Hexafluoroacetone hydrate as a structure modifier in proteins: characterization of a molten globule state of hen egg-white lysozyme

A molten globule-like state of hen egg-white lysozyme has been characterized in 25% aqueous hexafluoroacetone hydrate (HFA) by CD, fluorescence, NMR, and H/D exchange experiments. The far UV CD spectra of lysozyme in 25% HFA supports retention of native-like secondary structure while the loss of near UV CD bands are indicative of the overall collapse of the tertiary structure. The intermediate state in 25% HFA exhibits an enhanced affinity towards the hydrophobic dye, ANS, and a native-like tryptophan fluorescence quenching. 1-D NMR spectra indicates loss of native-like tertiary fold as evident from the absence of ring current-shifted 1H resonances. CD, fluorescence, and NMR suggest that the transition from the native state to a molten globule state in 25% HFA is a cooperative process. A second structural transition from this compact molten globule-like state to an "open" helical state is observed at higher concentrations of HFA (> or = 50%). This transition is characterized by a dramatic loss of ANS binding with a concomitant increase in far UV CD bands. The thermal unfolding of the molten globule state in 25% HFA is sharply cooperative, indicating a predominant role of side-chain-side-chain interactions in the stability of the partially folded state. H/D exchange experiments yield higher protection factors for many of the backbone amide protons from the four alpha-helices along with the C-terminal 3(10) helix, whereas little or no protection is observed for most of the amide protons from the triple-stranded antiparallel beta-sheet domain. This equilibrium molten globule-like state of lysozyme in 25% HFA is remarkably similar to the molten globule state observed for alpha-lactalbumin and also with the molten globule state transiently observed in the kinetic refolding experiments of hen lysozyme. These results suggest that HFA may prove generally useful as a structure modifier in proteins.     

The pH dependence of hydrogen-deuterium exchange in trp repressor: the exchange rate of amide protons in proteins reflects tertiary interactions, not only secondary structure

The pH dependence of amide proton exchange rates have been measured for trp-repressor. One class of protons exchanges too fast to be measured in these experiments. Among the protons that have measurable hydrogen-deuterium exchange rates, two additional classes may be distinguished. The second class of protons are in elements of secondary structure that are mostly on the surface of the protein, and exchange linearly with increasing base concentration (log kex versus pH). The third class of amide protons is characterized by much higher protection against exchange at higher pH. These protons are located in the core of the protein, in helices B and C. The exchange rate in the core region does not increase linearly with pH, but rather goes through a minimum around pH 6. The mechanism of exchange for the slowly exchanging core protons is interpreted in terms of the two-process model of Hilton and Woodward (1979, Biochemistry 18:5834-5841), i.e., exchange through both a local mechanism that does not require unfolding of the protein, and a mechanism involving global unfolding of the protein. The increase in exchange rates at low pH is attributed to a partial unfolding of the repressor. It is concluded that the formation of secondary structure alone is insufficient to account for the high protection factors seen in the core of native proteins at higher pH, and that tertiary interactions are essential to stabilize the structure.     

Hydrogen exchange in ribonuclease A and ribonuclease S: evidence for residual structure in the unfolded state under native conditions

Two-dimensional NMR spectroscopy has been used to monitor the exchange of backbone amide protons in ribonuclease A (RNase A) and its subtilisin-cleaved form, ribonuclease S (RNase S). Exchange measurements at two different pH values (5.4 and 6.0) show that the exchange process occurs according to the conditions of the EX2 limit. Differential scanning calorimetry measurements have been carried out in 2H2O under conditions analogous to those used in the NMR experiments in order to determine the values of DeltaCp, DeltaHu and Tm, corresponding to the thermal denaturation of both proteins. For the amide protons of a large number of residues in RNase A, the free energies at 25 degreesC for exchange competent unfolding processes are much lower than the calorimetric denaturation free energies, thus showing that exchange occurs through local fluctuations in the native state. For 20 other protons, the cleavage reaction had approximately the same effect on the exchange rate constants than on the equilibrium constant for unfolding, indicating that those protons exchange by global unfolding. There is a good agreement between the residues to which these protons belong and those involved in the putative folding nucleation site identified by quench-flow NMR studies. The unfolding free energies of the slowest exchanging protons, DeltaGex, as evaluated from exchange data, are much larger than the calorimetric free energies of unfolding, DeltaGu. Given the agreement between DeltaDeltaGex(A-S), the difference in free energy from exchange for a given proton of the two proteins, and DeltaDeltaGu(A-S), the difference in the calorimetric free energy of the two proteins, the discrepancy indicates that the intrinsic exchange rates in the unfolded state of those protons cannot be approximated by those measured in short unstructured peptides and, consequently, exchange for those protons in RNase A and S must occur through a rather structured denatured state.     

