Thermally induced hydrogen exchange processes in small proteins as seen by FTIR spectroscopy

Fourier-transform infrared (FTIR) spectroscopy has been used to study the thermally induced exchange characteristics of those backbone amide protons which persist H-D exchange at ambient conditions in ribonuclease A, in wild type ribonuclease T1 and some of its variants, and in the histone-like protein HBsu. The H-D exchange processes were induced by increasing the thermal energy of the protein solutions in two ways: (i) by linearly increasing the temperature, and (ii) by a temperature jump. To trace the H-D exchange in the proteins, various infrared absorption bands known to be sensitive to H-D exchange were used as specific monitors. Characteristic H-D exchange curves were obtained from which the endpoints (TH/D) of H-D exchange could be determined. The H-D exchange curves, the TH/D-values and the phase transition temperatures Tm were used to estimate the structural flexibility and stability of the given proteins. It is suggested that time-resolved FTIR spectroscopy can be used to determine global stability parameters of proteins.

Ribonuclease A revisited: infrared spectroscopic evidence for lack of native-like secondary structures in the thermally denatured state

To address a number of conflicting reports in the literature, we undertook an infrared spectroscopic study to test for the presence of native-like secondary structures in thermally denatured ribonuclease A. Ribonuclease A does not aggregate at high temperatures, and the infrared spectrum shows a completely featureless amide I band contour. Using 13C-labeled urea, we were also able to obtain the infrared spectrum of the chemically denatured protein, which is practically identical with that of the heat-denatured protein. To the best of our knowledge, this is the first study that uses 13C-labeled urea as a chemical denaturant which circumvents the problem encountered with the strong absorption of urea in the conformation-sensitive amide I region of proteins; it opens up the possibility of investigating protein folding/unfolding processes in the presence of high concentrations of chemical denaturants. From an analysis of the amide I region of the infrared spectra of thermally and chemically denatured RNase A, it was concluded that heat-denatured ribonuclease A does not contain any significant amount of authentic hydrogen-bonded secondary structures. Furthermore, a comparison of the infrared spectra of ribonuclease A with those of ribonuclease T1 demonstrates that in spite of major differences between their native structures there are practically no differences between their heat-denatured states. This would not be expected if there were residual native-like secondary structures in the thermally denatured state of one or both of these proteins.

Temperature-jump-induced refolding of ribonuclease A: a time-resolved FTIR spectroscopic study

FTIR difference spectroscopy has been used for the first time to investigate the kinetics of secondary structure formation during refolding. The refolding process of ribonuclease A (RNase A) as a model system was induced by applying a temperature-jump of 60 degrees. The temperature-jump was triggered by rapidly injecting a small volume of the thermally unfolded protein solution at 80 degrees C into a special cuvette system kept at 20 degrees C. The dead-time of the injection and the time resolution of the FTIR spectrometer permitted the observation of refolding processes in a time window ranging from 170 ms to several minutes. Specifically, the formation of beta-structures and the disappearance of irregular conformations could be observed in this time interval.

Aspartate-bond isomerization affects the major conformations of synthetic peptides

The aspartic acid bond changes to an beta-aspartate bond frequently as a side-reaction during peptide synthesis and often as a post-translational modification of proteins. The formation of beta-asparate bonds is reported to play a major role not only in protein metabolism, activation and deactivation, but also in pathological processes such as deposition of the neuritic plaques of Alzheimer's disease. Recently, we reported how conformational changes following the aspartic-acid-bond isomerization may help the selective aggregation and retention of the amyloid beta peptide in affected brains (Fabian et al., 1994). In the current study we used circular dichroism, Fourier-transform infrared spectroscopy, and molecular modeling to characterize the general effect of the beta-aspartate-bond formation on the conformation of five sets of synthetic model peptides. Each of the non-modified, parent peptides has one of the major secondary structures as the dominant spectroscopically determined conformation: a type I beta turn, a type II beta turn, short segments of alpha or 3(10) helices, or extended beta strands. We found that both types of turn structures are stabilized by the aspartic acid-bond isomerization. The isomerization at a terminal position did not affect the helix propensity, but placing it in mid-chain broke both the helix and the beta-pleated sheet with the formation of reverse turns. The alteration of the geometry of the lowest energy reverse turn was also supported by molecular dynamics calculations. The tendency of the aspartic acid-bond isomerization to stabilize turns is very similar to the effect of incorporating sugars into synthetic peptides and suggests a common feature of these post-translational modifications in defining the secondary structure of protein fragments.

