Nucler magnetic resonance studies of the unfolding of pancreatic ribonuclease.

The thermal unfolding of ribonuclease at a number of pH values has been studied by ¹H nuclear magnetic resonance spectroscopy, under conditions where the unfolding is fully reversible and concentration-independent. At pH¹ 5.5 (uncorrected for the deuterium isotope effect) there is evidence for a conformational change affecting His-48 and perhaps a methionine residue at temperatures below the major thermal transition. No evidence for intermediates in the major transition was found. The product of thermal unfolding under these conditions is not a random coil, and the remaining elements of structure probably include a phenylalanine and two histidine residues. At pH¹ 1.5 and pH¹ 2.9, the product of thermal unfolding is closer to a random coil, and under these conditions the changes in area of the histidine C₍₂₎H resonances with temperature give evidence for the existence of an intermediate in the unfolding process in which His-12 and His-119 are in a solvent-like environment, while His-48 and His-105 are not (see Westmoreland &; Matthews (1973)). The changes in the spectra of ribonuelease between pH¹ 5.5 and pH¹ 1.5 are described, and the possible relation between these changes and the alterations in thermal unfolding with pH are discussed.     

On the domain structure of antithrombin III. Tentative localization of the heparin binding region using 1H NMR spectroscopy

The denaturation of human and bovine antithrombin III by guanidine hydrochloride has been followed by 1H NMR spectroscopy. The same unfolding transition seen previously from circular dichroism studies [Villanueva, G. B., & Allen, N. (1983) J. Biol. Chem. 258, 14048-14053] at low denaturant concentration was detected here by discontinuous changes in the chemical shifts of the C(2) protons of two of the five histidines in human antithrombin III and of three of the six histidines in bovine antithrombin III. These two histidines in human antithrombin III are assigned to residue 1 and, more tentatively, to residue 65. Two of the three histidines similarly affected in the bovine protein appear to be homologous to residues in the human protein. This supports the proposal of similar structures for the two proteins. In the presence of heparin, the discontinuous titration behavior of these histidine resonances is shifted to higher denaturant concentration, reflecting the stabilization of the easily unfolded first domain of the protein by bound heparin. From the tentative assignment of one of these resonances to histidine-1, it is proposed that the heparin binding site of antithrombin III is located in the N-terminal region and that this region forms a separate domain from the rest of the protein. The pattern of disulfide linkages is such that this domain may well extend from residue 1 to at least residue 128. Thermal denaturation also leads to major perturbation of these two histidine resonances in human antithrombin III, though stable intermediates in the unfolding were not detected.     

Denaturant dependence of equilibrium unfolding intermediates and denatured state structure of horse ferricytochrome c

Nuclear magnetic resonance spectroscopy is employed to characterize unfolding intermediates and the denatured state of horse ferricytochrome c in guanidine hydrochloride. Unfolded and partially unfolded species with non-native heme ligation are detected by analysis of hyperfine-shifted (1)H resonances. Two equilibrium unfolding intermediates with His-Lys heme axial ligation are detected, as are two unfolded species with bis-His heme ligation. These results are contrasted with previous results on horse ferricytochrome c denaturation by urea, for which only one unfolding intermediate and one unfolded species were detected by NMR spectroscopy. Urea and guanidine hydrochloride are often used interchangeably in protein denaturation studies, but these results and those of others indicate that unfolded and intermediate states in these two denaturants may have substantially different properties. Implications of these results for folding studies and the biological function of mitochondrial cytochromes c are discussed.     