Solution structure of oxidized Saccharomyces cerevisiae iso-1-cytochrome c

The solution structure of oxidized Saccharomycescerevisiae Cys102Ser iso-1-cytochromechas been determined using 1361 meaningful NOEs (of 1676 total) after extending the published proton assignment [Gao, Y., et al. (1990) Biochemistry 29, 6994-7003] to 77% of all proton resonances. The NOE patterns indicate that secondary structure elements are maintained upon oxidation in solution with respect to the solid state and solution structures of the reduced species. Constraints derived from the pseudocontact shifts [diamagnetic reference shift values are those of the reduced protein [Baistrocchi, P., et al. (1996) Biochemistry 35, 13788-13796]] were used in the final stages of structure calculations. After restrained energy minimization with constraints from NOEs and pseudocontact shifts, a family of 20 structures with rmsd values of 0.58 +/- 0.08 and 1.05 +/- 0.10 A (relative to the average structure) for the backbone and all heavy atoms, respectively, was obtained. The solution structure is compared with the crystal structure and the structures of related systems. Twenty-six amide protons were detected in the NMR spectrum 6 days after the oxidized lyophilized protein was dissolved in D2O (pH 7.0 and 303 K); in an analogous experiment, 47 protons were observed in the spectrum of the reduced protein. The decrease in the number of nonexchanging amide protons, which mainly are found in the loop regions 14-26 and 75-82, confirms the greater flexibility of the structure of oxidized cytochrome c in solution. Our finding of increased solvent accessibility in these loop regions is consistent with proposals that an early step in unfolding the oxidized protein is the opening of the 70-85 loop coupled with dissociation of the Met80-iron bond.     

Stability of recombinant yeast protoporphyrinogen oxidase: effects of diphenyl ether-type herbicides and diphenyleneiodonium

Protoporphyrinogen oxidase catalyzes the oxygen-dependent aromatization of protoporphyrinogen IX to protoporphyrin IX and is the molecular target of diphenyl ether-type herbicides. Structural features of yeast protoporphyrinogen oxidase were assessed by circular dichroism studies on the enzyme purified from E. coli cells engineered to overproduce the protein. Coexpression of the bacterial gene ArgU that encodes tRNAAGA,AGG and a low induction temperature for protein synthesis were critical for producing protoporphyrinogen oxidase as a native, active, membrane-bound flavoprotein. The secondary structure of the protoporphyrinogen oxidase was 40.0 +/- 1. 5% alpha helix, 23.5 +/- 2.5% beta sheet, 18.0 +/- 2.0% beta turn, and 18.5 +/- 2.5% random-coil. Purified protoporphyrinogen oxidase appeared to be a monomeric protein that was relatively heat-labile (Tm of 44 +/- 0.5 degreesC). Acifluorfen, a potent inhibitor that competes with the tetrapyrrole substrate, and to a lower extent FAD, the cofactor of the enzyme, protected the protein from thermal denaturation, raising the Tm to 50.5 +/- 0.5 degreesC (acifluorfen) and 46.5 +/- 0.5 degreesC (FAD). However, diphenyleneiodonium, a slow tight-binding inhibitor that competes with dioxygen, did not protect the enzyme from heat denaturation. Acifluorfen binding to the protein increased the activation energy for the denaturation from 15 to 80 kJ.mol-1. The unfolding of the protein was a two-step process, with an initial fast reversible unfolding of the native protein followed by slow aggregation of the unfolded monomers. Functional analysis indicated that heat denaturation caused a loss of enzyme activity and of the specific binding of radiolabeled inhibitor. Both processes occurred in a biphasic manner, with a transition temperature of 45 degreesC.     

