Reflections on biocatalysis involving phosphorus

Early studies on chemical synthesis of biological molecules can be seen to progress to preparation and biological evaluation of phosphonates as analogues of biological phosphates, with emphasis on their isosteric and isopolar character. Work with such mimics progressed into structural studies with a range of nucleotide-utilising enzymes. The arrival of metal fluorides as analogues of the phosphoryl group, PO(3)(-), for transition state (TS) analysis of enzyme reactions stimulated the symbiotic deployment of (19)F NMR and protein crystallography. Characteristics of enzyme transition state analogues are reviewed for a range of reactions. From the available MF(x) species, trifluoroberyllate gives tetrahedral mimics of ground states (GS) in which phosphate is linked to carboxylate and phosphate oxyanions. Tetrafluoroaluminate is widely employed as a TS mimic, but it necessarily imposes octahedral geometry on the assembled complexes, whereas phosphoryl transfer involves trigonal bipyramidal (tbp) geometry. Trifluoromagnesate (MgF(3)(-)) provides the near-ideal solution, delivering tbp geometry and correct anionic charge. Some of the forty reported tbp structures assigned as having AlF(3)(0) cores have been redefined as trifluoromagnesate complexes. Transition state analogues for a range of kinases, mutases, and phosphatases provide a detailed description of mechanism for phosphoryl group transfer, supporting the concept of charge balance in their TS and of concerted-associative pathways for biocatalysis. Above all, superposition of GS and TS structures reveals that in associative phosphoryl transfer, the phosphorus atom migrates through a triangle of three, near-stationary, equatorial oxygens. The extension of these studies to near attack conformers further illuminates enzyme catalysis of phosphoryl transfer.

The natural design of vancomycin family antibiotics to bind their target peptides

The vancomycin family of antibiotics provide a rare opportunity among natural systems to study a molecular recognition process in which both the 'receptor' and the 'ligand' are relatively small molecules. Unlike the vast majority of antibiotics, in the vancomycin family the antibiotic performs the role of the receptor. All members of the family are covalently cross-linked heptapeptides that contain a variety of glycosidic modifications. Their site of action in bacterial cell walls is modelled by simple dipeptides and tripeptides. NMR experiments have been used to characterize the binding of these species through the study of both the complex and the free components. In unbound antibiotics conformational freedom is observed in regions of the molecule not severely restricted by covalent linkages. On binding of the ligand much of this conformational freedom is lost and the hydrophobic side chains of the antibiotics reside close to the intermolecular hydrogen-bonding interactions, thus shielding these interactions from the solvent. The charged amino groups of the N-terminus and disaccharide region of vancomycin are orientated not to optimize intermolecular electrostatic interactions but rather to retain solvation. This causes further hydrophobic faces to be presented to the ligand. Removal of saccharide units from the antibiotics leads to small losses in binding energy but may have considerable influence on the selectivity of the antibiotics. Specific dimerization through the non-ligand-binding faces of ristocetin is observed at millimolar concentrations. The geometry of the dimeric complex enables a close approach of the ligand carboxylate anion and the charged amino group of the novel sugar, ristosamine.

Amyloid fibril formation by human stefin B: influence of the initial pH-induced intermediate state

The amyloid fibril field is briefly described, with some stress put on differences between various proteins and possible role for domain swapping. In the main body of the text, first, a short review is given of the folding properties of both human stefins, alpha/beta-type globular proteins of 53% identity with a known three-dimensional fold. Second, in vitro study of amyloid fibril formation by human stefin B (type I cystatin) is described. Solvents of pH 4.8 and pH 3.3 with and without 2,2,2-trifluoroethanol (TFE) were probed, as it has been shown previously that stefin B forms acid intermediates, a native-like and molten globule intermediate, respectively. The kinetics of fibrillation were measured by thioflavin T fluorescence and CD. At pH 3.3, the protein is initially in the molten globule state. The fibrillation is faster than at pH 4.8; however, there is more aggregation observed. On adding TFE at each pH, the fibril formation is further accelerated.

Structure of TCTP reveals unexpected relationship with guanine nucleotide-free chaperones

The translationally controlled tumor-associated proteins (TCTPs) are a highly conserved and abundantly expressed family of eukaryotic proteins that are implicated in both cell growth and the human acute allergic response but whose intracellular biochemical function has remained elusive. We report here the solution structure of the TCTP from Schizosaccharomyces pombe, which, on the basis of sequence homology, defines the fold of the entire family. We show that TCTPs form a structural superfamily with the Mss4/Dss4 family of proteins, which bind to the GDP/GTP free form of Rab proteins (members of the Ras superfamily) and have been termed guanine nucleotide-free chaperones (GFCs). Mss4 also acts as a relatively inefficient guanine nucleotide exchange factor (GEF). We further show that the Rab protein binding site on Mss4 coincides with the region of highest sequence conservation in the TCTP family. This is the first link to any other family of proteins that has been established for the TCTP family and suggests the presence of a GFC/GEF at extremely high abundance in eukaryotic cells.

