Oligomeric states along the folding pathways of ß2-microglobulin: kinetics, thermodynamics, and structure.

The transition of proteins from their soluble functional state to amyloid fibrils and aggregates is associated with the onset of several human diseases. Protein aggregation often requires some structural reshaping and the subsequent formation of intermolecular contacts. Therefore, the study of the conformation of excited protein states and their ability to form oligomers is of primary importance for understanding the molecular basis of amyloid fibril formation. Here, we investigated the oligomerization processes that occur along the folding of the amyloidogenic human protein ß2-microglobulin. The combination of real-time two-dimensional NMR data with real-time small-angle X-ray scattering measurements allowed us to derive thermodynamic and kinetic information on protein oligomerization of different conformational states populated along the folding pathways. In particular, we could demonstrate that a long-lived folding intermediate (I-state) has a higher propensity to oligomerize compared to the native state. Our data agree well with a simple five-state kinetic model that involves only monomeric and dimeric species. The dimers have an elongated shape with the dimerization interface located at the apical side of ß2-microglobulin close to Pro32, the residue that has a trans conformation in the I-state and a cis conformation in the native (N) state. Our experimental data suggest that partial unfolding in the apical half of the protein close to Pro32 leads to an excited state conformation with enhanced propensity for oligomerization. This excited state becomes more populated in the transient I-state due to the destabilization of the native conformation by the trans-Pro32 configuration.

[Structural dynamics, stability and folding of proteins].

The present concepts of protein folding in vitro are reviewed. According to these concepts, amino acid sequence of protein, which has appeared a result of evolutionary selection, determines the native structure of protein, the pathway of protein folding, and the existence of free energy barrier between native and denatured states of protein. The latter means that protein macromolecule can exist in either native or denatured state. And all macromolecules in the native state are identical but for structural fluctuations due to Brownian motion of their atoms. Identity of all molecules in native state is of primary importance for their correct functioning. The dependence of protein stability, which is measured as the difference between free energy of protein in native and denatured states, on temperature and denaturant concentration is discussed. The modern approaches characterizing transition state and nucleation are regarded. The role of intermediate and misfolded states in amorphous aggregate and amyloid fibril formation is discussed.

Is folding of beta-lactoglobulin non-hierarchic? Intermediate with native-like beta-sheet and non-native alpha-helix.

The refolding of beta-lactoglobulin, a beta-barrel protein consisting of beta strands betaA-betaI and one major helix, is unusual because non-native alpha-helices are formed at the beginning of the process. We studied the refolding kinetics of bovine beta-lactoglobulin A at pH 3 using the stopped-flow circular dichroism and manual H/(2)H exchange pulse labeling coupled with heteronuclear NMR. The protection pattern from the H/(2)H exchange of the native state indicated the presence of a stable hydrophobic core consisting of betaF, betaG and betaH strands. The protection pattern of the kinetic intermediate obtained about one second after initiating the reaction was compared with that of the native state. In this relatively late kinetic intermediate, which still contains some non-native helical structure, the disulfide-bonded beta-hairpin made up of betaG and betaH strands was formed, but the rest of the molecule was fluctuating, where the non-native alpha-helices may reside. Subsequently, the core beta-sheet extends, accompanied by a further alpha-helix to beta-sheet transition. Thus, the refolding of beta-lactoglobulin exhibits two elements: the critical role of the core beta-sheet is consistent with the hierarchic mechanism, whereas the alpha-helix to beta-sheet transition suggests the non-hierarchic mechanism.

Transient non-native secondary structures during the refolding of alpha-lactalbumin detected by infrared spectroscopy.

Stopped-flow Fourier-transform infrared spectroscopy (SF-FTIR) was used to identify native as well as non-native secondary structures during the refolding of the calcium-binding protein alpha-lactalbumin. Infrared absorbance spectra were recorded in real time after a pH jump induced refolding of the protein. In the presence of calcium, the refolding is fast with concerted appearance of secondary structures; in its absence, folding is much slower and intricate, with transient formation and disappearance of non-native beta-sheet. The possibility of detecting native as well as non-native structures at the same time is especially valuable in providing insight into the complexity of the refolding process of a protein.

Solution structure and dynamics of bovine beta-lactoglobulin A.

Using heteronuclear NMR spectroscopy, we studied the solution structure and dynamics of bovine beta-lactoglobulin A at pH 2.0 and 45 degrees C, where the protein exists as a monomeric native state. The monomeric NMR structure, comprising an eight-stranded continuous antiparallel beta-barrel and one major alpha-helix, is similar to the X-ray dimeric structure obtained at pH 6.2, including betaI-strand that forms the dimer interface and loop EF that serves as a lid of the interior hydrophobic hole. [1H]-15N NOE revealed that betaF, betaG, and betaH strands buried under the major alpha-helix are rigid on a pico- to nanosecond time scale and also emphasized rapid fluctuations of loops and the N- and C-terminal regions.

