Aromatic and methyl NOEs highlight hydrophobic clustering in the unfolded state of an SH3 domain

The N-terminal SH3 domain of Drosophila drk (drkN SH3 domain) exists in equilibrium between a folded (F(exch)) state and a relatively compact unfolded (U(exch)) state under nondenaturing conditions. Selectively labeled samples of the domain have been analyzed by NOESY NMR experiments to probe residual hydrophobic clustering in the U(exch) state. The labeling strategy included selective protonation of aromatic rings or delta-methyl groups on Ile and Leu residues in a highly deuterated background. Combined with long mixing times, the methods permitted observation of significant numbers of long-range interactions between hydrophobic side chains, providing evidence for multiple conformers involving non-native hydrophobic clusters around the Trp 36 indole. Comparison of these data with previously reported HN-HN NOEs yields structural insight into the diversity of structures within the U(exch) ensemble in the drkN SH3 domain. Many of the HN-HN NOEs are consistent with models containing compact residual nativelike secondary structure and greater exposure of the Trp 36 indole to solvent, similar to kinetic intermediates formed in the hierarchic condensation model of folding. However, the methyl and aromatic NOE data better fit conformations with non-native burial of the Trp indole surrounded by hydrophobic groups and more loosely formed beta-structure; these structural characteristics are more consistent with those of kinetic intermediates formed during the hydrophobic collapse mechanism of folding. This suite of NOE data provides a more complete picture of the structures that span the U(exch) state ensemble, from conformers with non-native structure but long-range contacts to those that are highly nativelike. Together, the results are also consistent with the folding funnel view involving multiple folding pathways for this molecule.     

NOE data demonstrating a compact unfolded state for an SH3 domain under non-denaturing conditions.

The N-terminal SH3 domain of drk (drkN SH3) is unstable, existing in equilibrium between a folded state (Fexch) and an unfolded state (Uexch) under non-denaturing buffer conditions. Using a15N/2H-labeled sample, long range amide NOEs can be observed in the Uexchstate as a result of reduced relaxation, in some cases correlating protons over 40 residues apart. These long range NOEs disappear upon addition of 2 M guanidinium chloride, demonstrating that there are substantial differences between the Uexchand the guanidine denatured states. Calculations using the long range NOEs of the Uexchstate yield highly compact structures having non-native turns and a non-native buried tryptophan residue. These structures agree with experimental stopped-flow fluorescence data and analytical ultracentrifugation results. Since protein stability depends on the structural and dynamic properties of both the folded and unfolded states, this study provides insights into the stability of the drkN SH3 domain. These results provide the first strong NOE-based evidence for compact unfolded states of proteins and suggest that some unfolded states under physiological conditions have specific interactions leading to compact structures.     

Distribution of molecular size within an unfolded state ensemble using small-angle X-ray scattering and pulse field gradient NMR techniques

The size distribution of molecules within an unfolded state of the N-terminal SH3 domain of drk (drkN SH3) has been studied by small-angle X-ray scattering (SAXS) and pulsed-field-gradient NMR (PFG-NMR) methods. An empirical model to describe this distribution in the unfolded state ensemble has been proposed based on (i) the ensemble-averaged radius of gyration and hydrodynamic radius derived from the SAXS and PFG-NMR data, respectively, and (ii) a histogram of the size distribution of structures obtained from preliminary analyses of structural parameters recorded on the unfolded state. Results show that this unfolded state, U(exch), which exists in equilibrium with the folded state, F(exch), under non-denaturing conditions, is relatively compact, with the average size of conformers within the unfolded state ensemble only 30-40% larger than the folded state structure. In addition, the model predicts a significant overlap in the size range of structures comprising the U(exch) state with those in a denatured state obtained by addition of 2 M guanidinium chloride.     

