Conformational analysis of a set of peptides corresponding to the entire primary sequence of the N-terminal domain of the ribosomal protein L9: evidence for stable native-like secondary structure in the unfolded state

There is considerable interest in the structure of the denatured state and in the role local interactions play in protein stability and protein folding. Studies of peptide fragments provide one method to assess local conformational preferences which may be present in the denatured state under native-like conditions. A set of peptides corresponding to the individual elements of secondary structure derived from the N-terminal domain of the ribosomal protein L9 have been synthesized. This small 56 residue protein adopts a mixed alpha-beta topology and has been shown to fold rapidly in an apparent two-state fashion. The conformational preferences of each peptide have been analyzed by proton nuclear magnetic resonance spectroscopy and circular dichroism spectroscopy. Peptides corresponding to each of the three beta-stands and to the first alpha-helix are unstructured as judged by CD and NMR. In contrast, a peptide corresponding to the C-terminal helix is remarkably structured. This 17 residue peptide is 53 % helical at pH 5.4, 4 degrees C. Two-dimensional NMR studies demonstrate that the helical structure is distributed approximately uniformly throughout the peptide, although there is some evidence for fraying at the C terminus. Detailed analysis of the NMR spectra indicate that the helix is stabilized, in part, by a native N-capping interaction involving Thr40. A mutant peptide which lacks Thr40 is only 32 % helical. pH and ionic strength-dependent studies suggested that charge charge interactions make only a modest net contribution to the stability of the peptide. The protein contains a trans proline peptide bond located at the first position of the C-terminal helix. NMR analysis of the helical peptide and of a smaller peptide containing the proline residue indicates that only a small amount of cis proline isomer (8 %) is likely to be populated in the unfolded state.     

Hydrogen-1 and carbon-13 nuclear magnetic resonance conformational studies of the His-Pro peptide bond: conformational behavior of TRH

Cis/trans isomerism of the His-Pro peptide bond provides a convenient model for the effect of a slow conformational change which may have wider biological significance. Above the imidazole pK, His-Pro is conformationally analogous to the (isosteric) peptide Phe-Pro. Protonation of the imidazole sidechain is associated with a large decrease in the cis/trans ratio. Detailed 1H and 13C n.m.r. analysis suggests the importance of electrostatic/hydrogen bonding interactions between the charged imidazolium sidechain and the proline carboxyl as the basis for this effect. In contrast to a previous report, cis/trans isomerism in TRH is shown to be related to titration of the imidazole sidechain, exhibiting a pK of 6.1.     

Equilibrium of the Cis-Trans Isomerisation of the Peptide Bond with N-alkyl Amino Acids Measured by 2D NMR

The conformational cis-trans equilibrium around the peptide bond in model tripeptides has been determined by 2D NMR methods (HOHAHA, ROESY). The study was limited to three different N-substituted amino acids in position 2, namely Pro (proline), Tic (1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid), and N-MePhe (N-methylphenylalanine). In all cases the amino acid in position 1 was tyrosine and in position 3, phenylalanine. The results of our studies show that the cis-trans ratio depends mostly on the configuration of the amino acids forming the peptide bond undergoing the cis-trans isomerisation. The amino acid following the sequence (in position 3) does not have much influence on the cis-trans isomerisation, indicating that there is no interaction of the side chains between these amino acids. The model peptides with the L-Tyr-L-AA-(L- or D-)Phe (where AA is N-substituted amino acid) chiralities give 80–100% more of the cis form in comparison to the corresponding peptides with the D-Tyr-L-AA-(L-or D-)Phe chiralities. These results indicate that the incorporation of N-substituted amino acids in small peptides with the same chirality as the precedent amino acid involved in the peptide bond undergoing the cis/trans isomerisation moves the equilibrium to a significant amount of the cis form.     