Location and properties of metal-binding sites on the human prion protein

Although a functional role in copper binding has been suggested for the prion protein, evidence for binding at affinities characteristic of authentic metal-binding proteins has been lacking. By presentation of copper(II) ions in the presence of the weak chelator glycine, we have now characterized two high-affinity binding sites for divalent transition metals within the human prion protein. One is in the N-terminal octapeptide-repeat segment and has a K(d) for copper(II) of 10(-14) M, with other metals (Ni(2+), Zn(2+), and Mn(2+)) binding three or more orders of magnitude more weakly. However, NMR and fluorescence data reveal a previously unreported second site around histidines 96 and 111, a region of the molecule known to be crucial for prion propagation. The K(d) for copper(II) at this site is 4 x 10(-14) M, whereas nickel(II), zinc(II), and manganese(II) bind 6, 7, and 10 orders of magnitude more weakly, respectively, regardless of whether the protein is in its oxidized alpha-helical (alpha-PrP) or reduced beta-sheet (beta-PrP) conformation. A role for prion protein (PrP) in copper metabolism or transport seems likely and disturbance of this function may be involved in prion-related neurotoxicity.

Wild-type and met-65-->Leu variants of human cystatin A are functionally and structurally identical

The solution structure of an N-terminally truncated and mutant form (M65L(2-98)) of the human cysteine protease inhibitor cystatin A has been reported that reveals extensive structural differences when compared to the previously published structure of full-length wild-type (WT) cystatin A. On the basis of the M65L(2-98) structure, a model of the inhibitory mechanism of cystatin A was proposed wherein specific interactions between the N- and C-terminal regions of cystatin A are invoked as critical determinants of protease binding. To test this model and to account for the reported differences between the two structures, we undertook additional structural and mechanistic analyses of WT and mutant forms of human cystatin A. These show that modification at the C-terminus of cystatin A by the addition of nine amino acids has no effect upon the affinity of papain inhibition (K(D) = 0.18+/-0.02 pM) and the consequences of such modification are not propagated to other parts of the structure. These findings indicate that perturbation of the C-terminus can be achieved without any measurable effect on the N-terminus or the proteinase binding loops. In addition, introduction of the methionine-65 --> leucine substitution into cystatin A that retains the N-terminal methionine (M65L(1-98)) has no significant effect upon papain binding (K(D) = 0.34+/-0.02 pM). Analyses of the structures of WT and M65L(1-98) using (1)H NMR chemical shifts and residual dipolar couplings in a partially aligning medium do not reveal any evidence of significant differences between the two inhibitors. Many of the differences between the published structures correspond to major violations by M65L(2-98) of the WT constraints list, notably in relation to the position of the N-terminal region of the inhibitor, one of three structural motifs indicated by crystallographic studies to be involved in protease binding by cystatins. In the WT structure, and consistent with the crystallographic data, this region is positioned adjacent to another inhibitory motif (the first binding loop), whereas in M65L(2-98) there is no proximity of these two motifs. As the NMR data for both WT9C and M65L(1-98) are wholly consistent with the published structure of WT cystatin A and incompatible with that of M65L(2-98), we conclude that the former represents the most reliable structural model of this protease inhibitor.

The major transition state in folding need not involve the immobilization of side chains

During protein folding in which few, if any, definable kinetic intermediates are observable, the nature of the transition state is central to understanding the course of the reaction. Current experimental data does not distinguish the relative contributions of side chain immobilization and dehydration phenomena to the major rate-limiting transition state whereas this distinction is central to theoretical models that attempt to simulate the behavior of proteins during folding. Renaturation of the small proteinase inhibitor cystatin under oxidizing versus reducing conditions is the first experimental case in which these processes can be studied independently. Using this example, we show that sidechain immobilization occurs downstream of the major folding transition state. A consequence of this is the existence of states with disordered side chains, which are distinct from kinetic protein folding intermediates and which lie within the folded state free energy well.

Structural mobility of the human prion protein probed by backbone hydrogen exchange

Prions, the causative agents of Creutzfeldt-Jacob Disease (CJD) in humans and bovine spongiform encephalopathy (BSE) and scrapie in animals, are principally composed of PrPSc, a conformational isomer of cellular prion protein (PrPC). The propensity of PrPC to adopt alternative folds suggests that there may be an unusually high proportion of alternative conformations in dynamic equilibrium with the native state. However, the rates of hydrogen/deuterium exchange demonstrate that the conformation of human PrPC is not abnormally plastic. The stable core of PrPC has extensive contributions from all three alpha-helices and shows protection factors equal to the equilibrium constant for the major unfolding transition. A residual, hyper-stable region is retained upon unfolding, and exchange analysis identifies this as a small nucleus of approximately 10 residues around the disulfide bond. These results show that the most likely route for the conversion of PrPC to PrPSc is through a highly unfolded state that retains, at most, only this small nucleus of structure, rather than through a highly organized folding intermediate.