NMR conformational study of the sixth transmembrane segment of sarcoplasmic reticulum Ca2+-ATPase.

In current topological models, the sarcoplasmic reticulum Ca2+-ATPase contains 10 putative transmembrane spans (M1-M10), with spans M4/M5/M6 and probably M8 participating in the formation of the membranous calcium-binding sites. We describe here the conformational properties of a synthetic peptide fragment (E785-N810) encompassing the sixth transmembrane span (M6) of Ca2+-ATPase. Peptide M6 includes three residues (N796, T799, and D800) out of the six membranous residues critically involved in the ATPase calcium-binding sites. 2D-NMR experiments were performed on the M6 peptide selectively labeled with 15N and solubilized in dodecylphosphocholine micelles to mimic a membrane-like environment. Under these conditions, M6 adopts a helical structure in its N-terminal part, between residues I788 and T799, while its C-terminal part (G801-N810) remains disordered. Addition of 20% trifluoroethanol stabilizes the alpha-helical N-terminal segment of the peptide, and reveals the propensity of the C-terminal segment (G801-L807) to form also a helix. This second helix is located at the interface or in the aqueous environment outside the micelles, while the N-terminal helix is buried in the hydrophobic core of the micelles. Furthermore, the two helical segments of M6 are linked by a flexible hinge region containing residues T799 and D800. These conformational features may be related to the transient formation of a Schellman motif (L797VTDGL802) encoded in the M6 sequence, which probably acts as a C-cap of the N-terminal helix and induces a bend with respect to the helix axis. We propose a model illustrating two conformations of M6 and its insertion in the membrane. The presence of a flexible region within M6 would greatly facilitate concomitant participation of all three residues (N796, T799, and D800) believed to be involved in calcium complexation.

Rapid collapse and slow structural reorganisation during the refolding of bovine alpha-lactalbumin.

The refolding of bovine alpha-lactalbumin (BLA) from its chemically denatured state in 6 M GuHCl has been investigated by a variety of complementary biophysical approaches. CD experiments indicate that the species formed in the early stages of refolding of the apo-protein have at least 85 % of the alpha-helical content of the native state, and kinetic NMR experiments show that they possess near-native compactness. Hydrogen exchange measurements using mass spectrometry and NMR indicate that persistent structure in these transient species is located predominantly in the alpha-domain of the native protein and is similar to that present in the partially folded A-state formed by the protein at low pH. The extent of the exchange protection is, however, small, and there is no evidence for the existence of well-defined discrete kinetic intermediates of the type populated in the refolding of the structurally homologous c-type lysozymes. Rather, both mass spectrometric and NMR data indicate that the rate-determining transition from the compact partially structured (molten globule) species to the native state is highly cooperative. The data show that folding in the presence of Ca2+ is similar to that in its absence, although the rate is increased by more than two orders of magnitude. Sequential mixing experiments monitored by fluorescence spectroscopy indicate that this slower folding is not the result of the accumulation of kinetically trapped species. Rather, the data are consistent with a model in which binding of Ca2+ stabilizes native-like contacts in the partially folded species and reduces the barriers for the conversion of the protein to its native state. Taken together the results indicate that folding of BLA, in the presence of its four disulphide bonds, corresponds to one of the limiting cases of protein folding in which rapid collapse to a globule with a native-like fold is followed by a search for native-like side-chain contacts that enable efficient conversion to the close packed native structure.

Slow cooperative folding of a small globular protein HPr.

The folding of an 85-residue protein, the histidine-containing phosphocarrier protein HPr, has been studied using a variety of techniques including DSC, CD, ANS fluorescence, and NMR spectroscopy. In both kinetic and equilibrium experiments the unfolding of HPr can be adequately described as a two-state process which does not involve the accumulation of intermediates. Thermodynamic characterization of the native and the transition states has been achieved from both equilibrium and kinetic experiments. The heat capacity change from the denatured state to the transition state (3. 2 kJ mol-1 K-1) is half of the heat capacity difference between the native and denatured states (6.3 kJ mol-1 K-1), while the solvent accessibility of the transition state (0.36) indicates that its compactness is closer to that of the native than that of the denatured state. The high value for the change in heat capacity upon unfolding results in the observation of cold denaturation at moderate denaturant concentrations. Refolding from high denaturant concentrations is, however, slow. The rate constant of folding in water, (14.9 s-1), is small compared to that reported for other proteins of similar size under similar conditions. This indicates that very fast refolding is not a universal character of small globular proteins which fold in the absence of detectable intermediates.