31P n.m.r. studies of complexes of NADPH and NADP+ with Escherichia coli dihydrofolate reductase

We have measured the ³¹P n.m.r. spectra of NADP⁺ and NADPH in their binary complexes with Escherichia coli dihydrofolate reductase and in ternary complexes with the enzyme and folate or methotrexate. The ³¹P chemical shift of the 2′ phosphate group is the same in all complexes; its value indicates that it is binding in the dianionic state and its pH independence suggests that it is interacting strongly with cationic residue(s) on the enzyme. Similar behaviour has been noted previously for the complexes with the Lactobacillus casei enzyme although the ³¹P shift is somewhat different in this complex, possibly due to an interaction between the 2′ phosphate group and His 64 which is not conserved in the E. coli enzyme. For the coenzyme complexes with both enzymes ³¹POC₂¹H_2′ spin-spin interactions were detected (7.5–7.8 Hz) on the 2′ phosphate resonances, indicating a POC₂H_2′ dihedral angle of 30 or 330 : this is in good agreement with the value of 330° measured in crystallographic studies¹ (Matthews et al., 1978) on the L. casei enzyme. NADPH-MTX complex. The pyrophosphate resonances are shifted to different extents in the various complexes and there is evidence that there is more OPO bond angle distortion in the E. coli enzyme complexes than in those with the L. casei enzyme. The effects of ³¹POC₅¹H_5′ spin coupling were detected on one pyrophosphate resonance and indicate that the POC₅H_5′ torsion angle has changed by at least ～30° on binding to the E. coli enzyme: this is considerably less than the distortion (～50°) observed previously in the L. casei enzyme complex.     

A study of the histidine residues of human carbonic anhydrase B using 270 MHz proton magnetic resonance

Nine resonances in the 270 MHz proton magnetic resonance spectrum of human carbonic anhydrase B have been identified with imidazole C₍₂₎ protons of histidine residues, six of which are observed to titrate with pK_a values in the range 4.7 to 7.4. The behaviour of the nine resonances has been studied in the presence of the inhibitors, iodide, cyanide, acetate, hexacyanochromate, and imidazole. Measurements have also been made of the enzyme in its apo, cobalt, and mono-alkylated forms. Used in conjunction with the crystal structure, these results have enabled the tentative assignment of all nine resonances to particular histidine residues in the amino-acid sequence. Three of the active-site histidines at positions 64, 67, and 200 have low pK_a values and cannot be directly linked to the activity of the enzyme. However, the resonances assigned to the three metal-liganding histidines do exhibit changes on anion binding and with pH, which parallel changes in the esterase activity. These results are consistent with the model of an ionizable water molecule bound to the zinc ion.Linewidth measurements of the resonances of the histidine residues on the enzyme surface are used to estimate pseudo-first-order rate constants of the order of 4 × 10³ s^?1 for D⁺ exchange between imidazole N and solvent in the absence of buffer. These rates are observed to increase in the presence of small amounts of the buffers Tris and imidazole.     

Two-domain structure of microsomal reduced nicotinamide adenine dinucleotide-cytochrome b5 reductase.

NADH-cytochrome b₅ reductase is an amphiphilic protein consisting of a hydrophilic (FAD-containing) moiety and a hydrophobic (membrane-binding) segment and exists in aqueous media as an oligomeric aggregate. Circular dichroism studies have shown that denaturation of the reductase by guanidine hydrochloride in the presence of Emulgen 109P, a nonionic detergent, is a two-stage process as a function of the denaturant concentration. The first transition occurs at about 1 m guanidine hydrochloride and the second one at much higher concentrations. The guanidine hydrochloride concentration causing the second-stage unfolding depends on the concentration of Emulgen 109P. A hydrophilic fragment of the reductase lacking the hydrophobic segment undergoes one-stage denaturation at about 1 m guandine hydrochloride regardless of the presence and absence of Emulgen 109P. Both the reductase as well as the hydrophilic fragment lose their NADH-ferricyanide reductase activity and FAD also at about 1 m guanidine hydrochloride in the presence of the detergent. These findings suggest that the first-stage denaturation of the reductase represents the unfolding of the hydrophilic moiety and the second one that of the hydrophobic segment. Gel chromatography experiments have suggested that in the presence of Emulgen 109P the reductase exists as a mixed micelle with the detergent and this aggregation state persists even after the first-stage denaturation (unfolding of the hydrophilic moiety). The dissociation of the mixed micelle seems to take place concomitant with the second-stage denaturation. It is concluded that the two moieties of the reductase molecule, though linked to each other covalently, exist as independent domains undergoing unfolding separately at least in the presence of Emulgen 109P. This structural feature of the reductase is similar to that of cytochrome b₅ reported by us. The reductase is, therefore, another example of amphiphilic membrane proteins having two structurally independent domains in the molecule.     

