Structure and dynamics of the alpha-lactalbumin molten globule: fluorescence studies using proteins containing a single tryptophan residue.

The fluorescence properties of three variants of alpha-lactalbumin (alpha-LA) containing a single tryptophan residue were investigated under native, molten globule, and unfolded conditions. These proteins have levels of secondary structure and stability similar to those of the wild type. The fluorescence signal in the native state is dominated by that of W104, with the signal of W60 and W118 significantly quenched by the disulfide bonds in their vicinity. In the molten globule state, the magnitude of the fluorescence signal of W60 and W118 increases, due to the loss of rigid, specific side chain packing. In contrast, the magnitude of the signal of W104 decreases in the molten globule state, perhaps due to the protonation of H107 or quenching by D102 or K108. The solvent accessibilities of individual tryptophan residues were investigated by their fluorescence emission maximum and by acrylamide quenching studies. In the native state, the order of solvent accessibility is as follows: W118 > W60 > W104. This order changes to W60 > W104 > W118 in the molten globule state. Remarkably, the solvent accessibility of W118 in the alpha-LA molten globule is lower than that in the native state. The dynamic properties of the three tryptophan residues were examined by time-resolved fluorescence anisotropy decay studies. The overall rotation of the molecule can be observed in both the native and molten globule states. In the molten globule state, there is an increase in the extent of local backbone fluctuations with respect to the native state. However, the fluctuation is not sufficient to result in complete motional averaging. The three tryptophan residues in the native and molten globule states have different degrees of motional freedom, reflecting the folding pattern and dynamic heterogeneity of these states. Taken together, these studies provide new insight into the structure and dynamics of the alpha-LA molten globule, which serves as a prototype for partially folded proteins.

Local and long-range interactions in the thermal unfolding transition of bovine pancreatic ribonuclease A.

This research was undertaken to distinguish between local and global unfolding in the reversible thermal denaturation of bovine pancreatic ribonclease A (RNase A). Local unfolding was monitored by steady-state and time-resolved fluorescence of nine mutants in each of which a single tryptophan was substituted for a wild-type residue. Global unfolding was monitored by far-UV circular dichroism and UV absorbance. All the mutants (except F8W and D38W) exhibited high specific enzymatic activity, and their far-UV CD spectra were very close to that of wild-type RNase A, indicating that the tryptophan substitutions did not affect the structure of any of the mutants (excluding K1W and Y92W) under folding conditions at 20 degrees C. Like wild-type RNase A, the various mutants exhibited reversible cooperative thermal unfolding transitions at pH 5, with transition temperatures 2.5-11 degrees C lower than that of the wild-type transition, as detected by far-UV CD or UV absorbance. Even at 80 degrees C, well above the cooperative transition of all the RNase A mutants, a considerable amount of secondary and tertiary structure was maintained. These studies suggest the following two-stage mechanism for the thermal unfolding transition of RNase A as the temperature is increased. First, at temperatures lower than those of the main cooperative transition, long-range interactions within the major hydrophobic core are weakened, e.g., those involving residues Phe-8 (in the N-terminal helix) and Lys-104 and Tyr-115 (in the C-terminal beta-hairpin motif). The structure of the chain-reversal loop (residues 91-95) relaxes in the same temperature range. Second, the subsequent higher-temperature cooperative unfolding transition is associated with a loss of secondary structure and additional changes in the tertiary contacts of the major hydrophobic core, e.g., those involving residues Tyr-73, Tyr-76, and Asp-38 on the other side of the molecule. The hydrophobic interactions of the C-terminal loop of the protein are enhanced by high temperature, and perhaps are responsible for the preservation of the local structural environment of Trp-124 at temperatures slightly above the major cooperative transition. The results shed new light on the thermal unfolding transitions, generally supporting the thermal unfolding hypothesis of Burgess and Scheraga, as modified by Matheson and Scheraga.

Distributions of intramolecular distances in the reduced and denatured states of bovine pancreatic ribonuclease A. Folding initiation structures in the C-terminal portions of the reduced protein.