Tyrosine- versus serine-phosphorylation leads to conformational changes in a synthetic tau peptide

One of the major immunodominant epitopes of the paired helical filaments (PHF) of Alzheimer's disease is the peptide sequence GAEIVYKSPVVSGD (T3), comprising amino acids 389-402 of the microtubule-associated protein, tau, when it is phosphorylated at the first serine residue. While the corresponding anti-PHF monoclonal antibody recognizes the peptide phosphorylated at either serine, it does not recognize the tyrosine-phosphorylated peptide. Here we describe the effect of serine- versus tyrosine-phosphorylation on the conformation of a synthetic tau peptide. While adding a phosphate to the serine residue has practically no impact on the structure of the non-phosphorylated peptide, phosphorylation of the tyrosine results in considerable conformational changes.

Isotope-edited Fourier transform infrared spectroscopy studies of calmodulin's interaction with its target peptides

The ubiquitous calcium-binding protein calmodulin (CaM) regulates a wide variety of cellular events by binding to and activating many distinct target enzymes. The CaM-binding domains of most of these enzymes are contained in a contiguous stretch of amino acids with a length of approximately 20 residues. In this work, we have used "isotope-edited" Fourier transform infrared spectroscopy to study the interaction of CaM with synthetic peptides resembling the CaM-binding domains of myosin light chain kinase (MLCK), constitutive nitric oxide synthase (cNOS), and caldesmon (CaD). Uniform labeling of CaM with carbon-13 causes the amide I band of the protein to shift approximately 55 cm-1 to lower frequency in D2O, leaving a clear window in the infrared spectrum for observing the amide I band of the unlabeled target peptides. Upon complex formation, the amide I bands of the CaM-binding domains of MLCK and cNOS shift 4 cm-1 toward higher frequency (to approximately 1648 cm-1), and have a narrower bandwidth compared to the peptide in aqueous solution. These spectral changes and the fact that the infrared spectra of these two peptides in their complex with CaM closely resemble those recorded in a mixture of D2O and the helix inducing solvent trifluoroethanol indicate that they bind to CaM in an alpha-helical conformation. The CaM-binding domain of CaD also showed similar, but less dramatic, spectral changes; this is in agreement with the fact that it binds to CaM with lower affinity and a shorter alpha-helix.(ABSTRACT TRUNCATED AT 250 WORDS)

Impact of point mutations on the structure and thermal stability of ribonuclease T1 in aqueous solution probed by Fourier transform infrared spectroscopy

We undertook a detailed comparative analysis of the infrared spectra of wild-type ribonuclease T1 and three mutants: two single mutants, Tyr-45-->Trp (Y45W) and Trp-59-->Tyr (W59Y), and a double mutant, Tyr-45-->Trp/Trp-59-->Tyr (Y45W/W59Y). These mutants were selected because they are known to affect the activity of the enzyme. The structural differences were evaluated by using peptide backbone and side-chain "marker" bands as conformation-sensitive monitors. All mutations lead to a decrease of the thermal transition temperature, though the mutation Tyr-45-->Trp affects the Tm to a lesser degree than the replacement of Trp-59 by Tyr, both in the single (W59Y) and in the double (Y45W/W59Y) mutant. Small changes in the protein backbone conformation and in the microenvironment of certain amino acids, induced by the point mutations, could be detected. In particular, we found subtle differences in the hydrogen bonding pattern of the beta-strands in the mutants W59Y and Y45W/W59Y, compared to that in wild-type RNase T1 and in the mutant Y45W. Practically identical spectra in the amide I region were obtained for the double mutant Y45W/W59Y and the single mutant W59Y, demonstrating that it is the change from Trp to Tyr in position 59 (located at the interface between the alpha-helix and a beta-strand) which affects the overall protein conformation. The mutation Tyr to Trp in position 45, on the other hand, has practically no impact on the polypeptide backbone conformation.(ABSTRACT TRUNCATED AT 250 WORDS)