15N magnetic resonance studies of the binding of 15N-labeled cyanide to various hemoproteins.

The ¹⁵N paramagnetic shifts of iron-bound C¹⁵N^? were studied for myoglobin, hemoglobin, cytochrome c and other modified hemoproteins. Two characteristic ¹⁵N resonances at 977 and 1045 ppm (with respect to ¹⁵NO₃^? as an internal standard) were found for human adult hemoglobin cyanide, while only single resonances were observed for other cyano hemoproteins. These two resonances are assigned to iron-bound C¹⁵N of α and β subunits of hemoglobin. The substantial difference in the C¹⁵N isotropic shifts in various hemoproteins is discussed in relation to iron-proximal histidine binding and heme-apoprotein interactions.     

Effects of an interchain disulfide bond on tropomyosin structure: intrinsic fluorescence and circular dichroism studies

An interchain disulfide crosslink was introduced into rabbit skeletal tropomyosin (TM) at Cys190 by two different methods under non-denaturing conditions. The effects of the crosslink on the structure of tropomyosin were investigated by fluorescence and circular dichroism methods as a function of temperature and guanidine · hydrochloride concentration. Four different preparations were studied: Nbs₂-TM, red-TM crosslinked with Ellman's reagent, 5,5′-dithiobis(2-nitrobenzoate); O₂-TM, TM whose SH groups were air-oxidized; red-TM, TM reduced with dithiothreitol; IA-TM, red-TM whose SH groups were blocked with iodoacetamide. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis studies indicated that SS crosslinks were quantitatively introduced between the subunits of TM for Nbs₂-TM and O₂-TM. In the completely folded state (below 25 °C or in the absence of denaturant) and in the unfolded state (above 65 °C or greater than 4 m-guanidine · hydrochloride) all of the samples had the same Tyr fluorescence quantum yield, accessibility to acrylamide fluorescence quenching, fluorescence polarization and mean residue rotation at 222 nm. Thermal and denaturant-induced unfolding profiles at pH 7.5 were obtained for each sample with measurements of these parameters. The main transition at about 45 °C or 2 m-guanidine · hydrochloride was shifted about +7 deg. C and 0.8 m in guanidine · hydrochloride, respectively, for the crosslinked samples as compared to the uncrosslinked samples. In addition, a destabilizing pretransition was observed in the 30 to 45 °C region or the 0 to 2 m-guanidine · hydrochloride region only for the crosslinked samples when polarization or ellipticity was measured. Studies of the ability of Nbs₂ to crosslink red-TM as a function of guanidine · hydrochloride concentration indicated that the chains separate at Cys190 between 0 and 2 m-guanidine · hydrochloride before they dissociate. Thus, the effect of the SS crosslink at Cys190 on the conformation of TM at physiological temperatures appears to be related to the inherent instability of the molecule in this region of the sequence.     

The charge-relay system of serine proteinases: proton magnetic resonance titration studies of the four histidines of porcine trypsin.