NMR structure of the alpha-hemoglobin stabilizing protein: insights into conformational heterogeneity and binding

The structure of alpha-hemoglobin stabilizing protein (AHSP), a molecular chaperone for free alpha-hemoglobin, has been determined using NMR spectroscopy. The protein native state shows conformational heterogeneity attributable to the isomerization of the peptide bond preceding a conserved proline residue. The two equally populated cis and trans forms both adopt an elongated antiparallel three alpha-helix bundle fold but display major differences in the loop between the first two helices and at the C terminus of helix 3. Proline to alanine single point mutation of the residue Pro-30 prevents the cis/trans isomerization. The structure of the P30A mutant is similar to the structure of the trans form of AHSP in the loop 1 region. Both the wild-type AHSP and the P30A mutant bind to alpha-hemoglobin, and the wild-type conformational heterogeneity is quenched upon complex formation, suggesting that just one conformation is the active form. Changes in chemical shift observed upon complex formation identify a binding interface comprising the C terminus of helix 1, the loop 1, and the N terminus of helix 2, with the exposed residues Phe-47 and Tyr-51 being attractive targets for molecular recognition. The characteristics of this interface suggest that AHSP binds at the intradimer alpha1beta1 interface in tetrameric HbA.     

s-Cis and s-trans isomerism of the His-Pro peptide bond in angiotensin and thyroliberin analogues.

The dipeptide His-Pro isomerizes from all-s-trans to partly s-cis when titrated in D2O from acidic to neutral pD as observed by 13C and 1H nuclear magnetic resonance of the proline side chain. This isomerization is reported by the His C-2 and C-4 protons and carbons which show distinct, well-resolved resonances for each isomer. The influence of the His-Pro peptide bond rotational state on the histidine protons far removed from the bond has not been previously observed in model compounds or peptides. The peptides thyroliberin (TRH), [3-MeHis2]-TRH, and [3-MeHis6]-, [Sar1,Al8]-, and Nalpha-acetylangiotensin II were found to similarly isomerize from all-s-trans to partly s-cis as reported by their His C-2 and C-4 proton resonances. The His C-2 and C-4 protons in the peptides [1,3-diMeHis2]-TRH and [1-MeHis6]-, and [homoHis6]-angiotensin do not report this isomerization. Angiotensin II has previously been found to exhibit the same isomerization. The reporting of the s-trans to s-cis isomerization by the His C-2 proton appears to be correlated with the known potencies of the five angiotensin peptides in rat uterine strips and of the three TRH peptides by radioimmunoassay of released thyrotropin.     

Conformational flexibility and folding of synthetic peptides representing an interdomain segment of polypeptide chain in the pyruvate dehydrogenase multienzyme complex of Escherichia coli

Synthetic peptides (32 residues in length) were synthesized with amino acid sequences identical to, or related to, the long (alanine + proline)-rich region of polypeptide chain that links the innermost lipoyl domain to the dihydrolipoamide dehydrogenase-binding domain in the dihydrolipoyl acetyltransferase component of the pyruvate dehydrogenase multienzyme complex of Escherichia coli. The 400-MHz 1H NMR spectra of the peptide (Mr approximately 2800) closely resembled the sharp resonances in the spectrum of the intact complex (Mr approximately 5 x 10(6], and the apparent pKa (6.4) of the side chain of a histidine residue in one of the peptides was found to be identical to that previously observed for a histidine residue inserted by site-directed mutagenesis into the corresponding position in the same (alanine + proline)-rich region of a genetically reconstructed enzyme complex. These results strongly support the view that the three long (alanine + proline)-rich regions of the dihydrolipoyl acetyltransferase chains are exposed to solvent and enjoy substantial conformational flexibility in the enzyme complex. More detailed analysis of the peptides by circular dichroism and by 1H and 13C NMR spectroscopy revealed that they were disordered in structure but were not random coils. In particular, all the Ala-Pro peptide bonds were greater than 95% in the trans configuration, consistent with a stiffening of the peptide structure. Differences in the sequences of the three long (alanine + proline)-rich segments may reflect structural tuning of these segments to optimize lipoyl domain movement in enzyme catalysis.     

