NMR of hydrogen bonding in cold-shock protein A and an analysis of the influence of crystallographic resolution on comparisons of hydrogen bond lengths

Hydrogen bonding in cold-shock protein A of Escherichia coli has been investigated using long-range HNCO spectroscopy. Nearly half of the amide protons involved in hydrogen bonds in solution show no measurable protection from exchange in water, cautioning against a direct correspondence between hydrogen bonding and hydrogen exchange protection. The N to O atom distance across a hydrogen bond, R(NO), is related to the size of the (3h)J(NC') trans hydrogen bond coupling constant and the amide proton chemical shift. Both NMR parameters show poorer agreement with the 2.0-A resolution X-ray structure of the cold-shock protein studied by NMR than with a 1.2-A resolution X-ray structure of a homologous cold-shock protein from the thermophile B. caldolyticus. The influence of crystallographic resolution on comparisons of hydrogen bond lengths was further investigated using a database of 33 X-ray structures of ribonuclease A. For highly similar structures, both hydrogen bond R(NO) distance and Calpha coordinate root mean square deviations (RMSD) show systematic increases as the resolution of the X-ray structure used for comparison decreases. As structures diverge, the effects of coordinate errors on R(NO) distance and Calpha coordinate root mean square deviations become progressively smaller. The results of this study are discussed with regard to the influence of data precision on establishing structure similarity relationships between proteins.

An NMR-based quenched hydrogen exchange investigation of model amyloid fibrils formed by cold shock protein A

Acid-denatured cold shock protein A (CspA) self-assembles into polymers with properties typical of amyloid fibrils. In the present work, a quenched hydrogen exchange experiment was used to probe the interactions of CspA fibrils with solvent. Exchange was initiated by incubating suspensions of fibrils in D2O, and quenched by flash freezing. Following lyophilization, exchange-quenched samples were dissolved in 90% DMSO/10% D2O, giving DMSO-denatured monomers. Intrinsic exchange rates for denatured CspA in 90% DMSO/10% D2O (pH* 4.5) were sufficiently slow (approximately 1 x 10(-3) min-1) to enable quantification of NMR signal intensity decays due to H/D exchange in the fibrils. Hydrogen exchange rate constants for CspA fibrils were found to vary less than 3-fold from a mean value of 5 x 10(-5) min-1. The uniformity of rate constants suggests that exchange is in the EX1 limit, and that the mechanism of exchange involves a cooperative dissociation of CspA monomers from fibrils, concomitant with unfolding. Previous studies indicated that the highest protection factors in native CspA are approximately 10(3), and that protection factors for the acid-denatured monomer precursors of CspA fibrils are close to unity. Because exchange in is in the EX1 regime, it is only possible to place a lower limit of at least 10(5) on protection factors in CspA fibrils. The observation that all amide protons are protected from exchange indicates that the entire CspA polypeptide chain is structured in the fibrils.

Observation of the closing of individual hydrogen bonds during TFE-induced helix formation in a peptide

Helix formation of an S-peptide analog, comprising the first 20 residues of Ribonuclease A and two additional N-terminal residues, was studied by measuring hydrogen bond (H-bond) (h3)J(NC') scalar couplings as a function of 2,2,2-trifluoroethanol (TFE) concentration. The (h3)J(NC') couplings give direct evidence for the closing of individual backbone N-H***O = C H-bonds during the TFE-induced formation of secondary structure. Whereas no (h3)J(NC') correlations could be detected without TFE, alpha-helical (i,i +4) H-bond correlations were observed for the amides of residues A5 to M15 in the presence of TFE. The analysis of individual coupling constants indicates that alpha-helix formation starts at the center of the S-peptide around residue E11 and proceeds gradually from there to both peptide ends as the TFE concentration is increased. At 60% to 90% TFE, well-formed alpha-helical H-bonds were observed for the amides hydrogens of residues K9 to Q13, whereas H-bonds of residues T5 to A8, H14, and M15 are affected by fraying. No intramolecular backbone H-bonds are present at and beyond the putative helix stop signal D16. As the (h3)J(NC') constants represent ensemble averages and the dependence of (h3)J(NC') on H-bond lengths is very steep, the size of the individual (h3)J(NC') coupling constants can be used as a measure for the population of a closed H-bond. These individual populations are in agreement with results derived from the Lifson-Roig theory for coil-to-helix transitions. The present work shows that the closing of individual H-bonds during TFE-induced helix formation can be monitored by changes in the size of H-bond scalar couplings.