Zinc chelation and structural stability of adenylate kinase from Bacillus subtilis

Adenylate kinase from Bacillus subtilis, like the enzyme from Bacillus stearothermophilus, contains a structural zinc atom. Cys153 in the enzyme from B. stearothermophilus, which is involved in the zinc coordination, is replaced in the adenylate kinase from B. subtilis by an aspartic acid residue. Therefore, we were interested in establishing whether this difference has an impact on the structure, the metal chelation, and the overall stability of these proteins. We also were interested in determining whether His138, which is conserved in many adenylate kinases, can act as a fourth partner in the metal chelation and, in general, whether His can successfully replace Cys or Asp in coordinating zinc in the adenylate kinase from B. subtilis. The adk gene from B. subtilis was cloned by polymerase chain reaction. The wild-type protein, together with several variants obtained by site-directed mutagenesis, were expressed in Escherichia coli and analyzed by biochemical and physicochemical methods. The H138N and D153C mutants of adenylate kinase from B. subtilis exhibited properties similar to those of the wild-type protein, indicating that His138 is not involved in metal coordination and that Asp153, just like Cys in the analogous position in the enzyme from B. stearothermophilus, can participate in zinc chelation. This is the first experimental evidence indicating that aspartic acid can be involved in the coordination of a structural zinc atom. On the other hand, the D153H and D153T variants showed significant changes in their zinc-binding properties. Dialysis of the latter proteins against buffer (in both the presence and the absence of 2 mM EDTA) resulted in removal of the metal ion and loss of enzymatic activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Synthetic post-translationally modified human A beta peptide exhibits a markedly increased tendency to form beta-pleated sheets in vitro

The beta-amyloid peptide (A beta) is the major constituent of senile plaques, one of the hallmark neuropathological lesions of Alzheimer's disease. Recently a post-translationally modified analogue of the human beta-amyloid peptide, which contains isoaspartic residues in positions 1 and 7, was isolated from parenchyma and leptomeningeal microvasculature of Alzheimer's disease patients [Roher, A. E., Lowenson, JD., Clarke, S., Wolkow, C., Wang, R., Cotter, R. J., Reardon, I. M., Zürcher-Neely, H. A., Heinrikson, R. L., Ball, M. J. & Greenberg, B. D. (1993) J. Biol. Chem. 268, 3072-3083]. We used circular dichroism and Fourier-transform infrared spectroscopy to characterize the conformational changes on human A beta upon substitution of Asp1 and Asp7 to isoaspartic residues. We found that the intermolecular beta-pleated-sheet content is markedly increased for the post-translationally modified peptide compared to that in the corresponding unmodified human or rodent A beta sequences both in aqueous solutions in the pH 7-12 range, and in membrane-mimicking solvents (such as aqueous octyl-beta-D-glucoside or aqueous acetonitrile solutions). These findings underline the importance of the originally alpha-helical N-terminal regions of the unmodified A beta peptides in defining its secondary structure and may offer an explanation for the selective aggregation and retention of the isomerized A beta peptide in Alzheimer's-disease-affected brains.

