Comparison of the conformations of cyclolinopeptide A in the solid state and in solution

Cyclolinopeptide A, a cyclic nonapeptide isolated from linseed, has lately attracted large interest for its cytoprotective activity. The recent elucidation of its solid state structure has prompted us to undertake a detailed conformational analysis in solution. Room-temperature 1H-nmr spectra in several solvents (DMSO-d6, DMSO-d6/D2O/H2O, CD3OH, (CD3)2CDOH, CDCl3) all show very broad lines, indicating the presence of chemical exchange among several conformers. It proved possible to freeze a single conformational state in CDCl3 at 214 K. Unusual chemical shifts and nuclear Overhauser enhancements are consistent with the main features of the solid state structure.     

Molecular dynamics analysis of chymosin conformations in solution and in crystalline environment

The method of molecular dynamics in explicit solvent was applied to test the hypothesis of the existence of a self-inhibited form of chymosin in solution. The paths and energies were calculated for chymosin in solution and in a crystalline environment. The modeling revealed that the intermolecular contacts of chymosin in crystal have negligible influence on the energy stabilization of its self-inhibited conformation. On the other hand, upon molecular dynamics simulation of the active and self-inhibited forms in solution their conformational energies proved to be quite close and the potential barrier between them relatively low. All this supports the possibility of chymosin to adopt spontaneously the self-inhibited conformation in solution, and indicates that it is one of the really existing enzyme forms rather than a crystal packing artifact. The results obtained open novel approaches to studying the specificity of chymosin as well as other aspartic proteinases.     

Circular dichroism-inhibitor titrations of arsanilazotyrosine-248 carboxypeptidase A.

Coupling of carboxypeptidase with diazotized arsanilic acid specifically modifies a single tyrosyl residue. Yet, owing to the fact that the resultant azoTyr-248 can form an intramolecular chelate with zinc, two different circular dichroism probes result: azoTyr-248 itself and the azoTyr-248-Zn chelate. Both are environmentally sensitive and, characteristically, each can signal the same or different perturbations, as is apparent from circular dichroic spectra. This dual probe function greatly magnifies the scope of these chromophores in mapping the topography of the active center with respect to sites of interaction of inhibitors (or substrates). Titration of the azoenzyme with a series of synthetic, competitive inhibitors, e.g., L-benzylsuccinate, L-phenyllactate, and L-Phe, and with the pseudosubstrate, Gly-L-Tyr, in turn generates characteristic circular dichroic spectra. Their analysis yields a single binding constant for each of these agents, one molecule of each binding to the active center. Mixed inhibitions, as seen with beta-phenylpropionate and phenylacetate, resolved previously into competitive and noncompetitive components, are characterized by different spectral effects. Two molecules of these agents bind to the enzyme, consistent with both thermodynamic and enzymatic studies. The interactions leading to competitive and noncompetitive inhibition, respectively, can be recognized and assigned, based on the manner in which the extrema at 340 and 420 nm, reflecting azoTyr-248, and the negative 510-nm circular dichroism band, typical of its chelate with zinc, are affected and on the pH dependence of spectral and kinetic data. Certai4 noncompetitive inhibitors and modifiers induce yet other spectral features. Each probe is very sensitive to changes in its particular active center environment, though both can be relatively insensitive to inhibitors interacting at a distance from the active center.     

Environment and conformation dependent sensitivity of the arsanilazotyrosine-248 carboxypeptidase A chromophore.

