Reversible photocontrol of peptide helix content: adjusting thermal stability of the cis state

Cross-linking reagents based on an azobenzene core can be used to reversibly photoregulate secondary structure when introduced as intramolecular bridges in peptides and proteins. Photoisomerization of the azobenzene core in the trans to cis direction is triggered by photon absorption but isomerization from cis to trans occurs thermally as well as photochemically. The rate of the thermal process effectively determines the half-life of the cis form as well as the extent to which the trans form can be recovered. We designed and characterized a series of methanethiosulfonate (MTS)-bearing thiol-reactive azo-benzene-based cross-linkers. These cross-linkers are shown to permit photoregulation of helix content in a test peptide with half-lives for the cis conformation ranging from 11 s to 43 h at 25 degrees C. The cross-linkers described here thus broaden the range of reagents available for reversible photocontrol of peptide and protein conformation.     

A blue-green absorbing cross-linker for rapid photoswitching of peptide helix content

Azobenzene derivatives can be used to reversibly photoregulate secondary structure when introduced as intramolecular bridges in peptides and proteins. Here we report the design, synthesis, and characterization of a disubstituted N,N-dialkyl azobenzene derivative that absorbs near 480 nm in aqueous solution and relaxes with a half-life of approximately 50 ms at room temperature. The wavelength of maximum absorbance and the rate of thermal relaxation are solvent-dependent. An increase in the percentage of organic solvent leads, in general, to a blue shift in the absorbance maximum and a slowing of the relaxation rate. In accordance with the design, the thermal relaxation of the azobenzene cross-linker from cis to trans causes an increase in the helix content of one peptide where the linker is attached via cysteine residues spaced at i, i + 11 positions and a decrease in helix content of another peptide with cysteine residues spaced at i, i + 7. This cross-linker design thus expands the possibilities for fast photocontrol of peptide and protein structure.     

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.     

The conformational equilibria of a renin inhibitor peptide in solution

The conformational equilibrium of a decapeptide renin inhibitor (Renin Inhibitory Peptide (RIP), NH-P-H-P-F-H-F-F-V-Y-K-CO2H) in water, methanol and trifluoroethanol has been investigated. The value of a combined spectroscopic approach was apparent, with the need to define conformational states that were mixtures of conformational forms. Similarities between this study and that of the Melanin Concentrating Hormone (MCH) core peptide (5-14) are notable [1]. In water, two beta-turn conformations and an extended form were found to be in equilibrium, with cis/trans isomerism at Pro-3. Extended conformations associated with the P(II) helix and irregular forms were more favoured in aqueous environments. In MeOH and TFE, two beta-turn conformations associated with overlapping sequences and cis/trans isomerism at Pro-3 amide bond were seen to be in equilibrium. 2D ROESY and chemical-exchange cross-peaks were detected by 1H NMR and used to build up detailed models of the interconverting beta-turn conformations of RIP.     

Local and nonlocal environments around Cis peptides

Although the vast majority of peptide bonds in folded proteins are found in the trans conformation, a small percentage are found in the less energetically favorable cis conformation. Though the mechanism of cis peptide bond formation remains unknown, the role of local aromatics has been emphasized in the literature. This paper presents results from a comprehensive statistical analysis of both the local and nonlocal (i.e., tertiary) environment around cis peptides. In addition to an increased frequency of aromatic residues in the local environment around cis peptides, a number of nonlocal differences in protein secondary and tertiary structure between cis and trans peptides are found: (i) coil regions containing cis peptides are almost twice as long as those without cis peptides and include more Tyr and Pro residues; (ii) cis peptides occur with high frequencies in coil regions near large beta-structures; (iii) there is a nonlocal enrichment of Cys, His, Tyr, and Ser in the tertiary environment surrounding cis peptides when compared to trans peptides; and (iv) on average, cis peptides make fewer medium-range and more long-range contacts than trans peptides do. On the basis of these observations, it is concluded that nonlocal factors play a significant role in cis peptide formation, which has not been fully appreciated previously. An autocatalytic model for cis peptide formation is discussed as are consequences for 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.     

