RNA methylation under heat shock control.

Structural, biochemical, and genetic techniques were applied to investigate the function of FtsJ, a recently identified heat shock protein. FtsJ is well conserved, from bacteria to humans. The 1.5 A crystal structure of FtsJ in complex with its cofactor S-adenosylmethionine revealed that FtsJ has a methyltransferase fold. The molecular surface of FtsJ exposes a putative nucleic acid binding groove composed of highly conserved, positively charged residues. Substrate analysis showed that FtsJ methylates 23S rRNA within 50S ribosomal subunits in vitro and in vivo. Null mutations in ftsJ show a dramatically altered ribosome profile, a severe growth disadvantage, and a temperature-sensitive phenotype. Our results reveal an unexpected link between the heat shock response and RNA metabolism.

Analysis of a mutation in phosphodiesterase type 4 that alters both inhibitor activity and nucleotide selectivity.

Cyclic nucleotide phosphodiesterase type 4 (PDE4) is a cAMP-specific phosphodiesterase that is found as four distinct genes in the mammalian genome (PDE4A, 4B, 4C, and 4D). Mutation analysis was done to identify the amino acids involved in activity and inhibitor selectivity. Mutations at Asp333 were made in HSPDE4D3 based on mutations that affect rolipram sensitivity in RNPDE4B1. The PDE4D3 Asp-Asn mutant was resistant to inhibition by rolipram as well as several other PDE4 inhibitors tested. These results suggest that this residue is near the inhibitor binding pocket in PDE4D3. Sequence comparison of PDE4 with cGMP-specific PDE proteins shows a conserved aspartic acid at position 333 in PDE4D3 and a conserved asparagine at this position in PDE enzymes that hydrolyze cGMP. Therefore, cGMP hydrolysis by PDE4D3 Asp-Asn was measured. PDE4D3 Asp-Asn hydrolyzes cGMP with kinetic constants similar to those observed for this protein with cAMP (K(m) approximately 20 microM, V(max) approximately 2 micromol AMP/min/mg recombinant protein). Under identical conditions, the K(m) value for cAMP hydrolysis by wild-type PDE4D3 is 3 microM and the V(max) value is 1 micromol AMP/min/mg recombinant protein. In addition, the PDE4D3 Asp-Ala mutant protein could hydrolyze cGMP. Finally, the analogous mutation in HSPDE4B1 (Asp413Asn) also allows hydrolysis of cGMP. These results show that this aspartic acid residue is important in inhibitor binding and nucleotide discrimination and suggest this residue is in the active site of PDE4.

Crystal structure of the catalytic domain of the human cell cycle control phosphatase, Cdc25A.

Cdc25 phosphatases activate the cell division kinases throughout the cell cycle. The 2.3 A structure of the human Cdc25A catalytic domain reveals a small alpha/beta domain with a fold unlike previously described phosphatase structures but identical to rhodanese, a sulfur-transfer protein. Only the active-site loop, containing the Cys-(X)5-Arg motif, shows similarity to the tyrosine phosphatases. In some crystals, the catalytic Cys-430 forms a disulfide bond with the invariant Cys-384, suggesting that Cdc25 may be self-inhibited during oxidative stress. Asp-383, previously proposed to be the general acid, instead serves a structural role, forming a conserved buried salt-bridge. We propose that Glu-431 may act as a general acid. Structure-based alignments suggest that the noncatalytic domain of the MAP kinase phosphatases will share this topology, as will ACR2, a eukaryotic arsenical resistance protein.

Structure and function of the protein tyrosine phosphatases.

The tyrosine and dual-specificity phosphatases are involved in signaling, cell growth and differentiation, and the cell cycle. The enzymes share a common catalytic mechanism mediated by an active site cysteine, arginine and aspartic acid. Supplementary domains assist in targeting and substrate specificity.

The X-ray crystal structures of Yersinia tyrosine phosphatase with bound tungstate and nitrate. Mechanistic implications.