An intrahelical salt bridge within the trigger site stabilizes the GCN4 leucine zipper

We previously reported that a helical trigger segment within the GCN4 leucine zipper monomer is indispensable for the formation of its parallel two-stranded coiled coil. Here, we demonstrate that the intrinsic secondary structure of the trigger site is largely stabilized by an intrahelical salt bridge. Removal of this surface salt bridge by a single amino acid mutation induced only minor changes in the backbone structure of the GCN4 leucine zipper dimer as verified by nuclear magnetic resonance. The mutation, however, substantially destabilized the dimeric structure. These findings support the proposed hierarchic folding mechanism of the GCN4 coiled coil in which local helix formation within the trigger segment precedes dimerization.

Microscopic stability of cold shock protein A examined by NMR native state hydrogen exchange as a function of urea and trimethylamine N-oxide

Native state hydrogen exchange of cold shock protein A (CspA) has been characterized as a function of the denaturant urea and of the stabilizing agent trimethylamine N-oxide (TMAO). The structure of CspA has five strands of beta-sheet. Strands beta1-beta4 have strongly protected amide protons that, based on experiments as a function of urea, exchange through a simple all-or-none global unfolding mechanism. By contrast, the protection of amide protons from strand beta5 is too weak to measure in water. Strand beta5 is hydrogen bonded to strands beta3 and beta4, both of which afford strong protection from solvent exchange. Gaussian network model (GNM) simulations, which assume that the degree of protection depends on tertiary contact density in the native structure, accurately predict the strong protection observed in strands beta1-beta4 but fail to account for the weak protection in strand beta5. The most conspicuous feature of strand beta5 is its low sequence hydrophobicity. In the presence of TMAO, there is an increase in the protection of strands beta1-beta4, and protection extends to amide protons in more hydrophilic segments of the protein, including strand beta5 and the loops connecting the beta-strands. TMAO stabilizes proteins by raising the free energy of the denatured state, due to highly unfavorable interactions between TMAO and the exposed peptide backbone. As such, the stabilizing effects of TMAO are expected to be relatively independent of sequence hydrophobicity. The present results suggest that the magnitude of solvent exchange protection depends more on solvent accessibility in the ensemble of exchange susceptible conformations than on the strength of hydrogen-bonding interactions in the native structure.

NMR evidence for progressive stabilization of native-like structure upon aggregation of acid-denatured LysN

The acid-denatured form of the protein LysN aggregates reversibly at pH 2.0. The strength of self-association increases with increasing Cl(-) anion concentration. At low concentrations of protein or Cl(-) anion, resonances of denatured LysN are in slow exchange with a minor form of the protein, which shows native-like NMR chemical shifts. The minor native-like resonances increase in intensity with increasing protein concentration, demonstrating that a native-like monomer fold is stabilized on aggregation of the acid-denatured protein. At high concentrations of protein or Cl(-) anion, interconversion between the major and minor resonances appears to shift from slow to intermediate exchange on the NMR timescale. NMR line-broadening is more pronounced for the major resonances of the denatured protein, which show sigmoidal decay curves with increasing Cl(-) concentration. The mid-points of the decay curves for residues in different parts of the molecule are non-coincident. We propose that differences in the NMR line-broadening transitions of individual residues reflect a stepwise stabilization of native-like structure on aggregation, starting with the segments of the protein that form the initial association interface. The resonances of the denatured protein with the greatest sensitivity to self-association correspond roughly to those that are most perturbed in the native protein on binding of the natural substrate tRNA(Lys). This suggests that the hydrophobic surfaces that promote intermolecular misfolding of acid-denatured LysN, may resemble those used for substrate binding by the native protein.

