Catalysis of proline-directed protein phosphorylation by peptidyl-prolyl cis/trans isomerases

Proline-directed protein phosphorylation was shown to depend on the capacity of the targeted Ser(Thr)-Pro bond to exhibit conformational polymorphism. The cis/trans isomer specificity underlying ERK2-catalyzed phosphate transfer leads to a complete discrimination of the cis Ser(Thr)-Pro conformer of oligopeptide substrates. We investigated in vitro the ERK2-catalyzed phosphorylation of Aspergillus oryzae RNase T1 containing two Ser-Pro bonds both of which share high stabilization energy in their respective native state conformation, the cis Ser54-Pro and the trans Ser72-Pro moiety. Despite trans isomer specificity of ERK2, a doubly phosphorylated RNase T1 was found as the final reaction product. Similarly, the RNase T1 S54G/P55N and RNase T1 P73V variants, which retain the prolyl bond conformations of the RNase T1-wt, were both monophosphorylated with a catalytic efficiency kcat/KM of 425 M(-1) s(-1) and 1228 M(-1) s(-1), respectively. However, initial phosphorylation rates did not depend linearly on the ERK2 concentration. The phosphorylation rate of the resulting plateau region at high ERK2 concentrations can be increased up to threefold for the RNase T1 P73V variant in the presence of the peptidyl-prolyl cis/trans isomerase Cyclophilin 18, indicating a conformational interconversion as the rate limiting step in the catalyzed phosphate group transfer. Using peptidyl-prolyl cis/trans isomerases with different substrate specificity, we identified a native state conformational equilibrium of the Ser54-Pro bond with the minor trans Ser54-Pro bond as the phosphorylation-sensitive moiety. This technique can therefore be used for a determination of the ratio and the interconversion rates of prolyl bond isomers in the native state of proteins.     

Inhibition of Pin1 reduces glutamate-induced perikaryal accumulation of phosphorylated neurofilament-H in neurons

Under normal conditions, the proline-directed serine/threonine residues of neurofilament tail-domain repeats are exclusively phosphorylated in axons. In pathological conditions such as amyotrophic lateral sclerosis (ALS), motor neurons contain abnormal perikaryal accumulations of phosphorylated neurofilament proteins. The precise mechanisms for this compartment-specific phosphorylation of neurofilaments are not completely understood. Although localization of kinases and phosphatases is certainly implicated, another possibility involves Pin1 modulation of phosphorylation of the proline-directed serine/threonine residues. Pin1, a prolyl isomerase, selectively binds to phosphorylated proline-directed serine/threonine residues in target proteins and isomerizes cis isomers to more stable trans configurations. In this study we show that Pin1 associates with phosphorylated neurofilament-H (p-NF-H) in neurons and is colocalized in ALS-affected spinal cord neuronal inclusions. To mimic the pathology of neurodegeneration, we studied glutamate-stressed neurons that displayed increased p-NF-H in perikaryal accumulations that colocalized with Pin1 and led to cell death. Both effects were reduced upon inhibition of Pin1 activity by the use of an inhibitor juglone and down-regulating Pin1 levels through the use of Pin1 small interfering RNA. Thus, isomerization of lys-ser-pro repeat residues that are abundant in NF-H tail domains by Pin1 can regulate NF-H phosphorylation, which suggests that Pin1 inhibition may be an attractive therapeutic target to reduce pathological accumulations of p-NF-H.     

Peptidyl-prolyl cis-trans isomerase activity as studied by dynamic proton NMR spectroscopy

Recently the identity of the peptidyl-prolyl cis-trans isomerase (PPIase), which accelerates the cis/trans isomerization of prolyl peptide bonds and cyclophilin, the binding protein for the immunosuppressive drug Cyclosporin A (CsA), was discovered. The PPIase catalysis toward the substrate Suc-Ala-Phe-Pro-Phe-pNA has been studied by 1H NMR spectroscopy. Using the bandshape analysis technique the rate of interconversion between the cis and trans isomers of the substrate could be measured in the presence of PPIase and under equilibrium conditions. The acceleration is inhibited by equimolar amounts of CsA. The results provide evidence that the PPIase catalysis is more complex than a simple exchange between two states.     