Thermodynamic stability of the P4-P6 domain RNA tertiary structure measured by temperature gradient gel electrophoresis

The P4-P6 domain RNA from the Tetrahymena self-splicing group I intron is an independent unit of tertiary structure that, in the kinetic folding pathway, folds before the rest of the intron and then stabilizes the remainder of the intron's tertiary structure. We have employed temperature gradient gel electrophoresis (TGGE) to examine the unfolding of the tertiary structure of P4-P6. In 0.9 mM Mg2+, the global tertiary fold of the molecule has a melting temperature of approximately 40 degreesC and is completely unfolded by 60 degreesC. Calculated thermodynamic parameters for folding of P4-P6 are DeltaH degrees' = -28 +/- 3 kcal/mol and DeltaS degrees' = -91 +/- 8 eu under these conditions. Chemical probing of the P4-P6 tertiary structure using dimethyl sulfate and CMCT confirms that these TGGE experiments monitor the unfolding of the global tertiary fold of the domain and that the secondary structure is largely unaffected over this temperature range. Thus, unlike the entropically driven P1 docking and guanosine binding steps of Tetrahymenagroup I intron self-splicing, which have positive or zero DeltaH terms, P4-P6 tertiary structure formation is stabilized by a negative DeltaH term. This implies that enthalpically favorable hydrogen bond formation, nucleotide base stacking, and/or binding of Mg2+ within the folded structure are responsible for stabilizing the P4-P6 domain.     

The exchangeable yeast ribosomal acidic protein YP2beta shows characteristics of a partly folded state under physiological conditions

The eukaryotic acidic ribosomal P proteins, contrary to the standard r-proteins which are rapidly degraded in the cytoplasm, are found forming a large cytoplasmic pool that exchanges with the ribosome-bound proteins during translation. The native structure of the P proteins in solution is therefore an essential determinant of the protein-protein interactions that take place in the exchange process. In this work, the structure of the ribosomal acidic protein YP2beta from Saccharomyces cerevisiae has been investigated by fluorescence spectroscopy, circular dichroism (CD), nuclear magnetic resonance (NMR), and sedimentation equilibrium techniques. We have established the fact that YP2beta bears a 22% alpha-helical secondary structure and a noncompact tertiary structure under physiological conditions (pH 7.0 and 25 degrees C); the hydrophobic core of the protein appears to be solvent-exposed, and very low cooperativity is observed for heat- or urea-induced denaturation. Moreover, the 1H-NMR spectra show a small signal dispersion, and virtually all the amide protons exchange with the solvent on a very short time scale, which is characteristic of an open structure. At low pH, YP2beta maintains its secondary structure content, but there is no evidence for tertiary structure. 2,2,2-Trifluoroethanol (TFE) induces a higher amount of alpha-helical structure but also disrupts any trace of the remaining tertiary fold. These results indicate that YP2beta may have a flexible structure in the cytoplasmic pool, with some of the characteristics of a "molten globule", and also point out the physiological relevance of such flexible protein states in processes other than protein folding.     

Determination of the equilibrium micelle-inserting position of the fusion peptide of gp41 of human immunodeficiency virus type 1 at amino acid resolution by exchange broadening of amide proton resonances

The exchange broadening of backbone amide proton resonances of a 23-mer fusion peptide of the transmembrane subunit of HIV-1 envelope glycoprotein gp41, gp41-FP, was investigated at pH 5 and 7 at room temperature in perdeuterated sodium dodecyl sulfate (SDS) micellar solution. Comparison of resonance peaks for these pHs revealed an insignificant change in exchange rate between pH 5 and 7 for amide protons of residues 4 through 14, while the exchange rate increase at neutral pH was more prominent for amide protons of the remaining residues, with peaks from some protons becoming undetectable. The relative insensitivity to pH of the exchange for the amide protons of residues 4 through 14 is attributable to the drastic reduction in [OH-] in the micellar interior, leading to a decreased exchange rate. The A15-G16 segment represents a transition between these two regimes. The data are thus consistent with the notion that the peptide inserts into the hydrophobic core of a membrane-like structure and the A15-G16 dipeptide is located at the micellar-aqueous boundary.     