An NMR investigation of solution aggregation reactions preceding the misassembly of acid-denatured cold shock protein A into fibrils

At pH 2.0, acid-denatured CspA undergoes a slow self-assembly process, which results in the formation of insoluble fibrils. 1H-15N HSQC, 3D HSQC-NOESY, and 15N T2 NMR experiments have been used to characterize the soluble components of this reaction. The kinetics of self-assembly show a lag phase followed by an exponential increase in polymerization. A single set of 1H-15N HSQC cross-peaks, corresponding to acid-denatured monomers, is observed during the entire course of the reaction. Under lag phase conditions, 15N resonances of residues that constitute the beta-strands of native CspA are selectively broadened with increasing protein concentration. The dependence of 15N T2 values on spin echo period duration demonstrates that line broadening is due to fast NMR exchange between acid-denatured monomers and soluble aggregates. Exchange contributions to T2 relaxation correlate with the squares of the chemical shift differences between native and acid-denatured CspA, and point to a stabilization of native-like structure upon aggregation. Time-dependent changes in 15N T2 relaxation accompanying the exponential phase of polymerization suggest that the first three beta-strands may be predominantly responsible for association interfaces that promote aggregate growth. CspA serves as a useful model system for exploring the conformational determinants of denatured protein misassembly.

NMR hydrogen exchange of the OB-fold protein LysN as a function of denaturant: the most conserved elements of structure are the most stable to unfolding

The structure of LysN contains an OB-fold motif composed of a structurally conserved five-stranded beta-barrel capped by a poorly conserved alpha-helix between strands beta3 and beta4. Two additional alpha-helices, unique to the LysN structure, flank the N terminus of the OB-fold. The stability of LysN to unfolding has been investigated with NMR native state hydrogen exchange measurements as a function of guanidinium hydrochloride concentration, and equilibrium unfolding transitions monitored by ellipticity at 222 nm and fluorescence at 350 nm. The spectrophotometric measurements suggest an apparent two-state unfolding transition with DeltaGu(0) approximately 6 kcal/mol and m approximately 3 kcal/(molM). By contrast, NMR hydrogen exchange measurements manifest a distribution of DeltaGu(0) and m values which indicate that the protein can undergo subglobal unfolding. The largest DeltaGu(0) values from hydrogen exchange are for residues in the beta-sheet of the protein. These values, which reflect complete unfolding of the protein, are between 3 and 4 kcal/mol higher than those obtained from circular dichroism or fluorescence. This discrepancy may be due to the comparison of NMR hydrogen exchange parameters measured at residue-level resolution, with spectrophotometric parameters that reflect an unresolved super position of unfolding transitions of the alpha-helices and beta-strands. The largest DeltaGu(0) values obtained from hydrogen exchange for the subset of residues in the alpha-helices of the protein, agree with the DeltaGu(0) values obtained from circular dichroism or fluorescence. Based on the hydrogen exchange data, however, the three alpha-helices of LysN are on average 3 kcal/mol less stable than the beta-sheet. Consistent with the subglobal unfolding of LysN evinced by hydrogen exchange, a deletion mutant that lacks the first alpha-helix of the protein retains a cooperatively folded structure. Taken together with previous results on the OB-fold proteins SN and CspA, the present results for LysN suggest that the most conserved elements of structure in the OB-fold motif are the most resistant to denaturation. In all three proteins, stability to denaturation correlates with sequence hydrophobicity.

Contributions of the ionization states of acidic residues to the stability of the coiled coil domain of matrilin-1

The pKa values of eight glutamic acid residues in the homotrimeric coiled coil domain of chicken matrilin-1 have been determined from 2D H(CA)CO NMR spectra recorded as a function of the solution pH. The pKa values span a range between 4.0 and 4.7, close to or above those for glutamic acid residues in unstructured polypeptides. These results suggest only small favorable contributions to the stability of the coiled coil from the ionization of its acidic residues.

NMR structure of a parallel homotrimeric coiled coil

The solution structure of the oligomerization domain of cartilage matrix protein (also known as matrilin-1) has been determined by heteronuclear NMR spectroscopy. The domain folds into a parallel, disulfide-linked, three-stranded, alpha-helical coiled coil, spanning five heptad repeats in the amino acid sequence. The sequence of the first two heptad repeats shows some deviations from the consensus of hydrophobic and hydrophilic residue preferences. While the corresponding region of the coiled coil has a higher intrinsic flexibility, backbone alpha-helix and superhelix parameters are consistent with a regular coiled coil structure.