Differences in the effects of TFE on the folding pathways of human stefins A and B

Trifluoroethanol (TFE) has been used to probe differences in the stability of the native state and in the folding pathways of the homologous cysteine protein inhibitors, human stefin A and B. After complete unfolding in 4.5 mol/L GuHCl, stefin A refolded in 11% (vol/vol) TFE, 0.75 mol/L GuHCl, at pH 6.0 and 20 degrees C, with almost identical first-order rate constants of 4.1 s-1 and 5.5 s-1 for acquisition of the CD signal at 230 and 280 nm, respectively, rates that were markedly greater than the value of 0.11 s-1 observed by the same two probes when TFE was absent. The acceleration of the rates of refolding, monitored by tyrosine fluorescence, was maximal at 10% (vol/vol) TFE. Similar rates of refolding (6.2s-1 and 7.2 s-1 for ellipticity at 230 and 280 nm, respectively) were observed for stefin A denatured in 66% (vol/vol) TFE, pH 3.3, when refolding to the same final conditions. After complete unfolding in 3.45 mol/L GuHCl, stefin B refolded in 7% (vol/vol) TFE, 0.57 mol/L GuHCl, at pH 6.0 and 20 degrees C, with a rate constant for the change in ellipticity at 280 nm of 32.8 s-1; this rate was only twice that observed when TFE was absent. As a major point of distinction from stefin A, the refolding of stefin B in the presence of TFE showed an overshoot in the ellipticity at 230 nm to a value 10% greater than that in the native protein; this signal relaxed slowly (0.01 s-1) to the final native value, with little concomitant change in the near-ultraviolet CD signal; the majority of this changes in two faster phases. After denaturation in 42% (vol/vol) TFE, pH 3.3, the kinetics of refolding to the same final conditions exhibited the same rate-limiting step (0.01 s-1) but were faster initially. The results show that similarly to stefin A, stefin B forms its hydrophobic core and predominant part of the tertiary structure faster in the presence of TFE. The results imply that the alpha-helical intermediate of stefin B is highly structured. Proteins 1999;36:205-216.

Identification of amino acid residues critical for aggregation of human CC chemokines macrophage inflammatory protein (MIP)-1alpha, MIP-1beta, and RANTES. Characterization of active disaggregated chemokine variants

Human CC chemokines macrophage inflammatory protein (MIP)-1alpha, MIP-1beta, and RANTES (regulated on activation normal T cell expressed) self-associate to form high-molecular mass aggregates. To explore the biological significance of chemokine aggregation, nonaggregating variants were sought. The phenotypes of 105 hMIP-1alpha variants generated by systematic mutagenesis and expression in yeast were determined. hMIP-1alpha residues Asp26 and Glu66 were critical to the self-association process. Substitution at either residue resulted in the formation of essentially homogenous tetramers at 0.5 mg/ml. Substitution of identical or analogous residues in homologous positions in both hMIP-1beta and RANTES demonstrated that they were also critical to aggregation. Our analysis suggests that a single charged residue at either position 26 or 66 is insufficient to support extensive aggregation and that two charged residues must be present. Solution of the three-dimensional NMR structure of hMIP-1alpha has enabled comparison of these residues in hMIP-1beta and RANTES. Aggregated and disaggregated forms of hMIP-1alpha, hMIP-1beta, and RANTES generally have equivalent G-protein-coupled receptor-mediated biological potencies. We have therefore generated novel reagents to evaluate the role of hMIP-1alpha, hMIP-1beta, and RANTES aggregation in vitro and in vivo. The disaggregated chemokines retained their human immunodeficiency virus (HIV) inhibitory activities. Surprisingly, high concentrations of RANTES, but not disaggregated RANTES variants, enhanced infection of cells by both M- and T-tropic HIV isolates/strains. This observation has important implications for potential therapeutic uses of chemokines implying that disaggregated forms may be necessary for safe clinical investigation.

Multiple folding pathways for heterologously expressed human prion protein

Human PrP (residues 91-231) expressed in Escherichia coli can adopt several conformations in solution depending on pH, redox conditions and denaturant concentration. Oxidised PrP at neutral pH, with the disulphide bond intact, is a soluble monomer which contains 47% alpha-helix and corresponds to PrPC. Denaturation studies show that this structure has a relatively small, solvent-excluded core and unfolds to an unstructured state in a single, co-operative transition with a DeltaG for folding of -5.6 kcal mol-1. The unfolding behaviour is sensitive to pH and at 4.0 or below the molecule unfolds via a stable folding intermediate. This equilibrium intermediate has a reduced helical content and aggregates over several hours. When the disulphide bond is reduced the protein adopts different conformations depending upon pH. At neutral pH or above, the reduced protein has an alpha-helical fold, which is identical to that observed for the oxidised protein. At pH 4 or below, the conformation rearranges to a fold that contains a high proportion of beta-sheet structure. In the reduced state the alpha- and beta-forms are slowly inter-convertible whereas when oxidised the protein can only adopt an alpha-conformation in free solution. The data we present here shows that the human prion protein can exist in multiple conformations some of which are known to be capable of forming fibrils. The precise conformation that human PrP adopts and the pathways for unfolding are dependent upon solvent conditions. The conditions we examined are within the range that a protein may encounter in sub-cellular compartments and may have implications for the mechanism of conversion of PrPC to PrPSc in vivo. Since the conversion of PrPC to PrPSc is accompanied by a switch in secondary structure from alpha to beta, this system provides a useful model for studying major structural rearrangements in the prion protein.