A protein folding intermediate of ribonuclease T1 characterized at high resolution by 1D and 2D real-time NMR spectroscopy

The rate-limiting step during the refolding of S54G/P55N ribonuclease T1 is determined by the slow trans-->cis prolyl isomerisation of Pro39. We investigated the refolding of this variant by one-dimensional (1D) and two-dimensional (2D) real-time NMR spectroscopy, initiated by a tenfold dilution from 6 M guanidine hydrochloride at 10 degreesC. Two intermediates could be resolved with the 1D approach. The minor intermediate, which is only present early during refolding, is largely unfolded. The major intermediate, with an incorrect trans Pro39 peptide bond, is highly structured with 33 amide protons showing native chemical shifts and native NOE patterns. They could be assigned in a real-time 2D-NOESY (nuclear Overhauser enhancement spectroscopy) by using a new assignment strategy to generate positive and negative signal intensities for native and non-native NOE cross-peaks, respectively. Surprisingly, amide protons with non-native environments are located not only close to Tyr38-Pro39, but are spread throughout the entire protein, including the C-terminal part of the alpha-helix, beta-strands 3 and 4 and several loop regions. Native secondary and tertiary structure was found for the major intermediate in the N-terminal beta-strands 1 and 2 and the C terminus (connected by the disulfide bonds), the N-terminal part of the alpha-helix, and the loops between beta-strands 4/5 and 5/6. Implications of these native and non-native structure elements of the intermediate for the refolding of S54G/P55N ribonuclease T1 and for cis/trans isomerizations are discussed.     

Ternary complex between elongation factor Tu.GTP and Phe-tRNA(Phe)

The effect of aminoacylation and ternary complex formation with elongation factor Tu.GTP on the tertiary structure of yeast tRNA(Phe) was examined by 1H-NMR spectroscopy. Esterification of phenylalanine to tRNA(Phe) does not lead to changes with respect to the secondary and tertiary base pair interactions of tRNA. Complex formation of Phe-tRNA(Phe) with elongation factor Tu.GTP results in a broadening of all imino proton resonances of the tRNA. The chemical shifts of several NH proton resonances are slightly changed as compared to free tRNA, indicating a minor conformational rearrangement of Phe-tRNA(Phe) upon binding to elongation factor Tu.GTP. All NH proton resonances corresponding to the secondary and tertiary base pairs of tRNA, except those arising from the first three base pairs in the aminoacyl stem, are detectable in the Phe-tRNA(Phe)-elongation factor Tu-GTP ternary complex. Thus, although the interactions between elongation factor Tu and tRNA accelerate the rate of NH proton exchange in the aminoacyl stem-region, the Phe-tRNA(Phe) preserves its typical L-shaped tertiary structure in the complex. At high (> 10(-4) M) ligand concentrations a complex between tRNA(Phe) and elongation factor Tu-GDP can be detected on the NMR time-scale. Formation of this complex is inhibited by the presence of any RNA not related to the tRNA structure. Using the known tertiary structures of yeast tRNA(Phe) and Thermus thermophilus elongation factor Tu in its active, GTP form, a model of the ternary complex was constructed.     

Thermodynamics of the interaction of human immunoglobulin E with its high-affinity receptor Fc epsilon RI

We have employed isothermal titration calorimetry (ITC) and circular dichroism (CD) spectroscopy to characterize the binding of soluble fragments of IgE (IgE-Fc and Fc epsilon 3-4) to a soluble fragment of the high-affinity receptor Fc epsilon RI alpha-chain (sFc epsilon RI alpha). The thermodynamic parameters for the interaction of IgE-Fc and Fc epsilon 3-4 with sFc epsilon RI alpha, determined using ITC, confirm the earlier conclusion that the C epsilon 2 domain is not involved in the interaction and that the stoichiometry of both complexes is 1:1. For both IgE-Fc and Fc epsilon 3-4, the value of Delta H degrees is -36.9 +/- 4.6 kcal mol-1 at 37.3 degreesC and Delta Cp degrees is -820 +/- 120 cal mol-1 K-1. The temperature at which DeltaS degrees is zero is 284 +/- 1 K, indicating that the entropy contribution to the thermodynamics of association is unfavorable at physiological temperature. Of particular interest is the large value of Delta Cp degrees. The large surface area of IgE and Fc epsilon RI alpha that is implicated in complex formation from previous mutagenesis studies on the two proteins may account in part for the magnitude of Delta Cp degrees. Additional contributions may arise from hydration within the binding site and changes in tertiary structure of the individual components of the complex. However, the CD spectra of IgE, IgE-Fc, and Fc epsilon 3-4 complexes with sFc epsilon RI alpha are merely the sum of the spectra of their individual components, indicating that the secondary structure of the immunoglobulin domain folds are preserved on complex formation. Thus, any change in tertiary structure must be limited to the relative disposition of the immunoglobulin domains C epsilon 3 and C epsilon 4 in IgE and the two immunoglobulin-like domains in the alpha-chain of Fc epsilon RI.     

