Searching for folding initiation sites of staphylococcal nuclease: A study of N-terminal short fragments

Impact of Turn Propensity on the Folding Rates of Z34C Protein: Implications for the Folding of Helix-Turn-Helix Motif

The rate-limiting step for the folding of the helix-turn-helix (HTH) protein, Z34C, involves β-turn region ²⁰DPNL²³. This reverse turn has been observed to be part of the transition state in the folding process for Z34C, influencing its folding rates. Molecular dynamics simulations were performed on this turn peptide and its two mutants, D20A and P21A, to study turn formation using GROMOS54A7 force field. We find that this region has a turn propensity of its own, and the highest turn propensity is observed for the wild-type, which correlates well with available experimental results. We also find that a slight unfavorable change in ΔG _{turn folding} causes a drastic change in the folding rates of HTH motif and a mechanistic interpretation is given. Implications of these observations for the folding of the HTH protein Z34C are discussed.

A shorter peptide model from staphylococcal nuclease for the folding-unfolding equilibrium of a beta-hairpin shows that unfolded state has significant contribution from compact conformational states

It is important to understand the conformational features of the unfolded state in equilibrium with folded state under physiological conditions. In this paper, we consider a short peptide model LMYKGQPM from staphylococcal nuclease to model the conformational equilibrium between a hairpin conformation and its unfolded state using molecular dynamics simulation under NVT conditions at 300K using GROMOS96 force field. The free energy landscape has overall funnel-like shape with hairpin conformations sampling the minima. The "unfolded" state has a higher free energy of approximately 12kJ/mol with respect to native hairpin minimum and occupies a plateau region. We find that the unfolded state has significant contributions from compact conformations. Many of these conformations have hairpin-like topology. Further, these compact conformational forms are stabilized by hydrophobic interactions. Conversion between native and non-native hairpins occurs via unfolded states. Frequent conversions between folded and unfolded hairpins are observed with single exponential kinetics. We compare our results with the emerging picture of unfolded state from both experimental and theoretical studies.

Folding stability and cooperativity of the three forms of 1-110 residues fragment of staphylococcal nuclease

Folding stability and cooperativity of the three forms of 1-110 residues fragment of staphylococcal nuclease (SNase110) have been studied by various biophysical and NMR methods. Samples of G-88W- and V-66W-mutant SNase110, namely G-88W110 and V-66W110, in aqueous solution and SNase110 in 2.0 M TMAO are adopted in this study. The unfolding transitions and folded conformations of the three SNase fragments were detected by far- and near-ultraviolet circular dichroism and intrinsic tryptophan fluorescence measurements. The tertiary structures and internal motions of the fragments were determined by NMR spectroscopy. Both G-88W and V-66W single mutations as well as a small organic osmolyte (Trimethylamine N-oxide, TMAO) can fold the fragment into a native-like conformation. However, the tertiary structures of the three fragments exhibit different degrees of folding stability and compactness. G-88W110 adopts a relatively rigid structure representing a most stable native-like beta-subdomain conformation of the three fragments. V-66W110- and TMAO-stabilized SNase110 produce less compact structures having a less stable "beta-barrel" structural region. The different folding status accounts for the different backbone dynamic and urea-unfolding transition features of the three fragments. The G-20I/G-29I-mutant variants of the three fragments have provided the evidence that the folding status is correlated closely to the packing of the beta-strands in the beta-barrel of the fragments. The native-like beta-barrel structural region acts as a nonlocal nucleus for folding the fragment. The tertiary folding of the three fragments is initiated by formation of the local nucleation sites at two beta-turn regions, I-18-D-21 and Y-27-Q-30, and developed by the formation of a nonlocal nucleation site at the beta-barrel region. The formation of beta-barrel and overall structure is concerted, but the level of cooperativity is different for the three 1-110 residues SNase fragments.