X-ray crystal structures of the Yersinia tyrosine phosphatase (PTPase) in complex with tungstate and nitrate have been solved to 2. 4-A resolution. Tetrahedral tungstate, WO42-, is a competitive inhibitor of the enzyme and is isosteric with the substrate and product of the catalyzed reaction. Planar nitrate, NO3-, is isosteric with the PO3 moiety of a phosphotransfer transition state. The crystal structures of the Yersinia PTPase with and without ligands, together with biochemical data, permit modeling of key steps along the reaction pathway. These energy-minimized models are consistent with a general acid-catalyzed, in-line displacement of the phosphate moiety to Cys403 on the enzyme, followed by attack by a nucleophilic water molecule to release orthophosphate. This nucleophilic water molecule is identified in the crystal structure of the nitrate complex. The active site structure of the PTPase is compared to alkaline phosphatase, which employs a similar phosphomonoester hydrolysis mechanism. Both enzymes must stabilize charges at the nucleophile, the PO3 moiety of the transition state, and the leaving group. Both an associative (bond formation preceding bond cleavage) and a dissociative (bond cleavage preceding bond formation) mechanism were modeled, but a dissociative-like mechanism is favored for steric and chemical reasons. Since nearly all of the 47 invariant or highly conserved residues of the PTPase domain are clustered at the active site, we suggest that the mechanism postulated for the Yersinia enzyme is applicable to all the PTPases.

Contribution of a salt bridge to binding affinity and dUMP orientation to catalytic rate: mutation of a substrate-binding arginine in thymidylate synthase.

Invariant arginine 179, one of four arginines that are conserved in all thymidylate synthases (TS) and that bind the phosphate moiety of the substrate 2'-deoxyuridine-5'-monophosphate (dUMP), can be altered even to a negatively charged glutamic acid with little effect on kcat. In the mutant structures, ordered water or the other phosphate-binding arginines compensate for the hydrogen bonds made by Arg179 in the wild-type enzyme and there is almost no change in the conformation or binding site of dUMP. Correlation of dUMP Kds for TS R179A and TS R179K with the structures of their binary complexes shows, that the positive charge on Arg179 contributes significantly to dUMP binding affinity. kcat/K(m) for dUMP measures the rate of dUMP binding to TS during the ordered bi-substrate reaction, and in the ternary complex dUMP provides a binding surface for the cofactor. kcat/K(m) reflects the ability of the enzyme to accept a properly oriented dUMP for catalysis and is less sensitive than is Kd to the changes in electrostatics at the phosphate binding site.

Significance of structural changes in proteins: expected errors in refined protein structures.

A quantitative expression key to evaluating significant structural differences or induced shifts between any two protein structures is derived. Because crystallography leads to reports of a single (or sometimes dual) position for each atom, the significance of any structural change based on comparison of two structures depends critically on knowing the expected precision of each median atomic position reported, and on extracting it for each atom, from the information provided in the Protein Data Bank and in the publication. The differences between structures of protein molecules that should be identical, and that are normally distributed, indicating that they are not affected by crystal contacts, were analyzed with respect to many potential indicators of structure precision, so as to extract, essentially by "machine learning" principles, a generally applicable expression involving the highest correlates. Eighteen refined crystal structures from the Protein Data Bank, in which there are multiple molecules in the crystallographic asymmetric unit, were selected and compared. The thermal B factor, the connectivity of the atom, and the ratio of the number of reflections to the number of atoms used in refinement correlate best with the magnitude of the positional differences between regions of the structures that otherwise would be expected to be the same. These results are embodied in a six-parameter equation that can be applied to any crystallographically refined structure to estimate the expected uncertainty in position of each atom. Structure change in a macromolecule can thus be referenced to the expected uncertainty in atomic position as reflected in the variance between otherwise identical structures with the observed values of correlated parameters.

A ligand-induced conformational change in the Yersinia protein tyrosine phosphatase.