Reversible conversion of monomeric human prion protein between native and fibrilogenic conformations

Prion propagation involves the conversion of cellular prion protein (PrPC) into a disease-specific isomer, PrPSc, shifting from a predominantly alpha-helical to beta-sheet structure. Here, conditions were established in which recombinant human PrP could switch between the native alpha conformation, characteristic of PrPC, and a compact, highly soluble, monomeric form rich in beta structure. The soluble beta form (beta-PrP) exhibited partial resistance to proteinase K digestion, characteristic of PrPSc, and was a direct precursor of fibrillar structures closely similar to those isolated from diseased brains. The conversion of PrPC to beta-PrP in suitable cellular compartments, and its subsequent stabilization by intermolecular association, provide a molecular mechanism for prion propagation.

Mechanism-based inhibition of C5-cytosine DNA methyltransferases by 2-H pyrimidinone

DNA duplexes in which the target cytosine base is replaced by 2-H pyrimidinone have previously been shown to bind with a significantly greater affinity to C5-cytosine DNA methyltransferases than unmodified DNA. Here, it is shown that 2-H pyrimidinone, when incorporated into DNA duplexes containing the recognition sites for M.HgaI-2 and M.MspI, elicits the formation of inhibitory covalent nucleoprotein complexes. We have found that although covalent complexes are formed between 2-H pyrimidinone-modified DNA and both M.HgaI-2 and M.MspI, the kinetics of complex formation are quite distinct in each case. Moreover, the formation of a covalent complex is still observed between 2-H pyrimidinone DNA and M.MspI in which the active-site cysteine residue is replaced by serine or threonine. Covalent complex formation between M.MspI and 2-H pyrimidinone occurs as a direct result of nucleophilic attack by the residue at the catalytic position, which is enhanced by the absence of the 4-amino function in the base. The substitution of the catalytic cysteine residue by tyrosine or chemical modification of the wild-type enzyme with N-ethylmaleimide, abolishes covalent interaction. Nevertheless the 2-H pyrimidinone-substituted duplex still binds to M.MspI with a greater affinity than a standard cognate duplex, since the 2-H pyrimidinone base is mis-paired with guanine.

Characterisation of low free-energy excited states of folded proteins

It is demonstrated that the identity of residues accessing excited conformational states that are of low free energy relative to the ground state in proteins can be obtained from amide proton NMR chemical shift temperature dependences displaying significant curvature. For the N-terminal domain of phosphoglycerate kinase, hen egg-white lysozyme and BPTI, conformational heterogeneity arises from a number of independent sources, including: structural instability resulting from deletion of part of the protein; a minor conformer generated through disulphide bond isomerisation; an alternative hydrogen bond network associated with buried water molecules; alternative hydrogen bonds involving backbone amides and surface-exposed side-chain hydrogen bond acceptors; and the disruption of loops, ends of secondary structural elements and chain termini. In many of these cases, the conformational heterogeneity at these sites has previously been identified by X-ray and/or NMR studies, but conformational heterogeneity of buried water molecules has hitherto received little attention. These multiple independent low free-energy excited states each involve a small number of residues and are shown to be within 2.5 kcal mol-1 of the ground state. Their relationship with the partially unfolded forms previously characterised using amide proton exchange studies is discussed.

On the mechanism of human stefin B folding: II. Folding from GuHCl unfolded, TFE denatured, acid denatured, and acid intermediate states

It has been shown that human stefin B exhibits molten globule intermediates when denatured by acid or GuHCl. In the presence of TFE, it transforms into a highly helical state. In our first study on its folding mechanism (Zerovnik et al., Proteins 32:296-303), the kinetics measured by circular dichroism (CD) and fluorescence were correlated. In the present work the kinetics of folding were monitored by tyrosine fluorescence, ANS fluorescence, and, for certain reactions, far ultraviolet (UV) CD. The folding was started from the unfolded state in 3.45 M GuHCl, the acid denatured state at pH 1.8+/-0.2, an acid molten globule intermediate I1 (pH 3.3+/-0.1, low salt), a more structured acid molten globule intermediate I2 (pH 3.3+/-0.1, 0.42 M NaCl), and the TFE state (pH 3.3+/-0.1, 42% TFE). It has been found that all denatured states, including GuHCl, TFE, acid denatured and acid molten globule intermediate I1, fold with the same kinetics, provided that the final conditions are identical. This does not apply to the second acid molten globule intermediate I2, which demonstrates a higher rate of folding by a factor of 270. Different energy of activation and pH dependence were found for folding from states I1 or I2.

On the mechanism of human stefin B folding: I. Comparison to homologous stefin A. Influence of pH and trifluoroethanol on the fast and slow folding phases

The folding of human stefin B has been studied by several spectroscopic probes. Stopped-flow traces obtained by circular dichroism in the near and far UV, by tyrosine fluorescence, and by extrinsic probe ANS fluorescence are compared. Most (60+/-5%) of the native signal in the far UV circular dichroism (CD) appeared within 10 ms in an unresolved "burst" phase, which was followed by a fast phase (t = 83 ms) and a slow phase (t = 25s) with amplitudes of 30% and 10%, respectively. Similar fast and slow phases were also evident in the near UV CD, ANS fluorescence, and tyrosine fluorescence. By contrast, human stefin A, which has a very similar structure, exhibited only one kinetic phase of folding (t = 6s) detected by all the spectroscopic probes, which occurred subsequent to an initial "burst" phase observed by far UV CD. It is interesting that despite close structural similarity of both homologues they fold differently, and that the less stable human stefin B folds faster by an order of magnitude (comparing the non-proline limited phase). To gain more information on the stefin B folding mechanism, effects of pH and trifluoroethanol (TFE) on the fast and slow phases were investigated by several spectroscopic probes. If folding was performed in the presence of 7% of TFE, rate acceleration and difference in the mechanism were observed.