Two peptide fragments G55-I72 and K97-A109 from staphylococcal nuclease exhibit different behaviors in conformational preferences for helix formation

Two synthetic peptides, SNasealpha1 and SNasealpha2, corresponding to residues G55-I72 and K97-A109, respectively, of staphylococcal nuclease (SNase), are adopted for detecting the role of helix alpha1 (E57-A69) and helix alpha2 (M98-Q106) in the initiation of folding of SNase. The helix-forming tendencies of the two SNase peptide fragments are investigated using circular dichroism (CD) and two-dimensional (2D) nuclear magnetic resonance (NMR) methods in water and 40% trifluoroethanol (TFE) solutions. The coil-helix conformational transitions of the two peptides in the TFE-H2O mixture are different from each other. SNasealpha1 adopts a low population of localized helical conformation in water, and shows a gradual transition to helical conformation with increasing concentrations of TFE. SNasealpha2 is essentially unstructured in water, but undergoes a cooperative transition to a predominantly helical conformation at high TFE concentrations. Using the NMR data obtained in the presence of 40% TFE, an ensemble of alpha-helical structures has been calculated for both peptides in the absence of tertiary interactions. Analysis of all the experimental data available indicates that formation of ordered alpha-helical structures in the segments E57-A69 and M98-Q106 of SNase may require nonlocal interactions through transient contact with hydrophobic residues in other parts of the protein to stabilize the helical conformations in the folding. The folding of helix alpha1 is supposed to be effective in initiating protein folding. The formation of helix alpha2 depends strongly on the hydrophobic environment created in the protein folding, and is more important in the stabilization of the tertiary conformation of SNase.

Probing the folding capacity and residual structures in 1-79 residues fragment of staphylococcal nuclease by biophysical and NMR methods

1-79 residues SNase fragment (SNase79) has chain length containing a sequence for helix alpha(1), omega-loop, beta(I)-sheet, and partial beta(II)-sheet of native SNase. The incomplete "beta-barrel" structural region of SNase79 makes this fragment to be interested in investigation of its conformation. For this study, we use CD, fluorescence, and NMR spectroscopy to probe the folding capacity and the residual structures in SNase79. The optical spectra obtained for SNase79 and its mutants reveal the presence of retained capacity for folding of the fragment. The NMR derived (13)C(alpha) secondary chemical shifts, (3)J(NH-Halpha) coupling constants, amide-proton temperature coefficients, interresidue NOEs, and (15)N relaxation data determine the intrinsic propensities for helix- and turn- or beta-sheet-like conformations of SNase79, which is not the result of stabilizing inter-molecular interactions by oligomerization effects. The residual turn- and helix-like structures may serve as potential local nucleation sites, whereas the residual beta(I)-sheet-like structure can be regarded as a potential non-local nucleation site in the folding of SNase79. The intrinsic local and non-local interactions in these potential initiation sites are insufficient to stabilize the folding of SNase79 due to the shortage of relevant long-range interactions from other part of the fragment. The conformational ensemble of SNase79 is a highly heterogeneous collection of interconverting conformations having transiently populated helix- and beta-sheet- or turn-like structures.

Effect of N-terminal deletions on the foldability, stability, and activity of staphylococcal nuclease

The effect of N-terminally successive deletions on the foldability, stability, and activity of staphylococcal nuclease was examined. The structural changes in the nuclease caused by the deletions follow a hierarchical pattern: N-terminal truncation of the nuclease by up to nine residues clearly perturbs the conformation of the N-terminal beta-subdomain but does not affect the C-terminal alpha-subdomain; deletion of 11 or 12 residues perturbs the C-terminal alpha-subdomain, resulting in formation of a molten globule state; deletion of 13 residues causes the nuclease to become highly unfolded. N-terminally deleted nuclease delta11 retains the ability to fold but delta12 is not able to fold into an enzymatically active conformation, suggesting that 11 residues is the maximum length that can be deleted from the N-terminus while still retaining the folding competence of the nuclease. Further, the results suggest that proper folding of the C-terminal alpha-subdomain probably relies on the integrity of the N-terminal beta-subdomain.