Reaction of carboxypeptidase A crystals with diazotized arsanilic acid uniquely modifies Tyr-248 to form a monazo derivative, which-in solution-forms an intramolecular inner-sphere coordination complex in the active site zinc atom. tarsanilazocarboxypeptidase exhibits spectral properties that are closely similar to those of the model complex, tetrazolylazo-N-carbobenzoxytyrosine Zn2+, with a distinctive maximum at 510 nm. In addition, its circular dichroic spectrum reveals a negative extremum at this wavelength, also characteristic of this complex. Both spectra are exquisitely responsive to pth changes and serve to monitor formation and dissociation of the metal-azophenol complex. Two pKapp at 7.7 and 9.5 delineate the pH range over which the probe characteristics most effectively gauge conformational features of the active center of arsanilazcarboxypeptidase. Other environmental parameters, e.g., substrates and inhibitors, as well as crystallization of the enzyme also critically influence the formation and dissociation of the complex; the response of the probe suggests that they induce conformational movement of the azoTyr-248 residue away from the zinc atom. tthe now available chemical, functional, structural data bearing on the spatial relationships of Tyr-248 and Zn, both thought critical to catalysis, are evaluated, based on spectra of arsanilazo- and nitrocarboxypeptidase crystals and solutions as well as on detailed kinetic analyses of the native enzyme in both physical states and based on the X-ray structure analysis of the native enzyme and its Gly-L-Tyr complex. Collectively all of the data show that the conformation of carboxypeptidase in crystals differs from that in solution. Moreover, reexamination of the original X-ray maps reported in 1968 and thought to preclude a Tyr-248-Zn interaction now leads to the conclusion that in up to 25 per cent of the molecules in the crystals ttyr-248 interacts with the active site zinc atom (W.D. Lipscomb (1973), Proc. Nat. Acad. Sci U.S. 70, 3797). Thus, even in the crystals the enzyme exists in at least two different conformations. In one of these Tyr-248 is near while in the other it is far from the zinc atom. The spectral effects of Gly-L-Tyr and beta-phenylpropionate on solutions of arsanilazo- and of nitrocarboxypeptidase demonstrate that during the catalytic process Tyr-248 moves away from the zinc atom. This implies a mechanistic role for Tyr-248 different from that postulated on the basis of X-ray crystallographic analysis. Indeed, the proximity of ttyr-248 to the zinc atom, when altered by substrates and inhibitor, may reflect certain of the properties characteristic of the entatic, active site.     

The role of Tyr248 probed by mutant bovine carboxypeptidase A: insight into the catalytic mechanism of carboxypeptidase A

We have investigated the function of Tyr248 using bovine wild-type CPA and its Y248F and Y248A mutants to find that the K(M) values were increased by 4.5-11-fold and the k(cat) values were reduced by 4.5-10.7-fold by the replacement of Tyr248 with Phe for the hydrolysis of hippuryl-L-Phe (HPA) and N-[3-(2-furyl)acryloyl]-Phe-Phe (FAPP), respectively. In the case of O-(trans-p-chlorocinnamoyl)-L-beta-phenyllactate (ClCPL), an ester substrate, the K(M) value was increased by 2.5-fold, and the k(cat) was reduced by 20-fold. The replacement of Tyr248 with Ala decreased the k(cat) values by about 18- and 237-fold for HPA and ClCPL, respectively, demonstrating that the aromatic ring of Tyr248 plays a critical role in the enzymic reaction. The increases of the K(M) values were only 6- and 5-fold for HPA and ClCPL, respectively. Thus, the present study indicates clearly that Tyr248 plays an important role not only in the binding of substrate but also in the enzymic hydrolysis. The kinetic results may be rationalized by the proposition that the phenolic hydroxyl of Tyr248 forms a hydrogen bond with the zinc-bound water molecule, causing further activation of the water molecule by reducing its pK(a) value. The pH dependency study of k(cat) values and the solvent isotope effects also support the proposition. A unified catalytic mechanism is proposed that can account for the different kinetic behavior observed in the CPA-catalyzed hydrolysis of peptide and ester substrates.     

Computer simulation as a tool for tracing the conformational differences between proteins in solution and in the crystalline state

Knowledge about the architecture of macromolecules has been derived primarily from crystallography. Therefore, it has been a matter of concern whether the conformation of a macromolecule in solution, namely in vivo, might be different from that in the crystalline state. To determine the difference between the conformations, a protein (trypsin inhibitor) dissolved in water has been simulated using the method of molecular dynamics and the results are compared with those obtained from a simulation of the full crystalline unit cell. We report here that no significant difference was found for backbone atoms, except for two more or less flexible loops extending from the core of the protein and the very flexible carboxyterminal residues. The side-chains in which the conformation in solution differs considerably from that in the crystal all belong to polar residues.     

Discriminating between homodimeric and monomeric proteins in the crystalline state

Scores calculated from intermolecular contacts of proteins in the crystalline state are used to differentiate monomeric and homodimeric proteins, by classification into two categories separated by a cut-off score value. The generalized classification error is estimated by using bootstrap re-sampling on a nonredundant set of 172 water-soluble proteins whose prevalent quaternary state in solution is known to be either monomeric or homodimeric. A statistical potential, based on atom-pair frequencies across interfaces observed with homodimers, is found to yield an error rate of 12.5%. This indicates a small but significant improvement over the measure of solvent accessible surface area buried in the contact interface, which achieves an error rate of 15.4%. A further modification of the latter parameter relating the two most extensive contacts of the crystal results in an even lower error rate of 11.1%.     