Influence of sample pH on the conformational backbone dynamics of a pseudotripeptide (H-Tyr-TicΨ[CH2-NH] Phe-OH) incorporating a reduced peptide bond: An NMR investigation

In the present paper we investigate the influence of sample pH on the conformational and dynamical properties of the pseudotripeptide H-Tyr-TicΨ[CH₂NH]Phe-OH(TIP[Ψ]:Tic: l, 2, 3, 4,-tetrahydroisoquinoline-3-carboxylic acid) using various one- and two-dimensional nmt techniques in conjunction with molecular modeling. Studies were conducted at three different pH levels-corresponding to the zwitterionic peptide containing a formal positive charge(pH 3. 1).the deprotonated molecule(pH 9. 1), and a situation at neutral pH(pH 7. 2) involving both protonated and deprotonated states of the reduced peptide bond. Analysis of the one-dimensional¹H-nmr spectra reveals that in solution TIP[Ψ]is in slow dynamic exchange between conformations containing cis and trans configurations of the Tyr-Tic bond. An nmr pH dependence study of the cis:trans ratio indicated that the exchange process was governed by the protonation state of the reduced bond amine. From the nmr data, reduced peptide bond pK_avalues of 6. 5 and 7. 5 were determined for the cis and trans conformers, respectively. It was concluded that conformations containing a trans Tyr-Tic bond are stabilized at law pH by an intramolecular hydrogen bond between the Tyr carbonyl and the reduced peptide bond protonated amine. This observation was corroborated by molecular mechanics investigations that revealed low energy trans structures compatible with nmr structural data, and furthermore, were consistently characterized by the existence of a strong N⁺ H?O? C interaction closing a seven-membered cycle. The dynamics of cis-trans isomerization about the Tyr-Tic peptide bond were probed by nmr exchange experiments. The selective presaturation of exchanging resonances carried out at several temperatures between 50 and 70°C allowed the determination of isomerization rate constants as well as thermodynamic activation parameters. ΔG^≠ values were in close agreement with the cis → trans energy barrier found in X-Pro peptide fragments (～83 kJ/mol).A large entropic barrier determined for the trans → cis conversion of TIP[Ψ](5. 7 JK^?1 mol^?1 at pH 3. 1; 6. 5 JK^?1 mol^?1 at pH 9. 1) is discussed in terms of decreased solvent molecular ordering around the conformers possessing a trans Tyr-Tic bond. Evidence that the neutral form of the reduced peptide bond gains rigidity upon protonation was obtained from relaxation measurements in the rotating frame. T_Jp measurements of several protons in the vicinity of the reduced peptide bond were made as a function of spin-lock field. Quantitative analysis of the relaxation data indicated that chemical shift fluctuations in the 10^?4-10^?5s range were more pronounced in the case of deprotonated TIP[Ψ]. Results of molecular dynamics simulations in addition to ³ J _αβ coupling constant measurements support the experimentally observed greater flexibility in the C-terminal region of TIP[Ψ]. © 1995 John Wiley & Sons, Inc.     

Restricted backbone conformational and motional flexibilities of loops containing peptidyl-proline bonds dominate the enzyme activity of staphylococcal nuclease

