Secondary structures comparison of aquaporin-1 and bacteriorhodopsin: a Fourier transform infrared spectroscopy study of two-dimensional membrane crystals.

Aquaporins are integral membrane proteins found in diverse animal and plant tissues that mediate the permeability of plasma membranes to water molecules. Projection maps of two-dimensional crystals of aquaporin-1 (AQP1) reconstituted in lipid membranes suggested the presence of six to eight transmembrane helices in the protein. However, data from other sequence and spectroscopic analyses indicate that this protein may adopt a porin-like beta-barrel fold. In this paper, we use Fourier transform infrared spectroscopy to characterize the secondary structure of highly purified native and proteolyzed AQP1 reconstituted in membrane crystalline arrays and compare it to bacteriorhodopsin. For this analysis the fractional secondary structure contents have been determined by using several different algorithms. In addition, a neural network-based evaluation of the Fourier transform infrared spectra in terms of numbers of secondary structure segments and their interconnections [sij] has been performed. The following conclusions were reached: 1) AQP1 is a highly helical protein (42-48% alpha-helix) with little or no beta-sheet content. 2) The alpha-helices have a transmembrane orientation, but are more tilted (21 degrees or 27 degrees, depending on the considered refractive index) than the bacteriorhodopsin helices. 3) The helices in AQP1 undergo limited hydrogen/deuterium exchange and thus are not readily accessible to solvent. Our data support the AQP1 structural model derived from sequence prediction and epitope insertion experiments: AQP1 is a protein with at least six closely associated alpha-helices that span the lipid membrane.     

The thermophilic esterase from Archaeoglobus fulgidus: structure and conformational dynamics at high temperature

The esterase from the hyperthermophilic archaeon Archaeoglobus fulgidus is a monomeric protein with a molecular weight of about 35.5 kDa. The enzyme is barely active at room temperature, displaying the maximal enzyme activity at about 80 degrees C. We have investigated the effect of the temperature on the protein structure by Fourier-transform infrared spectroscopy. The data show that between 20 degrees C and 60 degrees C a small but significant decrease of the beta-sheet bands occurred, indicating a partial loss of beta-sheets. This finding may be surprising for a thermophilic protein and suggests the presence of a temperature-sensitive beta-sheet. The increase in temperature from 60 degrees C to 98 degrees C induced a decrease of alpha-helix and beta-sheet bands which, however, are still easily detected at 98 degrees C indicating that at this temperature some secondary structure elements of the protein remain intact. The conformational dynamics of the esterase were investigated by frequency-domain fluorometry and anisotropy decays. The fluorescence studies showed that the intrinsic tryptophanyl fluorescence of the protein was well represented by the three-exponential model, and that the temperature affected the protein conformational dynamics. Remarkably, the tryptophanyl fluorescence emission reveals that the indolic residues remained shielded from the solvent up to 80 degrees C, as shown from the emission spectra and by acrylamide quenching experiments. The relationship between enzyme activity and protein structure is discussed.     

Improved estimation of the secondary structures of proteins by vacuum-ultraviolet circular dichroism spectroscopy

The vacuum-ultraviolet circular dichroism (VUVCD) spectra of 16 globular proteins (insulin, lactate dehydrogenase, glucose isomerase, lipase, conalbumin, transferrin, catalase, subtilisin A, alpha-amylase, staphylococcal nuclease, papain, thioredoxin, carbonic anhydrase, elastase, avidin, and xylanase) were successfully measured in aqueous solutions at 25 degrees C from 260 to 160 nm under a high vacuum using a synchrotron-radiation VUVCD spectrophotometer. These proteins exhibited characteristic CD spectra below 190 nm that were related to their different secondary structures, which could not be detected with a conventional CD spectrophotometer. The component spectra of alpha-helices, beta-strands, turns, and unordered structures were obtained by deconvolution analysis of the VUVCD spectra of 31 reference proteins including the 15 proteins reported in our previous paper [Matsuo, K. et al. (2004) J. Biochem. 135, 405-411]. Prediction of the secondary-structure contents using the SELCON3 program was greatly improved, especially for alpha-helices, by extending the short-wavelength limit of CD spectra to 160 nm and by increasing the number of reference proteins. The numbers of alpha-helix and beta-strand segments, which were calculated from the distorted alpha-helix and beta-strand contents, were close to those obtained on X-ray crystallography. These results demonstrate the usefulness of synchrotron-radiation VUVCD spectroscopy for the secondary structure analysis of proteins.     

