Conformational stability of ribonuclease T1. I. Thermal denaturation and effects of salts.

The thermal transition of RNase T1 was studied by two different methods; tryptophan residue fluorescence and circular dichroism. The fluorescence measurements provide information about the environment of the indole group and CD measurements on the gross conformation of the polypeptide chain. Both measurements at pH 5 gave the same transition temperature of 56 degrees C and the same thermodynamic quantities, delta Htr (= 120 kcal/mol) and delta Str (= 360 eu/mol), for the transition from the native state to the thermally denatured state, indicating simultaneous melting of the whole molecule including the hydrophobic region where the tryptophan residue is buried. Stabilization by salts was observed in the pH range from 2 to 10, since the presence of 0.5 m NaCL caused an increase of about 5 degrees C to 10 degrees C in the transition temperature, depending on the pH. The fluorescence measurements on the RNase T1 complexed with 2'-GMP showed a transition with delta Htr =167 kcal/mol and delta Str =497 eu/mol at a transition temperature about 6 degrees C higher than that for the free enzyme. The large value of delta Htr for RNase T1 indicates the highly cooperative nature of the thermal transition; this value is much higher than those of other globular proteins. Analysis of the CD spectrum of thermally denatured RNase T1 suggests that the denatured state is not completely random but retains some ordered structures.     

Atomic mutations at the single tryptophan residue of human recombinant annexin V: effects on structure, stability, and activity.

The single tryptophan residue (Trp187) of human recombinant annexin V, containing 320 residues and 5328 atoms, was replaced with three different isosteric analogues where hydrogen atoms at positions 4, 5, and 6 in the indole ring were exchanged with fluorine. Such single atom exchanges of H --> F represent atomic mutations that result in slightly increased covalent bond lengths and inverted polarities in the residue side-chain structure. These minimal changes in the local geometry do not affect the secondary and tertiary structures of the mutants, which were identical to those of wild-type protein in the crystal form. But the mutants exhibit significant differences in stability, folding cooperativity, biological activity, and fluorescence properties if compared to the wild-type protein. These rather large global effects, resulting from the minimal local changes, have to be attributed either to the relatively strong changes in polar interactions of the indole ring or to differences in the van der Waals radii or to a combination of both facts. The changes in local geometry that are below resolution of protein X-ray crystallographic studies are probably of secondary importance in comparison to the strong electronegativity introduced by the fluorine atom. Correspondingly, these types of mutations provide an interesting approach to study cooperative functions of integrated residues and modulation of particular physicochemical properties, in the present case of electronegativity, in a uniquely structured and hierarchically organized protein molecule.     

The effect of medium on functional and structural properties of serum albumins. II. The effect of temperature on the N-form of human serum albumin

In order to investigate effects of temperature in the physiological range (from 10 to 50 degrees C) on structural, physical and functional properties of the N-form of human serum albumin (HSA), the temperature dependences of fluorescence parameters of Trp-214 residue of HSA and of the specifically bound dye ANS, as well as of association constants of ANS binding in the primary and secondary binding sites on HSA molecule were measured. The temperature-induced changes of these properties of HSA are essentially dependent on pH (7.0 or 5,6) and ionic strength (0.001-0.008 or 0.2 M NaCl). At pH 7.0 and 0.2 M NaCl the environment of Trp-214 remained invariant at temperature changes between 10 and 50 degrees C. On the other hand, the affinity to ANS of a primary binding site doubled and that of secondary ones halved. These affinity changes seem to be due, are least partly, to the heating-induced dissociation of Cl-ions, which are inhibitors of the primary dye binding. By lowering pH (to 5.6) and ionic strength the temperature-induced changes in the Trp-214 environment were observed. The changes are interpreted as indole group transition into the buried region, inaccesible to water (the "closing" of a structural slit). The affinity of secondary binding sites of ANS was halved.     

Ozonization of the tryptophyl residue in tryptophanase.

Tryptophanase of Escherichia coli was inactivated by ozonization in aqueous solution in a time-dependent fashion following pseudo-first order kinetics. Upon ozonization of the apoenzyme, the absorption peak of the tryptophyl residue at 280 nm gradually decreased concomitant with an appearance of a new peak at 320 nm indicating conversion of the tryptophyl residue to N′-formylkynurenine. The spectrophotometric titration of the coenzyme binding to the enzyme protein at 430 nm indicated that the dissociation constant for the coenzyme was almost 100 times increased upon ozonization presumably by weakening the interaction between the coenzyme and the indole moiety of the tryptophyl residue in the enzyme protein.     

