REVIEW
Collectin structure: A review
- KJELL HÅKANSSON, KENNETH B.M. REID
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- 05 October 2000, pp. 1607-1617
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Collectins are animal calcium dependent lectins that target the carbohydrate structures on invading pathogens, resulting in the agglutination and enhanced clearance of the microorganism. These proteins form trimers that may assemble into larger oligomers. Each polypeptide chain consists of four regions: a relatively short N-terminal region, a collagen like region, an α-helical coiled-coil, and the lectin domain. Only primary structure data are available for the N-terminal region, while the most important features of the collagen-like region can be derived from its homology with collagen. The structures of the α-helical coiled-coil and the lectin domain are known from crystallographic studies of mannan binding protein (MBP) and lung surfactant protein D (SP-D). Carbohydrate binding has been structurally characterized in several complexes between MBP and carbohydrate; all indicate that the major interaction between carbohydrate and collectin is the binding of two adjacent carbohydrate hydroxyl group to a collectin calcium ion. In addition, these hydroxyl groups hydrogen bond to some of the calcium amino acid ligands. While each collectin trimer contains three such carbohydrate binding sites, deviation from the overall threefold symmetry has been demonstrated for SP-D, which may influence its binding properties. The protein surface between the three binding sites is positively charged in both MBP and SP-D.
Research Article
Methionine oxidation within the cerebroside-sulfate activator protein (CSAct or Saposin B)
- JULIAN P. WHITELEGGE, BRANDON PENN, TRANG TO, JEFF JOHNSON, ALAN WARING, MARK SHERMAN, RICHARD L. STEVENS, CLAIRE B. FLUHARTY, KYM F. FAULL, ARVAN L. FLUHARTY
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- 05 October 2000, pp. 1618-1630
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The cerebroside-sulfate activator protein (CSAct or Saposin B) is a small water-soluble glycoprotein that plays an essential role in the metabolism of certain glycosphingolipids, especially sulfatide. Deficiency of CSAct in humans leads to sulfatide accumulation and neurodegenerative disease. CSAct activity can be measured in vitro by assay of its ability to activate sulfatide–sulfate hydrolysis by arylsulfatase A. CSAct has seven methionine residues and a mass of 8,845 Da when deglycosylated. Mildly oxidized, deglycosylated CSAct (+16 Da), separated from nonoxidized CSAct by reversed-phase high-performance liquid chromatography (RP-HPLC), showed significant modulation of the in vitro activity. Because oxidation partially protected against CNBr cleavage and could largely be reversed by treatment with dithiothreitol, it was concluded that the major modification was conversion of a single methionine to its sulfoxide. High-resolution RP-HPLC separated mildly oxidized CSAct into seven or more different components with shorter retention times than nonoxidized CSAct. Mass spectrometry showed these components to have identical mass (+16 Da). The shorter retention times are consistent with increased polarity accompanying oxidation of surface-exposed methionyl side chains, in general accordance with the existing molecular model. A mass-spectrometric CNBr mapping protocol allowed identification of five of the seven possible methionine–sulfoxide CSAct oxoforms. The most dramatic suppression of activity occurred upon oxidation of Met61 (26% of control) with other residues in the Q60MMMHMQ66 motif falling in the 30–50% activity range. Under conditions of oxidative stress, accumulation of minimally oxidized CSAct protein in vivo could perturb metabolism of sulfatide and other glycosphingolipids. This, in turn, could contribute to the onset and progression of neurodegenerative disease, especially in situations where the catabolism of these materials is marginal.