Phosphorylation-induced structural changes in the amyloid precursor protein cytoplasmic tail detected by NMR

The cytoplasmic tail of the amyloid precursor protein (APPc) interacts with several cellular factors implicated in intracellular signaling or proteolytic production of amyloid beta peptide found in senile plaques of Alzheimer's disease patients. APPc contains two threonine residues (654 and 668 relative to APP695, or 6 and 20 relative to APPc) and a serine residue (655 or 7, respectively) that are known to be phosphorylated in vivo and may play regulatory roles in these events. We show by solution NMR spectroscopy of a 49 residue cytoplasmic tail peptide (APP-C) that in all three cases, phosphorylation induces changes in backbone dihedral angles that can be attributed to formation of local hydrogen bonds between the phosphate group and nearby amide protons. Phosphorylation of S7 also induces chemical shift changes in the hydrophobic cluster (residues I8-V13), indicating additional medium-range effects. The most pronounced changes occur upon phosphorylation of T20, a neuron-specific phosphorylation site, where the N-terminal helix capping box previously characterized for this region is altered. Characterization of torsion angles and transient hydrogen bonds indicates that prolyl isomerization of the pThr-Pro peptide bond results from both destabilization of the N-terminal helix capping box and stabilization of the cis isomer by transient hydrogen bonds. The significant population of the cis isomer (9 %) present after phosphorylation of T20 suggests a potential role of selective recognition of cis versus trans isomers in response to phosphorylation of APP. Together, these structural changes indicate that phosphorylation may act as a conformational switch in the cytoplasmic tail of APP to alter specificity and affinity of binding to cytosolic partners, particularly in response to the abnormal phosphorylation events associated with Alzheimer's disease.     

Energetic coupling between native-state prolyl isomerization and conformational protein folding

In folded proteins, prolyl peptide bonds are usually thought to be either trans or cis because only one of the isomers can be accommodated in the native folded protein. For the N-terminal domain of the gene-3 protein of the filamentous phage fd (N2 domain), Pro161 resides at the tip of a beta hairpin and was found to be cis in the crystal structure of this protein. Here we show that Pro161 exists in both the cis and the trans conformations in the folded form of the N2 domain. We investigated how conformational folding and prolyl isomerization are coupled in the unfolding and refolding of N2 domain. A combination of single-mixing and double-mixing unfolding and refolding experiments showed that, in unfolded N2 domain, 7% of the molecules contain a cis-Pro161 and 93% of the molecules contain a trans-Pro161. During refolding, the fraction of molecules with a cis-Pro161 increases to 85%. This implies that 10.3 kJ mol(-1) of the folding free energy was used to drive this 75-fold change in the Pro161 cis/trans equilibrium constant during folding. The stabilities of the forms with the cis and the trans isomers of Pro161 and their folding kinetics could be determined separately because their conformational folding is much faster than the prolyl isomerization reactions in the native and the unfolded proteins. The energetic coupling between conformational folding and Pro161 isomerization is already fully established in the transition state of folding, and the two isomeric forms are thus truly native forms. The folding kinetics are well described by a four-species box model, in which the N2 molecules with either isomer of Pro161 can fold to the native state and in which cis/trans isomerization occurs in both the unfolded and the folded proteins.     

Solution structure of a DNA duplex containing a formamide-adenine base pair

The N-(2-deoxy-beta3-D-erythro-pentofuranosyl) formamide residue results from a ring fragmentation product of thymine or cytosine. The presence of a formamide-adenine base pair in the sequence 5'd(AGGAACCACG).d(CGTGGFTCCT) has been studied by 1H and 31P nuclear magnetic resonance (NMR) and molecular dynamics. There are two possible isomers for the formamide side chain, either cis or trans. For each isomer, we observed an equilibrium in solution between two forms. First, a species where the formamide is intrahelical and paired with the facing adenine. For the cis isomer, the formamide is in a syn conformation and two hydrogen bonds with adenine are formed. The trans isomer is in an anti conformation and a single hydrogen bond is observed. In the second form, whatever the isomer, the formamide is rejected outside the helix, whereas the adenine remains inside.     