The role of cis-trans isomerizations of peptidyl-proline bonds in the enzyme activity of staphylococcal nuclease (SNase) was examined by mutation of proline residues. The proline-free SNase ([Pro-]SNase), namely, P11A/P31A/P42A/P47T/P56A/P117G-mutant SNase, was adopted for elucidating the correlation between the nuclease activity and the backbone conformational and dynamic states of SNase. The 3D solution structure of [Pro-]SNase has been determined by heteronuclear NMR experiments. Comparing the structure of [Pro-]SNase with the structure of SNase revealed the conformational differences between the two proteins. In the structure of [Pro-]SNase, conformational rearrangements were observed for the loop of residues Ala112-His121 containing a trans Lys116-Gly117 peptide bond and for the C-terminal alpha-helical loop of residues Leu137-Glu142. Mutation of proline at position 117 also caused the conformational rearrangement of the p-loop (Asp77-Leu89), which is remote from the Ala112-His121 loop. The Ala112-His121 loop and p-loop are placed closer to each other in [Pro-]SNase than in SNase. The backbone dynamic features of the omega-loop (Pro42-Pro56) of SNase are different from those of [Pro-]SNase. The backbone of the omega-loop exhibits restricted flexibility with slow conformational exchange motions in SNase, but is highly flexible in [Pro-]SNase. The analysis indicates that the restrained backbone conformation of the Ala112-His121 loop and restricted flexibility of the omega-loop are two dominant factors determining the enzyme activity of SNase. Of the two factors, the former is correlated with the strained cis Lys116-Pro117 peptide bond and the latter is correlated with the cis-trans isomerizations of the His46-Pro47 peptide bond.     

Characterization of pH-dependent conformational heterogeneity in Rhodospirillum rubrum cytochrome c2 using 15N and 1H NMR

The 15N-enriched ferricytochrome c2 from Rhodospirillum rubrum has been studied by 15N and 1H NMR spectroscopy as a function of pH. The 15N resonances of the heme and ligand tau nitrogen are broadened beyond detection because of paramagnetic relaxation. The 15N resonance of the ligand histidine phi nitrogen was unambiguously identified at 184 ppm (pH 5.6). The 15N resonances of the single nonligand histidine are observed only at low pH, as in the ferrocytochrome because of the severe broadening caused by tautomerization. The dependence of the 15N and 1H spectra of the ferricytochrome on pH indicated that the ligand histidine tau NH does not dissociate in the neutral pH range and is involved in a hydrogen bond, similar to that in the reduced state. Because neither deprotonated nor non-hydrogen-bonded forms of the ligand histidine are observed in the spectra of either oxidation state, the participation of such forms in producing heterogeneous populations having different electronic g tensors is ruled out. Transitions having pKa's of 6.2, 8.6, and 9.2 are observed in the ferricytochrome. The localized conformational change around the omega loops is observed in the neutral pH range, as in the ferrocytochrome. Structural heterogeneity leads to multiple resonances of the heme ring methyl at position 8. The exchange rate between the conformations is temperature dependent. The transition with a pKa of 6.2 is assigned to the His-42 imidazole group. The displacement of the ligand methionine, which occurs with a pKa of 9.2, causes gross conformational change near the heme center.(ABSTRACT TRUNCATED AT 250 WORDS)     

Peptidyl-prolyl cis-trans isomerase does not affect the Pro-43 cis-trans isomerization rate in folded calbindin D9k

The calcium-binding protein calbindin D9k has previously been shown to exist in two folded forms only differing in the proline cis-trans isomerism of the Gly-42-Pro-43 amide bond. This bond is located in a flexible loop connecting the two EF-hand Ca2+ sites. Calbindin D9k therefore constitutes a unique test case for investigating if the recently discovered enzyme peptidyl-prolyl cis-trans isomerase (PPIase) can affect the cis-trans exchange rate in a folded protein. The 1H NMR saturation transfer technique has been used to measure the rate of interconversion between the cis and trans forms of calbindin in the presence of PPIase (PPIase:calbindin concentration ratio 1:10) at 35 degrees C. No rate enhancement could be detected.     

