The structural eye lens protein γD-crystallin is a major component of cataracts, but its conformation when aggregated is unknown. Using expressed protein ligation, we uniformly 13 C labeled one of the two Greek key domains so that they are individually resolved in two-dimensional (2D) IR spectra for structural and kinetic analysis. Upon acid-induced amyloid fibril formation, the 2D IR spectra reveal that the C-terminal domain forms amyloid β-sheets, whereas the N-terminal domain becomes extremely disordered but lies in close proximity to the β-sheets. Two-dimensional IR kinetics experiments show that fibril nucleation and extension occur exclusively in the C-terminal domain. These results are unexpected because the N-terminal domain is less stable in the monomer form. Isotope dilution experiments reveal that each C-terminal domain contributes two or fewer adjacent β-strands to each β-sheet. From these observations, we propose an initial structural model for γD-crystallin amyloid fibrils. Because only 1 μg of protein is required for a 2D IR spectrum, even poorly expressing proteins can be studied under many conditions using this approach. Thus, we believe that 2D IR and protein ligation will be useful for structural and kinetic studies of many protein systems for which IR spectroscopy can be straightforwardly applied, such as membrane and amyloidogenic proteins. C ataracts are a protein misfolding disease caused by the aggregation of lens crystallin proteins into insoluble deposits that blur vision (1, 2). Because these proteins are not regenerated, damage from UV radiation, oxidative stress, and other chemical modifications accumulates with time (1, 2). As a result, over 50% of the population over 55 develops age-related cataracts (2). Additionally, numerous mutations that destabilize crystallin protein folds are linked to inherited and juvenile-onset cataracts (1). Although the causative factors associated with this disease are known, the structures of the aggregates and the mechanisms by which they form are unknown.Like other protein aggregation diseases such as type II diabetes mellitus and Alzheimer's disease, the molecular structures of proteins in cataracts are difficult to determine. Atomic-level structures have been obtained for some amyloid aggregates of peptides using NMR spectroscopy (3, 4) and X-ray crystallography (5). However, the most widely used techniques for studying aggregate structures and aggregation mechanisms are circular dichroism spectroscopy, fluorescence spectroscopy, and transmission electron microscopy, which provide little detailed structural information. Two-dimensional (2D) IR spectroscopy is emerging as an important tool for studying protein aggregates such as amyloid fibrils (6-8) because it provides bond-by-bond structural resolution on kinetically evolving samples (6, 8-10). Two-dimensional IR spectroscopy probes secondary structure through cross peak couplings and solvent exposure through 2D lineshapes. Its bond-specific structural resolution comes from isotope labeling. Mech...
While amyloid formation has been implicated in the pathology of over twenty human diseases, the rational design of amyloid inhibitors is hampered by a lack of structural information about amyloid-inhibitor complexes. We use isotope labeling and two-dimensional infrared spectroscopy to obtain a residue-specific structure for the complex of human amylin, the peptide responsible for islet amyloid formation in type 2 diabetes, with a known inhibitor, rat amylin. Based on its sequence, rat amylin should block formation of the C-terminal β-sheet, but at 8 hours after mixing rat amylin blocks the N-terminal β-sheet instead. At 24 hours after mixing, rat amylin blocks neither β-sheet and forms its own β-sheet most likely on the outside of the human fibrils. This is striking because rat amylin is natively disordered and not previously known to form amyloid β-sheets. The results show that even seemingly intuitive inhibitors may function by unforeseen and complex structural processes.
We describe a methodology for studying protein kinetics using a rapid-scan technology for collecting 2D IR spectra. In conjunction with isotope labeling, 2D IR spectroscopy is able to probe the secondary structure and environment of individual residues in polypeptides and proteins. It is particularly useful for membrane and aggregate proteins. Our rapid-scan technology relies on a mid-IR pulse shaper that computer generates the pulse shapes, much like in an NMR spectrometer. With this device, data collection is faster, easier, and more accurate. We describe our 2D IR spectrometer, as well as protocols for 13 C= 18 O isotope labeling, and then illustrate the technique with an application to the aggregation of the human islet amyloid polypeptide form type 2 diabetes.
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 alpha-helix. By resolving individual backbone vibrational modes (amide I) using 1-(13)C=(18)O 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 alpha-helix (3.6 amino acids). The periodic trend is caused by the asymmetric environment of the membrane bilayer that exposes one face of the alpha-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.