Determination of the secondary structure content of proteins in aqueous solutions from their amide I and amide II infrared bands. Comparison between classical and partial least-squares methods

A method for estimating protein secondary structure from infrared spectra has been developed. The infrared spectra of H2O solutions of 13 proteins of known crystal structure have been recorded and corrected for the spectral contribution of water in the amide I and II region by using the algorithm of Dousseau et al. [Dousseau, F., Therrien, M., & Pézolet, M. (1989) Appl. Spectrosc. 43, 538-542]. This calibration set of proteins has been analyzed by using either a classical least-squares (CLS) method or the partial least-squares (PLS) method. The pure-structure spectra calculated by the classical least-squares method are in good agreement with spectra of poly(L-lysine) in the alpha-helix, beta-sheet, and undefined conformations. The results show that the best agreement between the secondary structure determined by X-ray crystallography and that predicted by infrared spectroscopy is obtained when both the amide I and II bands are used to generate the calibration set, when the PLS method is used, and when it is assumed that the secondary structure of proteins is composed of only four types of structure: ordered and disordered alpha-helices, beta-sheet, and undefined conformation. Attempts to include turns in the secondary structure estimation have led to a loss of accuracy. The standard deviation of the difference between X-ray and infrared secondary structure estimates with this method is 4.8% for the alpha-helix, 3.7% for the beta-sheet, and 5.1% for the undefined structure, whereas the regression coefficients are 0.95, 0.96, and 0.56, respectively. The spectra of the calibration proteins were also recorded in 2H2O solution.(ABSTRACT TRUNCATED AT 250 WORDS)     

Calcium-dependent conformational rearrangements and protein stability in chicken annexin A5

The conformational rearrangements that take place after calcium binding in chicken annexin A5 and a mutant lacking residues 3-10 were analyzed, in parallel with human annexin A5, by circular dichroism (CD), infrared spectroscopy (IR), and differential scanning calorimetry. Human and chicken annexins present a slightly different shape in the far-UV CD and IR spectra, but the main secondary-structure features are quite similar (70-80% alpha-helix). However, thermal stability of human annexin is significantly lower than its chicken counterpart (approximately 8 degrees C) and equivalent to the chicken N-terminally truncated form. The N-terminal extension contributes greatly to stabilize the overall annexin A5 structure. Infrared spectroscopy reveals the presence of two populations of alpha-helical structures, the canonical alpha-helices (approximately 1650 cm(-1)) and another, at a lower wavenumber (approximately 1634 cm(-1)), probably arising from helix-helix interactions or solvated alpha-helices. Saturation with calcium induces: alterations in the environment of the unique tryptophan residue of the recombinant proteins, as detected by near-UV CD spectroscopy; more compact tertiary structures that could account for the higher thermal stabilities (8 to 12 degrees C), this effect being higher for human annexin; and an increase in canonical alpha-helix percentage by a rearrangement of nonperiodical structure or 3(10) helices together with a variation in helix-helix interactions, as shown by amide I curve-fitting and 2D-IR.     