Systematic mutational analysis of the active-site threonine of HIV-1 proteinase: Rethinking the “fireman's grip” hypothesis
- KVIDO STRISOVSKY, UWE TESSMER, JOSMAR LANGNER, JAN KONVALINKA, HANS-GEORG KRÄUSSLICH
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- 05 October 2000, pp. 1631-1641
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Aspartic proteinases share a conserved network of hydrogen bonds (termed “fireman's grip”), which involves the hydroxyl groups of two threonine residues in the active site Asp-Thr-Gly triplets (Thr26 in the case of human immunodeficiency virus type 1 (HIV-1) PR). In the case of retroviral proteinases (PRs), which are active as symmetrical homodimers, these interactions occur at the dimer interface. For a systematic analysis of the “fireman's grip,” Thr26 of HIV-1 PR was changed to either Ser, Cys, or Ala. The variant enzymes were tested for cleavage of HIV-1 derived peptide and polyprotein substrates. PR(T26S) and PR(T26C) showed similar or slightly reduced activity compared to wild-type HIV-1 PR, indicating that the sulfhydryl group of cysteine can substitute for the hydroxyl of the conserved threonine in this position. PR(T26A), which lacks the “fireman's grip” interaction, was virtually inactive and was monomeric in solution at conditions where wild-type PR exhibited a monomer–dimer equilibrium. All three mutations had little effect when introduced into only one chain of a linked dimer of HIV-1 PR. In this case, even changing both Thr residues to Ala yielded residual activity suggesting that the “fireman's grip” is not essential for activity but contributes significantly to dimer formation. Taken together, these results indicate that the “fireman's grip” is crucial for stabilization of the retroviral PR dimer and for overall stability of the enzyme.
A single disulfide bond restores thermodynamic and proteolytic stability to an extensively mutated protein
- KEITH R. ROESLER, A. GURURAJ RAO
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- 05 October 2000, pp. 1642-1650
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The potential for engineering stable proteins with multiple amino acid substitutions was explored. Eleven lysine, five methionine, two tryptophan, one glycine, and three threonine substitutions were simultaneously made in barley chymotrypsin inhibitor-2 (CI-2) to substantially improve the essential amino acid content of the protein. These substitutions were chosen based on the three-dimensional structure of CI-2 and an alignment of homologous sequences. The initial engineered protein folded into a wild-type-like structure, but had a free energy of unfolding of only 2.2 kcal/mol, considerably less than the wild-type value of 7.5 kcal/mol. Restoration of the lysine mutation at position 67 to the wild-type arginine increased the free energy of unfolding to 3.1 kcal/mol. Subsequent cysteine substitutions at positions 22 and 82 resulted in disulfide bond formation and a protein with nearly wild-type thermodynamic stability (7.0 kcal/mol). None of the engineered proteins retained inhibitory activity against chymotrypsin or elastase, and all had substantially reduced inhibitory activity against subtilisin. The proteolytic stabilities of the proteins correlated with their thermodynamic stabilities. Reduction of the disulfide bond resulted in substantial loss of both thermodynamic and proteolytic stabilities, confirming that the disulfide bond, and not merely the cysteine substitutions, was responsible for the increased stability. We conclude that it is possible to replace over a third of the residues in CI-2 with minimal disruption of stability and structural integrity.
Understanding the sequence determinants of conformational switching using protein design
- SEEMA DALAL, LYNNE REGAN
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- 05 October 2000, pp. 1651-1659
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An important goal of protein design is to understand the forces that stabilize a particular fold in preference to alternative folds. Here, we describe an extension of earlier studies in which we successfully designed a stable, native-like helical protein that is 50% identical in sequence to a predominantly β-sheet protein, the B1 domain of Streptococcal IgG-binding protein G. We report the characteristics of a series of variants of our original design that have even higher sequence identity to the B1 domain. Their properties illustrate the extent to which protein stability and conformation can be modulated through careful manipulation of key amino acid residues. Our results have implications for understanding conformational change phenomena of central biological importance and in probing the malleability of the sequence/structure relationship.
Immucillin-H binding to purine nucleoside phosphorylase reduces dynamic solvent exchange
- FANG WANG, ROBERT W. MILES, GREGORY KICSKA, EDWARD NIEVES, VERN L. SCHRAMM, RUTH HOGUE ANGELETTI
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- 05 October 2000, pp. 1660-1668
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The rate and extent of hydrogen/deuterium (H/D) exchange into purine nucleoside phosphorylase (PNP) was monitored by electrospray ionization mass spectrometry (ESI-MS) to probe protein conformational and dynamic changes induced by a substrate analogue, products, and a transition state analogue. The genetic deficiency of PNP in humans is associated with severe T-cell immunodeficiency, while B-cell immunity remains functional. Inhibitors of PNP have been proposed for treatment of T-cell leukemia, to suppress the graft-vs.-host response, or to counter type IV autoimmune diseases without destroying humoral immunity. Calf spleen PNP is a homotrimer of polypeptide chains with 284 amino residues, molecular weight 31,541. Immucillin-H inhibits PNP with a Kd of 23 pM when only one of the three catalytic sites is occupied. Deuterium exchange occurs at 167 slow-exchange sites in 2 h when no catalytic site ligands are present. The substrate analogue and product prevented H/D exchange at 10 of the sites. Immucillin-H protected 32 protons from exchange at full saturation. When one of the three subunits of the homotrimer is filled with immucillin-H, and 27 protons are protected from exchange in all three subunits. Deuterium incorporation in peptides from residues 132–152 decreased in all complexes of PNP. The rate and/or extent of deuterium incorporation in peptides from residues 29–49, 50–70, 81–98, and 112–124 decreased only in the complex with the transition state analogue. The peptide-specific H/D exchange demonstrates that (1) the enzyme is most compact in the complex with immucillin-H, and (2) filling a single catalytic site of the trimer reduces H/D exchange in the same peptides in adjacent subunits. The peptides most highly influenced by the inhibitor surround the catalytic site, providing evidence for reduced protein dynamic motion caused by the transition state analogue.