Conformation of 4-thio- -lyxono-1,4-lactone in solution and in the crystalline state

The conformation in ²H₂O of 4-thio- -lyxono-1,4-lactone (1) was studied by nuclear magnetic resonance spectroscopy, by means of homonuclear (J_1H,1H) and heteronuclear (J_1H,13C) coupling constants. The couplings were directly measured by a two-dimensional heteronucleus-coupled ω₁ hetero-half-filtered proton-proton correlation (HETLOC) experiment, which does not require ¹³C isotopic enrichment. In solution, the thiolactone ring of 1 adopts preferentially the E₃ conformation, and its hydroxymethyl group populates mainly the gt rotamer. The X-ray diffraction data of a single crystal of 1 indicates that also in the solid state the thiolactone ring adopts an E₃ conformation, with a puckering somewhat larger than that observed for aldono-1,4-lactones and furanose rings. The molecules are linked by hydrogen bonds, which form chains. Particularly, O-5 is fully engaged as donor and acceptor in hydrogen bonding and the rotameric conformation of the hydroxymethyl group of 1 is fixed in the tg form.     

Tryptophan phosphorescence and the conformation of liver alcohol dehydrogenase in solution and in the crystalline state

Information on the effects of crystallization upon the structure of liver alcohol dehydrogenase from horse is obtained from a comparison of the phosphorescence properties of its tryptophan residues in solution and in the crystalline state. In the crystalline state the red shift in the phosphorescence spectrum of the solvent-exposed Trp-15 attests to a decreased polarity of its environment consistent with its shielding away from the aqueous solvent probably through its involvement in an intermolecular contact. On the other hand, the triplet-state lifetime of Trp-314 which is buried deeply in the coenzyme-binding domain demonstrates that the flexibility of this region of the macromolecule is unaffected by crystallization; a conclusion supported also by the similarity in the rate of oxygen quenching of its phosphorescence. Given that lattice constraints strongly inhibit large-scale conformational changes these results allow us to identify the average solution structure with the 'open' conformer determined crystallographically.     

Kinetic properties of tetrameric glycogen phosphorylase b in solution and in the crystalline state.

R-state monoclinic P2(1) crystals of phosphorylase have been shown to be catalytically active in the presence of an oligosaccharide primer and glucose-1-phosphate in 0.9 M ammonium sulfate, 10 mM beta-glycerophosphate, 0.5 mM EDTA, and 1 mM dithiothreitol, the medium in which the crystals are grown or equilibrated for crystallographic studies (Barford, D. & Johnson, L.N., 1989, Nature 360, 609-616; Barford, D., Hu, S.-H., & Johnson, L.N., 1991, J. Mol. Biol. 218, 233-260). Kinetic data suggest that the activity of crystalline tetrameric phosphorylase is similar to that determined in solution for the enzyme tetramer. However, large differences were found in the maximal velocities for both oligosaccharide or glucose-1-phosphate substrates between the soluble dimeric and crystalline tetrameric enzyme.     

A QM/MM analysis of the conformations of crystalline sucrose moieties

Both ab initio quantum mechanics (QM) and molecular mechanics (MM) were used to produce a hybrid energy surface for sucrose that simultaneously provides low energies for conformations that are observed in crystal structures and high energies for most unobserved structures. HF/6-31G* QM energies were calculated for an analogue based on tetrahydropyran (THP) and tetrahydrofuran (THF). Remaining contributions to the potential energy of sucrose were calculated with MM. To do this, the MM surface for the analogue was subtracted from the MM surface for the disaccharide, and the QM surface for the analogue was added. Prediction of the distribution of observable geometries was enhanced by reducing the strength of the hydrogen bonding. Reduced hydrogen-bonding strength is probably useful because many crystalline sucrose moieties do not have intramolecular hydrogen bonds between the fructose and glucose residues. Therefore, hydrogen bonding does not play a large role in determining the molecular conformation. On the hybrid energy surface that was constructed with a dielectric constant of 3.5, the average potential energy of 23 sucrose moieties from crystal structures is 1.16 kcal/mol, and the population of observed structures drops off exponentially as the energy increases.     