Protein tyrosine phosphatases (PTPases) play critical roles in the intracellular signal transduction pathways that regulate cell transformation, growth, and proliferation. The structures of several different PTPases have revealed a conserved active site architecture in which a phosphate-binding loop, together with an invariant arginine, cradle the phosphate of a phosphotyrosine substrate and poise it for nucleophilic attack by an invariant cysteine nucleophile. We previously reported that binding of tungstate to the Yop51 PTPase from Yersinia induced a loop conformational change that moved aspartic acid 356 into the active site, where it can function as a general acid. This is consistent with the aspartic acid donating a proton to the tyrosyl leaving group during the initial hydrolysis step. In this report, using a similar structure of the inactive Cys 403-->Ser mutant of the Yersinia PTPase complexed with sulfate, we detail the structural and functional details of this conformational change. In response to oxyanion binding, small perturbations occur in active site residues, especially Arg 409, and trigger the loop to close. Interestingly, the peptide bond following Asp 356 has flipped to ligate a buried, active site water molecule that also hydrogen bonds to the bound sulfate anion and two invariant glutamines. Loop closure also significantly decreases the solvent accessibility of the bound oxyanion and could effectively shield catalytic intermediates from phosphate acceptors other than water. We speculate that the intrinsic loop flexibility of different PTPases may be related to their catalytic rate and may play a role in the wide range of activities observed within this enzyme family.

The Cys(X)5Arg catalytic motif in phosphoester hydrolysis.

The Yersinia protein tyrosine phosphatase (PTPase) was identified in the genus of bacteria responsible for the plague or the Black Death and was shown to be essential for pathogenesis. The three-dimensional structure of the catalytic domain of the Yersinia PTPase has been solved, and this information along with a detailed kinetic analysis has led to a better understanding of the catalytic mechanism of the PTPase. Mutational and chemical modification experiments have established that an invariant Cys residue (Cys403) is directly involved in formation of a covalent phosphoenzyme intermediate. We have shown that Arg409 plays a critical role in PTPase action and that the Cys(X)5Arg active site motif forms a phosphate-binding loop which appears to represent the essential features necessary for catalysis by the PTPases, the dual specific phosphatases, and the low molecular weight acid phosphatases.

Crystal structure of Yersinia protein tyrosine phosphatase at 2.5 A and the complex with tungstate.

Protein tyrosine phosphatases (PTPases) and kinases coregulate the critical levels of phosphorylation necessary for intracellular signalling, cell growth and differentiation. Yersinia, the causative bacteria of the bubonic plague and other enteric diseases, secrete an active PTPase, Yop51, that enters and suppresses host immune cells. Though the catalytic domain is only approximately 20% identical to human PTP1B, the Yersinia PTPase contains all of the invariant residues present in eukaryotic PTPases, including the nucleophilic Cys 403 which forms a phosphocysteine intermediate during catalysis. We present here structures of the unliganded (2.5 A resolution) and tungstate-bound (2.6 A) crystal forms which reveal that Cys 403 is positioned at the centre of a distinctive phosphate-binding loop. This loop is at the hub of several hydrogen-bond arrays that not only stabilize a bound oxyanion, but may activate Cys 403 as a reactive thiolate. Binding of tungstate triggers a conformational change that traps the oxyanion and swings Asp 356, an important catalytic residue, by approximately 6 A into the active site. The same anion-binding loop in PTPases is also found in the enzyme rhodanese.

Water-mediated substrate/product discrimination: the product complex of thymidylate synthase at 1.83 A.

In an irreversible enzyme-catalyzed reaction, strong binding of the products would lead to substantial product inhibition. The X-ray crystal structure of the product complex of thymidylate synthase (1.83-A resolution, R factor = 0.183 for all data between 7.0 and 1.83 A) identifies a bound water molecule that serves to disfavor binding of the product nucleotide, dTMP. This water molecule is hydrogen bonded to absolutely conserved Tyr 146 (using the Lactobacillus casei numbering system) and is displaced by the C7 methyl group of the reaction product thymidylate. The relation between this observation and kinetic and thermodynamic values is discussed. The structure reveals a carbamate modified N-terminus that binds in a highly conserved site, replaced by side chains that can exploit the same site in other TS sequences. The enzyme-products complex is compared to the previously determined structure of enzyme-substrate-cofactor analog. This comparison reveals changes that occur between the first covalent complex formed between enzyme and substrate with an inhibitory cofactor analog and the completed reaction. The almost identical arrangement of ligands in these two structures contributes to our model for the TS reaction and verifies the physiological relevance of the mode in which potent inhibitors bind to this target for rational drug design.

