectively. Comparison of these His40Lys structures with the corresponding wild-type structures, containing 2'-GMP [Arni, R., Heinemann, U., Tokuoka, R., & Saenger, W. (1988) J. Biol. Chem. 263, 15358-15368] and vanadate [Kostrewa, D., Hui-Woog Choe, Heinemann, U., & Saenger, W. (1989) Biochemistry 28, 7692-7600] in the active site, respectively, leads to the following conclusions. First, the His40Lys mutation causes no significant changes in the overall structure of RNase T1; second, the Lys40 side chains in the mutant structures occupy roughly the same space as His40 in the corresponding wild-type RNase T1 structures.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structures of the ribonuclease MC1 mutants N71T and N71S in complex with 5'-GMP: structural basis for alterations in substrate specificity

Ribonuclease MC1 (RNase MC1), isolated from bitter gourd seeds, is a uridine specific RNase belonging to the RNase T2 family. Mutations of Asn71 in RNase MC1 to the amino acids Thr (N71T) and Ser (N71S) in guanosine preferential RNases altered the substrate specificity from uridine specific to guanosine specific, as shown by the transphosphorylation of diribonucleoside monophosphates [Numata, T., et al. (2001) Biochemistry 40, 524-530]. To elucidate the structural basis for the alteration of substrate specificity, crystal structures of the RNase MC1 mutants N71T and N71S, free or complexed with 5'-GMP, were determined at resolutions higher than 2 A. In the N71T-5'-GMP and N71S-5'-GMP complexes, the guanine moiety was, as in the case of the uracil moiety bound to wild-type RNase MC1, firmly stabilized in the B2 site by an extensive network of hydrogen bonds and hydrophobic interactions. Structure comparisons showed that mutations of Asn71 to Thr or Ser cause an enlargement of the B2 site, which then make it feasible to insert a guanine base into the B2 site of mutants N71T and N71S. This binding further allows for hydrogen bonding interaction of the side chain hydroxyl groups of Thr71 or Ser71 with the N7 atom of the guanine base. The mode of guanine binding of mutants N71T and N71S was found to be essentially identical to that of a guanosine preferential RNase NW from Nicotiana glutinosa. In particular, hydrogen bonds between the N7 atom of the guanine base and the hydroxyl groups of the amino acids at position 71 (RNase MC1 numbering) were completely conserved in three guanosine preferential enzymes, thereby indicating that the hydrogen bond may play an essential role in guanine binding in guanosine preferential RNases in the RNase T2 family. Consequently, it can be concluded that amino acids at position 71 (RNase MC1 numbering) serve as one of the determinants for substrate specificity (or preference) in the RNase T2 fimily by changing the size and shape of the B2 site.     

Three-dimensional structure of the ribonuclease T1 2'-GMP complex at 1.9-A resolution

The complex formed between the enzyme ribonuclease T1 (EC 3.1.27.3) and its specific inhibitor 2'-guanylic acid (2'-GMP) has been refined to R = 0.180 using x-ray diffraction data to 1.9-A resolution. The protein molecule displays a compact fold; a 4.5 turn alpha-helix packed over an antiparallel beta-pleated sheet shields most of the hydrophobic interior of the protein against the solvent. The extended pleated sheet structure of ribonuclease T1 is composed of three long and four short strands building up a two-stranded minor beta-sheet near the amino terminus and a five-stranded major sheet in the interior of the protein molecule. In the complex with ribonuclease T1, the inhibitor 2'-guanylic acid adopts the syn-conformation and C2'-endo sugar pucker. Binding of the nucleotide is mainly achieved through amino acid residues 38-46 of the protein. The catalytically active amino acid residues of ribonuclease T1 (His40, Glu58, Arg77, and His92) are located within the major beta-sheet which, as evident from the analysis of atomic temperature factors, provides an environment of minimal local mobility. The geometry of the active site is consistent with a mechanism for phosphodiester hydrolysis where, in the transesterification step, His40 and/or Glu58 act as a general base toward the ribose 2'-hydroxyl group and His92, as a general acid, donates a proton to the leaving 5'-hydroxyl group.     