Dramatic stabilization of an SH3 domain by a single substitution: roles of the folded and unfolded states

The N-terminal SH3 domain of the Drosophila drk protein (drkN SH3) exists in equilibrium between folded and unfolded states under non-denaturing buffer conditions. In order to examine the origins of this instability, we have made mutations in the domain and characterized the thermodynamics and kinetics of folding. Results of substitutions of negatively charged residues to neutral amino acid residues suggest that the large electrostatic potential of the domain does not play a dominant role in the instability of the domain. Sequence alignment of a large number of SH3 domains reveals that the drkN SH3 domain has a threonine (T22) at a position corresponding to an otherwise highly conserved glycine residue in the diverging beta-turn connecting the beta3 and beta4 strands. Mutation of T22 to glycine results in significant stabilization of the drkN SH3 domain by 2.5 kcal/mole. To further characterize the basis for the stabilization of the T22 mutant relative to wild-type, we made additional mutant proteins with substitutions of residue T22. A strong correlation is seen between protein stability or folding rate and propensity for native beta-turn structure at this position. Correlation of folding rates with AGADIR predictions of non-native helical structure in the diverging turn region, along with our previous NMR evidence for non-native structure in this region of the unfolded state of the drkN SH3 domain, suggests that the free energy of the unfolded state also plays a role in stability. This result highlights the importance of both folded and unfolded states for understanding protein stability.     

Structural comparison of the unstable drkN SH3 domain and a stable mutant

The N-terminal SH3 domain of the Drosophila adapter protein Drk (drkN SH3 domain) is marginally stable (DeltaG(U) = 1 kcal/mol) and exists in equilibrium between folded and highly populated unfolded states. The single substitution T22G, however, completely stabilizes the protein (DeltaG(U) = 4.0 kcal/mol). To probe the causes of instability of the wild-type (WT) protein and the dramatic stabilization of the mutant, we determined and compared nuclear magnetic resonance structures of the folded WT and mutant drkN SH3 domains. Residual dipolar coupling (RDC) and carbonyl chemical-shift anisotropy (C'-CSA) restraints measured for the WT and T22G domains were used for calculating the structures. The structures for the WT and mutant are highly similar. Thr22 of the WT and Gly22 of the mutant are at the i + 2 position of the diverging, type-II beta-turn. Interestingly, not only Gly22 but also Thr22 successfully adopt an alpha(L) conformation, required at this position of the turn, despite the fact that positive phi values are energetically unfavorable and normally disallowed for threonine residues. Forcing the Thr22 residue into this unnatural conformation increases the free energy of the folded state of the WT domain relative to its T22G mutant. Evidence for residual helix formation in the diverging turn region has been previously reported for the unfolded state of the WT drkN SH3 domain, and this, in addition to other residual structure, has been proposed to play a role in decreasing the free energy of the unfolded state of the protein. Together these data provide evidence that both increasing the free energy of the folded state and decreasing the free energy of the unfolded state of the protein contribute to instability of the WT drkN SH3 domain.     

Characterization of the hydrodynamic properties of the folding transition state of an SH3 domain by magnetization transfer NMR spectroscopy

Protein folding kinetic data have been obtained for the marginally stable N-terminal Src homology 3 domain of the Drosophila protein drk (drkN SH3) in an investigation of the hydrodynamic properties of its folding transition state. Due to the presence of NMR resonances of both folded and unfolded states at equilibrium, kinetic data can be derived from NMR magnetization transfer techniques under equilibrium conditions. Kinetic analysis as a function of urea (less than approximately 1 M) and glycerol enables determination of alpha values, measures of the energetic sensitivity of the transition state to the perturbation relative to the end states of the protein folding reaction (the folded and unfolded states). Both end states have previously been studied experimentally by NMR spectroscopic and other biophysical methods in great detail and under nondenaturing conditions. Combining these results with the kinetic folding data obtained here, we can characterize the folding transition state without requiring empirical models for the unfolded state structure. We are thus able to give a reliable measure of the solvent-accessible surface area of the transition state of the drkN SH3 domain (4730 +/- 360 A(2)) based on urea titration data. Glycerol titration data give similar results and additionally demonstrate that folding of this SH3 domain is dependent on solvent viscosity, which is indicative of at least partial hydration of the transition state. Because SH3 domains appear to fold by a common folding mechanism, the data presented here provide valuable insight into the transition states of the drkN and other SH3 domains.     