15N backbone dynamics of the S-peptide from ribonuclease A in its free and S-protein bound forms: toward a site-specific analysis of entropy changes upon folding

Backbone 15N relaxation parameters (R1, R2, 1H-15N NOE) have been measured for a 22-residue recombinant variant of the S-peptide in its free and S-protein bound forms. NMR relaxation data were analyzed using the "model-free" approach (Lipari & Szabo, 1982). Order parameters obtained from "model-free" simulations were used to calculate 1H-15N bond vector entropies using a recently described method (Yang & Kay, 1996), in which the form of the probability density function for bond vector fluctuations is derived from a diffusion-in-a-cone motional model. The average change in 1H-15N bond vector entropies for residues T3-S15, which become ordered upon binding of the S-peptide to the S-protein, is -12.6+/-1.4 J/mol.residue.K. 15N relaxation data suggest a gradient of decreasing entropy values moving from the termini toward the center of the free peptide. The difference between the entropies of the terminal and central residues is about -12 J/mol residue K, a value comparable to that of the average entropy change per residue upon complex formation. Similar entropy gradients are evident in NMR relaxation studies of other denatured proteins. Taken together, these observations suggest denatured proteins may contain entropic contributions from non-local interactions. Consequently, calculations that model the entropy of a residue in a denatured protein as that of a residue in a di- or tri-peptide, might over-estimate the magnitude of entropy changes upon folding.

Heteronuclear NMR assignments and secondary structure of the coiled coil trimerization domain from cartilage matrix protein in oxidized and reduced forms

The C-terminal oligomerization domain of chicken cartilage matrix protein is a trimeric coiled coil comprised of three identical 43-residue chains. NMR spectra of the protein show equivalent magnetic environments for each monomer, indicating a parallel coiled coil structure with complete threefold symmetry. Sequence-specific assignments for 1H-, 15N-, and 13C-NMR resonances have been obtained from 2D 1H NOESY and TOCSY spectra, and from 3D HNCA, 15N NOESY-HSQC, and HCCH-TOCSY spectra. A stretch of alpha-helix encompassing five heptad repeats (35 residues) has been identified from intra-chain HN-HN and HN-H alpha NOE connectivities. 3JHNH alpha coupling constants, and chemical shift indices. The alpha-helix begins immediately downstream of inter-chain disulfide bonds between residues Cys 5 and Cys 7, and extends to near the C-terminus of the molecule. The threefold symmetry of the molecule is maintained when the inter-chain disulfide bonds that flank the N-terminus of the coiled coil are reduced. Residues Ile 21 through Glu 36 show conserved chemical shifts and NOE connectivities, as well as strong protection from solvent exchange in the oxidized and reduced forms of the protein. By contrast, residues Ile 10 through Val 17 show pronounced chemical shift differences between the oxidized and reduced protein. Strong chemical exchange NOEs between HN resonances and water indicate solvent exchange on time scales faster than 10 s, and suggests a dynamic fraying of the N-terminus of the coiled coil upon reduction of the disulfide bonds. Possible roles for the disulfide crosslinks of the oligomerization domain in the function of cartilage matrix protein are proposed.

A fragment of staphylococcal nuclease with an OB-fold structure shows hydrogen-exchange protection factors in the range reported for "molten globules"

Hydrogen-exchange rates for an OB-fold subdomain fragment of staphylococcal nuclease have been measured at pH 4.7 and 4 degrees C, conditions close to the minimum of acid/base catalyzed exchange. The strongest protection from solvent exchange is observed for residues from a five-stranded beta-barrel in the NMR structure of the protein. Protection factors, calculated from the experimental hydrogen-exchange rates, range between 1 and 190. Similarly small protection factors have in many cases been attributed to "molten globule" conformations that are supposed to lack a specific tertiary structure. The present results suggest that marginal protection from solvent exchange does not exclude well-defined structure.