Reversible photocontrol of DNA binding by a designed GCN4-bZIP protein

Synthetic photocontrolled proteins could be powerful tools for probing cellular chemistry. Several previous attempts to produce such systems by incorporating photoisomerizable chromophores into biomolecules have led to photocontrol but with incomplete reversibility, where the chromophore becomes trapped in one photoisomeric state. We report here the design of a modified GCN4-bZIP DNA-binding protein with an azobenzene chromophore introduced between Cys residues at positions 262 and 269 (S262C, N269C) within the zipper domain. As predicted, the trans form of the chromophore destabilizes the helical structure of the coiled-coil region of GCN4-bZIP, leading to diminished DNA binding relative to wild type. Trans-to-cis photoisomerization of the chromophore increases helical content and substantially enhances DNA binding. The system is observed to be readily reversible; thermal relaxation of the chromophore to the trans state and concomitant dissociation of the protein-DNA complex occurs with tau(1/2) approximately 10 min at 37 degrees C. It appears that conformational dynamics in the zipper domain make the transition state for isomerization readily available so that retention of reversible switching is observed.     

Deletion of a single amino acid changes the folding of an apamin hybrid sequence peptide to that of endothelin

The solution conformations of a hybrid sequence peptide related to the bee venom peptide apamin have been determined using two-dimensional ¹H-nmr. Apamin is an 18 amino acid peptide containing a C-terminal helix that is stabilized by two disulfide bonds. The deletion of one residue (K4) of the N-terminal “scaffold” region of the apamin sequence results in a helical peptide, but with a change in the pairing of cysteines to form the disulfide cross links. The new disulfide arrangement is analogous to that of the vasoconstrictor peptide endothelin. Two sets of nmr resonances were observed for the apamin-deletion (AD) peptide, due to cis-trans isomerism at the A4-P5 peptide bond. The cis isomer of the AD peptide contains a tight turn in residues 3–6, which is required for formation of the α-helix in residues 7–15. Nuclear Overhauser effects observed for the trans AD peptide are not consistent with any single unique fold, indicating the presence of conformational averaging when the peptide adopts the trans form. Distance geometry calculations on the cis AD peptide reveal an α-helical structure that appears to be more like that of apamin than the crystal structure of human endothelin, despite the reversal of the disulfide pattern in the AD peptide from that of apamin to that of endothelin.© 1997 John Wiley & Sons, Inc. Biopoly 41 : 451–460, 1997     

1H-nmr studies on the structure of a new thionin from barley endosperm

A new thionin from barley, ω-hordothionin, has been shown to exist in aqueous solution as a mixture of two different isoforms in a 3:2 ratio, as revealed by a complete analysis of its two-dimensional ¹H-nmr spectra. The conformational heterogeneity arises frtm cis–trans isomerism ahout the Phe 12–Pro 13 peptide bond, where the major, form corresponds to the cis conformation. The complete assignment of chemical shifts and nuclear Overhaiiser effects (NOES) of the two isoforms allow a detailed comparative analysis of their conformational properties, even though a complete calculation of their solution structures is not possible because of a somewhat limited number of NOE constraints. Structures for the two isomers could be modeled, however, on the basis of the high structural homology between ω-hordothionin and related γ-thionins, and under the conditions of satisfying all observed experimental data. The two isoforms adopt practically identical global folds and the structural changes imposed by cis–trans isomerization are confined to the region proximal to Pro 13. The cis–trans isomerism occurs in a conserved loop connecting the first β-strand of the triple-stranded antiparallel β-sheet and the α-helix. A comparative analysis of the sequences of this loop in the different thionins suggests that the cis–trans equilibrium about the X-Pro peptide bond depends on the size of the side chain of X (X = Gly in γ-thionins and Phe in ω-thionin). The structural homology of this new thionin with γ-thionins as well as with some scorpion toxins and insect defensins suggests that these proteins may share a common mode of functional activity. © 1995 John Wiley & Sons, Inc.     