The role of Gly-4 of human cystatin A (stefin A) in the binding of target proteinases. Characterization by kinetic and equilibrium methods of the interactions of cystatin A Gly-4 mutants with papain, cathepsin B, and cathepsin L

The importance of the evolutionarily conserved Gly-4 residue for the affinity and kinetics of interaction of cystatin A with several cysteine proteinases was assessed by site-directed mutagenesis. Even the smallest replacement, by Ala, resulted in approximately 1000-, approximately 10- and approximately 6000-fold decreased affinities for papain, cathepsin L, and cathepsin B, respectively. Substitution by Ser gave further 3-8-fold reductions in affinity, whereas the largest decreases, >10(5)-fold, were observed for mutations to Arg and Glu. The kinetics of inhibition of papain by the mutants with small side chains, Ala and Ser, were compatible with a one-step bimolecular reaction similar to that with wild-type cystatin A. The decreased affinities of these mutants for papain and cathepsin L were due exclusively to increased dissociation rate constants, but the reduced affinities for cathepsin B were due also to decreased association rate constants. The latter finding indicates that the intact N-terminal region serves as a guide directing cystatin A to the active site of cathepsin B, as has been proposed for cystatin C. The kinetics of binding of the mutants with charged side chains, Arg and Glu, to papain were consistent with a two-step binding mechanism, in which the mutant side chains are accommodated in the complex by a conformational change. The NMR solution structure of the Ala and Trp mutants showed only minor changes compared with wild-type cystatin A, indicating that the large reductions in affinity for proteinases are not due to altered structures of the mutants. Instead, a side chain larger than a hydrogen atom at position 4 affects the interaction with the proteinase most likely by interfering with the binding of the N-terminal region.

Structure of a kinetic protein folding intermediate by equilibrium amide exchange

A combination of equilibrium amide exchange and kinetic folding data show that the essential features of the complex topology of the N-terminal domain of a thermophilic phosphoglycerate kinase are established on a millisecond or faster timescale, before the rate-limiting step in the folding pathway commences.

Protein folding and intermediates

With the exception of the discovery of the rate of formation of the earliest intermediates, there have been no major conceptual leaps in our understanding of protein folding reactions over the past two years. Rather, this period has seen an extension of two established techniques: first, mutational analysis combined with a kinetic definition of the energy landscape of the reaction; and second, the use of hydrogen/deuterium exchange of backbone amide groups combined with NMR. Owing to the application of these methods to a wider range of proteins, it is now possible to draw some general conclusions about the physical processes that direct a protein to its native fold.

Is the structure of the N-domain of phosphoglycerate kinase affected by isolation from the intact molecule?

The structural integrity of the isolated N-domain (residues 1-174) of Bacillus stearothermophilus 3-phosphoglycerate kinase (PGK) has been investigated using heteronuclear NMR spectroscopy. Analysis of 13C chemical shifts, amide protection, and comparison of observed and expected sequential NOE intensities calculated from the crystal structure of the domain in the intact protein indicate that the secondary structure of the isolated domain is unchanged from that found in the intact molecule. Markedly shifted 1H resonances, amide protection, and long-range NOEs indicate that the tertiary structure is similarly unaffected. These results are confirmed by an excellent agreement (standard deviation 0.28 ppm) between observed H alpha chemical shifts and those calculated from the high-resolution (1.6 A) crystal structure of intact PGK [Davies et al. (1994) Acta Crystallogr. D50, 202-209]. The only region perturbed by loss of interactions with the C-domain is a small portion of the substrate-binding site (residues 148-152) whose amide protons are poorly protected from solvent. These results provide a structural basis for the analysis of the folding of the domains of PGK as isolated units and within the intact molecule [Parker et al. (1996) Biochemistry (in press)] and contrast with the notion that the native tertiary fold of the N-domain of PGK requires the whole polypeptide chain, including the entire C-domain [Mas et al. (1995) Biochemistry 34, 7931-7940]. Assignments of backbone 13C, 15N, HN, and H alpha resonances are provided.