磷酸化对多肽中Xaa-Pro片段肽脯酰胺键顺反异构的影响研究

多肽和蛋白质中Xaa-Pro片段肽脯酰胺键顺反异构对其构象与功能有重要影响.设计合成了一系列模型多肽及其磷酸化多肽,并采用核磁共振实验和分子动力学模拟的方法,研究了所合成多肽中肽脯酰胺键的顺反异构化.结果表明,对脯氨酸之前的Xaa残基进行侧链O-磷酸化会极大地影响该顺反异构化过程,进而调节肽链构象.此外,磷酸化使得多肽顺式构象比例增加,且当磷酸基团不带负电荷时顺式构象所占比例最大.同时,分子动力学模拟所得结果与核磁共振实验相一致,包括最稳定构象和顺反构象统计分布.磷酸基团所带电荷及其空间位阻可能是影响这类磷酸化多肽构象变化的主要因素.     

Position-dependent interactions between cysteine residues and the helix dipole

A protein model was developed for studying the interaction between cysteine residues and the helix dipole. Site-directed mutagenesis was used to introduce cysteine residues at the N-terminus of helix H in recombinant sperm whale myoglobin. Based on the difference in thiol pK(a) between folded proteins and an unfolded peptide, the energy of interaction between the thiolate and the helix dipole was determined. Thiolates at the N1 and N2 positions of the helix were stabilized by 0.3 kcal/mole and 0.7 kcal/mole, respectively. A thiolate at the Ncap position was stabilized by 2.8 kcal/mole, and may involve a hydrogen bond. In context with other studies, an experimentally observed helix dipole effect may be defined in terms of two distinct components. A charge-dipole component involves electrostatic interactions with peptide bond dipoles in the first two turns of the helix and affects residues at all positions of the terminus; a hydrogen bond component involves one or more backbone amide groups and is only possible at the capping position due to conformational restraints elsewhere. The nature and magnitude of the helix dipole effect is, therefore, position-dependent. Results from this model system were used to interpret cysteine reactivity in rodent hemoglobins and the thioredoxin family.     

The hsp70 chaperone DnaK is a secondary amide peptide bond cis-trans isomerase

Peptidyl prolyl cis-trans isomerases can enzymatically assist protein folding, but these enzymes exclusively target the peptide bond preceding proline residues. Here we report the identification of the Hsp70 chaperone DnaK as the first member of a novel enzyme class of secondary amide peptide bond cis-trans isomerases (APIases). APIases selectively accelerate the cis-trans isomerization of nonprolyl peptide bonds. Results from independent experiments support the APIase activity of DnaK: (i) exchange crosspeaks between the cis-trans conformers appear in 2D (1)H NMR exchange spectra of oligopeptides (ii) the rate constants for the cis-trans isomerization of various dipeptides increase and (iii) refolding of the RNase T1 P39A variant is catalyzed. The APIase activity shows both regio and stereo selectivity and is stimulated two-fold in the presence of the complete DnaK/GrpE/DnaJ/ATP refolding system. Moreover, known DnaK-binding oligopeptides simultaneously affect the APIase activity of DnaK and the refolding yield of denatured firefly luciferase in the presence of DnaK/GrpE/DnaJ/ATP. These results suggest a new role for the chaperone as a regioselective catalyst for bond rotation in polypeptides.     

Proline cis-trans isomerization and protein folding

Proline cis-trans isomerization plays a key role in the rate-determining steps of protein folding. The energetic origin of this isomerization process is summarized, and the folding and unfolding of disulfide-intact bovine pancreatic ribonuclease A is used as an example to illustrate the kinetics and structural features of conformational changes from the heterogeneous unfolded state (consisting of cis and trans isomers of X-Pro peptide groups) to the native structure in which only one set of proline isomers is present.     