The purpose of this investigation is to characterize the reduced state of RNase A (r-RNase A) in terms of (i) intramolecular distances, (ii) the sequence of formation of stable loops in the initial stages of folding, and (iii) the unfolding transitions induced by GdnHCl. This is accomplished by identifying specific subdomain structures and local and long-range interactions that direct the folding process of this protein and lead to the native fold and formation of the disulfide bonds. Eleven pairs of dispersed sites in the RNase A molecule were labeled with fluorescent donor and acceptor probes, and the distributions of intramolecular distances (IDDs) were determined by means of time-resolved dynamic nonradiative excitation energy transfer (TR-FRET) measurements. The mutants were designed to search for (a) a possible nonrandom fold of the backbone in the collapsed state and (b) possible loops stabilized by long-range interactions. It was found that, under folding conditions, (i) the labeled mutants of r-RNase A in refolding buffer (the R(N) state) exhibit features of specific (nonrandom) compact but very dispersed subdomain structures (indicated by short mean distances, broad IDDs, and a weak dependence of the mean distances on segment length), (ii) the backbone fold in the C-terminal beta-like portion of the molecule appears to adopt a native-like overall fold, (iii) the N-terminal alpha-like portion of the chain is separated from the C-terminal core by very large intramolecular distances, larger than those in the crystal structure, and (iv) perturbations by addition of GdnHCl reveal several conformational transitions in different sections of the chain. Addition of GdnHCl to the native disulfide-intact protein provided a reference state for the extent of expansion of intramolecular distances under denaturing conditions. In conclusion, r-RNase A under folding conditions (the R(N) state) is poised for the final folding step(s) with a native-like trace of the chain fold but a large separation between the two subdomains which is then decreased upon introduction of three of the four native disulfide cross-links.

Design consideration and probes for fluorescence resonance energy transfer studies.

Spectroscopic properties of two newly synthesized water-soluble thiol-reactive fluorescent probes, 7-(iodoacetamido)-coumarin-4-carboxylic acid (I-Cca) and N-iodoacetyl-beta-(2-naphthyl)alanine (I-Nal), were characterized using single cysteine mutants of Escherichia coli adenylate kinase. Together with two known water-soluble thiol-reactive dyes (Lucifer yellow iodoacetamide and 5-iodoacetamidosalicylic acid) and as well, tryptophan residues (either native or inserted into a protein by site directed mutagenesis), these probes can be arranged pairwise in a molecular tool set for studies of structural transitions in proteins by means of fluorescence resonance energy-transfer (FRET) experiments. A set of seven donor/acceptor pairs which allow determination of intramolecular distances and their distributions over the range 10-40 A in labeled protein derivatives is described. The charged groups present in the probes facilitate the conjugation reaction and improve postlabeling purification. General considerations for design of charged probes and site-directed labeling for applications of FRET methods in studies of protein structure and dynamics are presented.

Towards a mechanism of AMP-substrate inhibition in adenylate kinase from Escherichia coli.

Crystallographic studies on adenylate kinase (AK) suggest that binding of ATP causes the LID domain of the enzyme to close over the ATP molecule (Schlauderer et al. (1996) J. Mol. Biol. 256, 223-227). The method of time-resolved fluorescence resonance energy transfer was applied to study the proposed structural change in AK from Escherichia coli. Two active derivatives of the (C77S, A73C, V142C)-AK mutant containing the excitation energy donor attached to one of the two cysteine residues and the acceptor attached to the other cysteine were prepared to monitor displacements of the LID domain in response to substrate binding. Binding of either ATP or AMP was accompanied by an approximately 9 A decrease in the interprobe distances suggesting LID domain closure. Closure of the LID domain in response to AMP binding may be a possible reason for the strong AMP-substrate inhibition known for E. coli AK.

Domain closure in adenylate kinase.