Buried S-nitrosocysteine revealed in crystal structures of human thioredoxin

We have determined the 1.65 A crystal structure of human thioredoxin-1 after treatment with S-nitrosoglutathione, providing a high-resolution view of this important protein modification and mechanistic insight into protein transnitrosation. Thioredoxin-1 appears to play an intermediary role in cellular S-nitrosylation and is important in numerous biological and pathobiological activities. S-Nitroso modifications of cysteines 62 and 69 are clearly visible in the structure and display planar cis geometries, whereas cysteines 32, 35, and 73 form intra- and intermolecular disulfide bonds. Surprisingly, the Cys 62 nitroso group is completely buried and pointing to the protein interior yet is the most readily formed at neutral pH. The Cys 69 nitroso group is also protected but requires a higher pH for stable formation. The helix intervening between residues 62 and 69 shifts by approximately 0.5 A to accommodate the SNO groups. The crystallographic asymmetric unit contains three independent molecules of thioredoxin, providing three views of the nitrosated protein. The three molecules are in general agreement but display subtle differences, including both cis and trans conformers for Cys 69 SNO in molecule C, and greater disorder in the Cys 62-Cys 69 helix in molecule B. Possible mechanisms for protein transnitrosation with specific geometric requirements and charge stabilization of the nitroxyl disulfide reaction intermediate are discussed.     

Design and characterization of stimuli-responsive FLAG-tag analogues and the illumination-induced modulation of their interaction with antibody 4E11

An azobenzene group containing beta-amino acid N-Fmoc-4-aminomethyl phenylazobenzoic acid was synthesized and with the exception of the C-terminal amino acid residue was substituted by solid-phase peptide synthesis into all positions of the FLAG sequence (DYKDDDDK), an octapeptide capable of specific interaction with the monoclonal antibody 4E11. The trans state of the beta-amino acid was thermodynamically more stable than the cis state. However, the molecule could be switched into the cis conformation by illumination at 340 nm. Peptides containing the artificial amino acid also became photoresponsive. In the absence of light, the spontaneous back-isomerization into the trans conformation of the photoresponsive was extremely slow (>8 h no significant increase in trans content). When illuminated with visible light (440 nm), the back-isomerization from the cis to the trans state was accelerated and occurred with a half-life of approximately 10 min. The cis form of the photopeptides was more hydrophilic than the trans form, as evidenced by differences in the retention time of the two isomeric forms in reversed-phase chromatography. Photopeptides that contained the intact sequences responsible for binding of the FLAG tag to the antibody, namely, the DYK motive at the N-terminus, showed binding to the antibody in both a dot blot immunoassay and in Biacore binding studies, albeit with lower affinity than the unmodified FLAG sequence. Peptides with a substitution in positions 4-6 showed differences in binding strength between the trans and the cis form in the Biacore studies, no such difference could be observed for the peptide with a substitution in position 7.     

Photomodulation of conformational states. III. Water-soluble bis-cysteinyl-peptides with (4-aminomethyl) phenylazobenzoic acid as backbone constituent