Peaks corresponding to the C₍₂₎-protons of all four histidine residues of porcine β-trypsin were resolved in 250 MHz nuclear magnetic resonance spectra after deuteration of the slowly exchangeable N-H groups (whose resonances obscure the histidine peaks) by reversible unfolding of the protein in D₂O. One of the four peaks was assigned to the charge-relay histidine in the active site of trypsin (His(57) in the bovine chymotrypsinogen numbering system). Whereas the three other histidine C₍₂₎-peaks exhibited normal titration curves with single pK′ values of 7.20, 6.71 and 6.67, the peak assigned to His(57) had an abnormal titration curve showing two protonation steps in the pH range from 1 to 9. The first protonation with a pH′_mid of 5.0 is rapid on the nuclear magnetic resonance time-scale; the second with a pH′_mid of 4.5 is slow and apparently involves conformational transitions between two states having lifetimes of approximately 18 ms.In the complex between porcine β-trypsin and bovine pancreatic trypsin inhibitor (Kunitz) His(57) was found to be insensitive to pH over the range from 4 to 9 and its chemical shift resembles that of His(57) in the singly protonated charge relay of free trypsin. This result provides direct evidence that the trypsin charge relay acts as a proton acceptor in the initial catalytic step which leads to the formation of a tetrahedral complex. In the presence of equimolar bovine pancreatic trypsin inhibitor (Kunitz) the pH'_mid of the conformational transition that affects the charge-relay histidine is lowered from 4.5 to approximately 3.5.     

An acid induced conformational transition of denatured cytochrome c in urea and guanidine hydrochloride solutions.

Previous work has shown that at neutral pH ferricytochrome c (horse heart) retains certain residual structures in concentrated solutions of urea or guanidine hydrochloride (Tsong, T. Y. (1974), J. Biol. Chem. 249, 1988). Present studies reveal that cooperative unfolding of these residual structures can be achieved by acidification of the protein to pH 4 in 9 M urea but can only be partially achieved in a 6 M guanidine hydrochloride solution. The evidence that the residual structures unfold in 9 M urea upon acidification is twofold. (1) Further uncoupling of the Trp-59-heme interaction occurs; this is reflected in the intensification of the tryptophan fluorescence from 55 to 90 percent relative to that of free tryptophan in the same solvent. (2) The intrinsic viscosity of the protein solution increases from 15.0 to 21 ml/g. The acidification also induces a spin-state transformation of the heme group at pH 5 both in urea and in guanidine hydrochloride. Acidic titration of the protein in urea and guanidine hydrochloride indicates that the unfolding involves the absorption of a single proton. However, the kinetics of the spin-state transformation are triphasic. These results suggest that the displacement of the ligand His-18 by a solvent molecule and the subsequent disintegration of the residual structures are complex processes and involve at least three kinetic steps. The ineffectiveness of guanidine hydrochloride as a denaturant for ferricytochrome c is shown to be due to the presence of the high concentration of Cl minus which can stabilize certain elements of the protein structure.     

Electrostatic and conformational effects on the reaction of thiol groups of calf thymus histone H3 with 5,5'-dithiobis(2-nitrobenzoic acid).

The presence of highly basic proteins (histones or protamines), causes an increase in the rate of the reaction of 5,5′-dithiobis(2-nitrobenzoic acid) (Nbs₂) with the tripeptide model glutathione. This effect is explained by considering that polycationic molecules, such as histones or protamines, can attract the negatively charged reacting molecules, thus producing a catalytic effect. This effect disappears at high ionic strength due to a shielding of the charges; Urea causes a shift to the K_2(app)vs. pH curve for the histone H3-Nbs₂ reaction. This shift (2.1 units of pH for 8 m urea) indicates that urea denatures, at least to some extent, the tertiary structure of the microenvironments containing cysteine of histone H3, but it is unable to eliminate an unspecific electrostatic effect (similar to that caused by polycations in the GSH-Nbs₂ reaction), which also contributes to the increase of the reaction rate. Combined effects of urea and ionic strength on the reaction of GSH and of histone H3 with Nbs₂ gives rise to shifts of both curves of K_2(app)us. pH, approaching one to the other very closely. This is interpreted as due to the appearance of shielding effects on the electrostatic charges of the histone, and also of the small molecules. The greater efficiency of guanidine hydrochloride, compared to that of urea, in causing a shift of the rate constant curve of histone H3 is interpreted as due to a combined effect of denaturation and electrostatic shielding in the case of guanidine hydrochloride.     