Origins of helix-coil switching in a light-sensitive peptide

Intramolecular cross-linking of peptides by the light-sensitive compound diiodoacetamideazobenzene has been shown to permit reversible photocontrol of the helix-coil transition. Cross-linking between Cys residues spaced at i and i + 7 positions with the trans form of the linker was found to produce a decreased helix content compared to that of the non-cross-linked peptide. Photoisomerization to the cis form of the linker led to substantially higher helix content than in the non-cross-linked peptide. Detailed conformational analysis of the system leads to the conclusion that photocontrol of helix content does not involve specific interactions between the linker and the peptide. Instead, the change in peptide helix content caused by photoisomerization can be predicted by comparing the length ranges of the cis and trans forms of the linker with the expected distance distribution of the Cys attachment points in the intrinsic conformational ensemble of the peptide. The analysis presented here should help to guide the use of these and related linkers for the conformational control of a variety of peptide and protein systems.     

Neutron structure of subtilisin BPN': effects of chemical environment on hydrogen-bonding geometries and the pattern of hydrogen-deuterium exchange in secondary structure elements

The neutron structure of subtilisin BPN' has been refined and analyzed at 2.0-A resolution. The structure studied was a mutant variant of subtilisin, Met222----Gln, and was used because large, uninhibited crystals could be grown, which was not the case for the native molecule. Comparison of the structure with that of the native molecule indicated that the two structures are essentially the same. Using the capability of the neutron method to locate hydrogen and deuterium atoms, the protonation states of the six histidine residues were assigned. The active site histidine, His64, was found to be neutral at the pH of the analysis (pH 6.1). This group has an unexpectedly low pKa compared to assignments made by other techniques. The altered pKa of the group could result from electrostatic effects of other molecules in the crystal lattice. The dihedral conformations of a majority of the hydroxyl rotors were assigned. The preferred orientation was trans (180 degrees) with the other two low-energy conformers (60 degrees, 300 degrees) about equally populated. For the serines, about 21% of the hydroxyls act exclusively as H-bond acceptors and 37% as H-bond donors, and in 42% the group functions as both. The experimentally observed dihedral conformations were compared to predicted conformations based on calculated energy criteria and showed a strong correspondence. Deviation from low-energy states could usually be explained by local electrostatic effects. The hydrogen exchange pattern of subtilisin identified the beta-sheet and alpha-helix secondary structure elements to be the most resistant to exchange. Fifty-five percent of the peptide amide hydrogens were fully exchanged, 15% unexchanged, and 30% partially exchanged. The largest concentration of unexchanged sites was in the seven-stranded parallel beta-sheet, in which there were 11 fully protected groups. Little correlation was found between H-bond length and angle and a peptide group's susceptibility toward exchange. Of the five alpha-helices the most protected from exchange is the one defined by residues 224-236. The pattern of exchange identifies regions in this helix where the H-bonding regularity is disrupted.     

The role of PII conformations in the calculation of peptide fractional helix content.

Changes in the temperature, pH, ionic strength, or denaturant concentration of aqueous solutions of the monomeric non-alpha-helical peptide acetylYEAAAKEAPAKEAAAKAamide generate changes in its dichroic spectrum characteristic for a conformational transition. This transition has the characteristic features of a residue PII/unstructured conformational equilibrium in which PII denotes an extended left-handed helical conformation and unstructured denotes all the remaining conformations in a random coil ensemble. Replacement of the proline residue facilitates population of residues in an alpha-helical conformation. However, the ellipticity values for these non-proline peptides merge with the ellipticity of the proline peptide as the population of residues in the alpha-helix conformation is diminished. This convergence suggests that all residues in a host/guest peptide series of the same length share a common PII/unstructured conformational equilibrium in a given solvent. We propose that the fractional helix content of peptides within such a series may be estimated by using a two-state calculation in which the ellipticity for the non-alpha-helix conformations is provided by a peptide having a central proline guest residue.     