Detection of residue contacts in a protein folding intermediate.

Protein folding can be described in terms of the development of specific contacts between residues as a highly disordered polypeptide chain converts into the native state. Here we describe an NMR based strategy designed to detect such contacts by observation of nuclear Overhauser effects (NOEs). Experiments with alpha-lactalbumin reveal the existence of extensive NOEs between aromatic and aliphatic protons in the archetypal molten globule formed by this protein at low pH. Analysis of their time development provides direct evidence for near-native compactness of this state. Through a rapid refolding procedure the NOE intensity can be transferred efficiently into the resolved and assigned spectrum of the native state. This demonstrates the viability of using this approach to map out time-averaged interactions between residues in a partially folded protein.

Protein folding monitored at individual residues during a two-dimensional NMR experiment.

An approach is described to monitor directly at the level of individual residues the formation of structure during protein folding. A two-dimensional heteronuclear nuclear magnetic resonance (NMR) spectrum was recorded after the rapid initiation of the refolding of a protein labeled with nitrogen-15. The intensities and line shapes of the cross peaks in the spectrum reflected the kinetic time course of the folding events that occurred during the spectral accumulation. The method was used to demonstrate the cooperative nature of the acquisition of the native main chain fold of apo bovine alpha-lactalbumin. The general approach, however, should be applicable to the investigation of a wide range of chemical reactions.

Ca2+ translocation across sarcoplasmic reticulum ATPase randomizes the two transported ions.

Cytoplasmic Ca2+ dissociation is sequential, and the Ca2+ ions bound to the nonphosphorylated ATPase are commonly represented as superimposed on each other, so that the superficial Ca2+ is freely exchangeable from the cytoplasm, whereas the deeper Ca2+ is not. Under conditions where ADP-sensitive phosphoenzyme accumulates (leaky vesicles, 5 degrees C, pH 8, 300 mM K+), luminal Ca2+ dissociation is sequential as well, so that the representation of two superimposed Ca2+ ions still holds on the phosphoenzyme, with the superficial Ca2+ facing the lumen freely exchangeable and the deeper Ca2+ blocked by the superficial Ca2+. Under the same conditions, we have investigated whether a prebuilt Ca2+ order is maintained during membrane translocation. Starting from a prebuilt order on the cytoplasmic side, we showed that the Ca2+ ions cannot be identified after translocation to the luminal side. The same result was obtained starting from a prebuilt order on the luminal side and following the luminal to cytoplasmic translocation. We conclude that the two Ca2+ ions are mixed during ATP-induced phosphorylation as well as during ADP-induced dephosphorylation.

The modulation of Ca2+ binding to sarcoplasmic reticulum ATPase by ATP analogues is pH-dependent.

Excess ATP is known to enhance Ca(2+)-ATPase activity and, among other effects, to accelerate the Ca2+ binding reaction. In previous work, we studied the pH dependence of this reaction and proposed a 3H+/2Ca2+ exchange at the transport sites, in agreement with the H+/Ca2+ counter transport. Here we studied the effect of ADP and nonhydrolyzable ATP analogues on the Ca2+ binding reaction at various pH values. At pH 6, where Ca2+ binding is monophasic and slow, ADP, adenosine 5'-(beta,gamma-methylene)triphosphate (AMP-PCP), or adenyl-5'-yl imidodiphosphate (AMPPNP) increased the Ca2+ binding rate constant 20-fold. At pH 7 and 8, where Ca2+ binding is biphasic, the nucleotides induce fast and monophasic Ca2+ binding. At pH 7, AMP-PCP accelerated Ca2+ binding with an apparent dissociation constant of 10 microM. At acidic pH, ADP, AMPPCP, or AMPPNP increased the equilibrium affinity of Ca2+ for ATPase, whereas at alkaline pH, these nucleotides had no effect. At pH 5.5, AMPPCP increased equilibrium Ca2+ binding with an apparent dissociation constant of 1 microM.

Following protein folding in real time using NMR spectroscopy.

The refolding of apo bovine alpha-lactalbumin has been monitored in real time by NMR spectroscopy following rapid in situ dilution of a chemically denatured state. By examining individual resonances in the time-resolved NMR spectra, the native state has been shown to emerge in a cooperative manner from an intermediate formed in the dead-time of the experiments. The kinetics of folding to the native state are closely similar to those observed by stopped-flow fluorescence and near-UV circular dichroism. The NMR spectrum of the transient intermediate resembles closely that of the well characterized stable molten globule state formed at low pH. The results suggest that NMR can play a key role in describing at an atomic level the structural transitions occurring during protein folding.

Lumenal Ca2+ dissociation from the phosphorylated Ca(2+)-ATPase of the sarcoplasmic reticulum is sequential.