The solution conformations of gramicidin A and its analogs

The conformational states in dioxane and ethanol of gramicidin A and of analogs varying in chain length and amino acid sequence have been studied. Infrared, CD, and polarization of fluorescence spectra of the peptides were measured, from which dimerization constants were determined and spectral characteristics of the monomeric and dimeric states obtained. Resonance splitting of the amide I ir band has been calculated for all gramicidin A models proposed earlier. Detailed comparison of the experimental and computed spectra showed that the four dimeric gramicidin species present in solution are predominantly antiparallel double ?ππ_ld helices in equilibrium with smaller amounts of head-to-head associated π_LD helices. The gramicidin A monomer was found to be a π_LD^4.4 helix in dioxane. For each conformational form the number of residues per turn and the helical sense were determined. The relationship between the amino acid sequence and the structure and stability of the dimer in the series of gramicidin A and its analogs is discussed. The above findings are rationalized in terms of the membrane channel properties of gramicidin A, in particular the conformational rearrangements occurring during the passage of metal ions through the channel and also the differences in conformation of the antibiotic in nonpolar solutions and in the membrane.     

Arginine 127 stabilizes the transition state in carboxypeptidase

Crystallographic studies suggest that Arg-127 is a key amino acid in the hydrolysis of peptides and esters by carboxypeptidase A. The guanidinium group of Arg-127 is hypothesized to stabilize the oxyanion of the tetrahedral intermediate formed by the attack of water on the scissile carbonyl bond. We have replaced this amino acid in rat carboxypeptidase A1 with lysine (R127K), methionine (R127M), and alanine (R127A), in order to define the role of Arg-127 in carboxypeptidase catalyzed hydrolysis. The wild-type and mutant enzymes were expressed in yeast and purified. Kinetic studies show that Arg-127 substitution decreases kcat for both ester and amide substrates, whereas Km is relatively unchanged; for R127M and R127A this corresponds to a 6 kcal/mol decrease in transition state stabilization of the rate-limiting step. The binding affinity for the phosphonate transition state analog, Cbz-Phe-Ala(P)-OAla, was decreased by 5.4 kcal/mol, whereas binding affinity for the ground state inhibitor, DL-benzylsuccinic acid, was decreased by only 1.7 kcal/mol for R127M. Electrostatic calculations employing a finite difference solution to the Poisson-Boltzmann equation predict that the positive charge of Arg-127 should stabilize the transition state by 6-8 kcal/mol. Therefore, the experimental and theoretical data suggest that the primary role of Arg-127 is stabilization of the transition state through electrostatic interaction with the oxyanion.     

Structure of a novel leech carboxypeptidase inhibitor determined free in solution and in complex with human carboxypeptidase A2

Leech carboxypeptidase inhibitor (LCI) is a novel protein inhibitor present in the medicinal leech Hirudo medicinalis. The structures of LCI free and bound to carboxypeptidase A2 (CPA2)have been determined by NMR and X-ray crystallography, respectively. The LCI structure defines a new protein motif that comprises a five-stranded antiparallel beta-sheet and one short alpha-helix. This structure is preserved in the complex with human CPA2 in the X-ray structure, where the contact regions between the inhibitor and the protease are defined. The C-terminal tail of LCI becomes rigid upon binding the protease as shown in the NMR relaxation studies, and it interacts with the carboxypeptidase in a substrate-like manner. The homology between the C-terminal tails of LCI and the potato carboxypeptidase inhibitor represents a striking example of convergent evolution dictated by the target protease. These new structures are of biotechnological interest since they could elucidate the control mechanism of metallo-carboxypeptidases and could be used as lead compounds for the search of fibrinolytic drugs.     

Two conformations of crystalline adenylate kinase.

Pig muscle adenylate kinase (EC2.7.4.3) can exist in three crystal forms, which are interconvertible. For crystal form A the enzyme structure is known in atomic detail. We report the X-ray diffraction analysis of crystal form B at 4.7 Å resolution and a comparison with the A form. During the transition from A to B the packing arrangement of the molecules changes slightly. Moreover, the individual molecule undergoes an appreciable conformational change: by displacing a chain segment of seven residues and two adjacent α-helices a hydrophobic pocket is opened deep in the cleft near the centre of the molecule. Concomitantly the β-pleated sheet is enlarged by about four hydrogen bonds in the B form. Several lines of evidence indicate that the observed conformational change is an intrinsic property of the molecule and is not induced by crystal packing forces.