Analysis of the internal motion of free and ligand-bound human lysozyme by use of 15N NMR relaxation measurement: A comparison with those of hen lysozyme
- SHOUHEI MINE, TADASHI UEDA, YOSHIO HASHIMOTO, TAIJI IMOTO
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- 05 October 2000, pp. 1669-1684
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Human lysozyme has a structure similar to that of hen lysozyme and differs in amino acid sequence by 51 out of 129 residues with one insertion at the position between 47 and 48 in hen lysozyme. The backbone dynamics of free or (NAG)3-bound human lysozyme has been determined by measurements of 15N nuclear relaxation. The relaxation data were analyzed using the Lipari–Szabo formalism and were compared with those of hen lysozyme, which was already reported (Mine S et al., 1999, J Mol Biol 286:1547–1565). In this paper, it was found that the backbone dynamics of free human and hen lysozymes showed very similar behavior except for some residues, indicating that the difference in amino acid sequence did not affect the behavior of entire backbone dynamics, but the folded pattern was the major determinant of the internal motion of lysozymes. On the other hand, it was also found that the number of residues in (NAG)3-bound human and hen lysozymes showed an increase or decrease in the order parameters at or near active sites on the binding of (NAG)3, indicating the increase in picosecond to nanosecond. These results suggested that the immobilization of residues upon binding (NAG)3 resulted in an entropy penalty and that this penalty was compensated by mobilizing other residues. However, compared with the internal motions between both ligand-bound human and hen lysozymes, differences in dynamic behavior between them were found at substrate binding sites, reflecting a subtle difference in the substrate-binding mode or efficiency of activity between them.
High resolution refinement of β-galactosidase in a new crystal form reveals multiple metal-binding sites and provides a structural basis for α-complementation
- DOUGLAS H. JUERS, RAYMOND H. JACOBSON, DALE WIGLEY, XUE-JUN ZHANG, REUBEN E. HUBER, DALE E. TRONRUD, BRIAN W. MATTHEWS
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- 05 October 2000, pp. 1685-1699
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The unrefined fold of Escherichia coli β-galactosidase based on a monoclinic crystal form with four independent tetramers has been reported previously. Here, we describe a new, orthorhombic form with one tetramer per asymmetric unit that has permitted refinement of the structure at 1.7 Å resolution. This high-resolution analysis has confirmed the original description of the structure and revealed new details. An essential magnesium ion, identified at the active site in the monoclinic crystals, is also seen in the orthorhombic form. Additional putative magnesium binding sites are also seen. Sodium ions are also known to affect catalysis, and five putative binding sites have been identified, one close to the active site. In a crevice on the protein surface, five linked five-membered solvent rings form a partial clathrate-like structure. Some other unusual aspects of the structure include seven apparent cis-peptide bonds, four of which are proline, and several internal salt-bridge networks. Deep solvent-filled channels and tunnels extend across the surface of the molecule and pass through the center of the tetramer. Because of these departures from a compact globular shape, the molecule is not well characterized by prior empirical relationships between the mass and surface area of proteins. The 50 or so residues at the amino terminus have a largely extended conformation and mostly lie across the surface of the protein. At the same time, however, segment 13–21 contributes to a subunit interface, and residues 29–33 pass through a “tunnel” formed by a domain interface. Taken together, the overall arrangement provides a structural basis for the phenomenon of α-complementation.