Pin1-dependent prolyl isomerization regulates dephosphorylation of Cdc25C and tau proteins

The reversible protein phosphorylation on serine or threonine residues that precede proline (pSer/Thr-Pro) is a key signaling mechanism for the control of various cellular processes, including cell division. The pSer/Thr-Pro moiety in peptides exists in the two completely distinct cis and trans conformations whose conversion is catalyzed specifically by the essential prolyl isomerase Pin1. Previous results suggest that Pin1 might regulate the conformation and dephosphorylation of its substrates. However, it is not known whether phosphorylation-dependent prolyl isomerization occurs in a native protein and/or affects dephosphorylation of pSer/Thr-Pro motifs. Here we show that the major Pro-directed phosphatase PP2A is conformation-specific and effectively dephosphorylates only the trans pSer/Thr-Pro isomer. Furthermore, Pin1 catalyzes prolyl isomerization of specific pSer/Thr-Pro motifs both in Cdc25C and tau to facilitate their dephosphorylation by PP2A. Moreover, Pin1 and PP2A show reciprocal genetic interactions, and prolyl isomerase activity of Pin1 is essential for cell division in vivo. Thus, phosphorylation-specific prolyl isomerization catalyzed by Pin1 is a novel mechanism essential for regulating dephosphorylation of certain pSer/Thr-Pro motifs.     

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.     

Stress and strain in staphylococcal nuclease.

Protein molecules generally adopt a tertiary structure in which all backbone and side chain conformations are arranged in local energy minima; however, in several well-refined protein structures examples of locally strained geometries, such as cis peptide bonds, have been observed. Staphylococcal nuclease A contains a single cis peptide bond between residues Lys 116 and Pro 117 within a type VIa beta-turn. Alternative native folded forms of nuclease A have been detected by NMR spectroscopy and attributed to a mixture of cis and trans isomers at the Lys 116-Pro 117 peptide bond. Analyses of nuclease variants K116G and K116A by NMR spectroscopy and X-ray crystallography are reported herein. The structure of K116A is indistinguishable from that of nuclease A, including a cis 116-117 peptide bond (92% populated in solution). The overall fold of K116G is also indistinguishable from nuclease A except in the region of the substitution (residues 112-117), which contains a predominantly trans Gly 116-Pro 117 peptide bond (80% populated in solution). Both Lys and Ala would be prohibited from adopting the backbone conformation of Gly 116 due to steric clashes between the beta-carbon and the surrounding residues. One explanation for these results is that the position of the ends of the residue 112-117 loop only allow trans conformations where the local backbone interactions associated with the phi and psi torsion angles are strained. When the 116-117 peptide bond is cis, less strained backbone conformations are available. Thus the relaxation of the backbone strain intrinsic to the trans conformation compensates for the energetically unfavorable cis X-Pro peptide bond. With the removal of the side chain from residue 116 (K116G), the backbone strain of the trans conformation is reduced to the point that the conformation associated with the cis peptide bond is no longer favorable.     

Proline isomer-specific antibodies reveal the early pathogenic tau conformation in Alzheimer's disease

cis-trans isomerization of proteins phosphorylated by proline-directed kinases is proposed to control numerous signaling molecules and is implicated in the pathogenesis of Alzheimer's and other diseases. However, there is no direct evidence for the existence of cis-trans protein isomers in?vivo or for their conformation-specific function or regulation. Here we develop peptide chemistries that allow the generation of cis- and trans-specific antibodies and use them to raise antibodies specific for isomers of phosphorylated tau. cis, but not trans, p-tau appears early?in the brains of humans with mild cognitive impairment, accumulates exclusively in degenerated neurons, and localizes to dystrophic neurites during Alzheimer's progression. Unlike trans p-tau, the cis isomer cannot promote microtubule assembly, is more resistant to dephosphorylation and degradation, and is more prone to aggregation. Pin1 converts cis to trans p-tau to prevent Alzheimer's tau pathology. Isomer-specific antibodies and vaccines may therefore have value for the early diagnosis and treatment of Alzheimer's disease.     

A kinetic study of the folding of staphylococcal nuclease using size-exclusion chromatography.

The kinetics of the hydrodynamic volume change accompanying the reversible unfolding of staphylococcal nuclease have been observed by size-exclusion chromatography at 4 degrees C and pH 7.0 using the denaturant guanidine hydrochloride. The observed chromatographic profiles have been simulated by a six-component unfolding/refolding mechanism using a consistent set of equilibrium and kinetic parameters. The native protein is an equilibrium mixture of the cis and trans isomers of the peptide bond preceding proline-117. The native conformation containing the cis isomer dominates the equilibrium mixture, is more stable, and unfolds more slowly at its transition midpoint. The denatured protein is an equilibrium mixture of at least four components, the cis/trans isomers of proline-117 and one of the five remaining prolines. The dominant refolding pathway is initiated from the denatured component containing the trans isomer of proline-117. The six-component mechanism is consistent with tryptophan fluorescence kinetic measurements of the wild-type protein and with chromatographic measurements of a mutant P117G protein.     