Domain behavior during the folding of a thermostable phosphoglycerate kinase

Bacillus stearothermophilus phosphoglycerate kinase (bsPGK) is a monomeric enzyme of 394 residues comprising two globular domains (N and C), covalently linked by an interdomain alpha-helix (residues 170-185). The molecule folds to the native state in three stages. In the first, each domain rapidly and independently collapses to form an intermediate in which the N-domain is stabilized by 5.1 kcal mol-1 and the C-domain by 3.3 kcal mol-1 over their respective unfolded conformations. The N-domain then converts to a folded state at a rate of 1.2 s-1 (delta GI-F = 3.8 kcal mol-1), followed by the C-domain at 0.032 s-1 (delta GI-F = 12.1 kcal mol-1). It is this last step that limits the rate of acquisition of enzyme activity. In the dynamics of unfolding in water, the N-domain converts to the intermediate state at a rate of 8 x 10(-4) s-1, some 10(7) times faster than the C-domain. Consequently, the most populated intermediate in the folding reaction has a native-like N-domain, while that in the unfolding direction has a native-like C-domain. In a conventional sense, therefore, the folding/unfolding kinetics of bsPGK can be described as random order. Consistent with these observations, cutting the molecule in the interdomain helix produces two, independently stable units comprising residues 1-175 and 180-394. A detailed comparison of their folding behavior with that of the whole molecule reveals that true interdomain contacts are relatively weak, contributing approximately 1.4 kcal mol-1 to the stability of the active enzyme. The only interactions which contribute to the stability of rapidly formed intermediates or to transition states along the productive folding pathways are those within domain cores. Contacts formed either between domains or with the interdomain helix are made only in the folded ground state, but do not constitute a separate step in the folding mechanism. Intriguingly, the most pronounced effect of interdomain contacts on the kinetics of folding is inhibitory; the presence of the C-domain appearing to reduce the effective rate of acquisition of native structure within the N-domain.

Complexes formed between calmodulin and the antagonists J-8 and TFP in solution

The binding of the antagonists N-(8-aminooctyl)-5-iodonaphthalene-1-sulfonamide (J-8) and trifluoperazine (TFP) to intact calcium-saturated bovine calmodulin (CaM) and also of J-8 to the C-terminal domain (tr2c) has been investigated. Using a combination of NMR methods, including NOESY data, mobility measurements, and chemical shift and line-shape analysis, we show that the primary interaction between J-8 and tr2c is between the naphthalene ring of the antagonist and the hydrophobic pocket of the protein, similar to the binding of the hydrophobic side-chain residues of calmodulin target peptides. Comparison of the mobility of the drug, the intensity and pattern of intermolecular NOESY cross-peaks, and chemical shift changes shows that there is no significant change in the binding mode in J-8. CaM compared to J-8.tr2c, with one molecule binding to each domain. In particular, we find that the mobility of the aliphatic amino "tail" of J-8 remains highly mobile in both systems. This contrasts with the notion that the tail may bridge between the two domains to give a "globular" form of CaM. We also show that TFP induces very similar shift changes to J-8 and that the stoichiometry of the major binding event in all three cases is one drug molecule per domain. It also appears that secondary binding sites for the drug molecules are present in all three systems.

Determinants of DNA-binding specificity of ETS-domain transcription factors

Several mechanisms are employed by members of transcription factor families to achieve sequence-specific DNA recognition. In this study, we have investigated how members of the ETS-domain transcription factor family achieve such specificity. We have used the ternary complex factor (TCF) subfamily as an example. ERK2 mitogen-activated protein kinase stimulates serum response factor-dependent and autonomous DNA binding by the TCFs Elk-1 and SAP-la. Phosphorylated Elk-1 and SAP-la exhibit specificities of DNA binding similar to those of their isolated ETS domains. The ETS domains of Elk-1 and SAP-la and SAP-2 exhibit related but distinct DNA-binding specificities. A single residue, D-69 (Elk-1) or V-68 (SAP-1), has been identified as the critical determinant for the differential binding specificities of Elk-1 and SAP-1a, and an additional residue, D-38 (Elk-1) or Q-37 (SAP-1), further modulates their DNA binding. Creation of mutations D38Q and D69V is sufficient to confer SAP-la DNA-binding specificity upon Elk-1 and thereby allow it to bind to a greater spectrum of sites. Molecular modelling indicates that these two residues (D-38 and D-69) are located away from the DNA-binding interface of Elk-1. Our data suggest a mechanism in which these residues modulate DNA binding by influencing the interaction of other residues with DNA.

Calcium-induced structural changes and domain autonomy in calmodulin

We have determined the solution structures of the apo and (Ca2+)2 forms of the carboxy-terminal domain of calmodulin using multidimensional heteronuclear nuclear magnetic resonance spectroscopy. The results show that both forms adopt well-defined structures with essentially equal secondary structure. A comparison of the structures of the two forms shows that Ca2+ binding causes major rearrangements of the secondary structure elements with changes in inter-residue distances of up to 15 A and exposure of the hydrophobic interior of the four-helix bundle. Comparisons with previously determined high-resolution X-ray structures and models of calmodulin indicate that this domain is structurally autonomous.