A thermodynamic-kinetic analysis of the cytochrome P-450 heme pocket.

Spin state changes in the iron center of cytochrome P-450 during the catalytic cycle suggest alterations in the heme environment that insure proper substrate binding, an increase in redox potential, the formation of an active Fe-O complex, and the attack on the substrate. We used the spin state changes of the iron following physico-chemical perturbations, as an intrinsic probe of discrete changes around the heme, or of larger ones in the protein conformation. These environmental perturbations included temperature, solvent, substrate, and ionic environment. Aqueous and hydro-organic buffers provide complementary data and interpretations; the mixed solvent accommodates temperatures suitable for direct reaction rate measurements and amplified low to high spin transition. The results suggest that the group determining the heme spin state is influenced by the electrostatic potential created by several negative charges near the heme; the modulation of the spin state by various factors reflects the modulation of the electrostatic potential and of the internal paH value. Conformational changes of the whole protein are also indicated by the large entropy terms and their variation with experimental conditions.     

Secondary structure formation is the earliest structural event in the refolding of an all beta-sheet protein.

The refolding kinetics of cobrotoxin (CBTX), a small-molecular-weight ( approximately 7 kDa) all beta-sheet protein, has been monitored using a variety of biophysical techniques. The secondary structure formation and hydrophobic collapse occur as distinct events during the refolding of the protein. Complete secondary structure formation occurs prior to the clustering of the hydrophobic residues. The late stage(s) of the refolding pathway of CBTX is characterized by change(s) in the local environment and optical asymmetry of the indole ring of the sole tryptophan residue. The results obtained in the present study, to our knowledge, represent the first unambiguous experimental support for the framework model of protein folding.     

Energetics of charge-charge interactions between residues adjacent in sequence

Statistical analysis of the residue separation between a pair of ionizable side chains within 4 ? of each other was performed on a set of 1560 non-homologous PDB structures. We found that the frequency of pairs of like charges (i.e., pairs consisting of acidic residues Asp and Glu or pairs consisting of basic residues Arg and Lys) is two orders of magnitude lower than the pairs of oppositely charged residues (salt-bridges). We also found that for pairs of like charges the distribution is skewed dramatically towards short residue separation (<3). On the basis of these observations, we hypothesize that at short residue separation the repulsion between charges does not contribute much to the protein stability and the effects are largely dominated by the long range charge-charge interactions with other ionizable groups in the protein molecule. To test this hypothesis, we incorporated various pairs of charged residues at position 63 and 64 of ubiquitin and compared the stabilities of these variants. We also performed calculations of the expected changes in the charge-charge interactions. A very good correlation between experimental changes in the stability of ubiquitin variants, and changes in the energy of charge-charge interactions provides support for the hypothesis that a pair of ionizable residues next to each other in sequence modulates protein stability via long range charge-charge interactions with the rest of the protein.     

The effect of viscosity on the accessibility of the single tryptophan in human serum albumin.

When reactions take place with one of the reactants tied to protein matrix, movements along the reaction coordinate towards the transition state can become coupled to structural fluctuations of the protein matrix. This investigation aims to test the assumptions underlying the arguments supporting such a coupling. A coupling is allowed only if the activation barrier is high and broad enough as shown to be the case for the proton catalyzed isotope exchange at Trp-63 of lysozyme. In the present investigation the activation barrier for the same reaction has been lowered radically in an effort to show that the coupling, as measured by the dependence of rate on solution viscosity, will diminish and ideally vanish, despite the unchanged effects of cosolvents on the chemical activities of all the reactants. The isotope exchange rate at the indole nitrogen of the single tryptophan residue of human serum albumin was measured with UV. This residue is rigidly held to the protein surface and the solvent access, although restricted, corresponds to a partially exposed residue. As a consequence, the isotope exchange rates and the bimolecular quenching rate of fluorescence by acrylamide, also measured, are high. The experiments were carried out at pH 5.2 where the molecule is in the N-form and the exchange is catalyzed by OH- ions. The activation energy of the hydroxyl catalyzed reaction is 22 kJ lower than for the proton catalyzed process. Under these conditions the exchange rate is viscosity independent both in the case of glycerol and in ethylene glycol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electrostatic effects of charge perturbations introduced by metal oxidation in proteins. A theoretical analysis

A macroscopic dielectric model for the interactions between charges in proteins is used to calculate the changes in His residue pKa values induced in azurin by oxidation of the copper. The calculated results agree with nuclear magnetic resonance experiments to within the uncertainty associated with the measurements. It is found that a large apparent dielectric constant can describe the interaction between two protein groups, even if the shortest path between them is through the protein, which is assumed to have a low dielectric constant.     