Tryptophan solvent exposure in folded and unfolded states of an SH3 domain by 19F and 1H NMR

The isolated N-terminal SH3 domain of the Drosophila signal transduction protein Drk (drkN SH3) is a useful model for the study of residual structure and fluctuating structure in disordered proteins since it exists in slow exchange between a folded (Fexch) and compact unfolded (Uexch) state in roughly equal proportions under nondenaturing conditions. The single tryptophan residue, Trp36, is believed to play a key role in forming a non-native hydrophobic cluster in the Uexch state, with a number of long-range nuclear Overhauser contacts (NOEs) observed primarily to the indole proton. Substitution of Trp36 for 5-fluoro-Trp36 resulted in a substantial shift in the equilibrium to favor the Fexch state. A variety of 19F NMR measurements were performed to investigate the degree of solvent exposure and hydrophobicity associated with the 5-fluoro position in both the Fexch and Uexch states. Ambient T1 measurements and H2O/D2O solvent isotope effects indicated extensive protein contacts to the 5-fluoro position in the Fexch state and greater solvent exposure in the Uexch state. This was corroborated by the measurements of paramagnetic effects (chemical shift perturbations and T1 relaxation enhancement) from dissolved oxygen at a partial pressure of 20 atm. In contrast, paramagnetic effects from dissolved oxygen revealed less solvent exposure to the indole proton of Trp36 in the Uexch state than that observed for the Fexch state, consistent with the model in which Trp36 indole belongs to a non-native cluster. Thus, although the Uexch state may be described as a dynamically interconverting ensemble of conformers, there appears to be significant asymmetry in the environment of the indole group and the six-membered ring or backbone of Trp36. This implied lack of averaging of a side chain position is in contrast to the general view of fluctuating side chains within disordered states.     

Improved structural characterizations of the drkN SH3 domain unfolded state suggest a compact ensemble with native-like and non-native structure

Due to their dynamic ensemble nature and a deficiency of experimental restraints, disordered states of proteins are difficult to characterize structurally. Here, we have expanded upon our previous work on the unfolded state of the Drosophila drk N-terminal (drkN) SH3 domain with our program ENSEMBLE, which assigns population weights to pregenerated conformers in order to calculate ensembles of structures whose properties are collectively consistent with experimental measurements. The experimental restraint set has been enlarged with newly measured paramagnetic relaxation enhancements from Cu(2+) bound to an amino terminal Cu(2+)-Ni(2+) binding (ATCUN) motif as well as nuclear Overhauser effect (NOE) and hydrogen exchange data from recent studies. In addition, two new pseudo-energy minimization algorithms have been implemented that have dramatically improved the speed of ENSEMBLE population weight assignment. Finally, we have greatly improved our conformational sampling by utilizing a variety of techniques to generate both random structures and structures that are biased to contain elements of native-like or non-native structure. Although it is not possible to uniquely define a representative structural ensemble, we have been able to assess various properties of the drkN SH3 domain unfolded state by performing ENSEMBLE minimizations of different conformer pools. Specifically, we have found that the experimental restraint set enforces a compact structural distribution that is not consistent with an overall native-like topology but shows preference for local non-native structure in the regions corresponding to the diverging turn and the beta5 strand of the folded state and for local native-like structure in the region corresponding to the beta6 and beta7 strands. We suggest that this approach could be generally useful for the structural characterization of disordered states.     

15NH/D-SOLEXSY experiment for accurate measurement of amide solvent exchange rates: application to denatured drkN SH3

Amide solvent exchange rates are regarded as a valuable source of information on structure/dynamics of unfolded (disordered) proteins. Proton-based saturation transfer experiments, normally used to measure solvent exchange, are known to meet some serious difficulties. The problems mainly arise from the need to (1) manipulate water magnetization and (2) discriminate between multiple magnetization transfer pathways that occur within the proton pool. Some of these issues are specific to unfolded proteins. For example, the compensation scheme used to cancel the Overhauser effect in the popular CLEANEX experiment is not designed for use with unfolded proteins. In this report we describe an alternative experimental strategy, where amide ¹⁵N is used as a probe of solvent exchange. The experiment is performed in 50% H₂O–50% D₂O solvent and is based on the (HACACO)NH pulse sequence. The resulting spectral map is fully equivalent to the conventional HSQC. To fulfill its purpose, the experiment monitors the conversion of deuterated species, ¹⁵N^D, into protonated species, ¹⁵N^H, as effected by the solvent exchange. Conceptually, this experiment is similar to EXSY which prompted the name of ¹⁵N^H/D-SOLEXSY (SOLvent EXchange SpectroscopY). Of note, our experimental scheme, which relies on nitrogen rather than proton to monitor solvent exchange, is free of the complications described above. The developed pulse sequence was used to measure solvent exchange rates in the chemically denatured state of the drkN SH3 domain. The results were found to correlate well with the CLEANEX-PM data, r = 0.97, thus providing a measure of validation for both techniques. When the experimentally measured exchange rates are converted into protection factors, most of the values fall in the range 0.5–2, consistent with random-coil behavior. However, elevated values, ca. 5, are obtained for residues R38 and A39, as well as the side-chain indole of W36. This is surprising, given that high protection factors imply hydrogen bonding or hydrophobic burial not expected to occur in a chemically denatured state of a protein. We, therefore, hypothesized that elevated protection factors are an artefact arising from the calculation of the reference (random-coil) exchange rates. To confirm this hypothesis, we prepared samples of several short peptides derived from the sequence of the drkN SH3 domain; these samples were used to directly measure the reference exchange rates. The revised protection factors obtained in this manner proved to be close to 1.0. These results also have implications for the more compact unfolded state of drkN SH3, which appears to be fully permeable to water as well, with no manifestations of hydrophobic burial.     