Protein engineering as a strategy to avoid formation of amyloid fibrils
- VIRTUDES VILLEGAS, JESÚS ZURDO, VLADIMIR V. FILIMONOV, FRANCESC X. AVILÉS, CHRISTOPHER M. DOBSON, LUIS SERRANO
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- 05 October 2000, pp. 1700-1708
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The activation domain of human procarboxypeptidase A2 (ADA2h) aggregates following thermal or chemical denaturation at acidic pH. The aggregated material contains well-defined ordered structures with all the characteristics of the fibrils associated with amyloidotic diseases. Variants of ADA2h containing a series of mutations designed to increase the local stability of each of the two helical regions of the protein have been found to have a substantially reduced propensity to form fibrils. This arises from a reduced tendency of the denatured species to aggregate rather than from a change in the overall stability of the native state. The reduction in aggregation propensity may result from an increase in the stability of local relative to longer range interactions within the polypeptide chain. These findings show that the intrinsic ability of a protein to form amyloid can be altered substantially by protein engineering methods without perturbing significantly its overall stability or activity. This suggests new strategies for combating diseases associated with the formation of aggregated proteins and for the design of novel protein or peptide therapeutics.
NMR investigation of the interaction of the inhibitor protein Im9 with its partner DNase
- RUTH BOETZEL, MICHAEL CZISCH, ROBERT KAPTEIN, ANDREW M. HEMMINGS, RICHARD JAMES, COLIN KLEANTHOUS, GEOFFREY R. MOORE
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- 05 October 2000, pp. 1709-1718
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The bacterial toxin colicin E9 is secreted by producing Escherichia coli cells with its 9.5 kDa inhibitor protein Im9 bound tightly to its 14.5 kDa C-terminal DNase domain. Double- and triple-resonance NMR spectra of the 24 kDa complex of uniformly 13C and 15N labeled Im9 bound to the unlabeled DNase domain have provided sufficient constraints for the solution structure of the bound Im9 to be determined. For the final ensemble of 20 structures, pairwise RMSDs for residues 3–84 were 0.76 ± 0.14 Å for the backbone atoms and 1.36 ± 0.15 Å for the heavy atoms. Representative solution structures of the free and bound Im9 are highly similar, with backbone and heavy atom RMSDs of 1.63 and 2.44 Å, respectively, for residues 4–83, suggesting that binding does not cause a major conformational change in Im9. The NMR studies have also allowed the DNase contact surface on Im9 to be investigated through changes in backbone chemical shifts and NOEs between the two proteins determined from comparisons of 1H–1H–13C NOESY-HSQC spectra with and without 13C decoupling. The NMR-defined interface agrees well with that determined in a recent X-ray structure analysis with the major difference being that a surface loop of Im9, which is at the interface, has a different conformation in the solution and crystal structures. Tyr54, a key residue on the interface, is shown to exhibit NMR characteristics indicative of slow rotational flipping. A mechanistic description of the influence binding of Im9 has on the dynamic behavior of E9 DNase, which is known to exist in two slowly interchanging conformers in solution, is proposed.
Conformation and stability of thiol-modified bovine β lactoglobulin
- KAZUKO SAKAI, KAZUMASA SAKURAI, MIYO SAKAI, MASARU HOSHINO, YUJI GOTO
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- 05 October 2000, pp. 1719-1729
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Bovine β-lactoglobulin A assumes a dimeric native conformation at neutral pH, while the conformation at pH 2 is monomeric but still native. β-Lactoglobulin A has a free thiol at Cys121, which is buried between the β-barrel and the C-terminal major α-helix. This thiol group was specifically reacted with 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB) in the presence of 1.0 M Gdn-HCl at pH 7.5, producing a modified β-lactoglobulin (TNB-blg) containing a mixed disulfide bond with 5-thio-2-nitrobenzoic acid (TNB). The conformation and stability of TNB-blg were studied by circular dichroism (CD), tryptophan fluorescence, analytical ultracentrifugation, and one-dimensional 1H-NMR. The CD spectra of TNB-blg indicated disordering of the native secondary structure at pH 7.5, whereas a slight increase in the α-helical content was observed at pH 2.0. The tryptophan fluorescence of TNB-blg was significantly quenched compared with that of the intact protein, probably by the energy transfer to TNB. Sedimentation equilibrium analysis indicated that, at neutral pH, TNB-blg is monomeric while the intact protein is dimeric. In contrast, at pH 2.0, both the intact β-lactoglobulin and TNB-blg were monomeric. The unfolding transition of TNB-blg induced by Gdn-HCl was cooperative in both pH regions, although the degree of cooperativity was less than that of the intact protein. The 1H-NMR spectrum for TNB-blg at pH 3.0 was native-like, whereas the spectrum at pH 7.5 was similar to that of the unfolded proteins. These results suggest that modification of the buried thiol group destabilizes the rigid hydrophobic core and the dimer interface, producing a monomeric state that is native-like at pH 2.0 but is molten globule-like at pH 7.5. Upon reducing the mixed disulfide of TNB-blg with dithiothreitol, the intact β-lactoglobulin was regenerated. TNB-blg will become a useful model to analyze the conformation and stability of the intermediate of protein folding.