Accretion of structure in staphylococcal nuclease: an 15N NMR relaxation study

15N main-chain dynamics are compared in four forms of staphylococcal nuclease with different stabilities to unfolding: (1) SN-T, the ternary complex of the protein, Ca2+, and the inhibitor thymidine 3', 5'-bisphosphate; (2) SN, the protein in the absence of added ligands; (3) SN-OB, a folded fragment that corresponds to an "OB-fold" subdomain; (4) delta 131 delta, a denatured 131-residue fragment. SN-T exhibits very little internal motion on the nanosecond timescale. In SN, a moderate increase in flexibility is observed for the first three strands of the five-stranded beta-sheet, and for a loop between strands 4 and 5. In SN-OB, the loops between strands 3 and 4, and between strands 4 and 5, are extremely flexible on the nanosecond timescale. While the beta-sheets of SN-OB and SN have comparable dynamics on the nanosecond timescale, the beta-sheet in SN-OB experiences additional motion on a slower timescale of 330(+/-170) microseconds. We attribute the latter to interconversion between a major folded (> or = 98%) and a minor unfolded (> or = 2%) conformation. In delta 131 delta, the first three strands of beta-sheet experience conformational averaging on the millisecond timescale. Most of the remainder of the polypeptide chain is highly flexible on the nanosecond timescale. When all four forms of nuclease are considered, there is an increase in the proportion of residues with large amplitude internal motions (low order parameters) as the stability of the folded state is decreased. Residues with low order parameters cluster to distinct regions of the chain, and have H alpha chemical shifts and 3JHN-H alpha coupling constants that tend towards "random coil" values. Conversely, a trend towards uniformly high order parameters suggests a consolidation of structure with increasing stability to denaturation.

NMR structure of a stable "OB-fold" sub-domain isolated from staphylococcal nuclease

Similar folds often occur in proteins with dissimilar sequences. The OB-fold forms a part of the structures of at least seven non-homologous proteins that share either oligonucleotide or oligosaccharide binding functions. A 1-103 fragment corresponding to the OB-fold of the 149 amino acid residue staphylococcal nuclease gives NMR spectra characteristic of an unfolded protein, i.e. the wild-type nuclease sequence is insufficient to maintain a stable tertiary structure in the absence of the C-terminal one-third of this single-domain protein. By contrast, the 1-103 fragment of nuclease with the mutations Val66Leu and Gly88Val adopts a stable tertiary structure. The NMR solution structure of this latter fragment is a close variation of the OB-fold found in the X-ray structure of the parent protein. The Val66Leu and Gly88Val mutations appear to stabilize tertiary structure by consolidating the hydrophobic core of the nuclease OB-fold sub-domain. Taken together, these results suggest that recurrent structural motifs such as the OB-fold may in some cases represent vestiges of autonomous folding units that, during evolution, have become integrated into more complex cooperative folding domains.

Initial studies of the equilibrium folding pathway of staphylococcal nuclease

Spectroscopic methods were used to examine the sequential build up of structure in the denatured state of staphylococcal nuclease. The 'free energy distance' between the native and denatured states was manipulated by altering conditions in solution (for example altering urea or glycerol concentration) and by changing the amino acid sequences. Initial studies employed a fragment of nuclease, referred to as delta 131 delta, which lacks six structural residues from the amino terminus and one structural residue from the carboxy-terminus. Nuclear magnetic resonance analysis of this fragment in solution revealed a modest quantity of dynamic structure which is native-like in character. With the addition of urea, 12 new HN peaks appeared in the 1H-15N correlation spectrum, presumably as a result of the breakdown of residual structure involving the first three beta strands. With the addition of glycerol, there was a rapid increase in the quantity of beta sheet structure detected by circular dichroism spectroscopy. At very high glycerol concentrations, an increase in helical structure became apparent. These data in addition to previously published results suggest that: (i) a beta-meander (strands beta 1-beta 2-beta 3) and the second alpha helix (alpha 2) are among the most stable local structures; (ii) the five-strand beta-barrel forms in a reaction which does not require the presence of several other native substructures; and (iii) the last step on the equilibrium folding pathway may be the formation and packing of the carboxy terminal alpha helix (alpha 3) to give the native state.