Refined X-ray structure of the low pH form of ribonuclease T1-2'-guanylic acid complex at 1.9 A resolution

The three-dimensional X-ray structure of the RNase T1[EC 3.1.27.3]-2'GMP complex crystallized at low pH value (4.0) was determined, and refined to 1.9 A resolution to give a final R value of 0.203. The refined model includes 781 protein atoms, 24 inhibitor atoms, and 43 solvent molecules. The imidazole rings of His27 and His40 interact with the carboxyl side chains of Glu82 and Glu58, respectively, whereas that of His92 is in contact with the main chain carbonyl oxygen of Ala75. In the complex, the ribose ring of the 2'GMP molecule adopts a C2'-endo puckering, and the exocyclic conformation is gauche(-)-gauche(+). The glycosyl torsion angle is in the syn range with an intramolecular hydrogen bond between N3 and O5', and the 2'-phosphate orientation is trans-gauche(-). The guanine base of the inhibitor is tightly bound to the base recognition site with five hydrogen bonds (N1--Glu46O epsilon 2, N2---Asn98O,O6---Asn44N, and N7 ---Asn43N delta 2/Asn43N) and is sandwiched between the phenolic ring portions of Tyr42 and Tyr45 by stacking interactions. The 2'-phosphate group interacts with Arg77N eta 2, Glu58O episilon 2, and Tyr 38O eta but not with any of the histidine residues. Arg77N eta 2 also interacts with Tyr38O eta. There is no interaction between the ribose moiety of the inhibitor and the enzyme.     

Role of hydrogen bonding in the active site of human manganese superoxide dismutase

The side chain of Gln143, a conserved residue in manganese superoxide dismutase (MnSOD), forms a hydrogen bond with the manganese-bound solvent and is critical in maintaining catalytic activity. The side chains of Tyr34 and Trp123 form hydrogen bonds with the carboxamide of Gln143. We have replaced Tyr34 and Trp123 with Phe in single and double mutants of human MnSOD and measured their catalytic activity by stopped-flow spectrophotometry and pulse radiolysis. The replacements of these side chains inhibited steps in the catalysis as much as 50-fold; in addition, they altered the gating between catalysis and formation of a peroxide complex to yield a more product-inhibited enzyme. The replacement of both Tyr34 and Trp123 in a double mutant showed that these two residues interact cooperatively in maintaining catalytic activity. The crystal structure of Y34F/W123F human MnSOD at 1.95 A resolution suggests that this effect is not related to a conformational change in the side chain of Gln143, which does not change orientation in Y34F/W123F, but rather to more subtle electronic effects due to the loss of hydrogen bonding to the carboxamide side chain of Gln143. Wild-type MnSOD containing Trp123 and Tyr34 has approximately the same thermal stability compared with mutants containing Phe at these positions, suggesting the hydrogen bonds formed by these residues have functional rather than structural roles.     

The three-dimensional structure of guanine-specific ribonuclease F1 in solution determined by NMR spectroscopy and distance geometry.

Two-dimensional 1H-NMR studies have been performed on ribonuclease F1 (RNase F1), which contains 106 amino acid residues. Sequence-specific resonance assignments were accomplished for the backbone protons of 99 amino acid residues and for most of their side-chain protons. The three-dimensional structures were constructed on the basis of 820 interproton-distance restraints derived from NOE, 64 distance restraints for 32 hydrogen bonds and 33 phi torsion-angle restraints. A total of 40 structures were obtained by distance geometry and simulated-annealing calculations. The average root-mean-square deviation (residues 1-106) between the 40 converged structures and the mean structure obtained by averaging their coordinates was 0.116 +/- 0.018 nm for the backbone atoms and 0.182 +/- 0.015 nm for all atoms including the hydrogen atoms. RNase F1 was determined to be an alpha/beta-type protein. A well-defined structure constitutes the core region, which consists of a small N-terminal beta-sheet (beta 1, beta 2) and a central five-stranded beta-sheet (beta 3-beta 7) packed on a long helix. The structure of RNase F1 has been compared with that of RNase T1, which was determined by X-ray crystallography. Both belong to the same family of microbial ribonucleases. The polypeptide backbone fold of RNase F1 is basically identical to that of RNase T1. The conformation-dependent chemical shifts of the C alpha protons are well conserved between RNase F1 and RNase T1. The residues implicated in catalysis are all located on the central beta-sheet in a geometry similar to that of RNase T1.     

Conformational changes in phospholipase A2 upon binding to micellar interfaces in the absence and presence of competitive inhibitors. A 1H and 15N NMR study.

