Your search keyword '"Zanni, Martin T."' showing total 12 results

1. Molecular dynamics simulation study of water structure and dynamics on the gold electrode surface with adsorbed 4-mercaptobenzonitrile.

Author

Kwac, Kijeong, Yang, Nan, Ryan, Matthew J., Zanni, Martin T., and Cho, Minhaeng

Subjects

MOLECULAR dynamics, INTERFACE dynamics, ROTATIONAL motion, HYDROGEN bonding, COLLECTIVE behavior

Abstract

Understanding water dynamics at charged interfaces is of great importance in various fields, such as catalysis, biomedical processes, and solar cell materials. In this study, we implemented molecular dynamics simulations of a system of pure water interfaced with Au electrodes, on one side of which 4-mercaptobenzonitrile (4-MBN) molecules are adsorbed. We calculated time correlation functions of various dynamic quantities, such as the hydrogen bond status of the N atom of the adsorbed 4-MBN molecules, the rotational motion of the water OH bond, hydrogen bonds between 4-MBN and water, and hydrogen bonds between water molecules in the interface region. Using the Luzar–Chandler model, we analyzed the hydrogen bond dynamics between a 4-MBN and a water molecule. The dynamic quantities we calculated can be divided into two categories: those related to the collective behavior of interfacial water molecules and the H-bond interaction between a water molecule and the CN group of 4-MBN. We found that these two categories of dynamic quantities exhibit opposite trends in response to applied potentials on the Au electrode. We anticipate that the present work will help improve our understanding of the interfacial dynamics of water in various electrolyte systems. [ABSTRACT FROM AUTHOR]

Published

2024

2. The hydrogen-bonding dynamics of water to a nitrile-functionalized electrode is modulated by voltage according to ultrafast 2D IR spectroscopy.

Author

Ryan, Matthew J., Nan Yang, Kijeong Kwac, Wilhelm, Kiera B., Chi, Benjamin K., Weix, Daniel J., Minhaeng Cho, and Zanni, Martin T.

Subjects

VOLTAGE, MOLECULAR dynamics, SPECTROMETRY, ELECTRODES, INFRARED spectra

Abstract

We report the hydrogen-bonding dynamics of water to a nitrile-functionalized and plasmonic electrode surface as a function of applied voltage. The surface-enhanced two-dimensional infrared spectra exhibit hydrogen-bonded and non-hydrogen-bonded nitrile features in similar proportions, plus cross peaks between the two. Isotopic dilution experiments show that the cross peaks arise predominantly from chemical exchange between hydrogen-bonded and non-hydrogen-bonded nitriles. The chemical exchange rate depends upon voltage, with the hydrogen bond of the water to the nitriles breaking 2 to 3 times slower (>63 vs. 25 ps) under a positive as compared to a negative potential. Spectral diffusion created by hydrogen-bond fluctuations occurs on a ~1 ps timescale and is moderately potential-dependent. Timescales from molecular dynamics simulations agree qualitatively with the experiment and show that a negative voltage causes a small net displacement of water away from the surface. These results show that the voltage applied to an electrode can alter the timescales of solvent motion at its interface, which has implications for electrochemically driven reactions. [ABSTRACT FROM AUTHOR]

Published

2023

3. Picosecond Dynamics of a Membrane Protein Revealed by 2D IR

Author

Mukherjee, Prabuddha, Kass, Itamar, Arkin, Isaiah, and Zanni, Martin T.

Published

2006

4. Two-dimensional infrared (2D IR) spectroscopy for elucidating ion occupancies in the selectivity filter of ion channels1.

Author

Kratochvil, Huong T. and Zanni, Martin T.

Subjects

*POTASSIUM channels, *PROTEIN structure, *INFRARED spectroscopy, *PROTEIN synthesis, *MEMBRANE proteins, *ION channels, *MOLECULAR dynamics

Abstract

This article reviews work presented at the ESCBM 2017 on using two-dimensional infrared (2D IR) spectroscopy to probe ion binding configurations in the potassium ion channel KcsA. We discuss two studies in which we use 2D IR spectroscopy in conjunction with protein semisynthesis and molecular dynamics (MD) simulations to test against two competing models of ion permeation and to investigate how changes in the conformation of the intracellular gate affect the structure and ion affinities of the selectivity filter. In our initial study, the 2D IR spectrum of an isotopically labeled KcsA filter reveals two spectral features that correspond to different structures and ion binding configurations. MD simulations help us link the experiments to atomistic structures, allowing us to determine the prevailing mechanism of ion conduction. In a follow-up study, we probe how ion occupancies in the filter change with the opening and closing of the intracellular gate. We experimentally modulate the conformation of KcsA using different sample conditions, and are able to show that the ion occupancies in the filter change with the state of the gate, revealing complexities in the conformational landscape of the potassium ion channel. Our work shows the potential of these techniques in addressing the fundamental biophysical questions in membrane protein structure and function. [ABSTRACT FROM AUTHOR]

Published

2018

5. Two-dimensional infrared (2D IR) spectroscopy for elucidating ion occupancies in the selectivity filter of ion channels1.