Backbone dynamics of a highly disordered 131 residue fragment of staphylococcal nuclease

In order to characterize the dynamic properties of the denatured state of staphylococcal nuclease, R1, R2, and NOE relaxation parameters have been measured for the backbone 15N nuclei of a 131 residue fragment that serves as a model of the denatured state under non-denaturing conditions. The relaxation data indicate a wide range of amplitudes for segmental motion and are inconsistent with a random coil conformation. An optimal value of 7.8 ns was obtained for the molecular rotational correlation time tau m based on the analysis of the 79 residues for which R1, R2, and NOE relaxation data could be obtained. This value corresponds roughly to the slowest detectable motion on the nanosecond time scale and is of a magnitude consistent with global tumbling of a large portion of the molecule. For the majority of residues, experimental data could be described most adequately in terms of a modified "model-free" formalism which includes contributions from internal motions on both an intermediate (tau e) and a fast time scale (tau f) in the context of slow overall tumbling (tau m). The generalized order parameters S2, which gives the amplitude of motions on time scales faster than tau m, correlates with sequence hydrophobicity and suggests a relationship between chain flexibility and sequence propensity for hydrophobic collapse. The fractional populations of three alpha-helices in the protein show a stronger correlation with S2 values and hydrophobicities than with intrinsic helix propensities. These observations suggest that secondary structure may be preferentially stabilized in hydrophobic segments of the sequence.

Solution structure of a peptide fragment of human alpha-lactalbumin in trifluoroethanol: a model for local structure in the molten globule

BACKGROUND

At low pH, human alpha-lactalbumin forms a partly folded molten globule state that contains a non-native clustering of the side chains of Tyr103, Trp104 and His107. In order to understand the conformation of this region of the protein in the molten globule state, we investigated the structure of a peptide corresponding to residues 101-110 of human alpha-lactalbumin in trifluoroethanol.

RESULTS

We determined the structure of the 101-110 peptide from an NMR data set of 145 nuclear Overhauser effects and nine 3JHN alpha coupling constants, using an ensemble calculation approach to take into account the possibilities of conformational averaging of the data. The backbone of residues 3-10 in the peptide adopts a series of turns, that involving residues 5-8 being the best defined, while the side chains of residues 1, 3, 4, 5, 6 and 7 form a hydrophobic cluster.

CONCLUSIONS

The peptide conformation differs from that previously determined for residues 101-110 in crystal structures of native alpha-lactalbumin determined at both high and low pH, particularly in the relative orientations of the side chains. The series of turns seen in the peptide could, however, be related to the alpha-helical structure seen for residues 104-111 in crystals at high pH, and may be important in the molten globule state for bringing the peptide chain into a compact conformation where favourable interactions between the side chains can occur.

Structure and dynamics of a denatured 131-residue fragment of staphylococcal nuclease: a heteronuclear NMR study

A partially folded form of staphylococcal nuclease has been obtained by deleting residues 4-12 and 141-149 of the 149-residue wild-type protein. Sequence-specific NMR resonance assignments have been obtained for 106 of the 131 residues in this protein fragment by using multi-dimensional triple resonance NMR of samples enriched with 13C and 15N. Residues corresponding to helix 2 (residues 98-106) and helix 1 (residues 54-68) of the native state give chemical shifts and NOE effects characteristic of helical structure. These same residues, however, give coupling constants and NOE effects indicative of fast conformational averaging between helical and extended conformations. The residual helix structure observed in the nuclease fragment is thus considerably less persistent than the corresponding structure in the native state. Based on H alpha chemical shifts, we estimate the fractional population of helical conformers to be 30% for helix 2 and 10% for helix 1. Two segments, 83-86 and 94-97, show NOE effects, coupling constants, and lowered amide temperature coefficients consistent with a native-like reverse-turn structure. The C-terminal alpha-helix as well as the fourth and fifth strands of the 5-strand beta-barrel show little evidence for ordered structure. The first three strands of the beta-sheet, part of the catalytic loop, and the first turn of helix 3 give significantly poorer NMR data than the rest of the protein, possibly as a result of exchange broadening, and could not be characterized in detail. That the most persistent elements of structure in the fragment are native-like suggests that nuclease may fold by a hierarchical mechanism.

