Matteo De Poli scite author profile

We have combined two-dimensional infrared (2D IR) spectroscopy and isotope substitutions to reveal the vibrational couplings between a pair of amide-I and -II modes that are several residues away but directly connected through a hydrogen bond in a helical peptide. This strategy is demonstrated on a 3(10)-helical hexapeptide, Z-Aib-L-Leu-(Aib)2-Gly-Aib-OtBu, and its 13C=18O-Leu monolabeled and 13C=18O-Leu/15N-Gly bis-labeled isotopomers in CDCl3. The isotope-dependent amide-I/II cross peaks clearly show that the second and fourth peptide linkages are vibrationally coupled as they are in proximity, forming a 3(10)-helical turn. The experimental spectra are compared to simulations based on a vibrational exciton Hamiltonian model that fully takes into account the amide-I and -II modes. The amide-II local mode frequency is evaluated by a new model based on the effects of hydrogen-bond geometry and sites. Ab initio nearest-neighbor coupling maps of the amide-I/I, -I/II, -II/I and -II/II modes are generated by isotopically isolating the local modes of N-acetyl-glycine N'-methylamide (AcGlyNHMe). Longer range couplings are modeled by transition charge interactions. The effects of the capping groups are incorporated and isotope effects are analyzed based on ab initio calculations of six model compounds. The main features of the 2D IR spectra are reproduced by this modeling. The conformational sensitivity of the isotope-dependent amide-I/II cross peaks is discussed in comparison with the calculated spectra for a semiextended structure. Our experimental and theoretical study demonstrates that the combination of 2D IR and 13C=18O/15N labeling is a useful structural method for detecting helical turn formation with residue-level specificity.

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Couplings between Peptide Linkages across a 3₁₀-Helical Hydrogen Bond Revealed by Two-Dimensional Infrared Spectroscopy

Maekawa¹,

Poli²,

Toniolo³

et al. 2009

J. Am. Chem. Soc.

142

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Vibrational couplings between the amide modes are keenly dependent on peptide structure. Site-specific couplings can inform us of molecular conformation in detail. For example, when an amide-I mode couples to an amide-II mode that is three residues away because they are brought into proximity in the presence of an intramolecular C=O...H-N hydrogen bond, the coupling can provide direct evidence for single helical turn formation, a proposed key step in coil-helix transition. In this work, we measure 2D IR spectra of a 3(10)-helical hexapeptide, Z-Aib-l-Leu-(Aib)(2)-Gly-Aib-OtBu, and its (13)C=(18)O-Leu monolabeled and (13)C=(18)O-Leu/(15)N-Gly bis-labeled isotopomers in CDCl(3). The isotope-dependent amide-I/II cross-peaks clearly reveal the existence of vibrational coupling between the second and fourth peptide linkages that are connected through a 3(10)-helical hydrogen bond. Our results demonstrate that the combination of 2D IR and (13)C=(18)O/(15)N labeling is a useful structural method for probing local peptide conformation with residue-level specificity.

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Conformational photoswitching of a synthetic peptide foldamer bound within a phospholipid bilayer

Poli

Zawodny

Quinonero

et al. 2016

Science

160

137

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The dynamic properties of foldamers, synthetic molecules that mimic folded biomolecules, have mainly been explored in free solution. We report on the design, synthesis, and conformational behavior of photoresponsive foldamers bound in a phospholipid bilayer akin to a biological membrane phase. These molecules contain a chromophore, which can be switched between two configurations by different wavelengths of light, attached to a helical synthetic peptide that both promotes membrane insertion and communicates conformational change along its length. Light-induced structural changes in the chromophore are translated into global conformational changes, which are detected by monitoring the solid-state (19)F nuclear magnetic resonance signals of a remote fluorine-containing residue located 1 to 2 nanometers away. The behavior of the foldamers in the membrane phase is similar to that of analogous compounds in organic solvents.

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Induction of Unexpected Left‐Handed Helicity by an N‐Terminal L‐Amino Acid in an Otherwise Achiral Peptide Chain

et al. 2012

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Peptide helices containing L‐amino acids are typically right‐handed. Exceptions are peptide helices containing the achiral amino acids 2‐aminoisobutyric acid and glycine with a single chiral amino acid at the N terminus. These helices are left‐handed when the N‐terminal residue is a common tertiary proteinogenic amino acid, such as L‐valine (see picture, left), but right‐handed when the N‐terminal residue is the quaternary amino acid L‐α‐methylvaline (right).

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Engineering the Structure of an N-Terminal β-Turn To Maximize Screw-Sense Preference in Achiral Helical Peptide Chains

et al. 2014

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Oligomers of α-aminoisobutyric acid (Aib) are achiral peptides that typically adopt 3 10 helical conformations in which enantiomeric left-and right-handed conformers are, necessarily, equally populated. Incorporating a single protected chiral residue at the N-terminus of the peptide leads to induction of a screw-sense preference in the helical chain, which may be quantified (in the form of "helical excess") by NMR spectroscopy. Variation of this residue and its N-terminal protecting group leads to the conclusion that maximal levels of screw-sense preference are induced by bulky chiral tertiary amino acids carrying amide protecting groups or by chiral quaternary amino acids carrying carbamate protecting groups. Tertiary L-amino acids at the N-terminus of the oligomer induce a left-handed screw sense, while quaternary L-amino acids induce a righthanded screw sense. A screw-sense preference may also be induced from the second position of the chain, weakly by tertiary amino acids, and much more powerfully by quaternary amino acids. In this position, the L enantiomers of both families induce a right-handed screw sense. Maximal, and essentially quantitative, control is induced by an L-α-methylvaline residue at both positions 1 and 2 of the chain, carrying an N-terminal carbamate protecting group.

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Matteo De Poli

Toward Detecting the Formation of a Single Helical Turn by 2D IR Cross Peaks between the Amide-I and -II Modes

Couplings between Peptide Linkages across a 3₁₀-Helical Hydrogen Bond Revealed by Two-Dimensional Infrared Spectroscopy

Conformational photoswitching of a synthetic peptide foldamer bound within a phospholipid bilayer

Induction of Unexpected Left‐Handed Helicity by an N‐Terminal L‐Amino Acid in an Otherwise Achiral Peptide Chain

Engineering the Structure of an N-Terminal β-Turn To Maximize Screw-Sense Preference in Achiral Helical Peptide Chains

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Matteo De Poli

Toward Detecting the Formation of a Single Helical Turn by 2D IR Cross Peaks between the Amide-I and -II Modes

Couplings between Peptide Linkages across a 310-Helical Hydrogen Bond Revealed by Two-Dimensional Infrared Spectroscopy

Conformational photoswitching of a synthetic peptide foldamer bound within a phospholipid bilayer

Induction of Unexpected Left‐Handed Helicity by an N‐Terminal L‐Amino Acid in an Otherwise Achiral Peptide Chain

Engineering the Structure of an N-Terminal β-Turn To Maximize Screw-Sense Preference in Achiral Helical Peptide Chains

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Couplings between Peptide Linkages across a 3₁₀-Helical Hydrogen Bond Revealed by Two-Dimensional Infrared Spectroscopy