Secondary-structure analysis of proteins by vacuum-ultraviolet circular dichroism spectroscopy

The vacuum ultraviolet circular dichroism (VUVCD) spectra of 15 globular proteins (myoglobin, hemoglobin, human serum albumin, cytochrome c, peroxidase, alpha-lactalbumin, lysozyme, ovalbumin, ribonuclease A, beta-lactoglobulin, pepsin, trypsinogen, alpha-chymotrypsinogen, soybean trypsin inhibitor, and concanavalin A) were measured in aqueous solutions at 25 degrees C in the wavelength region from 260 to 160 nm under a high vacuum, using a synchrotron-radiation VUVCD spectrophotometer. The VUVCD spectra below 190 nm revealed some characteristic bands corresponding to different secondary structures. The contents of alpha-helices, beta-strands, turns, and unordered structures were estimated using the SELCON3 program with VUVCD spectra data on the 15 proteins. Prediction of the secondary-structure contents was greatly improved by extending the circular dichroism spectra to 165 nm. The numbers of alpha-helix and beta-strand segments calculated from the distorted alpha-helix and beta-strand contents did not differ greatly from those obtained from X-ray crystal structures. These results demonstrate that synchrotron-radiation VUVCD spectroscopy is a powerful tool for analyzing the secondary structures of proteins.     

Heat-induced secondary structure and conformation change of bovine serum albumin investigated by Fourier transform infrared spectroscopy

Fourier transform infrared (FT-IR) spectra were measured for an aqueous solution (pD = 5.40) of defatted monomer bovine serum albumin (BSA) over a temperature range of 25-90 degrees C to investigate temperature-induced secondary structure and conformation changes. The curve fitting method combined with the Fourier self-deconvolution technique allowed us to explore details of the secondary structure and conformation changes in defatted BSA. Particularly striking in the FT-IR spectra was an observation of the formation of an irreversible intermolecular beta-sheet of BSA on heating above 70 degrees C. A band at 1630 cm(-1) in the spectra was assigned to short-segment chains connecting alpha-helical segments. The transition temperature for the short-segment chains connecting alpha-helical segments is lower by 17-18 degrees C, when compared to those of the alpha-helix, turn, and intermolecular beta-sheet structures of BSA, suggesting that the alpha-helix and turn structures of BSA are cooperatively denatured on heating. Moreover, the results give an important feature in heat-induced denaturation of BSA that the conformation changes occur twice around both 57 and 75 degrees C. The appearance of two peaks is interpreted by the collapse of the N-terminal BSA domain due to the crevice in the vicinity between domains I and II at low-temperature transition and by the change in cooperative unit composed of the other two BSA domains at high-temperature transition.     

The esterase from the thermophilic eubacterium Bacillus acidocaldarius: structural-functional relationship and comparison with the esterase from the hyperthermophilic archaeon Archaeoglobus fulgidus

The esterase from the thermophilic eubacterium Bacillus acidocaldarius is a thermophilic and thermostable monomeric protein with a molecular mass of 34 KDa. The enzyme, characterized as a "B-type" carboxylesterase, displays the maximal activity at 65 degrees C. Interestingly, it is also quite active at room temperature, an unusual feature for an enzyme isolated from a thermophilic microorganism. We investigated the effect of temperature on the structural properties of the enzyme, and compared its structural features with those of the esterase from the hyperthermophilic archaeon Archaeoglobus fulgidus. In particular, the secondary structure and the thermal stability of the esterase were studied by FT-IR spectroscopy, while information on the conformational dynamics of the enzyme were obtained by frequency-domain fluorometry and anisotropy decays. Our data pointed out that the Bacillus acidocaldarius enzyme possesses a secondary structure rich in alpha-helices as described for the esterase isolated from Archaeoglobus fulgidus. Moreover, infrared spectra indicated a higher accessibility of the solvent ((2)H(2)O) to Bacillus acidocaldarius esterase than to Archaeoglobus fulgidus enzyme suggesting, in turn, a less compact structure of the former enzyme. The fluorescence studies showed that the intrinsic tryptophanyl fluorescence of the Bacillus acidocaldarius protein was well represented by the three-exponential model, and that the temperature affected the protein conformational dynamics. The data suggested an increase in the protein flexibility on increasing the temperature. Moreover, comparison of Bacillus acidocaldarius esterase with the Archaeoglobus fugidus enzyme fluorescence data indicated a higher flexibility of the former enzyme at all temperatures tested, supporting the infrared data and giving a possible explanation of its unusual relative high activity at low temperatures. Proteins 2000;40:473-481.     