An NMR study has been made of porcine pancreatic phospholipase A2 (PLA) in three environments: free in solution, in a binary complex with dodecylphosphocholine micelles, and in a ternary complex with a micelle and the substrate-like inhibitor (R)-1-octyl-2-(N-dodecanoylamino)-2-deoxyglycero-3-phosph oglycol. 1H and 15N chemical shifts, amide exchange rates, and NOE intensities are compared for the enzyme in different environments. From these data, structural differences are found for the N-terminal part, the end of the surface loop at residues Tyr69 and Thr70, and the active site residue His48, and also for the Ca-binding loop (residues 28-32). Specifically, when binding to a micelle, the side chains of residues Ala1, Trp3, and Tyr69, as well as all protons of Thr70, are found to be closer together. After subsequent introduction of the competitive inhibitor, further changes are found for these residues. The N-terminus is flexible in PLA free in solution, in contrast with the crystal structures where it adopts an alpha-helical conformation. According to the NMR data, this helix is rigidly formed only in the ternary complex. Furthermore, in the ternary complex, the N-terminal amino group and the exchangeable hydrogen at N3 of the ring of His48 are observed. We propose that PLA is activated in two steps. An initial conformational change occurs upon binding to a micellar interface. The catalytically active conformation of the enzyme, which has an extensive network of hydrogen bonds, is formed only when binding a substrate or competitive inhibitor at a lipid-water interface.     

Guanine binding site of the Nicotiana glutinosa ribonuclease NW revealed by X-ray crystallography

Ribonuclease NW (RNase NW), the wound-inducible RNase in Nicotiana glutinosa leaves, preferentially cleaves guanylic acid. We expressed the cDNA encoding RNase NW in the methylotrophic yeast Pichia pastoris using the expression vector pPIC9K, and the resulting recombinant RNase NW (ryRNaseNW) secreted into medium was purified to apparent homogeneity using column chromatography. The crystal structure of ryRNase NW bound to 5'-GMP was determined at 1.5 A resolution by molecular replacement with tomato RNase LE as a search model. The RNase NW structurally belongs to the (alpha + beta) class of proteins, having eight helices (five alpha-helices and three 3(10) helices) and six beta-strands, and its structure is highly similar to those of other plant RNases, including a uridylic acid preferential RNase MC1 from bitter gourd seeds. The guanine ring of 5'-GMP lies in a hydrophobic pocket of the molecular surface composed of Tyr17, Tyr71, Ala80, Leu79, and Phe89: the guanine base is sandwiched between aromatic side chains of Tyr17 and Phe89. In addition, the guanine base is firmly stabilized by a network of hydrogen bonds of the side chains of Gln12 and Thr78, as well as of the main chain of Leu79. Therefore, Gln12, Tyr17, Thr78, Leu79, and Phe89 are responsible for recognition of the guanine base by RNase NW, findings which provide insight into the manner in which RNase NW preferentially cleaves guanylic acid.     

Alteration of hydrogen bonding in the vicinity of histidine 48 disrupts millisecond motions in RNase A

The motion of amino acid residues on the millisecond (ms) time scale is involved in the tight regulation of catalytic function in numerous enzyme systems. Using a combination of mutational, enzymological, and relaxation-compensated (15)N Carr-Purcell-Meiboom-Gill (CPMG) methods, we have previously established the conformational significance of the distant His48 residue and the neighboring loop 1 in RNase A function. These studies suggested that RNase A relies on an intricate network of hydrogen bonding interactions involved in propagating functionally relevant, long-range ms motions to the catalytic site of the enzyme. To further investigate the dynamic importance of this H-bonding network, this study focuses on the individual replacement of Thr17 and Thr82 with alanine, effectively altering the key H-bonding interactions that connect loop 1 and His48 to the rest of the protein. (15)N CPMG dispersion studies, nuclear magnetic resonance (NMR) chemical shift analysis, and NMR line shape analysis of point mutants T17A and T82A demonstrate that the evolutionarily conserved single H-bond linking His48 to Thr82 is essential for propagating ms motions from His48 to the active site of RNase A on the time scale of catalytic turnover, whereas the T17A mutation increases the off rate and conformational exchange motions in loop 1. Accumulating evidence from our mutational studies indicates that residues experiencing conformational exchange in RNase A can be grouped into two separate clusters displaying distinct dynamical features, which appear to be independently affected by mutation. Overall, this study illuminates how tightly controlled and finely tuned ms motions are in RNase A, suggesting that designed modulation of protein motions may be possible.     

Chemical modifications of ribonuclease U1.

In order to obtain information on the nature of the amino acid residues involved in the activity of ribonuclease U1 [EC 3.1.4.8], various chemical modifications of the enzyme were carried out. RNase U1 was inactivated by reaction with iodoacetate at pH 5.5 with concomitant incorporation of 1 carboxymethyl group per molecule of the enzyme. The residue specifically modified by iodoacetate was identified as one of the glutamic acid residues, as in the case of RNase T1. The enzyme was also inactivated extensively by reaction with iodoacetamide at pH 8.0 with the loss of about one residue each of histidine and lysine. When RNase U1 was treated with a large excess of phenylglyoxal, the enzymatic activity and binding ability toward 3'-GMP were lost, with simultaneous modification of about 1 residue of arginine. The reaction of citraconic anhydride with RNase U1 led to the loss of enzymatic activity and modification of about 1 residue of lysine. The inactivated enzyme, however, retained binding ability toward 3'-GMP. These results indicate that there are marked similarities in the active sites of RNases T1 and U1.     