Characterization of the interaction between bovine pancreatic trypsin inhibitor and thiocyanate by NMR

The interaction between Bovine Pancreatic Trypsin Inhibitor and thiocyanate was studied using NMR spectroscopy following several experimental approaches. The chemical shift variations of the BPTI protons in the absence and in the presence of increasing thiocyanate concentrations (up to 0.2 M) were significant (> 0.05 ppm) for 30 protein protons belonging to 20 residues. The largest deviation, 0.2 ppm, was observed for the amide backbone proton of Arg42 in the absence of thiocyanate and in the presence of 40 molar equivalents of thiocyanate. The influence of the presence of thiocyanate on the electrostatic potential surrounding the protein was demonstrated by NOESY spectra selective at the water frequency: the presence of SCN- favours acid catalysed exchange and disfavours base catalysis. However, a specific effect of thiocyanate was pointed out since the comparison of the chemical shifts in the presence of 40 molar equivalents of KSCN and KCl, respectively, showed much more as well as larger deviations compared to measurements in the absence of salt. A dissociation constant, KD, for a 1/1 complex between BPTI and thiocyanate was calculated from chemical shifts measurements: KD = 89 +/- 8 mM. A second value, KD = 99 +/- 10 mM, was extracted from SC15N relaxation time measurements.     

Determination of the residence time of water molecules hydrating B'- DNA and B-DNA, by one-dimensional zero-enhancement nuclear Overhauser effect spectroscopy

The residence time of water in the minor groove of the d(CGCGAATTCGCG) duplex has been determined by a recent measurement combining nuclear Overhauser enhancements (NOE, ROE) and 17O relaxation dispersion. The time is in the range of nanoseconds, so that it may be measured by a rather simple method proposed here, namely the choice of conditions such that the NOE between the observed DNA proton and a nearby water proton is zero. This condition is realized when the residence time of the water molecule is 0.178 times the nuclear magnetic resonance period (e.g. 0.297 ns at 600 MHz). It may be achieved by varying the magnetic field and/or the temperature. The zero-NOE measurement may be performed by one-dimensional NMR, and has therefore good sensitivity. We have developed excitation sequences which suppress two spurious contributions to the NOE: from neighboring exchangeable protons and from H3' protons whose chemical shift is close to that of water. The method is applied here to the comparison of residence times of water next to B-DNA and next to B'-DNA, the latter corresponding to better stacked, propeller-twisted base-pairs and a correspondingly narrower minor groove. In the minor groove of [d(CGCGAATTCGCG)]2, a B'-DNA duplex, the residence time of the water molecule next to H2 of adenine(6) (underlined), is 0.6 ns at 10 degreesC, in good agreement with the value obtained previously. The residence time is slightly but distinctly shorter for the water next to A5, suggesting non-cooperative departure of these two molecules which are presumed to be part of the hydration spine. Near A5 and A4 of [d(AAAAATTTTT)]2, another B'-DNA duplex, the residence times are approximately twice as long, but the activation enthalpies are about the same, ca. 38 kJ/mol. The residence time in the minor groove of the regular B-DNA sequence d(CGCGATCGCG) was 0.3 ns at 10 degreesC, shorter than in the case of the B'-DNA sequences by factors of 2 and 4, respectively. The temperature dependence is less, with an activation enthalpy of 27 kJ/mol. The major groove residence times are comparable for the three sequences, and a few times shorter than those of minor groove water. A value of 0.36 ns, or even more in case of rotation of water, is obtained around -8 degreesC. The most striking aspect of these results is the relatively small difference in the residence times of reputedly fast and slow-exchanging water molecules bound to DNA in biological conditions. This suggests that the spine of hydration is perhaps not a major stabilizer of the B'-DNA structure as compared with B-DNA.     