Spectroscopic characterization of textilotoxin, a presynaptic neurotoxin from the venom of the Australian eastern brown snake (Pseudonaja t. textilis)

Spectroscopic behavior of textilotoxin, from the venom of Pseudonaja t. textilis, and its subunits were investigated using fluorescence, circular dichroism and Fourier transform infrared spectroscopy. Circular dichroism spectra of the B, C and D subunits indicate considerable similarity in their alpha-helix and beta-sheet contents. By contrast, the A subunit displays significantly more beta-sheet and 'remainder' structure. FTIR spectra confirm conclusions drawn from CD spectra. Fluorescence spectra indicate that, in general, tryptophan residues in the A, B and D subunits are relatively exposed to the solvent. The C subunit exhibits no fluorescence, suggesting a lack of tryptophan. Comparisons of individual subunit spectra with those of the intact toxin suggest that significant changes in secondary structure may occur when the toxin dissociates.     

The thermal denaturation of ribonuclease A in aqueous-methanol solvents.

Circular dichroism was used to monitor the thermal unfolding of ribonuclease A in 50% aqueous methanol. The spectrum of the protein at temperatures below -10 degrees C (pH* 3.0) was essentially identical to that of native ribonuclease A in aqueous solution. The spectrum of the thermally denatured material above 70 degrees C revealed some residual secondary structure in comparison to protein unfolded by 5 M Gdn.HCl at 70 degrees C in the presence or absence of methanol. The spectra as a function of temperature were deconvoluted to determine the contributions of different types of secondary structure. The position of the thermal unfolding transition as monitored by alpha-helix, with a midpoint at 38 degrees C, was at a much higher temperature than that monitored by beta-sheet, 26 degrees C, which also corresponded to that observed by delta A286, tyrosine fluorescence and hydrodynamic radius (from light scattering measurements). Thus, the loss of beta-sheet structure is decoupled from that of alpha-helix, suggesting a step-wise unfolding of the protein. The transition observed for loss of alpha-helix coincides with the previously measured transition for His-12 by NMR from a partially folded state to the unfolded state, suggesting that the unfolding of the N-terminal helix in RNase A is lost after unfolding of the core beta-sheet during thermal denaturation. The thermally denatured protein was relatively compact, as measured by dynamic light scattering.     

Infrared spectroscopic discrimination between the loop and alpha-helices and determination of the loop diffusion kinetics by temperature-jump time-resolved infrared spectroscopy for cytochrome c

The infrared (IR) absorption of the amide I band for the loop structure may overlap with that of the alpha-helices, which can lead to the misassignment of the protein secondary structures. A resolution-enhanced Fourier transform infrared (FTIR) spectroscopic method and temperature-jump (T-jump) time-resolved IR absorbance difference spectra were used to identify one specific loop absorption from the helical IR absorption bands of horse heart cytochrome c in D2O at a pD around 7.0. This small loop consists of residues 70-85 with Met-80 binding to the heme Fe(III). The FTIR spectra in amide I' region indicate that the loop and the helical absorption bands overlap at 1653 cm(-1) at room temperature. Thermal titration of the amide I' intensity at 1653 cm(-1) reveals that a transition in loop structural change occurs at lower temperature (Tm=45 degrees C), well before the global unfolding of the secondary structure (Tm approximately 82 degrees C). This loop structural change is assigned as being triggered by the Met-80 deligation from the heme Fe(III). T-jump time-resolved IR absorbance difference spectra reveal that a T-jump from 25 degrees C to 35 degrees C breaks the Fe-S bond between the Met-80 and the iron reversibly, which leads to a loop (1653 cm(-1), overlap with the helical absorption) to random coil (1645 cm(-1)) transition. The observed unfolding rate constant interpreted as the intrachain diffusion rate for this 16 residue loop was approximately 3.6x10(6) s(-1).     