Exposure of tryptophanyl residues in proteins. Quantitative determination by fluorescence quenching studies.

Acrylamide is an efficient quencher of tryptophanyl fluorescence which we report to be very discriminating in sensing the degree of exposure of this residue in proteins. The quenching reaction involves physical contact between the quencher and an excited indole ring, and can be kinetically described in terms of a collisional and a static component. The rate constant for the collisional component is a kinetic measure of the exposure of a residue in a protein, and values ranging from 4 X 10(9) M-1 S-1 for the fully exposed tryptophan in the polypeptide, adrenocorticotropin, to less than 5 X 10(8) M-1 S-1 for the buried residue in azurin have been found. Static quenching is readily detected in proteins that are denatured, or contain only a single fluorophor. Quenching patterns for most multi-tryptophan containing proteins are difficult to analyze precisely, but qualitative information can, nevertheless, be extracted. Applications of this probing technique for monitoring protein conformational changes, such as the acid-induced expansion of human serum albumin, and inhibitor binding to enzymes, are presented. The value of this method lies in its ability to sense not only the steady-state exposure of a residue in a protein, but also its dynamic exposure.     

The interaction of the trp repressor from Escherichia coli with L-tryptophan and indole propanoic acid

The binding of the corepressor, L-tryptophan, and an inducer, indole propanoic acid, to the trp repressor from Escherichia coli was studied by absorbance, fluorescence, circular dichroic and proton NMR spectroscopy. The two ligands bind to the same site on the repressor in the same orientation; they are molecular competitors. The binding site is of relatively low polarity and contains at least one methyl group that lies 0.3 nm over the indole moiety near the C5 proton of the bound ligand, and an aromatic residue, probably tyrosine. The dissociation constant was determined as a function of temperature and pH. At 25 degrees C in 0.1 M phosphate buffer, pH 7.6, the dissociation constant is 18 +/- 2 microM for both ligands. In the same buffer system, the van't Hoff enthalpy for dissociation is 35.5 +/- 1 kJ/mol for tryptophan, and 30.5 +/- 2 kJ/mol for indole propanoic acid. The affinity of the repressor for indole propanoic acid is independent of pH in the range 7 less than 10, but decreases four fold for tryptophan in the same range. The amino group of tryptophan makes a significant contribution to its binding affinity. Difference NMR spectra showed that there are few changes of protein resonances on binding ligands. The NMR signals of the bound resonances were assigned by difference and nuclear Overhauser effect spectroscopy. The properties of the bound resonances are consistent with the ligands being largely immobilised within the binding site. The difference spectra, and the known functional differences of the two ligands, suggest that tryptophan induces a slightly different conformational state in the repressor from that induced by indole propanoic acid. There is no evidence for a global transition. The rate of dissociation of ligands is relatively large, being in the range 400-600 s-1.     

Substrate-dependent transport mechanism in AcrB of multidrug resistant bacteria

The multidrug resistance (MDR) system effectively expels antibiotics out of bacteria causing serious issues during bacterial infection. In addition to drug, indole, a common metabolic waste of bacteria, is expelled by MDR system of gram-negative bacteria for their survival. Experimental results suggest that AcrB, one of the key components of MDR system, undergoes large scale conformation changes during the pumping due to proton-motive process. However, due to extremely short time scale, it is difficult to observe (experimentally) those changes in the AcrB, which might facilitate the pumping process. Molecular simulations can shed light to understand the conformational changes for transport of indole in AcrB. Examination of conformational changes using all-atom simulation is, however, impractical. Here, we develop a hybrid coarse-grained force field to study the conformational changes of AcrB in presence of indole in the porter domain of monomer II. Using the coarse-grained force field, we investigated the conformational changes of AcrB for a number of model systems considering the effect of protonation in aspartic acid (Asp) residues Asp407 and Asp408 in the transmembrane domain of monomer II. Our results show that in the presence of indole, protonation of Asp408 or Asp407 residue causes conformational changes from binding state to extrusion state in monomer II, while remaining two monomers (I and III) approach access state in AcrB protein. We also observed that all three AcrB monomers prefer to go back to access state in the absence of indole. Steered molecular dynamics simulations were performed to demonstrate the feasibility of indole transport mechanism for protonated systems. Identification of indole transport pathway through AcrB can be very helpful in understanding the drug efflux mechanism used by the MDR bacteria.     