Structural and physico-chemical characteristics of Bordetella pertussis adenylate kinase, a tryptophan-containing enzyme

The adk gene from the Gram-negative pathogen Bordetella pertussis was cloned by complementing the thermosensitive Escherichia coli adk strain CR341T28. B. pertussis adenylate kinase is a 218-amino-acid protein that has high similarity with adenylate kinase from Escherichia coli and Hemophilus influenzae (57%). A distinct characteristic of enzyme from B. pertussis, not found in other bacterial adenylate kinases, is the presence of a tryptophan residue at position 185. Although distant from the catalytic site, this single tryptophan serves as a convenient probe for monitoring the binding of nucleotide substrates or analogs to the enzyme. Differential scanning calorimetry and equilibrium unfolding experiments in guanidine.HCl indicate similar stabilities for adenylate kinase from B. pertussis and E. coli. An extensive comparison between physico-chemical properties of adenylate kinase from B. pertussis and the enzyme from E. coli showed that the kinetic and structural properties of the two enzymes are very similar. However, infrared spectroscopy has allowed to identify small but significant differences in the secondary structure of the two proteins.

Secondary structure and temperature-induced unfolding and refolding of ribonuclease T1 in aqueous solution. A Fourier transform infrared spectroscopic study

The secondary structure of ribonuclease T1 (RNase T1) in aqueous solution and its temperature-induced structural changes have been investigated by Fourier-transform infrared (FT-IR) spectroscopy. 13 to 14% alpha-helix and 32 to 33% beta-sheet were estimated from the resolution-enhanced FT-IR spectra, in agreement with the crystal structure which indicates 16% alpha-helix and 35% beta-sheet. Specific IR-marker bands are assigned to the different beta-sheet structures, to the slightly bent alpha-helix, and to beta-turn and irregular conformations present in RNase T1. The temperature dependence of the infrared spectra shows that the thermal unfolding and refolding of RNase T1 is fully reversible. This permitted the detailed analysis of structural changes that occur as a function of temperature by evaluating quantitatively the various secondary structure-related amide I band components and some amino acid side-chain vibrations as specific monitors. The secondary structure of RNase T1 is essentially retained in the temperature range between 20 and 50 degrees C. Significant perturbation of protein structure is initiated between 50 and 55 degrees C within regions of beta-sheet structures while the alpha-helix remains virtually intact up to 55 degrees C suggesting a "premelting" of RNase T1. Between 55 and 60 degrees C, a highly co-operative unfolding process is indicated by the simultaneous breakdown of all secondary structure components and by distinct changes of some specific side-chain vibrations. An analysis of the amide I band contour of RNase T1 at 70 degrees C proves that the unfolded state is predominantly, but not completely, irregular or "random coil". Residual, turn-like structures persisting even in the unfolded state are suggested by minor, turn related band components in the amide I region. From IR-spectra collected along a linear temperature gradient, intensity/temperature and frequency/temperature profiles were constructed using some peptide backbone and amino acid side-chain marker bands as local, structure-sensitive monitors. From these profiles individual transition temperatures tm and transition enthalpies delta H (van't Hoff) were calculated. The tm and delta H values revealed a small but distinct hysteresis between repetitive cycles of unfolding and refolding of the protein, suggesting slow refolding kinetics of RNase T1. Furthermore, the various infrared "marker bands" indicate a slightly different response towards temperature increase/decrease for different regions of the protein. The data demonstrate that infrared spectroscopy permits both the detailed analysis of structural changes occurring in a protein as a function of temperature and the determination of thermodynamic parameters characterizing its folded/unfolded state transition.

Comparative analysis of human and Dutch-type Alzheimer beta-amyloid peptides by infrared spectroscopy and circular dichroism

The 42 amino acid beta A4 peptide is the major constituent of the senile plaques, one of the hallmark neuropathological lesions of Alzheimer's disease. While C-terminally truncated variants were shown to be present in normal body fluids, a single Glu-->Gln change in the 39 amino acid form of beta A4 results in accelerated fibril formation in the brains of patients with Dutch-type hereditary cerebral hemorrhage with amyloidosis. In this study we used Fourier-transform infrared and circular dichroism spectroscopies on synthetic peptides to demonstrate that this mutation results in altered secondary structure in membrane mimicking solvents, characterized by a considerably higher beta-structure content for the mutant peptide. Moreover, extreme high and low pH were less effective in eliminating the beta-conformation for the Dutch-variant than for the normal human sequence.