Tryptophanyl fluorescence lifetime distribution of hyperthermophilic β-glycosidase from molecular dynamics simulation: A comparison with the experimental data
- ETTORE BISMUTO, PIER LUIGI MARTELLI, RITA CASADIO, GAETANO IRACE
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- 05 October 2000, pp. 1730-1742
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A molecular dynamics simulation approach has been utilized to understand the unusual fluorescence emission decay observed for β-glycosidase from the hyperthermophilic bacterium Solfolobus sulfataricus (Sβgly), a tetrameric enzyme containing 17 tryptophanyl residues for each subunit. The tryptophanyl emission decay of Sβgly results from a bimodal distribution of fluorescence lifetimes with a short-lived component centered at 2.5 ns and a long-lived one at 7.4 ns (Bismuto E, Nucci R, Rossi M, Irace G, 1999, Proteins 27:71–79). From the examination of the trajectories of the side chains capable of causing intramolecular quenching for each tryptophan microenvironment and using a modified Stern–Volmer model for the emission quenching processes, we calculated the fluorescence lifetime for each tryptophanyl residue of Sβgly at two different temperatures, i.e., 300 and 365 K. The highest temperature was chosen because in this condition Sβlgy evidences a maximum in its catalytic activity and is stable for a very long time. The calculated lifetime distributions overlap those experimentally determined. Moreover, the majority of trytptophanyl residues having longer lifetimes correspond to those originally identified by inspection of the crystallographic structure. The tryptophanyl lifetimes appear to be a complex function of several variables, such as microenvironment viscosity, solvent accessibility, the chemical structure of quencher side chains, and side-chain dynamics. The lifetime calculation by MD simulation can be used to validate a predicted structure by comparing the theoretical data with the experimental fluorescence decay results.
Structure of a (Cys3His) zinc ribbon, a ubiquitous motif in archaeal and eucaryal transcription
- HUNG-TA CHEN, PASCALE LEGAULT, JOHN GLUSHKA, JAMES G. OMICHINSKI, ROBERT A. SCOTT
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- 05 October 2000, pp. 1743-1752
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Transcription factor IIB (TFIIB) is an essential component in the formation of the transcription initiation complex in eucaryal and archaeal transcription. TFIIB interacts with a promoter complex containing the TATA-binding protein (TBP) to facilitate interaction with RNA polymerase II (RNA pol II) and the associated transcription factor IIF (TFIIF). TFIIB contains a zinc-binding motif near the N-terminus that is directly involved in the interaction with RNA pol II/TFIIF and plays a crucial role in selecting the transcription initiation site. The solution structure of the N-terminal residues 2–59 of human TFIIB was determined by multidimensional NMR spectroscopy. The structure consists of a nearly tetrahedral Zn(Cys)3(His)1 site confined by type I and “rubredoxin” turns, three antiparallel β-strands, and disordered loops. The structure is similar to the reported zinc-ribbon motifs in several transcription-related proteins from archaea and eucarya, including Pyrococcus furiosus transcription factor B (Pf TFB), human and yeast transcription factor IIS (TFIIS), and Thermococcus celer RNA polymerase II subunit M (TcRPOM). The zinc-ribbon structure of TFIIB, in conjunction with the biochemical analyses, suggests that residues on the β-sheet are involved in the interaction with RNA pol II/TFIIF, while the zinc-binding site may increase the stability of the β-sheet.