Refined structures of substrate-bound and phosphate-bound thymidylate synthase from Lactobacillus casei.

Crystal structures of two crystal forms of the complex of Lactobacillus casei (TS) with its substrate dUMP have been solved and refined at 2.55 A resolution. The two crystal forms differ by approximately 5% in the c-axis length. The TS-dUMP complexes are symmetric dimers with dUMP bound equivalently in both active sites. dUMP is non-covalently bound in the same conformation as in ternary complexes of TS with dUMP and cofactor or cofactor analogs. The same hydrogen bonds are made between TS and substrate in the binary and ternary complexes. We have also determined the 2.36 A crystal structure of phosphate-bound L. casei TS. This structure has been refined to an R-factor of 19.3% with highly constrained geometry. Refinement has revealed the locations of all residues in the protein, including the disordered residues 90 to 119, which are part of an insert found only in the L. casei and Staphylococcus aureus transposon Tn4003 TS sequences. The 2.9 A multiple isomorphous replacement (MIR) structure of L. casei TS in a complex with its substrate dUMP has been refined to a crystallographic R-factor of 15.5%. Reducing agents were withheld from crystallization solutions during MIR structure determination to allow heavy-metal labeling of the cysteine residues. Therefore, the active-site cysteine residue in this structure is oxidized and the dUMP is found at half-occupancy in the active site. No significant conformational difference was found between the phosphate-bound and dUMP-bound structures. The TS-dUMP structures were better ordered than the phosphate-bound TS or the oxidized TS-dUMP, particularly Arg23, which is clearly hydrogen-bonded to the phosphate group of dUMP. A large and a small P6(1)22 crystal form are observed for both phosphate-bound and dUMP-bound L. casei TS. The small cell forms of the phosphate-bound and dUMP-bound enzyme are isomorphous, whereas the cell constants of the larger cell form change slightly when dUMP is bound (c = 240 A versus c = 243 A). For both liganded and unliganded enzyme, conversion from the small to the large crystal form sometimes occurs spontaneously, and the crystal packing changes at a single interface. Conversion may be the result of a small change in pH in the mother liquor surrounding the crystal. A single intermolecular contact between symmetry-related Asp287 residues is disrupted on going from the small to the large crystal form.

Structure of a non-peptide inhibitor complexed with HIV-1 protease. Developing a cycle of structure-based drug design.

A stable, non-peptide inhibitor of the protease from type 1 human immunodeficiency virus has been developed, and the stereochemistry of binding defined through crystallographic three-dimensional structure determination. The initial compound, haloperidol, was discovered through computational screening of the Cambridge Structural Database using a shape complementarity algorithm. The subsequent modification is a non-peptidic lateral lead, which belongs to a family of compounds with well characterized pharmacological properties. This thioketal derivative of haloperidol and a halide counterion are bound within the enzyme active site in a mode distinct from the observed for peptide-based inhibitors. A variant of the protease cocrystallized with this inhibitor shows binding in the manner predicted during the initial computer-based search. The structures provide the context for subsequent synthetic modifications of the inhibitor.

Tracking conformational states in allosteric transitions of phosphorylase.

An intrinsic molecular property of a protein domain can be determined by calculating its principal axes from the inertia tensor matrix. The mass-weighted principal axes can be used to calculate an ellipsoid representing the shape of the protein domain, providing an easy means of visualizing domain movements. Most importantly, the mass-weighted principal axes provide an intuitive means of characterizing domain relationships within a protein, as well as the disposition of domains in different protein conformers. Thus, this method provides a simple, quantitative description of differences of domain positions within various protein structures. We show the utility of this method by characterizing the quaternary and tertiary differences as observed in eight structures of phosphorylated or dephosphorylated glycogen phosphorylase with different effectors bound. This analysis revealed domain movements which were characteristic of the activated phosphorylase structures. The monomers of the phosphorylase dimer were found to move apart by a 2.5-A translation and to rotate apart, in three orthogonal directions, by a minimum of 3.2 degrees. Analysis of the three domains within the phosphorylase monomer showed that both simple and complex domain movements occur and that multiple domain configurations are energetically stable. We suggest that the C-terminal domain of phosphorylase moves along a simple path in the transition from an inactive to active conformation. The direction of translation and rotation is consistent, but the magnitude is variable. In contrast, this analysis showed that the activation domain did not behave as a rigid body, and therefore, the motion of this domain is not as easily characterized.