D-trehalose/D-maltose-binding protein from the hyperthermophilic archaeon Thermococcus litoralis: the binding of trehalose and maltose results in different protein conformational states

In this work, we used fluorescence spectroscopy, molecular dynamics simulation, and Fourier transform infrared spectroscopy for investigating the effect of trehalose binding and maltose binding on the structural properties and the physical parameters of the recombinant D-trehalose/D-maltose binding protein (TMBP) from the hyperthermophilic archaeon Thermococcus litoralis. The binding of the two sugars to TMBP was studied in the temperature range 20 degrees-100 degrees C. The results show that TMBP possesses remarkable temperature stability and its secondary structure does not melt up to 90 degrees C. Although both the secondary structure itself and the sequence of melting events were not significantly affected by the sugar binding, the protein assumes different conformations with different physical properties depending whether maltose or trehalose is bound to the protein. At low and moderate temperatures, TMBP possesses a structure that is highly compact both in the absence and in the presence of two sugars. At about 90 degrees C, the structure of the unliganded TMBP partially relaxes whereas both the TMBP/maltose and the TMBP/trehalose complexes remain in the compact state. In addition, Fourier transform infrared results show that the population of alpha-helices exposed to the solvent was smaller in the absence than in the presence of the two sugars. The spectroscopic results are supported by molecular dynamics simulations. Our data on dynamics and stability of TMBP can contribute to a better understanding of transport-related functions of TMBP and constitute ground for targeted modifications of this protein for potential biotechnological applications.     

Mutation of invariant cysteines of mammalian metallothionein alters metal binding capacity, cadmium resistance, and 113Cd NMR spectrum.

Using a yeast expression vector system, we have expressed both wild type and six mutated Chinese hamster metallothionein coding sequences in a metal-sensitive yeast strain in which the endogenous metallothionein gene has been deleted. The mutant proteins have single or double cysteine to tyrosine replacements (C13Y, C50Y, and C13,50Y), single cysteine to serine replacements (C13S and C50S), or a single cysteine to alanine replacement (C50A). These proteins function in their yeast host in cadmium detoxification to differing extents. Metallothioneins which contain a cysteine mutation at position 50 (C50Y, C50S, C50A, and C13,50Y) conferred markedly less cadmium resistance than wild type metallothionein, or metallothionein with a single cysteine mutation at position 13 (C13Y and C13S). Wild type and three of the mutant Chinese hamster metallothioneins (C13Y, C50Y, and C13,50Y) were purified from yeast grown in subtoxic levels of either CdCl2 or 113CdCl2. All three of the mutant proteins bound less cadmium than the wild type protein when metal-binding stoichiometries were determined. The one-dimensional 113Cd NMR spectrum of the recombinant wild type Chinese hamster metallothionein was compared to the spectra of native rat and rabbit liver metallothioneins. The close correspondence between the 113Cd chemical shifts in these metallothioneins is consistent with the presence of two separate metal clusters, A and B, corresponding, respectively, to the alpha- and beta-domains, in the recombinant metallothionein. The one-dimensional 113Cd NMR spectra recorded on each of the three mutant metallothioneins, on the other hand, provide some indication as to the structural basis for the reduced, by one, metal stoichiometry of each of the mutant metallothioneins. For the C13Y mutant, it appears that the beta-domain now binds a total of two metal ions whereas with the C50Y mutant, the alpha-domain appears metal-deficient. For the double mutant, C13,50Y, the 113Cd resonances are indicative of major structural reorganizations in both domains.     