The aggregation of human amylin to form amyloid contributes to islet β-cell dysfunction in type 2 diabetes. Studies of amyloid formation have been hindered by the low structural resolution or relatively modest time resolution of standard methods. Two-dimensional infrared (2DIR) spectroscopy, with its sensitivity to protein secondary structures and its intrinsic fast time resolution, is capable of capturing structural changes during the aggregation process. Moreover, isotope labeling enables the measurement of residue-specific information. The diagonal line widths of 2DIR spectra contain information about dynamics and structural heterogeneity of the system. We illustrate the power of a combined atomistic molecular dynamics simulations and theoretical and experimental 2DIR approach by analyzing the variation in diagonal line widths of individual amide I modes in a series of labeled samples of amylin amyloid fibrils. The theoretical and experimental 2DIR line widths suggest a “W” pattern, as a function of residue number. We show that large line widths result from substantial structural disorder, and that this pattern is indicative of the stable secondary structure of the two β-sheet regions. This work provides a protocol for bridging MD simulation and 2DIR experiments for future aggregation studies.
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 frequen cies 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 linewidths 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 linewidth. Narrower linewidths 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.
A cost-efficient, time-reducing solid-phase synthesis of the amyloidogenic, 37 residue islet amyloid polypeptide (IAPP) is developed using two pseudoprolines (highlighted blue in sequence) in combination with microwave technology. A yield twice that obtained with conventional syntheses is realized. The utility of this protocol is demonstrated by the synthesis of a 13 C 18 Olabeled Ser-20 IAPP variant, a prohibitively expensive and chemically challenging site to label via other protocols. TEM analysis shows the peptide forms normal amyloid.Human islet amyloid polypeptide (IAPP or amylin) is a highly amyloidogenic 37 residue peptide that is stored with insulin and cosecreted from the β-cells of the pancreas. 1 The bioactive form contains an amidated C-terminus and a disulfide bond between two cysteine residues located at positions 2 and 7. IAPP forms amyloid deposits in the islets of the pancreas during type 2 diabetes, a process that is thought to contribute to the decline in β-cell mass observed in type 2 diabetes.1a,b ,2 Islet amyloid formation has been implicated as a © 2010 American Chemical Society * draleigh@notes.cc.sunysb.edu . Supporting Information Available:Description of the microwave temperature control and experimental methods for the preparation of 1-13 C 18 O Fmoc-O-tert-butyl-L-Ser. This material is available free of charge via the Internet at http://pubs.acs.org. The hydrophobicity of IAPP, combined with a significant number of β-branched amino acids, leads to difficulties in the solid-phase peptide synthesis (SPPS) of the peptide. IAPP has been successfully synthesized via Fmoc chemistry by the incorporation of three pseudoproline dipeptide derivatives, together with the double coupling of 20 amino acids. 4 Pseudoprolines induce significant kinks within the backbone of the growing chain, much like proline, remove hydrogen bond donors, and disrupt secondary structure, thus aiding in the prevention of aggregation. Standard TFA cleavage procedures regenerate the native structure of the peptide.5 The use of pseudoproline dipeptides and double coupling of the pseudoprolines, β-branched residues, and the residues immediately following the pseudoprolines and β-branched residues leads to a synthesis scheme which we have found typically generates 40-50 mg of pure peptide from a 0.25 mmol scale synthesis using PAL-PEG-PS resin. 4 Kelly and co-workers modified this procedure to significantly reduce the number of double couplings and obtained yields on the order of 20 mg of pure peptide from a 0.1 mmol scale synthesis. 6 Both of these methods used pseudoprolines at positions 8-9, 19-20, and 27-28. NIH Public AccessAdvances in microwave technology coupled with solid-phase peptide synthesis have led to reports of syntheses of difficult, hydrophobic peptides at greater yields than reported using conventional synthesis. 7 Microwave energy allows for rapid heating at the molecular level, driving the coupling and deprotection reaction rates forward while reducing aggregation. A solid-phase microwave-ass...
A series of non-natural infrared probes is reported that consist of a metal-tricarbonyl modified with a -(CH2)n- linker and cysteine-specific leaving group. They can be site-specifically attached to proteins using mutagenesis and similar protocols for EPR spin labels, which have the same leaving group. We characterize the label’s frequencies and lifetimes using 2D IR spectroscopy in solvents of varying dielectric. The frequency range spans 10 cm−1, and the variation in lifetimes ranges from 6 to 19 ps, indicating that these probes are very sensitive to their environments. Also, we attached probes with -(CH2)-, -(CH2)3-, -(CH2)4- linkers to ubiquitin at positions 6 and 63 and collected spectra in aqueous buffer. The frequencies and lifetimes were correlated for 3C and 4C linkers, as they were in the solvents, but did not correlate for the 1C linker. We concluded that lifetime measures solvation, whereas frequency reflects the electrostatics of the environment, which in the case of the 1C linker is a measure of the protein electrostatic field. We also labeled V71C α-synuclein in buffer and membrane-bound. Unlike most other infrared labels, this label has extremely-strong cross-sections and so can be measured with 2D IR spectroscopy at sub-millimolar concentrations. We expect that these labels will find use in studying the structure and dynamics of membrane-bound, aggregated, and kinetically-evolving proteins for which high signal-to-noise at low protein concentrations is imperative.
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