Structure and stability of monomeric lambda repressor: NMR evidence for two-state folding

The absence of equilibrium intermediates in protein folding reactions (i.e., two-state folding) simplifies thermodynamic and kinetic analyses but is difficult to prove rigorously. We demonstrate a sensitive method for detecting partially folded species based on using proton chemical shifts as local probes of structure. The coincidence of denaturation curves for probes throughout the molecule is a particularly stringent test for two-state folding. In this study we investigate a new form of the N-terminal domain of bacteriophage lambda repressor consisting of residues 6-85 (lambda 6-85) using nuclear magnetic resonance (NMR) and circular dichroism (CD). This truncated version lacks the residues required for dimerization and is monomeric under the conditions used for NMR. Heteronuclear NMR was used to assign the 1H, 15N, and backbone 13C resonances. The secondary and tertiary structure of lambda 6-85 is very similar to that reported for the crystal structure of the DNA-bound 1-92 fragment [Beamer, L. J., and Pabo, C. O. (1992) J. Mol. Biol. 227, 177-196], as judged by analysis of chemical shifts, amide hydrogen exchange, amide-alpha coupling constants, and nuclear Overhauser enhancements. Thermal and urea denaturation studies were conducted using the chemical shifts of the four aromatic side chains as local probes and the CD signal at 222 nm as a global probe. Plots of the fraction denatured versus denaturant concentration obtained from these studies are identical for all probes under all conditions studied. This observation provides strong evidence for two-state folding, indicating that there are no populated intermediates in the folding of lambda 6-85.     

Investigation of the structural basis for thermostability of DNA-binding protein HU from Bacillus stearothermophilus

Site-directed mutagenesis was used to identify amino acid residues essential for the thermostability of the DNA-binding protein HU from the thermophile Bacillus stearothermophilus (BstHU). Two mutants, BstHU-A27S and BstHU-V42I, in which Ala27 and Val42 in BstHU were replaced by the corresponding amino acids Ser27 and Ile42, respectively, in the homologue from a mesophile B. subtilis (BsuHU), were less stable than the wild-type BstHU (63.9 degreesC), showing Tm values of 58.4 degreesC and 60.1 degreesC, respectively, as estimated by circular dichroism (CD) analysis at pH 7.0. The denaturation of two mutants was further characterized using differential scanning calorimetry; the Tm values obtained by calorimetric analysis were in good agreement with those estimated by CD analysis. The results suggest that Ala27 and Val42 are partly responsible for enhancing the thermostability of BstHU. When considered together with previous results, it is revealed that Gly15, Ala27, Glu34, Lys38, and Val42 are essential for the thermostability of thermophilic protein BstHU. Moreover, five thermostabilizing mutations were simultaneously introduced into BsuHU, which resulted in a quintuple mutant with a Tm value of 71.3 degreesC, which is higher than that of BstHU, and also resulted in insusceptibility to proteinase digestion.     

Investigation of secondary and tertiary structural changes of cytochrome c in complexes with anionic lipids using amide hydrogen exchange measurements: an FTIR study

The structure of cytochrome c bound to anionic lipid membranes composed of dimyristoyl, dipalmitoyl, or dioleoyl phosphatidylglycerols, or of bovine heart cardiolipin, has been investigated by Fourier transform infrared spectroscopy. Only small changes in secondary structure, as registered by the amide I band of cytochrome c, were observed upon binding at temperatures below that of denaturation of the protein, and these were not coupled to the thermotropic phase transitions of the lipid. The denaturation temperature of the protein decreased by approximately 25-30 degrees upon binding, in a progression which correlated with that of the lipid phase transition temperatures, being approximately 7 degrees lower for complexes with dioleoyl than with dipalmitoyl phosphatidylglycerol. Large changes in the amide proton exchange characteristics, as monitored by the spectral shifts in the amide I band of the protein in D2O, were observed on binding cytochrome c to the lipid membranes. For the slowly exchanging population, the amide deuteration rates of the free protein were nearly independent of temperature, whereas those of the bound protein increased by up to two orders of magnitude over the temperature range from 10 to 40 degrees C. In addition, the extent of exchange differed between the bound and unbound protein. A structural transition in the bound protein was detected as a discontinuous step in Arrhenius plots of the deuterium exchange rates which occurred at a temperature in the region of 22 to 29 degrees C, depending on the lipid, far below that of denaturation. The temperature of this transition was determined by the physical state of the lipid, being 7 degrees lower for the lipids in the fluid state than for those in the gel state, and, for complexes with dimyristoyl phosphatidylglycerol, occurred at an intermediate temperature, being controlled by the lipid chain-melting transition at 27-28 degrees C. These results provide evidence for a coupling of the tertiary structure of the membrane-bound protein with the physical state of the membrane lipids.     

Solution structure of methionine-oxidized amyloid beta-peptide (1-40). Does oxidation affect conformational switching?