Reversible trifluoroacetic acid-induced conformational changes in glycophorin as detected by proton nuclear magnetic resonance spectroscopy

High-field (270 MHz) ¹H-NMR has been employed to study the solution conformation of glycophorin A, a sialoglycoprotein which spans the human erythrocyte membrane. Glycophorin A is one of the most fully characterized integral membrane proteins known, making it an excellent model for the study of membrane-bound proteins. This protein consists of three distinct domains: a glycosylated extracellular N-terminus, a hydrophobic intramembranous segment, and a polar cytoplasmic C-terminus. These domains contain aromatic residues which serve as convenient ¹H-NMR conformational probes. The aromatic region of the NMR spectrum of glycophorin A in ²H₂O shows single, well-resolved His and Tyr resonances. No resonances are observed, however, for the Phe residues which are located in or near the hydrophobic domain. These observations suggest that considerable heterogeneity with respect to segmental motions exists within the protein. This is consistent with circular dichroism data showing the intramembranous segment to be completely helical with the extremities of the protein being predominantly random coils. The helix of the hydrophrobic domain is remarkably resistant to conventional denaturing conditions including variations in pH, and temperature, and treatment with guanidine hydrochloride. However, in trifluoroacetic acid, which strongly solvates peptide backbones, there is extensive reversible unfolding of the helical structure as evidenced by the appearance of Phe resonances. Solvent titration experiments indicate that approximately a 1 : 1 volume ratio of trifluoroacetic acid to ²H₂O is required to initiate unfolding of the helix.     

Structural,thermodynamic, and phosphatidylinositol 3‐phosphate binding properties of Phafin2

Phafin2 is a phosphatidylinositol 3‐phosphate (PtdIns(3)P) binding protein involved in the regulation of endosomal cargo trafficking and lysosomal induction of autophagy. Binding of Phafin2 to PtdIns(3)P is mediated by both its PH and FYVE domains. However, there are no studies on the structural basis, conformational stability, and lipid interactions of Phafin2 to better understand how this protein participates in signaling at the surface of endomembrane compartments. Here, we show that human Phafin2 is a moderately elongated monomer of ～28 kDa with an intensity‐average hydrodynamic diameter of ～7 nm. Circular dichroism (CD) analysis indicates that Phafin2 exhibits an α/β structure and predicts ～40% random coil content in the protein. Heteronuclear NMR data indicates that a unique conformation of Phafin2 is present in solution and dispersion of resonances suggests that the protein exhibits random coiled regions, in agreement with the CD data. Phafin2 is stable, displaying a melting temperature of 48.4°C. The folding‐unfolding curves, obtained using urea‐ and guanidine hydrochloride‐mediated denaturation, indicate that Phafin2 undergoes a two‐state native‐to‐denatured transition. Analysis of these transitions shows that the free energy change for urea‐ and guanidine hydrochloride‐induced Phafin2 denaturation in water is ～4 kcal mol^?1. PtdIns(3)P binding to Phafin2 occurs with high affinity, triggering minor conformational changes in the protein. Taken together, these studies represent a platform for establishing the structural basis of Phafin2 molecular interactions and the role of the two potentially redundant PtdIns(3)P‐binding domains of the protein in endomembrane compartments.     

Free energy changes in ribonuclease A denaturation. Effect of urea, guanidine hydrochloride, and lithium salts

The unfolding of ribonuclease A by urea, guanidine hydrochloride, lithium perchlorate, lithium chloride, and lithium bromide has been followed by circular dichroic and difference spectral measurements. All three abnormal tyrosyl residues are normalized in urea and guanidine hydrochloride (delta epsilon 287 = -2700), only two are normalized in lithium bromide and lithium perchlorate (delta epsilon 287 = -1700), and only one is exposed in lithium chloride solutions (delta epsilon 287 = -700). The Gibbs energies are 4.7 +/- 0.1 kcal mol-1 for urea- and guanidine hydrochloride-denaturation, 3.8 +/- 0.2 kcal mol-1 for lithium perchlorate-denaturation, and 12.7 +/- 0.2 kcal mol-1 for lithium chloride- and lithium bromide-denaturation of ribonuclease A. The latter results suggest that the mechanism of the unfolding process in urea and guanidine hydrochloride is quite different from that in lithium salts.     