The x-ray structure of epoxide hydrolase from Agrobacterium radiobacter AD1. An enzyme to detoxify harmful epoxides.

Epoxide hydrolases catalyze the cofactor-independent hydrolysis of reactive and toxic epoxides. They play an essential role in the detoxification of various xenobiotics in higher organisms and in the bacterial degradation of several environmental pollutants. The first x-ray structure of one of these, from Agrobacterium radiobacter AD1, has been determined by isomorphous replacement at 2.1-A resolution. The enzyme shows a two-domain structure with the core having the alpha/beta hydrolase-fold topology. The catalytic residues, Asp107 and His275, are located in a predominantly hydrophobic environment between the two domains. A tunnel connects the back of the active-site cavity with the surface of the enzyme and provides access to the active site for the catalytic water molecule, which in the crystal structure, has been found at hydrogen bond distance to His275. Because of a crystallographic contact, the active site has become accessible for the Gln134 side chain, which occupies a position mimicking a bound substrate. The structure suggests Tyr152/Tyr215 as the residues involved in substrate binding, stabilization of the transition state, and possibly protonation of the epoxide oxygen.     

Relaxation kinetics of ribonuclease T1 binding with guanosine and 3'-GMP.

Temperature-jump relaxation kinetic studies were undertaken at 25 degrees C with ribonuclease T1 (RNase T1) alone and in the presence of guanosine (Guo) and 3'-guanylic acid (3'-GMP). No relaxations were observed in the absence of ligands and only one process was observed in their presence which reflected a simple on-off reaction in both cases. Apparent association rate constants, k(on), and dissociation rate constants, k(off), were evaluated at several pH values and their ratios, k(on)/k(off), were contrasted with independently determined values of the equilibrium association constant, Ka(eq). The value of k(on)/k(off) for Guo was significantly greater than Ka(eq), whereas Ka(eq) was significantly greater than k(on)/k(off) for 3'-GMP. The simplest interpretation of the result for Guo is that free RNase T1 undergoes a relatively slow undetected isomerization and Guo can bind only with one isomer. 3'-GMP can be considered to bind with the same preference, but in this case the initial enzyme complex undergoes a relatively slow undetected isomerization. These results are consistent with a recent NMR study which suggested that RNase T1 binding with Guo and 3'-GMP are coupled to slow exchange processes in a ligand dependent manner (Shimada, I. and Inagaki, F. (1990) Biochemistry 29, 757-764). It is tentatively concluded that binding of Guo and 3'-GMP at the active site of RNase T1 is limited to a sub-population of conformers involving the base-recognition site and that the phosphomonoester group of the nucleotide can engage in additional conformationally linked interactions at the adjacent catalytic site.     

E. COLI RNASE HI AND THE PHOSPHONATE-DNA/RNA HYBRID: MOLECULAR DYNAMICS SIMULATIONS

A model for the complex between E. coli RNase HI and the DNA/RNA hybrid (previously refined by molecular dynamics simulations) was used to determine the impact of the internucleotide linkage modifications (either 3′–O–CH₂–P–O–5′ or 3′–O–P–CH₂–O–5′) on the ability of the modified-DNA/RNA hybrid to create a complex with the protein. Modified internucleotide linkages were incorporated systematically at different positions close to the 3′-end of the DNA strand to interfere with the DNA binding site of RNase H. Altogether, six trajectories were produced (length 1.5). Mutual hydrogen bonds connecting both strands of the nucleic acids hybrid, DNA with RNase H, RNA with RNase H, and the scissile bond with the Mg⁺⁺ · 4H₂O chelate complex (bound in the active site) were analyzed in detail. Many residues were involved in binding of the DNA (Arg88, Asn84, Trp85, Trp104, Tyr73, Lys99, Asn100, Thr43, and Asn16) and RNA (Gln76, Gln72, Tyr73, Lys122, Glu48, Asn44, and Cys13) strand to the substrate-binding site of the RNase H enzyme. The most remarkable disturbance of the hydrogen bonding net was observed for structures with modified internucleotide linkages positioned in a way to interact with the Trp104, Tyr73, Lys99, and Asn100 residues (situated in the middle of the DNA binding site, where a cluster of Trp residues forms a rigid core of the protein structure).