Local stability identification and the role of a key aromatic amino acid residue in staphylococcal nuclease refolding

Staphylococcal nuclease (SNase) is a model protein that contains one domain and no disulfide bonds. Its stability in the native state may be maintained mainly by key amino acids. In this study, two point-mutated proteins each with a single base substitution [alanine for tryptophan (W140A) and alanine for lysine (K133A)] and two truncated fragment proteins (positions 1-139 [SNase(1-139) or W140O] and positions 1-141 [SNase(1-141) or E142O]) were generated. Differential scanning microcalorimetry in thermal denaturation experiments showed that K133A and E142O have nearly unchanged DeltaH(cal) relative to the wild-type, whereas W140A and W140O display zero enthalpy change (DeltaH(cal) approximately 0). Far-UV CD measurements indicate secondary structure in W140A but not W140O, and near-UV CD measurements indicate no tertiary structure in either W140 mutant. These observations indicate an unusually large contribution of W140 to the stability and structural integrity of SNase.

Cis/trans heterogeneity of Gln30-Pro31 peptide bond determines whether a 79-residue fragment of staphylococcal nuclease self-associates

The self-association reaction of a 79-residue fragment of staphylococcal nuclease (SNase79) was studied by far-UV CD, size-exclusion chromatography, and heteronuclear multidimensional NMR spectroscopy. A large population of SNase79 is in self-associated state while a small population of SNase79 is essentially in a monomeric state. The sequence region Thr13-Val39 is responsible for association interface of SNase79. The trans-conformation of X-prolyl bond Gln30-Pro31 may make residues Tyr27-Gln30, serve as a folding nucleation site, and lead the segment Thr13-Val39 of SNase79 to adopt a native-like beta-sheet conformation, which results in the self-association of SNase79. The non-native conformation of the segment Thr13-Val39 of SNase79 associated with the cis-conformation of X-prolyl bond Gln30-Pro31 may preclude SNase79 from the soluble aggregates.

The effects of amino acid replacements of glycine 20 on conformational stability and catalysis of staphylococcal nuclease

Staphylococcal nuclease (SNase) is a well-established model for protein folding studies. Its three-dimensional structure has been determined. The enzyme, Ca2+, and DNA or RNA substrate form a ternary complex. Glycine 20 is the second position of the first beta-turn of SNase, which may serve as the folding initiation site for the SNase polypeptide. To study the role of Gly20 in the conformational stability and catalysis of SNase, three mutants, in which Gly20 was replaced by alanine, valine, or isoleucine, were constructed and studied by using circular dichroism spectra, intrinsic and ANS-binding fluorescence spectra, stability and activity assays. The mutations have little effect on the conformational integrity of the mutants. However, the catalytic activity is reduced drastically by the mutations, and the stability of the protein is progressively decreased in the order G20A<G20V<G20I. Kinetic analysis indicates that the mutant enzymes G20A and G20V show almost 20-fold higher KmCa values than the wild-type enzyme, and the value for G20I is more than 50-fold higher. KACa values indicate more than 17.5-fold weaker binding of Ca2+ to the G20A and G20V mutants, and more than 39-fold weaker to the G20I mutant, compared to wild-type SNase. The above results suggest that the substitutions at Gly20 cause significantly weaker binding of Ca2+ in both the binary enzyme-Ca2+ complex and the ternary complex. However, there is little difference in the values of KmDNA and KSDNA between the mutants and the wild-type enzyme, suggesting that the substitutions at Gly20 have little effect on the binding of DNA substrates to the enzyme. Consistent with the changes in KmCa and KACa, the mutant enzymes G20A, G20V and G20I show about 10(3)-, 10(4)- and 10(5)-fold lower KCat values than the wild-type enzyme, respectively. These results suggest that Gly20 plays an important role in maintaining a suitable conformation at the active site of the enzyme.