Backbone 1H and 15N resonance assignments of the N-terminal SH3 domain of drk in folded and unfolded states using enhanced-sensitivity pulsed field gradient NMR techniques

Summary The backbone ¹H and ¹⁵N resonances of the N-terminal SH3 domain of the Drosophila signaling adapter protein, drk, have been assigned. This domain is in slow exchange on the NMR timescale between folded and predominantly unfolded states. Data were collected on both states simultaneously, on samples of the SH3 in near physiological buffer exhibiting an approximately 1:1 ratio of the two states. NMR methods which exploit the chemical shift dispersion of the ¹⁵N resonances of unfolded states and pulsed field gradient water suppression approaches for avoiding saturation and dephasing of amide protons which rapidly exchange with solvent were utilized for the assignment.Abbreviations 2D, 3D two-, three-dimensional - drkN SH3 N-terminal SH3 domain of Drosophila drk - HSQC heteronuclear single-quantum spectroscopy - NOE nuclear Overhauser enhancement - SH3 Src homology domain 3 - TOCSY total correlation spectroscopy     

Equilibrium unfolding of Escherichia coli ribonuclease H: characterization of a partially folded state.

We have examined the equilibrium unfolding of Escherichia coli ribonuclease HI (RNase H), a member of a family of enzymes that cleaves RNA from RNA:DNA hybrids. A completely synthetic gene was constructed that expresses a variant of the wild-type sequence with all 3 cysteines replaced with alanine. The resulting recombinant protein is active and folds reversibly. Denaturation studies monitored by circular dichroism and tryptophan fluorescence yield coincident curves that suggest the equilibrium unfolding reaction is a 2-state process. Acid denaturation, however, reveals a cooperative transition at approximately pH 1.8 to a partially folded state. This acid state can be further denatured in a reversible manner by the addition of heat or urea as monitored by either CD or tryptophan fluorescence. Analytical ultracentrifugation studies indicate that the acid state of RNase H is both compact and monomeric. Although compact, the acid state does not resemble the native protein: the acid state displays a near-UV CD spectrum similar to the unfolded state and binds to and enhances the fluorescence of the dye 1-anilinonaphthalene, 8-sulfonate much more than either the native or unfolded states. Therefore, the acid state of E. coli RNase H has the characteristics of a molten globule: it retains a high degree of secondary structure, remains compact, yet does not appear to contain a tightly packed core.     

The effect of the polyproline II (PPII) conformation on the denatured state entropy

Polyproline II (PPII) is reported to be a dominant conformation in the unfolded state of peptides, even when no prolines are present in the sequence. Here we use isothermal titration calorimetry (ITC) to investigate the PPII bias in the unfolded state by studying the binding of the SH3 domain of SEM-5 to variants of its putative PPII peptide ligand, Sos. The experimental system is unique in that it provides direct access to the conformational entropy change of the substituted amino acids. Results indicate that the denatured ensemble can be characterized by at least two thermodynamically distinct states, the PPII conformation and an unfolded state conforming to the previously held idea of the denatured state as a random collection of conformations determined largely by hard-sphere collision. The probability of the PPII conformation in the denatured states for Ala and Gly were found to be significant, approximately 30% and approximately 10%, respectively, resulting in a dramatic reduction in the conformational entropy of folding.     