Tryptophan phosphorescence studies of the D-galactose/D-glucose-binding protein from Escherichia coli provide a molecular portrait with structural and dynamics features of the protein

The D-galactose/D-glucose-binding protein (GGBP) from E. coli serves as an initial component for both chemotaxis toward glucose and high-affinity active transport of the sugar. In this work, we have used phosphorescence spectroscopy to investigate the effects of glucose and calcium on the dynamics and stability of GGBP. We found that GGBP exhibits a phosphorescence spectrum composed of two energetically distinct 0,0-vibrational bands centered at 404.43 and 409.61 nm; the large energy separation between them indicates two classes of chromophores making distinct dipolar interactions with their surrounding. Interestingly, the high-energy spectral component (404.43 nm) is one of the bluest spectra reported to date in proteins. Considering the ground state dipole direction, low-energy configurations for the indole side chain in proteins leading to blue-shifted spectra can arise from negative charges in proximity to the imidazole-ring nitrogen and/or positive charges near C4-C5 of the benzene ring. Among the five tryptophan residues of GGBP, Trp-284, located at the N-terminal domain of the protein, and Trp-183, located in the protein hinge region, make strong attractive charge interactions with surrounding side chains. Regarding Trp-284, the indole ring nitrogen is in contact with the negative charge of the Asp-267, whereas Trp-183 is next to the Glu-149 residue. In the latter, the ground state energy is further lowered by the proximity of the Arg-158 to the negative end (near C6) of the indole dipole. Regarding the red spectral component (409.61 nm), it is more intense than the blue component, presumably because more residues contribute to it. lambda 0,0 is typical of environments that are weakly polar or characterized by charges positioned near 90 degrees from the ground state dipole direction (the case of W195 and W127). The binding of glucose modifies the phosphorescence lifetime values as well as the spectrum of GGBP, shifting the blue band 0.54 nm to the blue and the red band 1 nm to the red. Finally, the removal of the calcium from GGBP structure causes variations in lifetime values and spectral shifts similar to those induced by glucose binding to the native protein. Aided by a detailed inspection of the three-dimensional structure of GGBP, these results contribute to a better understanding of the structure/function relationship of this protein.     

Molecular orbital study on the interaction between coenzymes and enzymes; NAD+ or NADH and dehydrogenases

The absorption band at 260 mμ of NAD⁺ shifts to 360 mg by interaction with GAPDH or its analogues. Two explanations have been given on this red shift; one is an addition of such nucleophilic residue as sulfhydryl group in the enzyme to the position four in nicotinamide nucleus of NAD⁺, and the other is the charge transfer from such aromatic amino acid as tryptophan to NAD⁺. In the present paper, possibility of the charge transfer from indole residue to NAD⁺ was investigated quantum chemically. Taking into account of the electric field due to the charges in the enzyme, the absorption band of the NAD⁺-enzyme complex at 360 mμ was explained as a charge transfer from indole nucleus to NAD⁺. The blue shift of the absorption band of NADH at 340 mμ was also explained by taking into account of the electric field and this supported the proposition of Kosower (1962a).Stacking of adenine nucleus with indole nucleus in the NAD⁺-enzyme complex was suggested from the NMR spectroscopic data. Our molecular orbital calculations predicted that the effects of adenine on spectral shifts were not significant.     

Molecular dynamics of tryptophan in ribonuclease-T1. II. Correlations with fluorescence.