Complete determination of the Pin1 catalytic domain thermodynamic cycle by NMR lineshape analysis

The phosphorylation-specific peptidyl-prolyl isomerase Pin1 catalyzes the isomerization of the peptide bond preceding a proline residue between cis and trans isomers. To best understand the mechanisms of Pin1 regulation, rigorous enzymatic assays of isomerization are required. However, most measures of isomerase activity require significant constraints on substrate sequence and only yield rate constants for the cis isomer, [Formula: see text] and apparent Michaelis constants, [Formula: see text]. By contrast, NMR lineshape analysis is a powerful tool for determining microscopic rates and populations of each state in a complex binding scheme. The isolated catalytic domain of Pin1 was employed as a first step towards elucidating the reaction scheme of the full-length enzyme. A 24-residue phosphopeptide derived from the amyloid precurser protein intracellular domain (AICD) phosphorylated at Thr668 served as a biologically-relevant Pin1 substrate. Specific (13)C labeling at the Pin1-targeted proline residue provided multiple reporters sensitive to individual isomer binding and on-enzyme catalysis. We have performed titration experiments and employed lineshape analysis of phosphopeptide (13)C-(1)H constant time HSQC spectra to determine [Formula: see text], [Formula: see text], [Formula: see text], and [Formula: see text] for the catalytic domain of Pin1 acting on this AICD substrate. The on-enzyme equilibrium value of [E·trans]/[E·cis]?=?3.9 suggests that the catalytic domain of Pin1 is optimized to operate on this substrate near equilibrium in the cellular context. This highlights the power of lineshape analysis for determining the microscopic parameters of enzyme catalysis, and demonstrates the feasibility of future studies of Pin1-PPIase mutants to gain insights on the catalytic mechanism of this important enzyme.     

Solution structure by NMR and molecular dynamics of a duplex containing a guanine opposite a N-(2-deoxy-beta-D-erythro-pentofuranosyl)formamide lesion

One- and two-dimensional NMR spectroscopy has been used combined with molecular dynamics to determine the fine structure of the DNA duplex 5'-d(AGGAGCCACG).d(CGTGGFTCCT) where F is the N-(2-deoxy-beta-D-erythro-pentofuranosyl)formamide residue which is a ring fragmentation product of thymine. The formamide deoxyribose exists as two isomers with respect to the orientation about the peptide bond. The two isomers (trans and cis) are observed in a ratio 3:2 in solution. For both species, the oligonucleotide adopts a globally B form structure although conformational changes are observed around the mismatch site. The formamide residue, whatever the isomer, is intrahelical and can pair with the guanine on the opposite strand with one hydrogen bond. For the cis isomer, the residue adopts a syn orientation and is able to form a second hydrogen bond with the guanine on the 5' side on the same strand. Off-resonance ROESY experiments have been used to investigate the chemical exchange observed at low temperature of the duplex. Conformational exchange has only been found for the oligonucleotide with the formamide residue in the trans conformation.     

The importance of anchorage in determining a strained protein loop conformation.

We examine the role of the conformational restriction imposed by constrained ends of a protein loop on the determination of a strained loop conformation. The Lys 116-Pro 117 peptide bond of staphylococcal nuclease A exists in equilibrium between the cis and trans isomers. The folded protein favors the strained cis isomer with an occupancy of 90%. This peptide bond is contained in a solvent-exposed, flexible loop of residues 112-117 whose ends are anchored by Val 111 and Asn 118. Asn 118 is constrained by 2 side-chain hydrogen bonds. We investigate the importance of this constraint by replacing Asn 118 with aspartate, alanine, and glycine. We found that removing 1 or more of the hydrogen bonds observed in Asn 118 stabilizes the trans configuration over the cis configuration. By protonating the Asp 118 side chain of N118D through decreased pH, the hydrogen bonding character of Asp 118 approached that of Asn 118 in nuclease A, and the cis configuration was stabilized relative to the trans configuration. These data suggest that the rigid anchoring of the loop end is important in establishing the strained cis conformation. The segment of residues 112-117 in nuclease A provides a promising model system for study of the basic principles that determine polypeptide conformations. Such studies could be useful in the rational design or redesign of protein molecules.     