Once two radioactive Ca2+ coming from the cytoplasm are bound to the transport sites of the nonphosphorylated ATPase, excess EGTA induces rapid dissociation of both ions, whereas excess nonradioactive Ca2+ only reaches one of the two bound Ca2+. This difference has been explained assuming that the two Ca2+ sites are in a single file channel in which the superficial Ca2+ is freely exchangeable from the cytoplasm, whereas the deeper Ca2+ is exchangeable only when the superficial site is vacant. The same experiment was done using phosphorylated ATPase to determine whether Ca2+ dissociation toward the lumen is sequential as well. Under conditions that allow ADP-sensitive phosphoenzyme to accumulate (leaky vesicles, 5 degrees C, pH 8, 300 mM KC1), we found the same two pools of Ca2+. Excess EGTA induced dissociation of both ions together with dephosphorylation. Excess nonradioactive Ca2+ induced the exchange of half the radioactive Ca2+ without any effect on the phosphoenzyme level. Our results show a close similarity between the transport sites of the nonphosphorylated and the phosphorylated enzymes, although the orientation, affinities, and dissociation rate constants are different.

Ca2+ binding to sarcoplasmic reticulum ATPase revisited. II. Equilibrium and kinetic evidence for a two-route mechanism.

The experiments reported in the present paper were designed to check the model proposed for Ca2+ binding in the preceding paper (Forge, V., Mintz, E., and Guillain, F. (1993) J. Biol. Chem. 268, 10953-10960). The pH dependence of the Mg(2+)-induced variation of the intrinsic fluorescence, as well as that of the phosphorylation by Pi, confirmed that there are several species of Ca(2+)-deprived ATPase. Kinetics of Ca2+ binding as a function of pH suggested that the deprotonated form of the ATPase binds Ca2+ rapidly (k > 50 s-1), whereas the protonated forms bind Ca2+ slowly (1.3-2.7 s-1). At variance with other models which are linear, slow and rapid Ca2+ binding take two different routes, and intermediate pH values and Mg2+, which favors the deprotonated forms, result in biphasic kinetics. Mg2+ binds to all Ca(2+)-deprived species and to species having one bound Ca2+ but does not bind to ECa2. This is the reason why Mg2+ inhibits Ca2+ binding, and this inhibition is removed in the presence of adenosine-5'-O-(3-thiotriphosphate) which drives Mg2+ into the catalytic site.

Ca2+ binding to sarcoplasmic reticulum ATPase revisited. I. Mechanism of affinity and cooperativity modulation by H+ and Mg2+.

H+ and Mg2+ are known to inhibit Ca2+ binding to the transport sites of sarcoplasmic reticulum-ATPase. Evaluation of the affinity for the Ca2+ binding sites requires measurement of the amount of Ca2+ bound to ATPase as a function of the free Ca2+ concentration imposed by a Ca2+ chelator. The choice of the chelator is crucial as it determines the accuracy of the free Ca2+ concentration. At pH > 7, the EGTA affinity for Ca2+ is higher than that of ATPase, inducing artifacts that alter the shape of the binding curves. Thus, we have used 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA), whose affinity is unchanged at pH > or = 7. Ca2+ binding was studied at equilibrium, from pH 6 to pH 8 and from 0 to 10 mM Mg2+, using EGTA and/or BAPTA and [45Ca]Ca2+. Under all conditions, the stoichiometry was 2 Ca2+/ATPase. At variance with previous studies, the Hill coefficient was 1.1-2 and higher at pH 6 than at pH 8. In addition, it decreased in the presence of Mg2+. The Ca2+ binding curves were analyzed according to a model in which they result from a sequential binding of two Ca2+, each binding step being modified by H+ and Mg2+. The effect of H+ is described by two steps involving two H+ and one H+, with pK 7 and 7.9, respectively. At pH 6, ATPase must lose two H+ for the first Ca2+ to bind and a third H+ for the second Ca2+ to bind. At pH 9, both Ca2+ bind without any H+ exchange. Mg2+ can bind to all species, except to that saturated with Ca2+. The species having lost two H+ has a higher affinity for Mg2+ (< or = 1 mM) than the species having bound three H+ (4 mM). The above model allows us to analyze the effects of H+ and Mg2+ at each Ca2+ binding step and to explain the changes in the apparent affinity and cooperativity.

Dimethyl sulfoxide favours the covalent phosphorylation and not the binding of Pi to sarcoplasmic reticulum ATPase.

Competition between Ca2+ binding and Pi phosphorylation showed that the affinity of Ca(2+)-ATPase for Pi was not changed by 20% DMSO. Thus, the enhancement of Pi phosphorylation in the presence of DMSO should not be attributed to a solvent effect on the affinity for Pi, but rather on the phosphorylation reaction itself.