Characterization of the Elk-1 ETS DNA-binding domain

The ETS domain family of transcription factors is comprised of several important proteins that are involved in controlling key cellular events such as proliferation, differentiation, and development. One such protein, Elk-1, regulates the activity of the c-fos promoter in response to extracellular stimuli. Elk-1 is representative of a subgroup of ETS domain proteins that utilize a bipartite recognition mechanism that is mediated by both protein-DNA and protein-protein interactions. In this study, we have overexpressed, purified, and characterized the ETS DNA-binding domain of Elk-1 (Elk-93). Elk-93 was expressed in Escherichia coli as a fusion protein with glutathione S-transferase and purified to homogeneity from both the soluble and insoluble fractions using a two-column protocol. A combination of CD, NMR, and fluorescence spectroscopy demonstrates that Elk-93 represents an independently folded domain of mixed alpha/beta structure in which the three conserved tryptophans appear to contribute to the hydrophobic core of the protein. Moreover, DNA binding studies demonstrate that Elk-93 binds DNA with both high affinity (Kd approximately 0.85 x 10(-10)M) and specificity. Circular permutation analysis indicates that DNA binding by Elk-93 does not induce significant bending of the DNA. Our results are discussed with respect to predictive models for the structure of the ETS DNA-binding domain.

The three-dimensional solution structure of human stefin A

The three-dimensional solution structure of recombinant human stefin A has been determined by a simulated annealing protocol using a total of 1113 distance and angle constraints obtained from 1H and 15N HMR spectroscopy. The solution structure is represented by a family of 17 conformers with an average root-mean-square deviation relative to the mean structure of 0.44 A for backbone atoms and 0.94 A for all heavy atoms for the main body of the structure. The protein has a well-defined global fold consisting of five anti-parallel beta-strands wrapped around a central five-turn alpha-helix. There is considerable similarity between the structural features of free stefin A in solution and the X-ray structure of the homologous protein stefin B in its complex with papain, but there are also some important differences in the regions which are fundamental to proteinase binding. The differences consist primarily of two regions of high conformational heterogeneity in free stefin A which correspond in stefin B to two of the components of the tripartite wedge that docks into the active site of the target proteinase. These regions, which are shown to be mobile in solution, are the five N-terminal residues and the second binding loop. In the bound conformation of stefin B they form a turn and a short helix, respectively.

Structural characterisation of human stefin A in solution and implications for binding to cysteine proteinases

Stefin A is a member of the cystatin superfamily of proteins which are tight and reversibly binding inhibitors of the papain-like cysteine proteinases. The 1H-NMR and 15N-NMR resonances of human stefin A have been sequentially assigned using two-dimensional homonuclear and heteronuclear NMR techniques in conjunction with three-dimensional heteronuclear methods. Characteristic sequential and medium range NOE contacts, J constants and hydrogen exchange data have been used to identify the secondary structural elements of the protein which consists of five anti-parallel beta-strands and a single alpha-helix. There is much similarity between the secondary structural features of stefin A and the homologous protein stefin B in its complex with papain [Stubbs, M. T., Laber, B., Bode, W., Huber, R., Jerala, R., Lenarcic, B. & Turk, V. (1990) EMBO. J. 9. 1939-1947] but also some important differences in regions which are fundamental to the binding event. The principal difference is the presence of two conformationally unrestricted regions in stefin A that form two of the components of the tripartite wedge which docks into the active site of the target proteinase. Specifically, these regions are the five N-terminal residues and the second binding loop, which form a turn and a short helix respectively, in the bound conformation of stefin B.

Peptide models of protein folding initiation sites. 1. Secondary structure formation by peptides corresponding to the G- and H-helices of myoglobin

Myoglobin has been extensively studied as a model system for protein folding in vitro. As part of an ongoing study of myoglobin folding, we have synthesized a series of peptide fragments corresponding to portions of the sequence of the sperm whale protein. The conformational preferences of these peptides have been investigated by circular dichroism and nuclear magnetic resonance spectroscopy in aqueous solution. In this paper we describe the folding propensities of two peptides (Mb-G and Mb-H), corresponding to the G- and H-helix segments of the myoglobin sequence. The Mb-G peptide shows evidence of a very small population of helical conformations in aqueous solution, both by CD and NMR. By contrast, the monomeric Mb-H peptide is found by CD to adopt a significant population (ca. 30%) of ordered helix and by NMR to populate helical conformations in rapid dynamic equilibrium with unfolded states. The Mb-H peptide undergoes a well-characterized, concentration-dependent monomer-tetramer equilibrium. At peptide concentrations greater than 1 mM there is an increase in the population of helix, to approximately 85% according to the CD spectrum, through self-association to form a tetramer. Both medium-range NOE connectivities and a CD spectrum characteristic of ordered helix are observed at low peptide concentrations, establishing that helical conformations are present in the monomeric state of Mb-H. The relative helicity at various sites throughout the Mb-H peptide has been estimated using a novel method for assessing the distribution of helical populations based on the relative magnitudes of medium-range d alpha beta (i,i+3) NOE connectivities. The population of ordered helix is seen to be highest in the center of the peptide sequence; the ends of the peptide show evidence of pronounced fraying.