Author

Kratochvil, Huong T. and Zanni, Martin T.

Subjects

POTASSIUM channels, PROTEIN structure, INFRARED spectroscopy, PROTEIN synthesis, MEMBRANE proteins, ION channels, MOLECULAR dynamics

Abstract

This article reviews work presented at the ESCBM 2017 on using two-dimensional infrared (2D IR) spectroscopy to probe ion binding configurations in the potassium ion channel KcsA. We discuss two studies in which we use 2D IR spectroscopy in conjunction with protein semisynthesis and molecular dynamics (MD) simulations to test against two competing models of ion permeation and to investigate how changes in the conformation of the intracellular gate affect the structure and ion affinities of the selectivity filter. In our initial study, the 2D IR spectrum of an isotopically labeled KcsA filter reveals two spectral features that correspond to different structures and ion binding configurations. MD simulations help us link the experiments to atomistic structures, allowing us to determine the prevailing mechanism of ion conduction. In a follow-up study, we probe how ion occupancies in the filter change with the opening and closing of the intracellular gate. We experimentally modulate the conformation of KcsA using different sample conditions, and are able to show that the ion occupancies in the filter change with the state of the gate, revealing complexities in the conformational landscape of the potassium ion channel. Our work shows the potential of these techniques in addressing the fundamental biophysical questions in membrane protein structure and function. [ABSTRACT FROM AUTHOR]

Published

2018

6. Structural motif of polyglutamine amyloid fibrils discerned with mixed-isotope infrared spectroscopy.

Author

Buchanan, Lauren E., Carr, Joshua K., Fluitt, Aaron M., Hoganson, Andrew J., Moran, Sean D., de Pablo, Juan J., Skinner, James L., and Zanni, Martin T.

Subjects

POLYGLUTAMINE, AMYLOID beta-protein, FOURIER transform infrared spectroscopy, NEURODEGENERATION, PROTEIN expression, MOLECULAR dynamics

Abstract

Polyglutamine (polyQ) sequences are found in a variety of proteins, and mutational expansion of the polyQ tract is associated with many neurodegenerative diseases. We study the amyloid fibril structure and aggregation kinetics of K2Q24K2W, a model polyQ sequence. Two structures have been proposed for amyloid fibrils formed by polyQ peptides. By forming fibrils composed of both 12C and 13C monomers, made possible by protein expression in Escherichia coli, we can restrict vibrational delocalization to measure 2D IR spectra of individual monomers within the fibrils. The spectra are consistent with a β-turn structure in which each monomer forms an antiparallel hairpin and donates two strands to a single β-sheet. Calculated spectra from atomistic molecular-dynamics simulations of the two proposed structures confirm the assignment. No spectroscopically distinct intermediates are observed in rapid-scan 2D IR kinetics measurements, suggesting that aggregation is highly cooperative. Although 2D IR spectroscopy has advantages over linear techniques, the isotope-mixing strategy will also be useful with standard Fourier transform IR spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2014

7. Two-dimensional infrared spectroscopymeasures the structural dynamics of a self-assembled film only onemolecule thick.

Author

Zanni, Martin T.

Subjects

*MONOMOLECULAR films, *MOLECULAR self-assembly, *MOLECULAR dynamics, *SURFACE chemistry, *INFRARED spectroscopy

Abstract

The author comments on a study by C. Yan and colleagues about molecular dynamics and structure of a self-assembled monolayer on a gold surface. Topics discussed include the use of two dimensional (2D) infrared (IR) spectroscopy to study the dynamics, a comparison between 2D IR and nuclear magnetic resonance (NMR) spectroscopies, and the measurement of spectral diffusion.

Published

2016

8. Probing the Effects of Gating on the Ion Occupancy of the K+ Channel Selectivity Filter Using Two-Dimensional Infrared Spectroscopy.

Author

Kratochvil, Huong T., Maj, Michal, Matulef, Kimberly, Annen, Alvin W., Ostmeyer, Jared, Perozo, Eduardo, Roux, Benoît, Valiyaveetil, Francis I., and Zanni, Martin T.