Modeling of loops in protein structures
- ANDRÁS FISER, RICHARD KINH GIAN DO, ANDREJ šALI
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- 05 October 2000, pp. 1753-1773
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Comparative protein structure prediction is limited mostly by the errors in alignment and loop modeling. We describe here a new automated modeling technique that significantly improves the accuracy of loop predictions in protein structures. The positions of all nonhydrogen atoms of the loop are optimized in a fixed environment with respect to a pseudo energy function. The energy is a sum of many spatial restraints that include the bond length, bond angle, and improper dihedral angle terms from the CHARMM-22 force field, statistical preferences for the main-chain and side-chain dihedral angles, and statistical preferences for nonbonded atomic contacts that depend on the two atom types, their distance through space, and separation in sequence. The energy function is optimized with the method of conjugate gradients combined with molecular dynamics and simulated annealing. Typically, the predicted loop conformation corresponds to the lowest energy conformation among 500 independent optimizations. Predictions were made for 40 loops of known structure at each length from 1 to 14 residues. The accuracy of loop predictions is evaluated as a function of thoroughness of conformational sampling, loop length, and structural properties of native loops. When accuracy is measured by local superposition of the model on the native loop, 100, 90, and 30% of 4-, 8-, and 12-residue loop predictions, respectively, had <2 Å RMSD error for the mainchain N, Cα, C, and O atoms; the average accuracies were 0.59 ± 0.05, 1.16 ± 0.10, and 2.61 ± 0.16 Å, respectively. To simulate real comparative modeling problems, the method was also evaluated by predicting loops of known structure in only approximately correct environments with errors typical of comparative modeling without misalignment. When the RMSD distortion of the main-chain stem atoms is 2.5 Å, the average loop prediction error increased by 180, 25, and 3% for 4-, 8-, and 12-residue loops, respectively. The accuracy of the lowest energy prediction for a given loop can be estimated from the structural variability among a number of low energy predictions. The relative value of the present method is gauged by (1) comparing it with one of the most successful previously described methods, and (2) describing its accuracy in recent blind predictions of protein structure. Finally, it is shown that the average accuracy of prediction is limited primarily by the accuracy of the energy function rather than by the extent of conformational sampling.
The oxidation produced by hydrogen peroxide on Ca-ATP-G-actin
- ALDO MILZANI, RANIERI ROSSI, PAOLO DI SIMPLICIO, DANIELA GIUSTARINI, ROBERTO COLOMBO, ISABELLA DALLEDONNE
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- 05 October 2000, pp. 1774-1782
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We report here that in vitro exposure of monomeric actin to hydrogen peroxide leads to a conversion of 6 of the 16 methionine residues to methionine sulfoxide residues. Although the initial effect of H2O2 on actin is the oxidation of Cys374, we have found that Met44, Met47, Met176, Met190, Met269, and Met355 are the other sites of the oxidative modification. Met44 and Met47 are the methionyl sites first oxidized. The methionine residues that are oxidized are not simply related to their accessibility to the external medium and are found in all four subdomains of actin. The conformations of subdomain 1, a region critical for the functional binding of different actin-binding proteins, and subdomain 2, which plays important roles in the polymerization process and stabilization of the actin filament, are changed upon oxidation. The conformational changes are deduced from the increased exposure of hydrophobic residues, which correlates with methionine sulfoxide formation, from the perturbations in tryptophan fluorescence, and from the decreased susceptibility to limited proteolysis of oxidized actin.
Crystal structure of the catalytic domain of human bile salt activated lipase
- SIMON TERZYAN, CHI-SUN WANG, DEBORAH DOWNS, BRET HUNTER, XUEJUN C. ZHANG
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- 05 October 2000, pp. 1783-1790
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Bile-salt activated lipase (BAL) is a pancreatic enzyme that digests a variety of lipids in the small intestine. A distinct property of BAL is its dependency on bile salts in hydrolyzing substrates of long acyl chains or bulky alcoholic motifs. A crystal structure of the catalytic domain of human BAL (residues 1–538) with two surface mutations (N186D and A298D), which were introduced in attempting to facilitate crystallization, has been determined at 2.3 Å resolution. The crystal form belongs to space group P212121 with one monomer per asymmetric unit, and the protein shows an α/β hydrolase fold. In the absence of bound bile salt molecules, the protein possesses a preformed catalytic triad and a functional oxyanion hole. Several surface loops around the active site are mobile, including two loops potentially involved in substrate binding (residues 115–125 and 270–285).