Ethanol and acetonitrile induces conformational changes in porcine pepsin at alkaline denatured state

Pepsin, a member of the aspartate protease family, exists in a partially unfolded state at alkaline pH where the N-terminal domain of pepsin has a flexible structure while the C-terminal domain has a highly folded structure. In this work, the conformational stability of porcine pepsin in an alkaline denatured (A(D)) state against acetonitrile and ethanol solvents was studied using a combination of electronic circular dichroism (ECD) and fluorescence techniques. The ECD results demonstrate that both ethanol and acetonitrile induce secondary structural changes in pepsin at A(D) state. However, the minimum concentration required to induce significant secondary structural changes in pepsin varies for ethanol (>30%, v/v) and acetonitrile (>60%, v/v) solvents. At maximum concentration used (90%, v/v), both solvents induce predominantly β-sheet conformation. Unlike acetonitrile, ethanol induces significant amount of non-native α-helical conformations at the intermediate concentrations (50-80%). The tryptophan fluorescence results demonstrate that both acetonitrile and ethanol induce substantial changes in the tertiary structure of pepsin in the A(D) state above certain concentrations. The current results have important implications in understanding the effect of co-solvents on the conformation of proteins in the "denatured state".     

Probing folding and fluorescence quenching in human gammaD crystallin Greek key domains using triple tryptophan mutant proteins

Human gammaD crystallin (HgammaD-Crys), a major component of the human eye lens, is a 173-residue, primarily beta-sheet protein, associated with juvenile and mature-onset cataracts. HgammaD-Crys has four tryptophans, with two in each of the homologous Greek key domains, which are conserved throughout the gamma-crystallin family. HgammaD-Crys exhibits native-state fluorescence quenching, despite the absence of ligands or cofactors. The tryptophan absorption and fluorescence quenching may influence the lens response to ultraviolet light or the protection of the retina from ambient ultraviolet damage. To provide fluorescence reporters for each quadrant of the protein, triple mutants, each containing three tryptophan-to-phenylalanine substitutions and one native tryptophan, have been constructed and expressed. Trp 42-only and Trp 130-only exhibited fluorescence quenching between the native and denatured states typical of globular proteins, whereas Trp 68-only and Trp 156-only retained the anomalous quenching pattern of wild-type HgammaD-Crys. The three-dimensional structure of HgammaD-Crys shows Tyr/Tyr/His aromatic cages surrounding Trp 68 and Trp 156 that may be the source of the native-state quenching. During equilibrium refolding/unfolding at 37 degrees C, the tryptophan fluorescence signals indicated that domain I (W42-only and W68-only) unfolded at lower concentrations of GdnHCl than domain II (W130-only and W156-only). Kinetic analysis of both the unfolding and refolding of the triple-mutant tryptophan proteins identified an intermediate along the HgammaD-Crys folding pathway with domain I unfolded and domain II intact. This species is a candidate for the partially folded intermediate in the in vitro aggregation pathway of HgammaD-Crys.     

Electrostatic screening and backbone preferences of amino acid residues in urea-denatured ubiquitin

Local structures in denatured proteins may be important in guiding a polypeptide chain during the folding and misfolding processes. Existence of local structures in chemically denatured proteins is a highly controversial issue. NMR parameters [coupling constants (3) J(H(alpha),H(N)) and chemical shifts] of chemically denatured proteins in general deviate little from their values in small peptides. These peptides were presumed to be completely unstructured; therefore, it was considered that chemically denatured proteins are random coils. But recent experimental studies show that small peptides adopt relatively stable structures in aqueous solutions. Small deviations of the NMR parameters from their values in small peptides may thus actually indicate the existence of local structures in chemically denatured proteins. Using NMR data and theoretical predictions we show here that fluctuating beta-strands exist in urea-denatured ubiquitin (8 M urea at pH 2). Residues in such beta-strands populate more frequently the left side of the broad beta region of -psi space. Urea-denatured ubiquitin contains no detectable beta-sheet secondary structures; nevertheless, the fluctuating beta-strands in urea-denatured ubiquitin coincide to the beta-strands in the native state. Formation of beta-strands is in accord with the electrostatic screening model of unfolded proteins. The free energy of a residue in an unfolded protein is in this model determined by the local backbone electrostatics and its screening by backbone solvation. These energy terms introduce strong electrostatic coupling between neighboring residues, which causes cooperative formation of beta-strands in denatured proteins. We propose that fluctuating beta-strands in denatured proteins may serve as initiation sites to form fibrils.     

Denatured states of ribonuclease A have compact dimensions and residual secondary structure.

