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Understanding the structure and dynamics of proteins is essential to understanding their roles and functions in these physiological processes. In this thesis, I describe the implementation of an ultrafast nonlinear spectroscopic technique, two-dimensional infrared (2D IR) spectroscopy to probe the structure and dynamics of ion channels and amyloid fibers. Regarding ion channels, I describe the combination of semisynthesis, 2D IR spectroscopy and molecular dynamic (MD) simulations in addressing the longstanding question of ion permeation through the selectivity filter of a potassium ion channel. I show that ions and water alternate through the filter and that these ions cannot occupy adjacent binding sites. Furthermore, 2D IR experiments revealed a flipped state that is predicted by MD simulations but not observed in x-ray crystallography. In another aspect of this work, we show that the collapsed state of the filter is structurally different in low K+ and low pH. Moreover, our work also reveals how the large conformational motions of the protein are coupled to structural changes in the selectivity filter, as evidenced by a change in the ion occupancy. In a second research direction, I developed an optical technique to quantify photoactivatable fluorophores with fluorescence microscopy. This technique allows for the quantification of a limitless number of fluorophores, and corrects for stochastic events such as fluorescence intermittency. This work can be extended to the study of amyloids, where determining the number of proteins in a prefibrillar aggregates is necessary for understanding their roles in amyloid related diseases. Finally, using 2D IR spectroscopy we describe the effect of common solvents on the anharmonicity of small molecule chromophores. The data indicates that the carbonyl anharmonicity, and, subsequently, the Stark tuning rate, is an intrinsic property of the carbonyl vibrational probes, which have important implications on the interpretation of carbonyl vibrational frequency shifts in the condensed phase.
An estimated 35% of the human proteome is intrinsically disordered. Disordered proteins play a key role in physiologic and pathologic regulation, recognition, and signaling making protein disorder the subject of increasing investigation. Since disordered samples do not generate x-ray quality crystals and since they have conformations that interconvert faster than the time resolution of NMR or ESR, little is known about their structure or function. By combining isotope-edited two-dimensional infrared spectroscopy (2D IR) with spectral modeling based on molecular dynamics simulations, this work will show that one can measure the residual structure and conformational heterogeneity of a putatively disordered sequence. This methodology was first used to study the structure and dynamics of the tryptophan zipper 2 (TZ2) peptide. The TZ2 peptide is a 12 residue engineered sequence that employs the "tryptophan zipper" motif to stabilize a p-hairpin fold. For this work five isotopologues of TZ2 were synthesized, the p-turn label K8, the midstrand labels T10 and T3T1O, the N-terminal label S1, and the unlabeled peptide UL. Temperature dependent FTIR and 2D IR studies in conjunction with modeling revealed that the TZ2 peptide at low temperatures exists as a folded peptide with a type I' turn and a small previously unobserved subpopulation of a bulged loop structure. Upon heating a fraying of the peptides termini is observed, in addition the population of the type I' turn increases relative to the population of the bulged turn. The TZ2 peptide provided a model hairpin system to test the utility of different forms of analysis and isotope labeling patterns for the subsequent study of disordered hairpin peptides. This methodology was next employed to gain insight into the structure of the elastin-like peptide GVGVPGVG, a prototypical disordered system. For this work nine isotopologues were studied in addition to size dependent variants based on the VPGVG sequence and point mutants variants of the form GVGXPGVG. The conformational ensemble was found to contain a high population of irregular P-turns possessing two peptide hydrogen bonds to the proline C=O (see figure below). Further, it was found that this population grows as a function of 1) side-chain volume for the peptide series GVGXPGVG, where X = Gly, Ala, and Val, and 2) polymer size for the peptide series GVG(VPGVG)a, where n = 1-6 and 251. These findings provide new insight into the molecular origin of the mechanical properties of biopolymers containing XPG turns including collagen (X = Pro), elastin (X = Val), mussel byssus (X = Gly), dragline spider silk (X = Gly), and wheat glutenin (X = Gln).`