Resonance Raman spectroscopy of chemically modified retinals: Assigning the carbon-methyl vibrations in the resonance Raman spectrum of rhodopsin

To assign the observed vibrationsl modes in the resonance Raman spectrum of the retinylidene chromophore of rhodopsin, we have studied chemically modified retinals. The series of analogs investigated are the n-butyl retinals substituted at C₉ and C₁₃. The results obtained for the 11-cis isomer have clearly assigned the CCH₃ vibrational frequencies observed in the spectrum of the retinylidene chromophore. The data show that the C₍₉₎CH₃ stretching vibration can be assigned to the vibrational mode observed in the 1017 cm^?1 region, and the vibration detected at 997 cm^?1 can be assigned to the C₍₁₃CH₃ vibration. The C₍₅₎CH₃ stretching mode does not contribute to the vibrations observed in this region. The splitting in the C_(n)CH₃ (n = 9, 13) vibration is characteristic of the 11-cis conformation. The results on the modified retinals do not support the hypothesis that the splitting arises from equilibrium mixtures of 11-cis, 12-s-cis and 11-cis, 12-s-trans in solution. Thus, this splitting cannot be used to determine whether the chromophore in rhodopsin is in a 12-s-cis or 12-s-trans conformation. However, our results demonstrate that there are other vibrational modes in the spectra which are sensitive to this conformational equilibrium and we use the presence of a strong ~ 1271 cm^?1 mode in bovine and squid rhodopsin spectra as an indication that the chromophore in these pigments is 11-cis, 12-s-trans.     

Static and dynamic quenching of protein fluorescence. II. lysozyme.

The fluorescence parameters—lifetime, relative quantum yield, wavelength of maximum fluorescence intensity, half-width, and polarization—of 0.01% lysozyme were measured at 15°C in aqueous solution, in glycerol–water mixtures (0–90% v/v glycerol), in aqueous urea (0–8M) solutions, and in aqueous guanidine hydrochloride (0–6.4M) solutions. The changes in the static and dynamic quenching of lysozyme fluorescence, monitored by the quantum yield and lifetime measurements, were correlated with the other fluorescence parameters and compared with our earlier results with bovine serum albumin. The results were interpreted in terms of induced conformational changes. The various perturbants altered the fluorescence parameters of lysozyme and bovine serum albumin very differently. The differences were shown to be entirely consistent with our earlier conclusion that bovine serum albumin fluorophores are nonsurface residues and with the conclusion of others that lysozyme fluorophores are surface residues. Unlike their effects on bovine serum albumin, urea and guanidine hydrochloride affect lysozyme structure quite differently, both in nature and degree. We have suggested that the affect of urea on lysozyme fluorescence is an indirect result of reduction in the size of the cleft brought about by the structure-breaking action of urea on water in the cleft. 4M Urea is sufficient for this reaction. Large decreases in the polarization of the fluorescence of lysozyme in the 0.8–1.6M and 3.2–4.8M guanidine hydrochloride ranges demonstrated two guanidine hydrochloride-induced conformation changes. A red shift of the fluorescence maximum to 354 nm indicated that the second transition completely exposes all fluorescing tryptophan residues of lysozyme to mobile solvent water. However, even 6.4M guanidine hydrochloride did not completely unravel the lysozyme molecule at 15°C, as evidenced by its failure to cause any of the tyrosine residues to become fluorescent.     

Reassignment of the active site histidines in ribonuclease A by selective deuteration studies.

The C₂H resonance of the active site histidine residue designated AS-2, which has the lower pK_a of the two active site histidines, has been correlated in both RNase A and RNase S by comparing the pH 3 to 5.5 regions of the chemical shift titration curves, the effect of the inhibitor CMP-3′ on the chemical shifts at pH 4.0, and the effect of Cu II on the line widths at pH 3.6. It has been demonstrated that resonance AS-2 is absent in the spectrum of RNase S′ reconstituted using S-peptide deuterated at the C₂ of His 12, and in that of the RNase S′-CMP-3′ complex. We thus demonstrate that histidine AS-2 is in fact His 12 in both enzymes. This finding is in agreement with out previous assignment of the exchangeable NH proton in RNase A to His 12, but reverses the assignments of the active site histidine C₂H resonances made earlier by other authors.     