Interaction of mammalian mitochondrial elongation factor EF-Tu with guanine nucleotides
- YING-CHUN CAI, JAMES M. BULLARD, NANCY L. THOMPSON, LINDA L. SPREMULLI
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- 05 October 2000, pp. 1791-1800
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Elongation factor Tu (EF-Tu) promotes the binding of aminoacyl-tRNA (aa-tRNA) to the acceptor site of the ribosome. During the elongation cycle, EF-Tu interacts with guanine nucleotides, aa-tRNA and its nucleotide exchange factor (EF-Ts). Quantitative determination of the equilibrium dissociation constants that govern the interactions of mammalian mitochondrial EF-Tu (EF-Tumt) with guanine nucleotides was the focus of the work reported here. Equilibrium dialysis with [3H]GDP was used to measure the equilibrium dissociation constant of the EF-Tumt·GDP complex (KGDP = 1.0 ± 0.1 μM). Competition of GTP with a fluorescent derivative of GDP (mantGDP) for binding to EF-Tumt was used to measure the dissociation constant of the EF-Tumt·GTP complex (KGTP = 18 ± 9 μM). The analysis of these data required information on the dissociation constant of the EF-Tumt·mantGDP complex (KmGDP = 2.0 ± 0.5 μM), which was measured by equilibrium dialysis. Both KGDP and KGTP for EF-Tumt are quite different (about two orders of magnitude higher) than the dissociation constants of the corresponding complexes formed by Escherichia coli EF-Tu. The forward and reverse rate constants for the association and dissociation of the EF-Tumt·GDP complex were determined using the change in the fluorescence of mantGDP upon interaction with EF-Tumt. These values are in agreement with a simple equilibrium binding interaction between EF-Tumt and GDP. The results obtained are discussed in terms of the recently described crystal structure of the EF-Tumt·GDP complex.
Thermodynamic dissection of the binding energetics of KNI-272, a potent HIV-1 protease inhibitor
- ADRIAN VELAZQUEZ-CAMPOY, IRENE LUQUE, MATTHEW J. TODD, MARK MILUTINOVICH, YOSHIAKI KISO, ERNESTO FREIRE
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- 05 October 2000, pp. 1801-1809
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KNI-272 is a powerful HIV-1 protease inhibitor with a reported inhibition constant in the picomolar range. In this paper, a complete experimental dissection of the thermodynamic forces that define the binding affinity of this inhibitor to the wild-type and drug-resistant mutant V82F/I84V is presented. Unlike other protease inhibitors, KNI-272 binds to the protease with a favorable binding enthalpy. The origin of the favorable binding enthalpy has been traced to the coupling of the binding reaction to the burial of six water molecules. These bound water molecules, previously identified by NMR studies, optimize the atomic packing at the inhibitor/protein interface enhancing van der Waals and other favorable interactions. These interactions offset the unfavorable enthalpy usually associated with the binding of hydrophobic molecules. The association constant to the drug resistant mutant is 100–500 times weaker. The decrease in binding affinity corresponds to an increase in the Gibbs energy of binding of 3–3.5 kcal/mol, which originates from less favorable enthalpy (1.7 kcal/mol more positive) and entropy changes. Calorimetric binding experiments performed as a function of pH and utilizing buffers with different ionization enthalpies have permitted the dissection of proton linkage effects. According to these experiments, the binding of the inhibitor is linked to the protonation/deprotonation of two groups. In the uncomplexed form these groups have pKs of 6.0 and 4.8, and become 6.6 and 2.9 in the complex. These groups have been identified as one of the aspartates in the catalytic aspartyl dyad in the protease and the isoquinoline nitrogen in the inhibitor molecule. The binding affinity is maximal between pH 5 and pH 6. At those pH values the affinity is close to 6 × 1010 M−1 (Kd = 16 pM). Global analysis of the data yield a buffer- and pH-independent binding enthalpy of −6.3 kcal/mol. Under conditions in which the exchange of protons is zero, the Gibbs energy of binding is −14.7 kcal/mol from which a binding entropy of 28 cal/K mol is obtained. Thus, the binding of KNI-272 is both enthalpically and entropically favorable. The structure-based thermodynamic analysis indicates that the allophenylnorstatine nucleus of KNI-272 provides an important scaffold for the design of inhibitors that are less susceptible to resistant mutations.