Using small-angle X-ray scattering and Fourier transform infrared spectroscopy, we have determined that the thermally denatured state of native ribonuclease A is on average a compact structure having residual secondary structure. Under strongly reducing conditions, the protein further unfolds into a looser structure with larger dimensions but still retains a comparable amount of secondary structure. The dimensions of the thermally and chemically denatured states of the reduced protein are different but both are more compact than is predicted for a random coil of the same length. These results demonstrate that thermal denaturation in ribonuclease A is not a simple two-state transition from a native to a completely disordered random coil state.     

Protein aggregation and amyloid fibril formation by an SH3 domain probed by limited proteolysis

The SH3 domains are small protein modules of 60-85 amino acid residues that are found in many proteins involved in intracellular signal transduction. The SH3 domain of the p85alpha subunit of bovine phosphatidylinositol 3'-kinase (PI3-SH3) under acidic solution adopts a compact denatured state from which amyloid fibrils are readily formed. This aggregation process has been found to be modulated substantially by solution conditions. Here, we have analyzed the conformational features of the native and acid denatured states of PI3-SH3 by limited proteolysis experiments using proteinase K and pepsin, respectively. Moreover, we have analyzed the propensity of PI3-SH3 to be hydrolyzed by pepsin at different stages in the process of aggregation and amyloid formation at pH 1.2 and 2.0 and compared the sites of proteolysis under these conditions with the conformational features of both native and aggregated PI3-SH3. The results demonstrate that the denatured state of PI3-SH3 formed at low pH is relatively resistant to proteolysis, indicating that it is partially folded. The long loop connecting beta-strands b and c in the native protein is the region in this structure most susceptible to proteolysis. Remarkably, aggregates of PI3-SH3 that are formed initially from this denatured state in acid solution display enhanced susceptibility to proteolysis of the long loop, suggesting that the protein becomes more unfolded in the early stages of aggregation. By contrast, the more defined amyloid fibrils that are formed over longer periods of time are completely resistant to proteolysis. We suggest that the protein aggregates formed initially are relatively dynamic species that are able readily to reorganize their interactions to enable formation of very well ordered fibrillar structures. In addition, the disordered and non-native character of the polypeptide chains in the early aggregates could be important in determining the high cytotoxicity that has been revealed in previous studies of these species.     

Paramagnetic relaxation enhancements in unfolded proteins: Theory and application to drkN SH3 domain

Site‐directed spin labeling in combination with paramagnetic relaxation enhancement (PRE) measurements is one of the most promising techniques for studying unfolded proteins. Since the pioneering work of Gillespie and Shortle (J Mol Biol 1997;268:158), PRE data from unfolded proteins have been interpreted using the theory that was originally developed for rotational spin relaxation. At the same time, it can be readily recognized that the relative motion of the paramagnetic tag attached to the peptide chain and the reporter spin such as ¹H^N is best described as a translation. With this notion in mind, we developed a number of models for the PRE effect in unfolded proteins: (i) mutual diffusion of the two tethered spheres, (ii) mutual diffusion of the two tethered spheres subject to a harmonic potential, (iii) mutual diffusion of the two tethered spheres subject to a simulated mean‐force potential (Smoluchowski equation); (iv) explicit‐atom molecular dynamics simulation. The new models were used to predict the dependences of the PRE rates on the ¹H^N residue number and static magnetic field strength; the results are appreciably different from the Gillespie–Shortle model. At the same time, the Gillespie–Shortle approach is expected to be generally adequate if the goal is to reconstruct the distance distributions between ¹H^N spins and the paramagnetic center (provided that the characteristic correlation time is known with a reasonable accuracy). The theory has been tested by measuring the PRE rates in three spin‐labeled mutants of the drkN SH3 domain in 2M guanidinium chloride. Two modifications introduced into the measurement scheme—using a reference compound to calibrate the signals from the two samples (oxidized and reduced) and using peak volumes instead of intensities to determine the PRE rates—lead to a substantial improvement in the quality of data. The PRE data from the denatured drkN SH3 are mostly consistent with the model of moderately expanded random‐coil protein, although part of the data point toward a more compact structure (local hydrophobic cluster). At the same time, the radius of gyration reported by Choy et al. (J Mol Biol 2002;316:101) suggests that the protein is highly expanded. This seemingly contradictory evidence can be reconciled if one assumes that denatured drkN SH3 forms a conformational ensemble that is dominated by extended conformations, yet also contains compact (collapsed) species. Such behavior is apparently more complex than predicted by the model of a random‐coil protein in good solvent/poor solvent.