Matthew J. Tucker scite author profile

We studied here the binding of the mastoparan X peptide to a zwitterionic lipid bilayer (POPC) and demonstrated that nitrile-derivatized amino acids can be used to determine the hydration state (or change in hydration state) of specific sites of membrane-interactive peptides (upon binding). We have also shown that polarized ATR-FTIR measurements can further be used to uncover information regarding the spatial orientation of individual side chains as well as their conformational preference within the lipid bilayer.

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Understanding the Mechanism of β-Hairpin Folding via φ-Value Analysis

Tucker

Gai

2006

Biochemistry

150

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The folding kinetics of a 16-residue beta-hairpin (trpzip4) and five mutants were studied by a laser-induced temperature-jump infrared method. Our results indicate that mutations which affect the strength of the hydrophobic cluster lead to a decrease in the thermal stability of the beta-hairpin, as a result of increased unfolding rates. For example, the W45Y mutant has a phi-value of approximately zero, implying a folding transition state in which the native contacts involving Trp45 are not yet formed. On the other hand, mutations in the turn or loop region mostly affect the folding rate. In particular, replacing Asp46 with Ala leads to a decrease in the folding rate by roughly 9 times. Accordingly, the phi-value for D46A is determined to be approximately 0.77, suggesting that this residue plays a key role in stabilizing the folding transition state. This is most likely due to the fact that the main chain and side chain of Asp46 form a characteristic hydrogen bond network with other residues in the turn region. Taken together, these results support the folding mechanism we proposed before, which suggests that the turn formation is the rate-limiting step in beta-hairpin folding and, consequently, a stronger turn-promoting sequence increases the stability of a beta-hairpin primarily by increasing its folding rate, whereas a stronger hydrophobic cluster increases the stability of a beta-hairpin primarily by decreasing its unfolding rate. In addition, we have examined the compactness of the thermally denatured and urea-denatured states of another 16-residue beta-hairpin, using the method of fluorescence resonance energy transfer. Our results show that the thermally denatured state of this beta-hairpin is significantly more compact than the urea-denatured state, suggesting that the very first step in beta-hairpin folding, when initiated from an extended conformation, probably corresponds to a process of hydrophobic collapse.

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Conformational Distribution of a 14-Residue Peptide in Solution: A Fluorescence Resonance Energy Transfer Study

2005

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We demonstrate here that a nitrile-derivatized phenylalanine residue, p-cyanophenylalanine (Phe(CN)), and tryptophan (Trp) constitute a novel donor-acceptor pair for fluorescence resonance energy transfer (FRET). The Förster distance of this FRET pair was determined to be approximately 16 A and hence is well suited for determining relatively short separation distances. To validate the applicability of this FRET pair in conformational studies, we studied the conformational heterogeneity of a 14-residue amphipathic peptide, Mastoparan X (MPx peptide), in water and 7 M urea solution as well as at different temperatures. Specifically, seven nitrile-derivatized mutants of the MPx peptide, each containing a Phe(CN) residue that replaces different positions along the peptide sequence (i.e., from position 5 to 11) and serves as a resonance energy donor to the native Trp residue at position 3, were studied spectroscopically. The FRET efficiencies obtained from these peptides allowed us to gain a global picture regarding the conformational distribution of the MPx peptide in different environments. Our results suggest that the MPx molecules exist in water as an ensemble of rather compact conformations, with a radius of gyration of approximately 4.2 A, whereas in 7 M urea the radius of gyration increases to approximately 6.5 A, indicating that the peptide conformations become more extended under this condition. However, we found that temperature had only a negligible effect on the size of the MPx peptide, underlining the difference between the thermally and chemically denatured states of polypeptides. The application of the Gaussian chain or the wormlike chain model allowed us to further obtain the probability distribution function of the separation distance between any two residues along the peptide sequence. We found that the effective bond length of the MPx peptide, obtained by using the Gaussian chain model, is 2.78 A in water and 4.28 A in 7 M urea.

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A novel fluorescent probe for protein binding and folding studies: p‐cyano‐phenylalanine

2006

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Recently, it is has been shown that the C=N stretching vibration of a non-natural amino acid, p-cyano-phenylalanine (PheCN), could be used as an infrared reporter of local environment. Here, we further showed that the fluorescence emission of PheCN is also sensitive to solvent and, therefore, could be used as a novel optical probe for protein binding and folding studies. Moreover, we found that the fluorescence quantum yield of PheCN is nearly five times larger than that of phenylalanine and, more importantly, can be selectively excited even when other aromatic amino acids are present, thus making it a more versatile fluorophore. To test the feasibility of using PheCN as a practical fluorescent probe, we studied the binding of calmodulin (CaM) to a peptide derived from the CaM-binding domain of skeletal muscle myosin light chain kinase (MLCK). The peptide (MLCK3CN) contains a single PheCN residue and has been shown to bind to CaM with high affinity. As expected, addition of CaM into a MLCK3CN solution resulted in quenching of the PheCN fluorescence. A series of stochiometric titrations further allowed us to determine the binding affinity (Kd) of this peptide to CaM. Taken together, these results indicated that the PheCN fluorescence is sensitive to environment and could be applicable to a wide variety of biological problems.

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2D IRphoton echo of azido-probes for biomolecular dynamics

Tucker

Gai

Fenlon

et al. 2011

Phys. Chem. Chem. Phys.

100

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The vibrations in the azido-, N3, asymmetric stretching region of 2′-azido-2′-deoxyuridine (N3dU) are examined by two-dimensional infrared spectroscopy. In water and tetrahydrofuran (THF), the spectra display a single sharp diagonal peak that shows solvent sensitivity. The frequency-frequency correlation time in water is 1.5 ps, consistent with H-bond making and breaking dynamics. The 2D IR spectrum is reproduced for N3dU in water based on a model correlation function and known linear response functions. Its large extinction coefficient, vibrational frequency outside the protein and nucleic acid IR absorption, and sensitivity to water dynamics renders -N3 a very useful probe for 2D IR and other nonlinear IR studies: its signal is ca. 100 times that of nitrile.

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Matthew J. Tucker

A New Method for Determining the Local Environment and Orientation of Individual Side Chains of Membrane-Binding Peptides

Understanding the Mechanism of β-Hairpin Folding via φ-Value Analysis

Conformational Distribution of a 14-Residue Peptide in Solution: A Fluorescence Resonance Energy Transfer Study

A novel fluorescent probe for protein binding and folding studies: p‐cyano‐phenylalanine

2D IRphoton echo of azido-probes for biomolecular dynamics

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