Temperature-jump (T-jump) two-dimensional infrared spectroscopy (2D IR) is developed, characterized, and applied to the study of protein folding and association. In solution, protein conformational changes span a wide range of timescale from nanoseconds to minutes. Ultrafast 2D IR spectroscopy measures time-dependent structural changes within the protein ensemble by probing the frequency changes associated with amide I backbone vibrations. Combining 2D IR with a perturbing laser-induced T-jump enables the study of conformational dynamics from 5 ns to 50 ms. To access a finer time-sampling of the conformational evolution, a one-dimensional variant of 2D IR, heterodyne-detected dispersed vibrational echo spectroscopy (HDVE), is implemented. The framework for interpreting transient HDVE and 2D IR spectra is developed, and we propose a method to remove the linear absorption distortions along both frequency axes. We first present the T-jump 2D IR spectra of a dipeptide to reveal the general amide I baseline response expected in the absence of conformational change. To facilitate the analysis of T-jump data, singular value decomposition (SVD) is employed for reducing noise, identifying the number of distinguishable states, and separating spectral changes based on shared timescales. Finally, T-jump 2D IR spectroscopy is applied to study the unfolding of ubiquitin, disordering of the 12-residue p-hairpin peptide trpzip2 (TZ2), and the dissociation of insulin dimers to monomers. Experimental results for ubiquitin highlight the importance of linear absorption corrections for interpretation of the data. In response to the T-jump, 2D IR results indicate p-sheet structure melts in ubiquitin with a small amplitude (~10 gs) and large amplitude (17 ms) response. Isotope-labeling T-jump experiments on TZ2 allow for the proposal of a free energy surface in which transitions from a native and misfolded state proceed through a disordered hub-like state with a 1-2 gs timescale. Multiple timescales are observed in the T-jump induced dissociation of insulin. Based on their spectral features and concentration dependence, the insulin timescales can be assigned to dissociation, disordering, and oligomerization processes. With these applications, we demonstrate the capability of T-jump 2D IR spectroscopy to reveal detailed molecular dynamics.
The advent of laser-based sources of ultrafast infrared pulses has extended the study of very fast molecular dynamics to the observation of processes manifested through their effects on the vibrations of molecules. In addition, non-linear infrared spectroscopic techniques make it possible to examine intra- and intermolecular interactions and how such interactions evolve on very fast time scales, but also in some instances on very slow time scales. Ultrafast Infrared Vibrational Spectroscopy is an advanced overview of the field of ultrafast infrared vibrational spectroscopy based on the scientific research of the leading figures in the field. The book discusses experimental and theoretical topics reflecting the latest accomplishments and understanding of ultrafast infrared vibrational spectroscopy. Each chapter provides background, details of methods, and explication of a topic of current research interest. Experimental and theoretical studies cover topics as diverse as the dynamics of water and the dynamics and structure of biological molecules. Methods covered include vibrational echo chemical exchange spectroscopy, IR-Raman spectroscopy, time resolved sum frequency generation, and 2D IR spectroscopy. Edited by a recognized leader in the field and with contributions from top researchers, including experimentalists and theoreticians, this book presents the latest research methods and results. It will serve as an excellent resource for those new to the field, experts in the field, and individuals who want to gain an understanding of particular methods and research topics.
Simulations of two-dimensional infrared (2DIR) spectroscopy of several proteins are presented. Applications of 2DIR spectroscopy to protein folding, protein aggregation, and photosensing are reported. We demonstrate that 2DIR spectroscopy is an excellent probe of protein structure and dynamics. Our simulations predict future experiments as well as provide detailed explanations of previous experiments. We also present simulations of the related two-dimensional ultraviolet and two-dimensional stimulated resonance Raman spectroscopies, which are shown to provide complementary information to 2DIR spectroscopy. This thesis can be viewed as a guide for the design and analysis of future two-dimensional optical measurements on proteins.