Conformation of d(GGGATCCC)2 in crystals and in solution studied by X-ray diffraction, Raman spectroscopy and molecular modelling

In the crystal, d(GGGATCCC)2 forms an A-DNA double helix as known from a single crystal X-ray diffraction study. Accordingly, in the Raman spectra of crystals the A-family marker bands at 664, 705, 807 and 1101 cm-1 and the spectral characteristics in the region 1200 to 1500 cm-1 clearly demonstrate the A-form as the dominant conformation. Bands at 691, 850, and 1080 cm-1, however, indicate that a minor fraction of the octamer molecules in the crystal is in an unusual, still not unequivocally identified conformation possibly belonging to the B-family. In solution, the octamer is in B-like conformation as shown by the presence of B-DNA Raman marker bands at 685, 837, 1094 and 1421 cm-1. Molecular modelling techniques lead to three structures with slightly different B-form geometries as the lowest energies models when a sigmoidal dielectric function with the bulk dielectric constant epsilon = 78 and the value q = -0.5e for the effective phosphate charges was used in the calculations. An A-form structure bearing a strong resemblance to the experimentally determined crystal structure becomes the lowest energy model structure when the electrostatic parameters are changed to epsilon = 30 and q = -0.25e, respectively.

Secondary structure of streptokinase in aqueous solution: a Fourier transform infrared spectroscopic study

The secondary structure of streptokinase (Sk) in aqueous solution was quantitatively examined by using Fourier transform infrared (FT-IR) spectroscopy. Resolution enhancement techniques, including Fourier deconvolution and derivative spectroscopy, were combined with band curve-fitting procedures to quantitate the spectral information from the amide I bands. Nine component bands were found under the broad, nearly featureless amide I bands which reflect the presence of various substructures. The relative areas of these component bands indicate an amount of beta-sheet between 30 and 37% and an alpha-helix content of only 12-13% in Sk. Further conformational substructures are assigned to turns (25-26%) and to "random" structures (15-16%). Additionally, the correlation of a pronounced component band near 1640 cm-1 (10-16% fractional area) with the possible presence of 3(10)-helices is discussed.

Limited proteolysis of streptokinase and properties of some fragments

Limited proteolysis of streptokinase (Sk) by trypsin and thermolysin was performed under various incubation conditions and analysed by polyacrylamide gel electrophoresis. Several fragments (Sk1, Tr27, Tr17, Th26, and Th16) were isolated and characterized further. The N-terminal sequences of Tr27, Tr17, Th26, Th16 and the C-terminal sequences of Tr27 and Th26 were determined by partial sequencing. The evidence available allows the positioning of these fragments within the Sk sequence. Fragment Sk1 is obtained by carefully standardized tryptic digestion of Sk and gel chromatography under non-denaturing conditions. Sk1 is formed by a large polypeptide Ser60-Lys293 and non-covalently bonded smaller polypeptides composed of amino acids from the N-terminal region Ile1-Lys59 of Sk. Fragment Tr27 consists of the large polypeptide Ser60-Lys293 of Sk1, and can be obtained from Sk1 by removal of the smaller N-terminal polypeptides under denaturing conditions. Fragment Th26 is composed of amino acids Phe63-His291. The N-termini of fragments Tr17 and Th16 start with Glu148 and Ile151. From their electrophoretically-determined sizes it can be concluded that they most probably have the same C-terminal amino acids, Lys293 and His291, as fragments Tr27 and Th26, respectively. Secondary structure elements of similar composition were found in all the fragments studied using circular dichroism (c.d.) and infrared (i.r.) measurements. Differential scanning calorimetric (d.s.c.) measurements were performed in order to correlate the sequence regions of Sk to energetic folding units of the protein. Fragments Sk1, Tr27, Th26, Tr17, and Th16 show one melting peak in the temperature range from 42.8 to 46.1 degrees C (thermal unfolding stage). For fragment Sk1, this melting peak can be separated by deconvolution into two transitions at T1 = 46.1 degree C and T2 = 47.3 degrees C with delta H1 = 450 kJ/mol and delta H2 = 219 kJ/mol, respectively. Fragments Tr17 and Th16 show one two-state transition at T = 42.8 degrees C with delta H = 326 kJ/mol.