In previous studies we have shown that light-induced cis/trans isomerization of the azobenzene moiety in cyclo-[Ala-Cys-Ala-Thr-Cys-Asp-Gly-Phe-AMPB] [AMPB: (4-aminomethyl)phenylazobenzoic acid] leads both in the monocyclic and in the oxidized bicyclic form to markedly differentiated conformational states in DMSO, a fact that lends itself for photomodulation of the redox potential of such bis-cysteinyl-peptides. For this purpose water-soluble systems are required, and this was achieved by replacing three residues outside the Cys-Ala-Thr-Cys active-site motif of thioredoxin reductase with lysines. The resulting cyclo-[Lys-Cys-Ala-Thr-Cys-Asp-Lys-Lys-AMPB] fully retains its photoresponsive properties in water as well assessed by uv and CD measurements. Paralleling results of the previously investigated azobenzene-containing cyclic peptides, the trans --> cis isomerization of the water-soluble monocyclic and oxidized bicyclic peptide is accompanied by a marked transition from a well-defined conformation to an ensemble of possible conformations. However, the conformational preferences are very dissimilar from those of the DMSO-soluble peptides. In fact, hydrogen bonds as well as secondary structure elements were found that change in the mono- and bicyclic peptide upon irradiation. The photo switch between different turn types and hydrogen bonding networks offers the structural rational for the significantly differentiated redox potentials, but also the possibility of monitoring by femtosecond uv-vis and ir spectroscopy fast and ultra fast backbone rearrangement processes following the electronic trans --> cis isomerization.     

Structure of human thioredoxin exhibits a large conformational change

Thioredoxin is an oxidoreductase, which is ubiquitously present across phyla from humans to plants and bacteria. Thioredoxin reduces a variety of substrates through active site Cys 32, which is subsequently oxidized to form the intramolecular disulphide with Cys 35. The thioredoxin fold is known to be highly stable and conformational changes in the active site loops and residues Cys 32, Cys 35 have been characterized between ligand bound and free structures. We have determined a novel 2.0 Å resolution crystal structure for a human thioredoxin, which reveals a much larger conformational change than previously characterized. The principal change involves unraveling of a helix to form an extended loop that is linked to secondary changes in further loop regions and the wider area of the active site Cys 32. This gives rise to a more open conformation and an elongated hydrophobic pocket results in place of the helix. Buried residue Cys 62 from this helix becomes exposed in the open conformation. This provides a structural basis for observations that the Cys 62 sidechain can form mixed disulphides and be modified by thiol reactive small molecules.     

Helices in peptoids of alpha- and beta-peptides

Peptoids of alpha- and beta-peptides (alpha- and beta-peptoids) can be obtained by shifting the amino acid side chains from the backbone carbon atoms of the monomer constituents to the peptide nitrogen atoms. They are, therefore, N-substituted poly-glycines and poly-beta-alanines, respectively. Due to the substituted nitrogen atoms, the ability for hydrogen bond formation between peptide bonds gets lost. It may be very interesting to see whether such non-natural oligomers could be regarded as foldamers, which fold into definite backbone conformers. In this paper, we provide a complete overview on helix formation in alpha- and beta-peptoids on the basis of systematic theoretical conformational analyses employing the methods of ab initio molecular orbital (MO) theory. It can be shown that the alpha- and beta-peptoid structures form helical structures with both trans and cis peptide bonds despite the missing hydrogen bonds. Obviously, the conformational properties of the backbone are more important for folding than the possibility of hydrogen bonding. There are close relationships between the helices of alpha-peptoids and poly-glycine and poly-proline helices of alpha-peptides, whereas the helices of beta-peptoids correspond to the well-known helical structures of beta-peptides as, for instance, the 3(1)-helix of beta-peptides with 14-membered hydrogen-bonded rings. Thus, alpha- and beta-peptoids enrich the field of foldamers and may be used as useful tools in peptide and protein design.     

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.     