The interactions of tryptophan-59 (TRP-59) and its protein environment in ribonuclease-T1 (RNAse-T1) were examined in a 50-ps molecular dynamics simulation. The simulation used was previously shown to demonstrate a fluorescence anisotropy decay that closely agreed with the experimentally determined limiting anisotropy for RNAse-T1 (Axelsen, P. H., C. Haydock, and F. G. Prendergast. 1988. Biophys. J. 54:249-258). Further characterization of TRP-59 side chain dynamics and its protein environment has now been completed and correlated to other photophysical properties of this protein. Angular fluctuations of the side chain occur at rates of 1-10 cycles/ps and are limited to +/- 0.3 radians in all directions. Side chain motions are primarily limited by nonpolar collisions, although most side chain atoms have some collisional contact with polar atoms in the adjacent protein matrix or water. The steric relationship between PRO-39 and TRP-59 changes abruptly at 16 ps into the simulation. Two types of interaction with water are observed. First, a structural water appears to H-bond with the greater than N-H group of TRP-59. Second, water frequently contacts the six-atom ring. The electrostatic field experienced by the TRP-59 rings appears to be relatively constant and featureless regardless of ring orientation. We make the following interferences from our data: The fluorescent emission of TRP-59 may be red-shifted relative to TRP in nonpolar solvents either as a result of specific interactions with the structural water or relaxations of proximal bulk water and polar protein moieties. The quenching efficiency of polar interactions with TRP-59 must be extremely low given their frequency and the high quantum yield of RNAse-T1. This low efficiency may be due to restricted and unfavorable interaction geometries. PRO-39 is located near two titratable HIS residues in RNAse-T1 and may be involved in pH-dependent fluorescence phenomena by virtue of a metastable interaction with TRP-59. The interaction of bulk water with TRP-59 illustrates features of the gated transition state model for transient exposure to exogenously added collisional quenching agents. The restrictive environment of TRP-59 suggests that extrinsic quenching can only occur via interactions with the edge of the indole six-atom ring and that the efficiency of a quencher in a protein environment is likely to be a function of molecular symmetry.     

Characterization of the indole triplet excited state in proteins utilizing laser flash photolysis

The triplet-triplet absorption spectrum of the sole indole side chain of human serum albumin and its decay kinetics were previously characterized, at room temperature, by using a conventional flash photolysis method [(1978) Proc. Natl. Acad. Sci. USA 75, 1172-1175]. Exploitation of this potentially useful long lived reporter group in protein studies was limited by the excessively large sample size required by that apparatus. The 265 nm laser flash instrument used in the present work avoids this problem at the price of a loss in photo-selectivity. We report that the latter concern can be mitigated. Melittin was studied first because this polypeptide contains a single aromatic residue (W-19), and because its monomeric and tetrameric forms are good models for solvent exposed and buried indole side chains of proteins. For both forms, the indole triplet and neutral radical absorption spectra could be readily time resolved and identified on the basis of shape and differential dioxygen sensitivity. The single tryptophan containing protein human serum albumin was studied next because it contains a large number of other 265 nm absorbing moieties whose transient spectra might complicate the detection of the indole triplet. These transients were shown to not interfere significantly in the wavelength region 450 nm to 600 nm, and, in contrast to the indole triplet, they were relatively dioxygen insensitive. Thus, a facile means is available by which the indole triplet of proteins may be characterized. Subsequently the question of whether this species could be detected in the presence of nuclei acid components was investigated by flashing the phage fd. The putative nucleic acid transients were shown not to interfere and the absorbance of the indole triplet was readily time resolved. The spectral assignment was persuasively confirmed by showing that the indole triplet absorption and phosphorescence emission spectra decay with the same lifetime. The present work thus provides additional evidence for the general applicability of the indole triplet excited state as a long lived intrinsic protein reporter group.     

Tryptophanyl substitutions in apomyoglobin affect conformation and dynamic properties of AGH subdomain

The solvent accessibilities to the tryptophanyl microenvironments of wild type sperm whale apomyoglobin (apoMb) and two mutants (W7F and W14F) containing a single tryptophan are measured by fluorescence quenching studies. The results are compared to those relative to horse apoMb. In the wild type sperm whale protein, no difference is noticed in the solvent accessibility of the two indole residues, as documented by the values of the Stern-Volmer constants. By contrast, the two tryptophan residues of horse apoMb are exposed to the solvent in a different way, thus indicating that some local conformational differences exist between the two homologous proteins in solution. The single W --> F substitution at either position 7 or 14 determines local conformational changes that increase the accessibility of the remaining indole residue but do not affect the overall architecture of the protein molecule.     