Characterization of a trifluoroethanol-induced partially folded state of alpha-lactalbumin

The protein alpha-lactalbumin exists in a partially folded molten globule state at pH 2.0, the A state. This state is believed to be compact, possessing a similar amount of secondary structure to the native state but having a flexible tertiary structure comprised mainly of non-specific hydrophobic clustering of residues. Addition of trifluoroethanol (TFE) to bovine, human and guinea pig alpha-lactalbumin at pH 2.0 has been found in each case to induce a conformational transition in the A state as monitored by circular dichroism, nuclear magnetic resonance chemical shifts, and 1-anilinonaphthalene-8-sulphonate binding. The mid-point of this transition is near 15% (v/v) TFE and is effectively complete by 50% (v/v) TFE at 315 K. Far ultraviolet circular dichroism ellipticities at 208 nm and 220 nm, usually taken as a measure of the degree of helical character, are substantially more negative in the TFE state than in the A state. Furthermore, backbone amide protons protected from solvent exchange in the A state are generally at least as strongly protected in the TFE state; patterns of protection appear similar in the two states and include at least part of both the B and C alpha-helices. One major difference from the A state is nevertheless evident: the ability to bind the fluorescent probe 1-anilinonaphthalene-8-sulphonate, characteristic of molten globule states, is lost in the TFE state. Like the A state, the TFE state of alpha-lactalbumin shows little chemical shift dispersion of side-chain resonances. Extensive line broadening in the nuclear magnetic resonance spectra, characteristic of slow conformational averaging in the A state, is, however, much reduced in the TFE state. The line narrowing observed in the TFE state has made it possible to obtain directly sequence-specific assignments for about 25% of the 123 residues of bovine alpha-lactalbumin in 50% (v/v) TFE. Two helices are amongst regions of structure so far identified from short-range backbone nuclear Overhauser enhancement (NOE) connectivities in two-dimensional spectra of the TFE state. One of the helices (residues 86 to 96) corresponds to the C-helix in the native structure. The other (residues 35 to 41) corresponds, however, to a region of the sequence that is not helical in the native state. The partially folded state of alpha-lactalbumin formed in TFE, therefore, supports both native and non-native secondary structure in the absence of persistent long-range tertiary structure.

Structure and dynamics of the acid-denatured molten globule state of alpha-lactalbumin: a two-dimensional NMR study

Two-dimensional 1H-NMR spectroscopy has been used to study the acid-denatured molten globule (A-state) of alpha-lactalbumin. The NMR spectra show that chemical shift dispersion is limited but significantly greater than that expected for a random coil conformation. The small chemical shift dispersion of side-chain resonances in the A-state together with line broadening associated with conformational averaging indicates that most of the long-range tertiary structure in the A-state is likely to be nonspecific. Side-chain resonances in the A-state are generally shifted somewhat upfield of random coil values; this and the observation of a large number of interresidue NOEs, however, indicate that some side-chain interactions, at least at the level of hydrophobic clustering, exist in the A-state. Analysis of NOESY spectra shows no evidence for an ordered structure for either of the two major clusters of aromatic residues which in the native structure make up part of the hydrophobic core of the helical domain of the native protein. A new aromatic cluster in the A-state which results from rearrangement of the side chains of Tyr103, Trp104, and His107 from their native state positions was, however, detected by a number of well-defined interresidue NOE effects. Similar NOE patterns are observed in a peptide corresponding to residues 101-110 of alpha-lactalbumin in trifluoroethanol, suggesting that the non-native structure in the 101-110 region of the A-state is not dependent on specific interactions with the rest of the chain. Trapping experiments indicate that amide protons from regions of the sequence which in the native state are helical are among those strongly protected from solvent exchange in the A-state; those from one of the helices (the C helix) were specifically identified. Taken together, these results reinforce a model of the A-state which has stable regions of localized secondary structure but a largely disordered tertiary structure.

1H-NMR assignments and local environments of aromatic residues in bovine, human and guinea pig variants of alpha-lactalbumin

1H-NMR assignments have been defined for the aromatic-ring protons of the bovine, guinea pig and human variants of alpha-lactalbumin. Spin-system networks were identified by means of double-quantum-filtered two-dimensional J-correlated spectroscopy and two-dimensional relayed coherence spectroscopy data. Analysis of two-dimensional nuclear-Overhauser-enhancement spectroscopy data of the proteins indicated that in each case two clusters of aromatic residues exist. The two clusters are also evident in the crystal structure of the human protein, and this evidence, in conjunction with sequence differences between the three proteins, permitted sequence-specific assignments to be made for the majority of aromatic residues. Remaining ambiguities in the assignments could be resolved by analysis of photochemically induced dynamic nuclear polarization (PCIDNP) effects. Comparison of the PCIDNP spectra of the three proteins indicated the presence of only minor differences in the surface exposure of conserved aromatic residues. Taken together, these results indicate that the environments of the conserved aromatic residues in bovine, guinea pig and human alpha-lactalbumin in solution are very similar to each other, and that the solution and the crystal forms of at least the human protein are similar.