Control of pH responsive peptide self-association during endocytosis is required for effective gene transfer

Cationic amphipathic histidine rich peptides demonstrate differential nucleic acid binding capabilities at neutral and acidic pH and adopt conformations at acidic pH that enable interaction with endosomal membranes, their subsequent disordering and facilitate entry of cargo to the cell cytosol. To better understand the relative contributions of each stage in the process and consequently the structural requirements of pH responsive peptides for optimal nucleic acid transfer, we used biophysical methods to dissect the series of events that occur during endosomal acidification. Far-UV circular dichroism was used to characterise the solution conformation of a series of peptides, containing either four or six histidine residues, designed to respond at differing pH while a novel application of near-UV circular dichroism was used to determine the binding affinities of the peptides for both DNA and siRNA. The peptide induced disordering of neutral and anionic membranes was investigated using (2)H solid-state NMR. While each of these parameters models key stages in the nucleic acid delivery process and all were affected by increasing the histidine content of the peptide, the effect of a more acidic pH response on peptide self-association was most notable and identified as the most important barrier to further enhancing nucleic acid delivery. Further, the results indicate that Coulombic interactions between the histidine residues modulate protonation and subsequent conformational transitions required for peptide mediated gene transfer activity and are an important factor to consider in future peptide design.     

Structures of the contryphan family of cyclic peptides. Role of electrostatic interactions in cis-trans isomerism

The contryphan family of cyclic peptides, isolated recently from various species of cone shell, has the conserved sequence motif NH(3)(+)-X(1)COD-WX(5)PWC-NH(2), where X(1) is either Gly or absent, O is 4-trans-hydroxyproline, and X(5) is Glu, Asp, or Gln. The solution structures described herein of two new naturally occurring contryphan sequences, contryphan-Sm and des[Gly1]-contryphan-R, are similar to those of contryphan-R, the structure of which has been determined recently [Pallaghy et al. (1999) Biochemistry 38, 11553-11559]. The (1)H NMR chemical shifts of another naturally occurring peptide, contryphan-P, indicate that it also adopts a similar structure. All of these contryphans exist in solution as a mixture of two conformers due to cis-trans isomerization about the Cys2-Hyp3 peptide bond. The lower cis-trans ratio for contryphan-Sm enabled elucidation of the 3D structure of both its major and its minor forms, for which the patterns of (3)J(H)(alpha)(HN) coupling constants are very different. As with contryphan-R, the structure of the major form of contryphan-Sm (cis Cys2-Hyp3 peptide bond) contains an N-terminal chain reversal and a C-terminal type I beta-turn. The minor conformer (trans peptide bond) forms a hairpin structure with sheetlike hydrogen bonds and a type II beta-turn, with the D-Trp4 at the 'Gly position' of the turn. The ratio of conformers arising from cis-trans isomerism around the peptide bond preceding Hyp3 is sensitive to both the amino acid sequence and the solution conditions, varying from 2.7:1 to 17:1 across the five sequences. The sequence and structural determinants of the cis-trans isomerism have been elucidated by comparison of the cis-trans ratios for these peptides with those for contryphan-R and an N-acetylated derivative thereof. The cis-trans ratio is reduced for peptides in which either the charged N-terminal ammonium or the X(5) side-chain carboxylate is neutralized, implying that an electrostatic interaction between these groups stabilizes the cis conformer relative to the trans. These results on the structures and cis-trans equilibrium of different conformers suggest a paradigm of 'locally determined but globally selected' folding for cyclic peptides and constrained protein loops, where the series of stereochemical centers in the loop dictates the favorable conformations and the equilibrium is determined by a small number of side-chain interactions.     

The Pro117 to glycine mutation of staphylococcal nuclease simplifies the unfolding-folding kinetics

Kinetics of unfolding and refolding of a staphylococcal nuclease mutant, in which Pro117 is replaced by glycine, have been investigated by stopped-flow circular dichroism, and the results are compared with those for the wild-type protein. In contrast to the biphasic unfolding of the wild-type nuclease, the unfolding of the mutant is represented by a single-phase reaction, indicating that the biphasic unfolding for the wild-type protein is caused by cis-trans isomerization about the prolyl peptide bond in the native state. The proline mutation also simplifies the kinetic refolding. Importance of the results in elucidating the folding mechanism is discussed.