Contribution of tertiary amides to the conformational stability of collagen triple helices

The collagen triple helix is composed of three polypeptide strands, each with a sequence of repeating (Xaa-Yaa-Gly) triplets. In these triplets, Xaa and Yaa are often tertiary amides: L-proline (Pro) and 4(R)-hydroxy-L-proline (Hyp). To determine the contribution of tertiary amides to triple-helical stability, Pro and Hyp were replaced in synthetic collagen mimics with a non-natural acyclic tertiary amide: N-methyl-L-alanine (meAla). Replacing a Pro or Hyp residue with meAla decreases triple-helical stability. Ramachandran analysis indicates that meAla residues prefer to adopt straight phi and psi angles that are dissimilar from those of the Pro and Hyp residues in the collagen triple helix. Replacement with meAla decreases triple-helical stability more than does replacement with Ala. All of the peptide bonds in triple-helical collagen are in the trans conformation. Although an Ala residue greatly prefers the trans conformation, a meAla residue exists as a nearly equimolar mixture of trans and cis conformers. These findings indicate that the favorable contribution of Pro and Hyp to the conformational stability of collagen triple helices arises from factors other than their being tertiary amides.     

Synthesis and application of an azobenzene amino acid as a light-switchable turn element in polypeptides

The synthesis of an azobenzene amino acid (aa) for use as a photo-inducible conformational switch in polypeptides is described. The compound can be easily incorporated into an aa sequence by solid-phase peptide synthesis using standard 9-fluorenylmethoxycarbonyl methods. A reversible conformational change of the peptide backbone is induced by switching between the cis and trans configurations of the azobenzene moiety by irradiation with light of suitable wavelength. Thermal cis --> trans isomerization of this azobenzene aa is slow, enabling detailed structural investigations of the modified peptides, e.g., using NMR techniques. The total time for the synthesis of the photoswitch is typically 4 d, with an overall yield of 40-50%.     

Ultrafast conformational dynamics in cyclic azobenzene peptides of increased flexibility

Structural changes of peptides containing the azobenzene dye 4-aminomethyl-phenylazobenzoic acid (AMPB) are studied with ultrafast spectroscopy. AMPB peptides are a new class of molecules where the photoisomerizable dye azobenzene is linked to the peptide moiety via a flexible methylene spacer. The ultrafast reactions in the femtosecond to nanosecond time domain are investigated for the optical switch AMPB, a linear and cyclic octapeptide, and a bicyclic octapeptide containing an additional disulfide bridge. These molecules with increasing conformational constraints are studied for the cis to trans and the trans to cis photoreactions. For the cis to trans reaction the isomerization of the chromophore occurs fast in the 1-ps range, whereas it is slower (10-ps range) in the trans to cis reaction. In all peptides the structural changes of the chromophore lead to modifications in the peptide structure in the 10-ps-1-ns time range. The results indicate that the chromophore AMPB acts simultaneously as a fast molecular switch and as a sensor for initial conformational dynamics in the peptide. Experiments in the mid-infrared range where the structural changes of the peptide backbone are directly observed demonstrate that the essential part of the structural dynamics in the bicyclic AMPB peptide occurs faster than 10 ns.     

Evidence that the substrate backbone conformation is critical to phosphorylation by p42 MAP kinase

The effect of prolyl bond isomers on the substrate recognition capabilities of various endoproteases may be investigated in a reaction where both cis/trans isomers co-exist. Here we address the question of whether enzyme reactions at the side chain of an amino acid preceding proline proceed through an isomer specific pathway. The proline-directed p42 mitogen-activated protein kinase (ERK2) was used to phosphorylate the serine side chain in Pro-Arg-Ser-Pro-Phe-4-nitroanilide under conditions where different amounts of cis prolyl isomer of the substrate were present. Initial phosphorylation rates were calculated ranging between zero at 100% cis isomer and around 60 pM/min at the equilibrium content of 83.5% trans isomer. In the presence of the peptidyl-prolyl cis/trans isomerase human hFKBP12 (500 nM), cis/trans isomerization proceeds rapidly, permitting the maximal phosphorylation rate to be observed in the dead time of the experiment. Results show that correct signature sequences are not sufficient to render potential substrates reactive to proline-directed enzymatic phosphorylations, but that the conformational state of the peptide bond following serine (threonine) is a critical determinant. Therefore, catalysis by peptidyl-prolyl cis/trans isomerases may add a new level of control to intracellular protein phosphorylations.