Polypeptide stimulators of the Ms-Lon protease
- STANISLAV G. RUDYAK, THOMAS E. SHRADER
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- 05 October 2000, pp. 1810-1817
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Both the peptidase activity against small fluorescent peptide substrates and the ATPase activity of Lon (La) proteases are stimulated by unstructured proteins such as α-casein. This stimulation reveals the simultaneous interaction of Lon with two proteolytic substrates—α-casein and the peptide substrate. To understand the cellular function of this stimulation, it is important to determine the physical properties of Lon stimulators. The abilities of compositionally simple random copolymers of amino acids (rcAAs) to stimulate the peptidase and ATPase activities of the Lon protease from Mycobacterium smegmatis (Ms-Lon) and its N-terminal truncation mutant (N-E226) were determined. We report that cationic but not anionic rcAAs stimulated Ms-Lon's peptidase activity but were themselves poor substrates for the enzyme. Peptidase stimulation by rcAAs correlated approximately with the degree of hydrophobicity of these polypeptides and reached levels >10-fold higher than observed previously for Ms-Lon stimulators such as α-casein. In contrast to α-casein, which stimulates Ms-Lon's peptidase activity by 40% and ATPase activity by 150%, rcAAs stimulated peptidase activity without concomitant stimulation of ATPase activity. Active site labeling experiments suggested that both rcAAs and ATP increased peptidase activity by increasing accessibility to the peptidase active site. Peptidase activity assays in the presence of both α-casein and rcAAs revealed that interactions of rcAAs and α-casein with Ms-Lon are extremely complex and not mutually exclusive. Specifically, (1) additions of low concentrations of α-casein (<50 μg/mL) caused a further stimulation of Ms-Lon's rcAA-stimulated peptidase activity; (2) additions of higher concentrations of α-casein inhibited Ms-Lon's rcAA-stimulated peptidase activity; (3) additions of all concentrations of α-casein inhibited N-E226's rcAA-stimulated peptidase activity. We conclude the Ms-Lon can interact with an rcAA, α-casein, and a substrate peptide simultaneously, and that formation of this quaternary complex requires the N-terminal domain of Ms-Lon. These data support models of Ms-Lon that include two allosteric polypeptide binding sites distinct from the catalytic peptidase site.
Insights into nucleotide binding in protein kinase A using fluorescent adenosine derivatives
- DA QUN NI, JENNIFER SHAFFER, JOSEPH A. ADAMS
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- Published online by Cambridge University Press:
- 05 October 2000, pp. 1818-1827
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The binding of the methylanthraniloyl derivatives of ATP (mant-ATP), ADP (mant-ADP), 2′deoxyATP (mant-2′deoxyATP), and 3′deoxyATP (mant-3′deoxyATP) to the catalytic subunit of protein kinase A was studied to gain insights into the mechanism of nucleotide binding. The binding of the mant nucleotides leads to a large increase in fluorescence energy transfer at 440 nm, allowing direct measurements of nucleotide affinity. The dissociation constant of mant-ADP is identical to that for ADP, while that for mant-ATP is approximately threefold higher than that for ATP. The dissociation constant for mant-3′deoxyATP is approximately fivefold higher than that for 3′deoxyATP while derivatization of 2′deoxyATP does not affect affinity. The time-dependent binding of mant-ATP, mant-2′deoxyATP, and mant-ADP, measured using stopped-flow fluorescence spectroscopy, is best fit to three exponentials. The fast phase is ligand dependent, while the two slower phases are ligand independent. The slower phases are similar but not identical in rate, and have opposite fluorescence amplitudes. Both isomers of mant-ATP are equivalent substrates, as judged by reversed-phase chromatography, although the rate of phosphorylation is approximately 20-fold lower than the natural nucleotide. The kinetic data are consistent with a three-step binding mechanism in which initial association of the nucleotide derivatives produces a highly fluorescent complex. Either one or two conformational changes can occur after the formation of this binary species, but one of the isomerized forms must have low fluorescence compared to the initial binary complex. These data soundly attest to the structural plasticity within the kinase core that may be essential for catalysis. Overall, the mant nucleotides present a useful reporter system for gauging these conformational changes in light of the prevailing three-dimensional models for the enzyme.