Secondary structure of the hydrophobic myelin protein in a lipid environment as determined by Fourier-transform infrared spectrometry

The secondary structure of a hydrophobic myelin protein (lipophilin), reconstituted with dimyristoylphosphatidylcholine or dimyristoylphosphatidylglycerol, was investigated by Fourier-transform infrared spectroscopy. Protein infrared spectra in the amide I region were analyzed quantitatively using resolution enhancement and band fitting procedures. Lipophilin in a phospholipid environment adopts a highly ordered secondary structure which at room temperature consists predominantly of alpha-helix (approximately 55%) and beta-type conformations (36%). The secondary structure of the protein is not affected by the lipid gel to liquid crystalline phase transition. Heating of the lipid-protein complex above approximately 35 degrees C results in a gradual decrease in alpha-helical content, accompanied by an increase in the amount of beta-structures. Lipophilin dissolved in 2-chloroethanol is, compared to the protein in a lipid environment, richer in the alpha-helical conformation but still contains a sizable amount of beta-structure.     

UV- and CD-spectra of restriction endonuclease EcoRII and DNA-methylase EcoRII

UV- and CD-spectra of homogeneous enzymes have been measured. Extinction coefficients estimated from the UV-spectra are 0.97 for restriction endonuclease EcoRII at 279.5 nm and 1.17 for DNA-methylase EcoRII at 279 nm. As it follows from the CD spectra, both enzymes have a well developed tertiary structure and a highly ordered secondary structure, which consists of 22% alpha-helices, 64% beta-structure and 9% bends for REcoRII and of 44% alpha-helices, 48% beta-structure and 4% bends for MEcoRII. Restriction endonuclease denatures at 50 degrees C, while DNA-methylase denatures at 45 degrees C, with partial reversibility upon cooling.     

Solution structure of MT_nc,a novel metallothionein from the Antarctic fish Notothenia coriiceps

The structure of [113Cd(7)]-metallothionein (MT_nc) of the Antarctic fish Notothenia coriiceps, the first three-dimensional structure of a fish metallothionein, was determined by homonuclear 1H NMR experiments and heteronuclear [1H, 113Cd]-correlation spectroscopy. MT_nc is composed of an N-terminal beta domain with 9 cysteines and 3 metal ions and a carboxy-terminal alpha-domain with 11 cysteines and 4 metal ions. The position of the ninth Cys of the alpha domain of MT_nc is different from the corresponding Cys of mammalian MTs. As a result, the last CXCC motif in the mammalian MT sequence becomes CXXXCC in the fish MT. This difference leads to a structural change of the alpha domain and, in turn, to a different charge distribution with respect to that observed in mammalian metallothioneins.     

Conformational properties of a peptide model for unfolded alpha-helices

Models of protein folding often hypothesize that the first step is local secondary structure formation. The assumption is that unfolded polypeptide chains possess an intrinsic propensity to form these local secondary structures. On the basis of this idea, it is tempting to model the local conformational properties of unfolded proteins using well-established residue secondary structure propensities, in particular, alpha-helix forming propensities. We have used spectroscopic methods to investigate the conformational behavior of a host-guest series of peptides designed to model unfolded alpha-helices. A suitable peptide model for unfolded alpha-helices was determined from studies of the length dependence of the conformational properties of alanine-based peptides. The chosen host peptide possessed a small, detectable, alpha-helix content. Substituting various representative guest residues into the central position of the host peptide at times changed the conformational behavior dramatically, and often in ways that could not be predicted from known alpha-helix forming propensities. The data presented can be used to rationalize some of these propensities. However, it is clear that secondary structure propensities cannot be used to predict the local conformational properties of unfolded proteins.     

Structural and functional relationships in 5'-nucleotidase from bull seminal plasma. A Fourier transform infrared study.