Coupling between local structure and global stability of a protein: mutants of staphylococcal nuclease

Staphylococcal nuclease exists in solution as a mixture of two folded (N and N') and two unfolded (U and U*) forms. Earlier workers [Evans et al. (1989) Biochemistry 28, 362] have proposed that the N'/N and U/U* structural differences involve cis/trans isomerization about the Lys116-Pro117 peptide bond with N and U cis and N' and U* trans. The present results show that residue changes throughout the nuclease structure have large effects on the distribution of the N and N'forms. The N'/N ratios at 313 K for nuclease H124L (N'/N = 0.07) and nuclease G79S (N'/N = 12) differ by 2 orders of magnitude. Thermodynamic parameters for equilibria linking the two folded and two unfolded substates were evaluated for seven mutants of nuclease which were found by kinetic assays to have similar enzymatic activities but by NMR spectroscopy to have a wide dispersion of thermal stabilities. Our results indicate that mutational perturbations of the N'/N equilibrium in folded nuclease (delta G for the N in equilibrium N' reaction) are strongly coupled to changes in the stability of the N form (delta G for the N in equilibrium U reaction), but much less so to the stability of the N' form (delta G for the N' in equilibrium U* reaction).

Hydrogen-1 NMR evidence for three interconverting forms of staphylococcal nuclease: effects of mutations and solution conditions on their distribution

It has been known for several years that 1H NMR spectra of the enzyme staphylococcal nuclease contain resonances due to conformational heterogeneity [Markley, J. L., Williams, M. N., & Jardetzky, O. (1970) Proc. Natl. Acad. Sci. U.S.A. 65, 645-651]. One source of conformational heterogeneity has been attributed recently to cis/trans isomeriation of the Lys116-Pro117 peptide bond [Evans, P. A., Dobson, C. M., Kautz, R. A., Hatfull, G., & Fox, R. O. (1987) Nature (London) 329, 266-268]. In this paper we present evidence for three interconverting folded forms of nuclease. Forms N and N' are monomeric; form N" appears at higher nuclease concentrations and probably corresponds to dimerized enzyme. Saturation transfer was used to demonstrate that exchange occurs between the denatured state and N". The effects of temperature, pH, and Ca2+ and nucleotide binding on NMR spectra of nuclease were examined. When the temperature is increased or the pH is lowered, form N' is favored relative to N. Binding of a competitive inhibitor (thymidine 3',5'-bisphosphate plus calcium ion) strongly favors one form of nuclease. 1H NMR spectra of wild-type nuclease, the single-mutant nucleases L89F and H124L, and the double-mutant nuclease F76V+H124L were compared. In the unligated proteins, the equilibrium constant for the conformational equilibrium N in equilibrium with N' is approximately 0.1 in wild-type nuclease and nuclease H124L; by contrast, this equilibrium constant is about 0.7 in nuclease L89F and 1.2 in nuclease F76V+H124L under similar conditions.

NMR assignments of the four histidines of staphylococcal nuclease in native and denatured states

NMR signals from all four histidine ring C epsilon protons and three of the four histidine C delta protons in the protein staphylococcal nuclease have been assigned by comparing spectra of the wild-type (Foggi strain) protein to spectra of three variants that each lack a different histidine residue. All proteins studied were cloned and overproduced in Escherichia coli. The NMR spectra of the three mutant proteins (H8R, H46Y, and H124L) used to make these assignments were similar to one another and to those of the wild type, except for signals from the mutated residues. The pKa values of those histidines conserved between the wild type and the mutants remained essentially unchanged. Multiple histidine C epsilon proton resonances due to non-native forms of nuclease were observed in both thermally induced and acid-induced unfolding. Residue-specific assignments of H epsilon protons in the thermally denatured forms of the mutant H46Y were obtained from connectivities to the native state by saturation transfer.