Peptide models of protein folding initiation sites. 2. The G-H turn region of myoglobin acts as a helix stop signal

A series of peptide fragments of sperm whale myoglobin, corresponding to segments of the region between the G- and H-helices of the protein, have been synthesized and their conformational preferences investigated using circular dichroism and nuclear magnetic resonance spectroscopy in aqueous solution and in solvent mixtures containing water and trifluoroethanol. The smallest fragment, Mb-GH5, a five-residue peptide with the sequence HPGDF corresponding to the connecting loop between the two helices in the folded protein, adopts highly populated turn conformations in aqueous solution. A 25-residue peptide, Mb-GH25, containing the same sequence flanked by contiguous segments of the G- and H-helix sequences, was also found to contain a high proportion of conformers with a turn in this region. No helix formation was observed in the flanking sequences in water solution, either in Mb-GH25 or in control 10-residue peptides (Mb-G10 and Mb-H10) with sequences corresponding to the G- and H-helix segments. No additional helicity above that of the sum of the components was observed for Mb-GH25, indicating that a helical hairpin structure is not formed in the monomeric peptide in aqueous solution. In the presence of TFE, ordered helix is formed in Mb-GH25 according to the CD spectrum, and NMR spectra indicate that this is localized in the N-terminal portion of the peptide. NOESY spectra clearly show that the turn conformation is retained under these conditions.(ABSTRACT TRUNCATED AT 250 WORDS)

Peptide models of protein folding initiation sites. 3. The G-H helical hairpin of myoglobin

As part of an extensive dissection of the folding pathway of myoglobin, a series of peptides corresponding to fragments of sperm whale myoglobin have been synthesized, and their conformational preferences investigated using circular dichroism and nuclear magnetic resonance spectroscopy in aqueous solution and in solvent mixtures containing water and trifluoroethanol. The behavior of short fragments corresponding to the sequences of the G- and H-helices of myoglobin and to the turn region between these helices has been described in accompanying papers. At the next level of complexity, peptide model compounds have been synthesized to explore the longer-range interactions which may take place in protein folding after initial secondary structure formation has occurred. A series of disulfide-bridged dimeric peptides containing the complete sequences of the G- and H-helices of myoglobin were synthesized and their conformational preferences examined. CD spectra indicate that disulfide-bridged peptides consisting of two H-helix sequences (Mb-HssH) and of one G- and one H-helix (Mb-GssH) are highly helical in water solution, as a result of intermolecular association. A 51-residue peptide, Mb-GH51, encompassing the entire G-H helical hairpin of myoglobin, including the turn sequence between the two helices, has been successfully synthesized by standard methods. This peptide was designed to be monomeric in aqueous solution. Mb-GH51 does not appear from CD spectra to contain any additional helix in water solution above what would be expected from an equimolar mixture of the G- and H-helix peptides. NMR spectra indicate that the turn conformation observed in shorter peptide fragments is retained in Mb-GH51 in high population.(ABSTRACT TRUNCATED AT 250 WORDS)

Folding of peptide fragments comprising the complete sequence of proteins. Models for initiation of protein folding. I. Myohemerythrin

In an attempt to delineate potential folding initiation sites for different protein structural motifs, we have synthesized series of peptides that span the entire length of the polypeptide chain of two proteins, and examined their conformational preferences in aqueous solution using proton nuclear magnetic resonance and circular dichroism spectroscopy. We describe here the behavior of peptides derived from a simple four-helix bundle protein, myohemerythrin. The peptides correspond to the sequences of the four long helices (the A, B, C and D helices), the N- and C-terminal loops and the connecting sequences between the helices. The peptides corresponding to the helices of the folded protein all exhibit preferences for helix-like conformations in solution. The conformational ensembles of the A- and D-helix peptides contain ordered helical forms, as shown by extensive series of medium-range nuclear Overhauser effect connectivities, while the B- and C-helix peptides exhibit conformational preferences for nascent helix. All four peptides adopt ordered helical conformations in mixtures of trifluoroethanol and water. The terminal and interconnecting loop peptides also appear to contain appreciable populations of conformers with backbone phi and psi angles in the alpha-region and include highly populated hydrophobic cluster and/or turn conformations in some cases. Trifluoroethanol is unable to drive these peptides towards helical conformations. Overall, the peptide fragments of myohemerythrin have a marked preference towards secondary structure formation in aqueous solution. In contrast, peptide fragments derived from the beta-sandwich protein plastocyanin are relatively devoid of secondary structure in aqueous solution (see accompanying paper). These results suggest that the two different protein structural motifs may require different propensities for formation of local elements of secondary structure to initiate folding, and that there is a prepartitioning of conformational space determined by the local amino acid sequence that is different for the helical and beta-sandwich structural motifs.

Conformation of a T cell stimulating peptide in aqueous solution

Using two-dimensional NMR spectroscopy and circular dichroism spectroscopy it is demonstrated that a T cell stimulating peptide corresponding to residues 132-153 of sperm whale myoglobin populates helical conformations in aqueous solution. This finding is in accordance with proposals that immunodominant sites in T cell stimulating peptides have a high conformational propensity. The observation of secondary structure in aqueous solutions of this and other immunogenic peptides has important implications for initiation of protein folding.

Forces in molecular recognition: comparison of experimental data and molecular mechanics calculations

NMR studies of the rotation barrier of the disaccharide of the glycopeptide antibiotic vancomycin have been used to test the performance of computer simulation techniques using molecular mechanics. In the absence of any solvated water, no correlation could be found between experiment and calculation. By introducing solvent water molecules into the binding region of the antibiotic, the NMR results could be simulated both qualitatively and quantitatively within experimental error without using massive computational resources.