Conformational analysis of cyclic hexapeptides designed as constrained ligands for the SH2 domain of the p85 subunit of phosphatidylinositol-3-OH kinase

The structures of the cyclic hexapeptide cyclo(-Gly-Tyr-Val-Pro-Met-Leu-) ( 1 ) and its phosphotyrosyl (pTyr) derivative cyclo[-Gly-Tyr(PO₃H₂)-Val-Pro-Met-Leu-] ( 2 ), designed as constrained models of a sequence that interacts with the src homology 2 (SH2) region of the p85 subunit of phosphatidylinositol-3-OH kinase (PI-3 kinase), were studied in methanol/water solutions by 500 MHz nmr spectroscopy. Compound 1 was found to exist as a 2:1 mixture of isomers about the Val-Pro bond (trans and cis prolyl) between 292–330 K in 75% CD₃O (D,H)/(D,H)₂O solutions. A third species of undetermined structure (ca. 5%) was also observed. Compound 2, a model of phosphorylated peptide ligand that binds to the PI-3 kinase SH2 domain, exhibited similar conformational isomerism. When either compound was dissolved in pure solvent [i.e., 100% CD₃O(H,D) or (H,D)₂O] the ratio of cis to trans isomers was ca 1:1. A battery of one- and two-dimensional nmr experiments at different temperatures and solvent compositions allowed a complete assignment of both the cis and trans forms of 1 and indicated the trans compound to be the major isomer. The spectral properties of the phosphorylated derivative 2 paralleled those of 1 , indicating like conformations for the two compounds. Analysis of rotating frame Overhauser spectroscopy data, coupling constants, amide proton temperature dependence, and amide proton exchange rates generated a set of constraints that were employed in energy minimization and molecular dynamics calculations using the CHARMM force field. The trans isomer exists with the tyrosine and C-terminal Tyr(+3) (Met) residues at opposite corners of the 18-membered ring separated by a distance of 16–18 Å, in contrast with the cis isomer where the side chains of these residues are much closer in space (7–14 Å). It was previously shown that the pTyr and the third amino acid C-terminal to this residue are the critical recognition elements for pTyr-peptide binding to the PI-3 kinase SH2 domain. Such cyclic structures may offer appropriate scaffolding for positioning important amino acid side chains of pTyr-containing peptides as a means of increasing their binding affinities to SH2 domains, and in turn provide a conceptual approach toward the design of SH2 domain directed peptidomimetics. © 1995 John Wiley & Sons, Inc.     

Conservation of cis prolyl bonds in proteins during evolution

In proteins and peptides, the vast majority of peptide bonds occurs in trans conformation, but a considerable fraction (about 5%) of X-Pro bonds adopts the cis conformation. Here we study the conservation of cis prolyl residues in evolutionary related proteins. We find that overall, in contrast to local, protein sequence similarity is a clear indicator for the conformation of prolyl residues. We observe that cis prolyl residues are more often conserved than trans prolyl residues, and both are more conserved than the surrounding amino acids, which show the same extent of conservation as the whole protein. The pattern of amino acid exchanges differs between cis and trans prolyl residues. Also, the cis prolyl bond is maintained in proteins with sequence identity as low as 20%. This finding emphasizes the importance of cis peptide bonds in protein structure and function.     

A conserved cis peptide bond is necessary for the activity of Bowman-Birk inhibitor protein

The Bowman-Birk inhibitor (BBI) family of protease inhibitors has an inhibitory region comprising a disulfide-linked nine-residue loop that adopts the characteristic canonical motif found in many serine protease inhibitors. A unique feature of the BBI loop is the presence of a cis peptide bond at the edge of the inhibitory loop. BBI-related protein fragments that encapsulate this loop retain the structure and inhibitory activity of the parent protein. The most common BBI loop sequence has a proline-proline element with a cis-trans geometry at P3'-P4'. We have examined this element by analysis of the inhibitory activity and structure for a series of synthetic fragments where each of these proline residues has been systematically replaced with alanine. The results show that only when a proline is present at P3' are potent inhibition and a cis peptide bond at that position in the solution structure observed, suggesting that this conformation is required for biological activity. Though a P4' proline is not essential for activity, it effectively stabilizes the cis conformation at P3' by suppressing alternative conformations. This is most evident from the Pro-Ala variant, which comprises a 1:1 mixture of slowly exchanging and structurally different cis and trans isomers. Monitoring the action of trypsin on this mixture by NMR shows that this protease interacts selectively with the cis P3' structure, providing direct evidence for the link between activity and the nativelike structure of the cis isomer. This is, to the best of our knowledge, the first example where cis isomer selectivity can be demonstrated for a proteinase.     