The method of time-resolved dynamic nonradiative excitation energy transfer (ET) was used to analyze the proposed domain closure in adenylate kinase (AK). A highly active mutant of Escherichia coli AK, (C77S, V169W, A55C)-AK, was prepared, in which the solvent- accessible residues valine 169 and alanine 55 were replaced by tryptophan (the donor of excitation energy) and cysteine, respectively. The latter was subsequently labeled with either 5- or 4-acetamidosalicylic acid (the acceptor). From the comparative analysis of AK crystal structures [Schulz, G.E., Müller, C.W., & Diederichs, K. (1990) J. Mol. Biol. 213, 627-630] (apo-AK,AK.AMP complex and AK.AP5A [P1,P5-di(adenosine-5') pentaphosphate] complex), "sequential formation" of the pseudoternary AK.AP5A complex is followed by two- step domain closure. The domain closure reduces interdomain distances in a two-step manner. Specifically, the distance between C alpha-atoms of the residues 169 and 55 (numbers correspond to those of E. coli AK) is decreased from 23.6 A in the apo-enzyme to 16.2 A upon the formation of the AK.AMP complex and to 12.3 A upon the further formation of the pseudoternary AK.AP5A complex. Time-resolved dynamic nonradiative excitation energy transfer was measured for the following ligand forms of the labeled derivative of the mutant enzyme: the apo-enzyme, the enzyme-MgATP complex, the enzyme.AMP complex, and the enzyme.AP5A "ternary" complex. The transfer efficiencies, which were determined in these experiments, were approximately 7.5%, 22%, 33%, and 65%, respectively. Global analyses of the time resolved ET experiments with the same ligand forms yielded intermolecular distance distributions with corresponding means of 31, 23, 19, and 12 A and full widths at half- maximum of 29, 24, 14, and 11 A. The data confirmed the proposed stepwise manner of the domain closure of the enzyme and revealed the presence of multiple conformations of E. coli AK in solution.

Nonlocal interactions stabilize long range loops in the initial folding intermediates of reduced bovine pancreatic trypsin inhibitor.

A search for the topology of the chain folding of reduced bovine pancreatic trypsin inhibitor (BPTI), in unfolded and partially folded states, was done by means of time resolved dynamic nonradiative excitation energy transfer (ET) measurements. Four double labeled BPTI derivatives were used in which the donor was attached to the N-terminal arginine residue and the acceptor was specifically attached to one of the lysine residues. The four derivatives form a series of labeled backbone segments of increasing length spanning the full lengths of the BPTI chain: 15, 26, 41, and 46 residues. The intramolecular segmental end-to-end distance (EED) distributions were determined for all the derivatives by global analysis of the decay curves of both the donor and the acceptor in the reduced state, in low (0.5 M) guanidinium chloride (GuHCl) concentrations at pH 3.6 and 2.1 (R and A states, respectively). The results show that, in the partial folding conditions of low GuHCl concentration, reduced BPTI is in a compact state, but in this state the polypeptide chain is not in a condensed statistical coil conformation. Two distinct subpopulations were found for the four intramolecular EED distributions. One subpopulation was compact, with native-like EED distribution, while the second was unfolded. The pairs of sites, residues 1 and 26 and residues 1 and 46, showed close proximity in the dominant subpopulation. These contacts form two loops (probably collapsed): one consists of the first 26 residues, and the second comprises the full length of the chain from the N- to the C-terminal segments, which is in fact made up to two shorter loops (1-26 and 27-46). The N-terminal 15 residue segment was relaxed into statistical coil-like non-native conformation, in contrast to its extended conformation in the native state. The effect of temperature in the range of 2-60 degrees C was small; the folded subpopulations were stable over this range. These results show that in BPTI the compact conformations found under unfolding and partially folding conditions have native-like chain topology. Under the conditions of transition to partially folding conditions the compact conformation is stabilized, not only by the hydrophobic collapse and the local interaction but also by nonlocal interactions (NLIs). Few specific, very stable NLIs between the three segments which form the main structural elements of the native conformation direct the formation of native-like topology of the chain in the transition.(ABSTRACT TRUNCATED AT 250 WORDS)