Measuring denatured state energetics: deviations from random coil behavior and implications for the folding of iso-1-cytochrome c

The changes in the free energy of the denatured state of a set of yeast iso-1-cytochrome c variants with single surface histidine residues have been measured in 3 M guanidine hydrochloride. The thermodynamics of unfolding by guanidine hydrochloride is also reported. All variants have decreased stability relative to the wild-type protein. The free energy of the denatured state was determined in 3 M guanidine hydrochloride by evaluating the strength of heme-histidine ligation through determination of the pK(a) for loss of histidine binding to the heme. The data are corrected for the presence of the N-terminal amino group which also ligates to the heme under similar solution conditions. Significant deviations from random coil behavior are observed. Relative to a variant with a single histidine at position 26, residual structure of the order of -1.0 to -2.5 kcal/mol is seen for the other variants studied. The data explain the slower folding of yeast iso-1-cytochrome c relative to the horse protein. The greater number of histidines and the greater strength of ligation are expected to slow conversion of the histidine-misligated forms to the obligatory aquo-heme intermediate during the ligand exchange phase of folding. The particularly strong association of histidine residues at positions 54 and 89 may indicate regions of the protein with strong energetic propensities to collapse against the heme during early folding events, consistent with available data in the literature on early folding events for cytochrome c.     

Proton and carbon magnetic resonance studies of the synthetic polypentapeptide of elastin.

Proton and ¹³C magnetic resonance studies are reported on the synthetic polypentapeptide of elastin, HCO-(Val₍₁₎-Pro₍₂₎-Gly₍₃₎-Val₍₄₎-Gly₍₅₎)_n-Val-OMe, where n ∼- 18. Temperature and solvent dependence of peptide N$\text{H}$ chemical shift and solvent dependence of peptide carbonyl chemical shift were used to delineate these moieties preliminary to identification of secondary structure.Based on these studies it is proposed, for the organic solvents of dimethyl sulfoxide, methanol, and low-temperature trifluoroethanol, that dynamic hydrogen bonds form in order of decreasing frequency of occurrence between the Val₍₁₎$\text{C}$O and the Val₍₄₎ N$\text{H}$ (a β-turn), between the Gly₍₃₎ N$\text{H}$ and the Gly₍₅₎$\text{C}$O (an 11-atom, hydrogen-bonded ring), and a more limited interaction between the Gly₍₃₎$\text{C}$O and the Gly₍₅₎ N$\text{H}$ (a γ-turn).Arguments are presented that relate the conformational features proposed above to the coacervate, which is a filamentous state.     

Metal ion-biomolecule interactions. Part 13. NMR evidence for the formation of the mixed ligand thymidine-mercury-guanosine complex. A model for a putative Hg(Il) interstrand cross-linking structure of DNA

¹H and ¹³C NMR evidence is presented for the formation of the mixed ligand complex, [ThyHg Guo] (E). This was obtained through equilibration, in dimethyl sulfoxide solution, of 1 equivalent of the symmetrical complex [ThyHgThy] (C) with 2 equivalents of free guanosine, or similarly 1 equivalent of [GuoHgGuo] (D) with 2 equivalents of free thymidine. The relative stabilities of the nucleoside-mercury-nucleoside complexes involved in the equilibration process is C > D > E. The mixed ligand complex E appears to contain a ThyN₃HgGuoN₁ bond and thus supports an interstrand structure previously proposed for Hg(II) binding to DNA. The relative stability C > D > E is consistent with the postulate that the [ThyHgThy] interstrand complex represents the thermodynamically most stable mode of Hg(Il)- DNA interaction under physiological conditions.