Subjects

*POTASSIUM channels, *POTASSIUM ions, *INFRARED spectroscopy, *MOLECULAR dynamics, *BINDING sites, *INTRACELLULAR membranes

Abstract

The interplay between the intracellular gate and the selectivity filter underlies the structural basis for gating in potassium ion channels. Using a combination of protein semisynthesis, two-dimensional infrared (2D IR) spectroscopy, and molecular dynamics (MD) simulations, we probe the ion occupancy at the S1 binding site in the constricted state of the selectivity filter of the KcsA channel when the intracellular gate is open and closed. The 2D IR spectra resolve two features, whose relative intensities depend on the state of the intracellular gate. By matching the experiment to calculated 2D IR spectra of structures predicted by MD simulations, we identify the two features as corresponding to states with S1 occupied or unoccupied by K+. We learn that S1 is >70% occupied when the intracellular gate is closed and <15% occupied when the gate is open. Comparison of MD trajectories show that opening of the intracellular gate causes a structural change in the selectivity filter, which leads to a change in the ion occupancy. This work reveals the complexity of the conformational landscape of the K+ channel selectivity filter and its dependence on the state of the intracellular gate. [ABSTRACT FROM AUTHOR]

Published

2017

9. Instantaneous ion configurations in the K+ ion channel selectivity filter revealed by 2D IR spectroscopy.

Author

Kratochvil, Huong T., Carr, Joshua K., Matulef, Kimberly, Annen, Alvin W., Hui Li, Maj, Michał, Ostmeyer, Jared, Serrano, Arnaldo L., Raghuraman, H., Moran, Sean D., Skinner, J. L., Perozo, Eduardo, Roux, Benoît, Valiyaveetil, Francis I., and Zanni, Martin T.

Subjects

*POTASSIUM channels, *INFRARED spectroscopy, *CELL membranes, *MOLECULAR dynamics, *WATER, *ION channels, *CONFORMATIONAL analysis

Abstract

Potassium channels are responsible for the selective permeation of K+ ions across cell membranes. K+ ions permeate in single file through the selectivity filter, a narrow pore lined by backbone carbonyls that compose four K+ binding sites. Here, we report on the two-dimensional infrared (2D IR) spectra of a semisynthetic KcsA channel with site-specific heavy (13C18O) isotope labels in the selectivity filter. The ultrafast time resolution of 2D IR spectroscopy provides an instantaneous snapshot of the multi-ion configurations and structural distributions that occur spontaneously in the filter. Two elongated features are resolved, revealing the statistical weighting of two structural conformations. The spectra are reproduced by molecular dynamics simulations of structures with water separating two K+ ions in the binding sites, ruling out configurations with ions occupying adjacent sites. [ABSTRACT FROM AUTHOR]

Published

2016

10. Two-Dimensional Sum-Frequency Generation Reveals Structure and Dynamics of a Surface-Bound Peptide.

Author

Laaser, Jennifer E., Skoff, David R., Jia-Jung Ho, Yongho Joo, Serrano, Arnaldo L., Steinkruger, Jay D., Gopalan, Padma, Gellman, Samuel H., and Zanni, Martin T.

Subjects

*MOLECULAR structure of polypeptides, *POLYPEPTIDES, *PEPTIDE spectra, *MONOMOLECULAR films, *MOLECULAR dynamics, *FOURIER transform infrared spectroscopy, *SURFACE chemistry

Abstract

Surface-hound polypeptides and proteins are increasingly used to functionalize inorganic interfaces such as electrodes, but their structural characterization is exceedingly difficult with standard technologies. In this paper, we report the first two-dimensional sum-frequency generation (2D SFG) spectra of a peptide monolayer, which are collected by adding a mid-IR pulse shaper to a standard femtosecond SFG spectrometer. On a gold surface, standard FTIR spectroscopy is inconclusive about the peptide structure because of solvation-induced frequency shifts, hut the 2D line shapes, anharmonic shifts, and lifetimes obtained from 2D SFG reveal that the peptide is largely α-helical and upright. Random coil residues are also observed, which do not themselves appear in SFG spectra due to their isotropic structural distribution, but which still absorb infrared light and so can be detected by cross-peaks in 2D SFG spectra. We discuss these results in the context of peptide design. Because of the similar way in which the spectra are collected, these 2D SFG spectra can be directly compared to 2D IR spectra, thereby enabling structural interpretations of surface-bound peptides and biomolecules based on the well- studied structure/2D JR spectra relationships established from soluble proteins. [ABSTRACT FROM AUTHOR]

Published

2014

11. Parallel β-Sheet Vibrational Couplings Revealed by 2D IR Spectroscopy of an Isotopically Labeled Macrocycle: Quantitative Benchmark for the Interpretation of Amyloid and Protein Infrared Spectra.