Shaker potassium channel gating. II: Transitions in the activation pathway

Voltage-dependent gating behavior of Shaker potassium channels without N-type inactivation (ShB delta 6-46) expressed in Xenopus oocytes was studied. The voltage dependence of the steady-state open probability indicated that the activation process involves the movement of the equivalent of 12-16 electronic charges across the membrane. The sigmoidal kinetics of the activation process, which is maintained at depolarized voltages up to at least +100 mV indicate the presence of at least five sequential conformational changes before opening. The voltage dependence of the gating charge movement suggested that each elementary transition involves 3.5 electronic charges. The voltage dependence of the forward opening rate, as estimated by the single- channel first latency distribution, the final phase of the macroscopic ionic current activation, the ionic current reactivation and the ON gating current time course, showed movement of the equivalent of 0.3 to 0.5 electronic charges were associated with a large number of the activation transitions. The equivalent charge movement of 1.1 electronic charges was associated with the closing conformational change. The results were generally consistent with models involving a number of independent and identical transitions with a major exception that the first closing transition is slower than expected as indicated by tail current and OFF gating charge measurements.     

Combining conformational flexibility and continuum electrostatics for calculating pK(a)s in proteins

Protein stability and function relies on residues being in their appropriate ionization states at physiological pH. In situ residue pK(a)s also provides a sensitive measure of the local protein environment. Multiconformation continuum electrostatics (MCCE) combines continuum electrostatics and molecular mechanics force fields in Monte Carlo sampling to simultaneously calculate side chain ionization and conformation. The response of protein to charges is incorporated both in the protein dielectric constant (epsilon(prot)) of four and by explicit conformational changes. The pK(a) of 166 residues in 12 proteins was determined. The root mean square error is 0.83 pH units, and >90% have errors of <1 pH units whereas only 3% have errors >2 pH units. Similar results are found with crystal and solution structures, showing that the method's explicit conformational sampling reduces sensitivity to the initial structure. The outcome also changes little with protein dielectric constant (epsilon(prot) 4-20). Multiconformation continuum electrostatics titrations show coupling of conformational flexibility and changes in ionization state. Examples are provided where ionizable side chain position (protein G), Asn orientation (lysozyme), His tautomer distribution (RNase A), and phosphate ion binding (RNase A and H) change with pH. Disallowing these motions changes the calculated pK(a).     

Protein in sugar films and in glycerol/water as examined by infrared spectroscopy and by the fluorescence and phosphorescence of tryptophan

Sugars are known to stabilize proteins. This study addresses questions of the nature of sugar and proteins incorporated in solid sugar films. Infrared (IR) and Raman spectroscopy was used to examine trehalose and sucrose films and glycerol/water solvent. Proteins and indole-containing compounds that are imbedded in the sugar films were studied by IR and optical (absorption, fluorescence, and phosphorescence) spectroscopy. Water is able to move in the sugar films in the temperature range of 20-300 K as suggested by IR absorption bands of HOH bending and OH stretching modes that shift continuously with temperature. In glycerol/water these bands reflect the glass transition at approximately 160 K. The fluorescence of N-acetyl-L-tryptophanamide and tryptophan of melittin, Ca-free parvalbumin, and staphylococcal nuclease in dry trehalose/sucrose films remains broad and red-shifted over a temperature excursion of 20-300 K. In contrast, the fluorescence of these compounds in glycerol/water solvent shift to the blue as temperature decreases. The fluorescence of the buried tryptophan in Ca-bound parvalbumin in either sugar film or glycerol/water remains blue-shifted and has vibronic resolution over the entire temperature range. The red shift for fluorescence of indole groups exposed to solvent in the sugars is consistent with the motion of water molecules around the excited-state molecule that occurs even at low temperature, although the possibility of static complex formation between the excited-state molecule and water or other factors is discussed. The phosphorescence yield for protein and model indole compounds is sensitive to the matrix glass transition. Phosphorescence emission spectra are resolved and shift little in different solvents or temperature, as predicted by the small dipole moment of the excited triplet state molecule. The conclusion is that the sugar film maintains the environment present at the glass formation temperature for surface Trp and amide groups over a wide temperature excursion. In glycerol/water these groups reflect local changes in the environment as temperature changes.