1.59 A structure of trypsin at 120 K: comparison of low temperature and room temperature structures.

The structure of a rat trypsin mutant [S195C] at a temperature of 120 K has been refined to a crystallographic R factor of 17.4% between 12.0 and 1.59 A and is compared with the structure of the D102N mutant at 295 K. A reduction in the unit cell dimensions in going from room temperature to low temperature is accompanied by a decrease in molecular surface area and radius of gyration. The overall structure remains similar to that at room temperature. The attainable resolution appears to be improved due to the decrease in the fall off of intensities with resolution [reduction of the temperature factor]. This decreases the uncertainty in the atomic positions and allows the localization of more protein atoms and solvent molecules in the low temperature map. The largest differences between the two models occur at residues with higher than average temperature factors. Several features can be localized in the solvent region of the 120 K map that are not seen in the 295 K map. These include several more water molecules as well as an interstitial sulfate ion and two interstitial benzamidine molecules.

Structure, multiple site binding, and segmental accommodation in thymidylate synthase on binding dUMP and an anti-folate.

The structure of Escherichia coli thymidylate synthase (TS) complexed with the substrate dUMP and an analogue of the cofactor methylenetetrahydrofolate was solved by multiple isomorphous replacement and refined at 1.97-A resolution to a residual of 18% for all data (16% for data greater than 2 sigma) for a highly constrained structure. All residues in the structure are clearly resolved and give a very high confidence in total correctness of the structure. The ternary complex directly suggests how methylation of dUMP takes place. C-6 of dUMP is covalently bound to gamma S of Cys-198(146) during catalysis, and the reactants are surrounded by specific hydrogen bonds and hydrophobic interactions from conserved residues. Comparison with the independently solved structure of unliganded TS reveals a large conformation change in the enzyme, which closes down to sequester the reactants and several highly ordered water molecules within a cavernous active center, away from bulk solvent. A second binding site for the quinazoline ring of the cofactor analogue was discovered by withholding addition of reducing agent during crystal storage. The chemical change in the protein is slight, and from difference density maps modification of sulfhydryls is not directly responsible for blockade of the primary site. The site, only partially overlapping with the primary site, is also surrounded by conserved residues and thus may play a functional role. The ligand-induced conformational change is not a domain shift but involves the segmental accommodation of several helices, beta-strands, and loops that move as units against the beta-sheet interface between monomers.

Plastic adaptation toward mutations in proteins: structural comparison of thymidylate synthases.

The structure of thymidylate synthase (TS) from Escherichia coli was solved from cubic crystals with a = 133 A grown under reducing conditions at pH 7.0, and refined to R = 22% at 2.1 A resolution. The structure is compared with that from Lactobacillus casei solved to R = 21% at 2.3 A resolution. The structures are compared using a difference distance matrix, which identifies a common core of residues that retains the same relationship to one another in both species. After subtraction of the effects of a 50 amino acid insert present in Lactobacillus casei, differences in position of atoms correlate with temperature factors and with distance from the nearest substituted residue. The dependence of structural difference on thermal factor is parameterized and reflects both errors in coordinates that correlate with thermal factor, and the increased width of the energy well in which atoms of high thermal factor lie. The dependence of structural difference on distance from the nearest substitution also depends on thermal factors and shows an exponential dependence with half maximal effect at 3.0 A from the substitution. This represents the plastic accommodation of the protein which is parameterized in terms of thermal B factor and distance from a mutational change.