Fourier transform infrared spectroscopy (FTIR) was used to investigate the secondary structure of 5'-nucleotidase from bull seminal plasma (BSP). Spectra of protein in both D2O and H2O were analyzed by deconvolution and second derivative methods in order to observe the overlapping components of the amide I band. The protein, which is made up of two apparently identical subunits and which contains two zinc atoms, was studied in its native form, in the presence of dithiotreitol (DTT) and after removal of the two zinc atoms by means of nitrilotriacetic acid (NTA). Deconvolved and second derivative spectra of amide I band showed that the native protein contains mostly beta-sheet structure with a minor content of alpha-helix. The quantitative analysis of the amide I components was performed by a curve-fitting procedure which revealed 54% beta-sheet, 18% alpha-helix, 22% beta-turns and 6% unordered structure. The second derivative and deconvolved spectra of amide I band showed that no remarkable changes in the secondary structure of 5'-nucleotidase were induced by either DTT or NTA. These results were confirmed by the curve-fitting analysis where little or no changes occurred in the relative content of amide I components when the protein was treated with DTT or with NTA. Major changes, however, were observed in the thermal denaturation behavior of the protein. The native protein showed denaturation at temperatures between 70 and 75 degrees C, while the maximum of denaturation was observed between 65 and 70 degrees C and between 55 and 60 degrees C in the presence of NTA and DTT, respectively. The results obtained indicate that the two separate subunits of the protein have essentially the same secondary structure as that of the native enzyme.     

Structure of rhodopsin in monolayers at the air-water interface: a PM-IRRAS and X-ray reflectivity study

Monomolecular films of the membrane protein rhodopsin have been investigated in situ at the air-water interface by polarization modulation infrared reflection absorption spectroscopy (PM-IRRAS) and X-ray reflectivity in order to find conditions that retain the protein secondary structure. The spreading of rhodopsin at 0 or 5 mN m(-1) followed by a 30 min incubation time at 21 degrees C resulted in the unfolding of rhodopsin, as evidenced from the large increase of its molecular area, its small monolayer thickness, and the extensive formation of beta-sheets at the expense of the alpha-helices originally present in rhodopsin. In contrast, when spreading is performed at 5 or 10 mN m(-1) followed by an immediate compression at, respectively, 4 or 21 degrees C, the secondary structure of rhodopsin is retained, and the thickness of these films is in good agreement with the size of rhodopsin determined from its crystal structure. The amide I/amide II ratio also allowed to determine that the orientation of rhodopsin only slightly changes with surface pressure and it remains almost unchanged when the film is maintained at 20 mN m(-1) for 120 min at 4 degrees C. In addition, the PM-IRRAS spectra of rod outer segment disk membranes in monolayers suggest that rhodopsin also retained its secondary structure in these films.     

Thermal denaturation of a recombinant mouse amelogenin: circular dichroism and differential scanning calorimetric studies

Conformational analyses of a recombinant mouse tooth enamel amelogenin (rM179) were performed using circular dichroism (CD), fluorescence, differential scanning calorimetry, and sedimentation equilibrium studies. The results show that the far-UV CD spectra of rM179 at acidic pH and 10 degrees C are different from the spectra of random coil in 6 M GdnHCl. A near-UV CD spectrum of rM179 at 10 degrees C is similar to that of rM179 in 6 M GdnHCl, which indicates that aromatic residues of native structure are exposed to solvent and rotate freely. Far-UV CD values of rM179 at 80 degrees C are different from that of random-coil structure in 6 M GdnHCl, which suggests that rM179 at 80 degrees C has specific secondary structures. A gradual thermal transition was observed by far-UV CD, which is interpreted as a weak cooperative transition from specific secondary structures to other specific secondary structures. The fluorescence emission maximum for the spectrum due to Trp residues in rM179 at 10 degrees C shows the same fluorescence emission maximum as rM179 in 6 M GdnHCl and amino acid Trp, which indicates that the three Trp in rM179 are exposed to solvent. Deconvolution of differential scanning calorimetry curve gives the population of three states (A, I, and C states). These results indicate that three states (A, I, and C) have specific secondary structures, in which hydrophobic and Trp residues are exposed to the solvent. The thermodynamic characteristics of rM179 are unique and different from a typical globular protein, proline-rich peptides, and a molten globule state.