Evaluation of similarities in the cis/trans isomerase function of trigger factor and DnaK

Two functionally redundant enzymes, trigger factor and the hsp70 chaperone DnaK, have been found to assist de novo protein folding in E coli. Trigger factor is a peripheral peptidyl prolyl cis/trans isomerase (PPIase) of the large subunit of the ribosome. In contrast, DnaK displays two catalytic features: the secondary amide peptide bond cis/trans isomerase (APIase) function supplemented by the ATPase site. APIases accelerate the cis/trans isomerization of nonprolyl peptide bonds. Both enzymes have affinity for an unfolded polypeptide chain. The diminished low temperature cell viability in the presence of trigger factor variants with impaired PPlase activity indicates that the enhancement of folding rates plays a crucial role in protein folding in vivo. For the DnaK-mediated increase in the folding yield in vitro, the minimal model for APlase catalysis involves the catalyzed partitioning of a rapidly formed folding intermediate as could be inferred from the DnaK/DnaJ/GrpE/ATP-assisted refolding of GdmCl-denatured luciferase. Using three different peptide bond cis/trans isomerization assays in vitro, we could show that there is no overlapping substrate specificity of trigger factor and DnaK. We propose that only if trigger factor recruits supplementing molecules is it capable of exhibiting functional complementarity with DnaK in protein folding.     

Thermodynamic origin of cis/trans isomers of a proline-containing beta-turn model dipeptide in aqueous solution: a combined variable temperature 1H-NMR, two-dimensional 1H,1H gradient enhanced nuclear Overhauser effect spectroscopy (NOESY), one-dimensional steady-state intermolecular 13C,1H NOE, and molecular dynamics study

The cis/trans conformational equilibrium of the two Ac-Pro isomers of the beta-turn model dipeptide [13C]-Ac-L-Pro-D-Ala-NHMe, 98% 13C enriched at the acetyl carbonyl atom, was investigated by the use of variable temperature gradient enhanced 1H-nmr, two-dimensional (2D) 1H,1H nuclear Overhauser effect spectroscopy (NOESY), 13C,1H one-dimensional steady-state intermolecular NOE, and molecular dynamics calculations. The temperature dependence of the cis/trans Ala(NH) protons are in the region expected for random-coil peptides in H2O (delta delta/delta T = -9.0 and -8.9 ppb for the cis and trans isomers, respectively). The trans NH(CH3) proton indicates smaller temperature dependence (delta delta/delta T approximately -4.8 ppb) than that of the cis isomer (-7.5 ppb). 2D 1H,1H NOESY experiments at 273 K demonstrate significant NOEs between ProH alpha-AlaNH and AlaNH-NH(R) for the trans isomer. The experimental NOE data, coupled with computational analysis, can be interpreted by assuming that the trans isomer most likely adopts an ensemble of folded conformations. The C-CONH(CH3) fragment exhibits significant conformational flexibility; however, a low-energy conformer resembles closely the beta II-turn folded conformations of the x-ray structure of the related model peptide trans-BuCO-L-Pro-Me-D-Ala-NHMe. On the contrary, the cis isomer adopts open conformations. Steady-state intermolecular solute-solvent (H2O) 13C,1H NOE indicates that the water accessibility of the acetyl carbonyl carbons is nearly the same for both isomers. This is consistent with rapid fluctuations of the conformational ensemble and the absence of a highly shielded acetyl oxygen from the bulk solvent. Variable temperature 1H-nmr studies of the cis/trans conformational equilibrium indicate that the trans form is enthalpically favored (delta H degree = -5.14 kJ mole-1) and entropically (delta S degree = -5.47 J.K-1.mole-1) disfavored relative to the cis form. This demonstrates that, in the absence of strongly stabilizing sequence-specific interresidue interactions involving side chains and/or charged terminal groups, the thermodynamic difference of the cis/trans isomers is due to the combined effect of intramolecular and intermolecular (hydration) induced conformational changes.