Conformational properties of streptokinase--secondary structure and localization of aromatic amino acids

The conformational properties of streptokinase (Sk) have been assessed by several spectroscopic techniques. A solvent accessibility of about 70% of the 22 Tyr residues was found by u.v. perturbation spectroscopy. Fluorescence spectroscopy indicates also the surface localization of the single Trp 6 residue. Circular dichroism (c.d.), infrared (i.r.), and Raman spectra were analysed in order to estimate the contents of secondary structure elements of Sk. Values in the range of 14-23% alpha-helices, 38-46% beta-structures, 10-30% turns and 12-23% residual structures were found. The characteristics of the c.d. spectrum support the classification of Sk as an alpha + beta protein. Effects of temperature, pH, and denaturants were studied by c.d. spectroscopy, and on spin-labelled Sk, by e.p.r. spectroscopy. Structural effects were induced at temperatures above 40 degrees C, pH values below 3.0 and urea concentrations above 2 M. At temperatures above 70 degrees C, at pH 2.1, and at urea and Gu.HCl concentrations of 7 M and 5 M, respectively, no further structural changes are revealed in the spectra. At temperatures around 50 degrees C, at pH 3.0, and denaturant concentrations of about 1 M Gu.HCl and 1 M to 2 M urea, c.d. effects were observed in the near-u.v. region indicating an increase in the asymmetry for aromatic amino acids in comparison with the structure of Sk in low ionic strength buffers at neutral pH, 20 degrees C and in the absence of denaturants. These effects were most pronounced for the temperature dependence of the c.d. spectra. E.p.r. spectroscopy has shown that loosening of the protein surrounding of the spin label already begins at 1 M urea and that the mobility of the spin label points to a structural change in Sk at 46 degrees C.

Transient 210-nm absorption in fused silica induced by high-power UV laser irradiation

Synthetic fused silica, exposed to high-power KrF excimer laser irradiation, shows the well-known induced absorption at 210 nm owing to E' center generation. Time-resolved absorption spectroscopy reveals that this induced absorption is transient in nature. The generation rate of E' centers depends strongly on the irradiation history, the OH content, and previous high-temperature processes. In order to explain the experimental observations, a nonabsorbing state of theE' center is postulated. The recovery of the induced optical absorption in high-OH fused silica is explained as a conversion from E' centers to these nonabsorbing centers.

Conserved unpaired adenine residues are important for ordered structures of 5S ribosomal RNA. An infrared study of the secondary and tertiary structure of Thermus thermophilus 5S rRNA

An improved set of infrared calibration spectra for the determination of G X C and A X U base pairs leads to 32 +/- 3 G X C (+ G X U) and 4 +/- 1 A X U base pairs for Thermus thermophilus 5S RNA in the presence and absence of Mg2+. These results give further support for the consensus secondary structure of 5S RNA recently proposed by several groups. T. thermophilus 5S RNA shows, in the presence of Mg2+, a distinct two-step thermal melting of its ordered structure. Based on new data about the stacking dependence of infrared intensities of unpaired ribonucleotides the spectral changes of the low-temperature transition should be explained by melting of stacked arrangements of unpaired bases and/or non-standard base pairs. Striking is the reduction in A stacking, which is not related to the melting of A X U base pairs, indicating the importance of the mostly conserved unpaired adenines for the Mg2+ stabilized higher-order structures especially within internal loops of 5S RNA.