The solution structure of Abeta(1-40)Met(O), the methionine-oxidized form of amyloid beta-peptide Abeta(1-40), has been investigated by CD and NMR spectroscopy. Oxidation of Met35 may have implications in the aetiology of Alzheimer's disease. Circular dichroism experiments showed that whereas Abeta(1-40) and Abeta(1-40)Met(O) both adopt essentially random coil structures in water (pH 4) at micromolar concentrations, the former aggregates within several days while the latter is stable for at least 7 days under these conditions. This remarkable difference led us to determine the solution structure of Abeta(1-40)Met(O) using 1H NMR spectroscopy. In a water-SDS micelle medium needed to solubilize both peptides at the millimolar concentrations required to measure NMR spectra, chemical shift and NOE data for Abeta(1-40)Met(O) strongly suggest the presence of a helical region between residues 16 and 24. This is supported by slow H-D exchange of amide protons in this region and by structure calculations using simulated annealing with the program XPLOR. The remainder of the structure is relatively disordered. Our previously reported NMR data for Abeta(1-40) in the same solvent shows that helices are present over residues 15-24 (helix 1) and 28-36 (helix 2). Oxidation of Met35 thus causes a local and selective disruption of helix 2. In addition to this helix-coil rearrangement in aqueous micelles, the CD data show that oxidation inhibits a coil-to-beta-sheet transition in water. These significant structural rearrangements in the C-terminal region of Abeta may be important clues to the chemistry and biology of Abeta(1-40) and Abeta(1-42).     

Three-dimensional solution structure and stability of phage 434 Cro protein

1H NMR resonances of the phage 434 Cro protein were assigned using standard 2D NMR methods, and its solution structure determined using 867 distance constraints in distance geometry (DIANA) calculations ultimately refined by restrained molecular dynamics (GROMOS). In the 20 best NMR structures, the average pairwise backbone and heavy atom RMSDs are 0.63 +/- 0.14 and 1.53 +/- 0.15 A, respectively, for the structurally well-defined residues 4-65. Residues 1-3 and 66-71 at the N- and C-termini are structurally disordered. The region 4-65 includes five alpha-helices and tight turns which define the hydrophobic core of the protein. The backbone and heavy atom RMSDs for residues 4-65 are 0.92 +/- 0.12 and 1.99 +/- 0.12 A, respectively, for the NMR versus the crystal structures, but there are significant differences in the side-chain conformations and solvent accessibilities for some core residues. Analytical ultracentrifugation experiments confirm that 434 Cro is monomeric even at the high NMR concentrations. 434 Cro folding under NMR solution conditions is two-state as indicated by coincident urea denaturation curves from circular dichroism and intrinsic fluorescence measurements. They yield values for 434 Cro stability which show good correspondence to the free energy for global unfolding determined by NMR hydrogen exchange measurements for the slowest exchanging amide protons.     

Cavity-creating mutation at the dimer interface of Plasmodium falciparum triosephosphate isomerase: restoration of stability by disulfide cross-linking of subunits

Disulfide engineering across subunit interfaces provides a means of inhibiting dissociation during unfolding of multimeric enzymes. Two symmetry-related intersubunit disulfide bridges were introduced across the interface of the dimeric enzyme triosephosphate isomerase from Plasmodium falciparum. This was achieved by mutating a tyrosine residue at position 74 at the subunit interface to a cysteine, thereby enabling it to form a covalent cross-link with a pre-existing cysteine at position 13 of the other subunit. The wild-type enzyme (TIMWT) and the oxidized (Y74Cox) and reduced (Y74Cred) forms of the mutant have similar enzymatic activity, absorption, and fluorescence spectra. All three proteins have similar far-UV CD spectra. The Y74Cred shows a distinct loss of near-UV CD. Thermal precipitation studies demonstrate that TIMWT and Y74Cox have very similar Tm values (Tm approximately 60 degreesC) whereas Y74Cred is surprisingly labile (Tm approximately 38 degreesC). The Y74C mutant results in the creation of a large cavity (approximately 100 A3) at the dimer interface. The crystal structure for the oxidized form of Y74C mutant, crystallized in the presence of low concentrations of dithiothreitol, reveals an asymmetric dimer containing a disulfide bridge at one site and a reduced dithiol cysteine at the other. The crystal structure of the mutant offers insights into the destabilization effects of the interfacial cavities and the role of disulfide tethering in restoring protein stability.