Author

Woys, Ann Marie, Almeida, Aaron M., Lu Wang, Chi-Cheng Chiu, McGovern, Michael, de Pablo, Juan J., Skinner, James L., Gellman, Samuel H., and Zanni, Martin T.

Subjects

*QUANTITATIVE chemical analysis, *PROTEIN spectra, *AMYLOID, *SPECTRUM analysis, *CARBOHYDRATES, *VIBRATIONAL spectra, *ANALYTICAL biochemistry, *INFRARED spectroscopy, *MOLECULAR dynamics

Abstract

Infrared spectroscopy is playing an important role in the elucidation of amyloid fiber formation, but the coupling models that link spectra to structure are not well tested for parallel β-sheets. Using a synthetic macrocycle that enforces a two stranded parallel β-sheet conformation, we measured the lifetimes and frequency for six combinations of doubly 13C=18O labeled amide I modes using 2D IR spectroscopy. The average vibrational lifetime of the isotope labeled residues was 550 fs. The frequencies of the labels ranged from 1585 to 1595 cm-1, with the largest frequency shift occurring for in-register amino acids. The 2D IR spectra of the coupled isotope labels were calculated from molecular dynamics simulations of a series of macrocycle structures generated from replica exchange dynamics to fully sample the conformational distribution. The models used to simulate the spectra include through-space coupling, through-bond coupling, and local frequency shifts caused by environment electrostatics and hydrogen bonding. The calculated spectra predict the line widths and frequencies nearly quantitatively. Historically, the characteristic features of β-sheet infrared spectra have been attributed to through-space couplings such as transition dipole coupling. We find that frequency shifts of the local carbonyl groups due to nearest neighbor couplings and environmental factors are more important, while the through-space couplings dictate the spectral intensities. As a result, the characteristic absorption spectra empirically used for decades to assign parallel β-sheet secondary structure arises because of a redistribution of oscillator strength, but the through-space couplings do not themselves dramatically alter the frequency distribution of eigenstates much more than already exists in random coil structures. Moreover, solvent exposed residues have amide I bands with >20 cm-1 line width. Narrower line widths indicate that the amide I backbone is solvent protected inside the macrocycle. This work provides calculated and experimentally verified couplings for parallel β-sheets that can be used in structure-based models to simulate and interpret the infrared spectra of β-sheet containing proteins and protein assemblies, such as amyloid fibers. [ABSTRACT FROM AUTHOR]

Published

2012

12. 2D IR Line Shapes Probe Ovispirin Peptide Conformation and Depth in Lipid Bilayers.

Author

Woys, Ann Marie, Yu-Shan Lin, Reddy, Allam S., Wei Xiong, de Pablo, Juan J., Skinner, James L., and Zanni, Martin T.

Subjects

*BILAYER lipid membranes, *POLYPEPTIDES, *RADIOLABELING, *MOLECULAR dynamics, *ANTIBIOTICS, *ION channels, *ELECTROSTATICS

Abstract

We report a structural study on the membrane binding of ovispirin using 2D IR line shape analysis, isotope labeling, and molecular dynamics simulations. Ovispirin is an antibiotic polypeptide that binds to the surfaces of membranes as an α-helix. By resolving individual backbone vibrational modes (amide I) using 1-13C=18O labeling, we measured the 2D IR line shapes for 15 of the 18 residues in this peptide. A comparison of the line shapes reveals an oscillation in the inhomogeneous line width that has a period equal to that of an α-helix (3.6 amino acids). The periodic trend is caused by the asymmetric environment of the membrane bilayer that exposes one face of the α-helix to much stronger environmental electrostatic forces than the other. We compare our experimental results to 2D IR line shapes calculated using the lowest free energy structure identified from molecular dynamics simulations. These simulations predict a periodic trend similar to the experiment and lead us to conclude that ovispirin lies in the membrane just below the headgroups, is tilted, and may be kinked. Besides providing insight into the antibiotic mechanism of ovispirin, our procedure provides an infrared method for studying peptide and protein structures that relies on the natural vibrational modes of the backbone. It is a complementary method to other techniques that utilize line shapes, such as fluorescence, NMR, and ESR spectroscopies, because it does not require mutations, the spectra can be quantitatively simulated using molecular dynamics, and the technique can be applied to difficult-to-study systems like ion channels, aggregated proteins, and kinetically evolving systems. [ABSTRACT FROM AUTHOR]

Published

2010