Femtosecond two-dimensional infrared spectroscopy in combination with isotope labeling and molecular dynamics simulation has been used to investigate the structures and dynamics of nonfolding peptides and collagen peptides. Homopolymeric peptides are simple yet important, serve as model systems for investigating the intrinsic propensity of protein folding, especially for those disordered or unfolded peptides in aqueous solution. Here the full structure of (Ala)5 has been studied. Two different isotope-labeled peptides, Ala-(13C)Ala-(13C,18O)Ala-Ala-Ala, and Ala-Ala-(13C,18O)Ala-(13C)Ala-Ala were strategically designed to simplify the four-oscillator system into three two-oscillator systems. By utilizing the different polarization dependence of diagonal and cross peaks, coupling constant β and angle θ between transition dipoles has been extracted through spectral fitting. The coupling constant is around 4 cm-1 and angle around 100. These parameters were related to the dihedral angles characterizing the peptide backbone structure through DFT calculated maps. The derived dihedrals are all located in the polyproline-II region. These results were compared to the conformations sampled by hamiltonian replica-exchange MD simulation with 3 different CHARMM force fields: C22, C36 and Drude. The C22 force field predicted too high α-helix population, whereas C36 predicted that polyproline-II is the dominate conformation, consistent with experimental findings. The Drude model predicted dominating beta-sheet. Since the 2D-IR derived results were obtained from fitting to a single set of structural parameters, the effect of structural fluctuation within one conformation and structural transition between different conformations was also discussed. The C36 MD trajectories were used to simulate 2D IR spectra using the sum-over-state method and the time-averaging approximation (TAA) method. Reasonable agreement with the experimental data was achieved. Collagen is the most abundant protein in mammal. Its structural properties are important for biological functions. Here, the structure and thermal melting of a model collagen peptide, (PPG)10, has been investigated. The temperature dependent linear IR spectra of the unlabeled peptide and two isotopomers (either 13C-16O or 13C-18O labeled on the 4th glycine residue) showed that the triple helix unravels with increasing temperature and leads to greater solvent exposure. With some adjustments of calculation parameters according to linear IR spectra, 2D IR spectral simulation based on MD trajectories and TAA reasonably reproduced experimental spectra taken at the parallel and perpendicular polarization conditions. Further refinement of models and parameters are needed to improve the simulation. Our results for model nonfolding peptides and collagen peptides contribute to the fundamental understanding of peptide structure and dynamics, and to the further development of theoretical models for simulating 2D IR spectra.
Two-Dimensional Optical Spectroscopy discusses the principles and applications of newly emerging two-dimensional vibrational and optical spectroscopy techniques. It provides a detailed account of basic theory required for an understanding of two-dimensional vibrational and electronic spectroscopy. It also bridges the gap between the formal developm
The amide II' diagonal provides a measure of the degree of exchange and the cross peaks between the structurally sensitive amide I/I' vibration and the solvent exposure sensitive amide II and II' modes reveal the location of exchange. Partial exchange of the secondary structure of ubiquitin is revealed by correlation of the different amide signatures through analysis of cross peak line shapes, positions and amplitudes. Results provide direct evidence for a highly stable helix and labile "--Sheet structure.
Proteins function as ensembles of interconverting structures. The motions span from picosecond bond rotations to millisecond and longer subunit displacements. Characterization of functional dynamics on all spatial and temporal scales remains challenging experimentally. Two-dimensional IR spectroscopy (2D IR) is maturing as a powerful approach for investigating proteins and their dynamics. This document outlines the advantages of IR spectroscopy, describes 2D IR and the information it provides, and introduces vibrational groups for protein analysis. Following this introduction, example studies are presented that illustrate the power and versatility of 2D IR for characterizing protein dynamics. The thesis concludes with a brief discussion of the outlook for biomolecular 2D IR.