Amyloid fibrils and tangles are signatures of Alzheimer disease, but nanometer-sized aggregation intermediates are hypothesized to be the structures most toxic to neurons. The structures of these oligomers are too small to be resolved by conventional light microscopy. We have developed a simple and versatile method, called transient amyloid binding (TAB), to image amyloid structures with nanoscale resolution using amyloidophilic dyes, such as Thioflavin T, without the need for covalent labeling or immunostaining of the amyloid protein. Transient binding of ThT molecules to amyloid structures over time generates photon bursts that are used to localize single fluorophores with nanometer precision. Continuous replenishment of fluorophores from the surrounding solution minimizes photobleaching, allowing us to visualize a single amyloid structure for hours to days. We show that TAB microscopy can image both the oligomeric and fibrillar stages of amyloid-β aggregation. We also demonstrate that TAB microscopy can image the structural remodeling of amyloid fibrils by epi-gallocatechin gallate. Finally, we utilize TAB imaging to observe the non-linear growth of amyloid fibrils

Bieschke, Jan

Ding, Tianben

Lew, Matthew D

Spehar, Kevin

English

Amyloid fibrils and tangles are signatures of Alzheimer disease, but nanometer-sized aggregation intermediates are hypothesized to be the structures most toxic to neurons. The structures of these oligomers are too small to be resolved by conventional light microscopy. We have developed a simple and versatile method, called transient amyloid binding (TAB), to image amyloid structures with nanoscale resolution using amyloidophilic dyes, such as Thioflavin T, without the need for covalent labeling or immunostaining of the amyloid protein. Transient binding of ThT molecules to amyloid structures over time generates photon bursts that are used to localize single fluorophores with nanometer precision. Continuous replenishment of fluorophores from the surrounding solution minimizes photobleaching, allowing us to visualize a single amyloid structure for hours to days. We show that TAB microscopy can image both the oligomeric and fibrillar stages of amyloid-β aggregation. We also demonstrate that TAB microscopy can image the structural remodeling of amyloid fibrils by epi-gallocatechin gallate. Finally, we utilize TAB imaging to observe the non-linear growth of amyloid fibril

Ding, T

Spehar, K

Bieschke, J

Lew, MD

UCL Discovery

PROCEEDINGS OF SPIESPIEDigitalLibrary.org/conference-proceedings-of-spieLong-term, super-resolution imagingof amyloid structures using transientamyloid binding microscopyTianben Ding, Kevin Spehar, Jan Bieschke, Matthew D.LewTianben Ding, Kevin Spehar, Jan Bieschke, Matthew D. Lew, "Long-term,super-resolution imaging of amyloid structures using transient amyloid bindingmicroscopy," Proc. SPIE 10884, Single Molecule Spectroscopy andSuperresolution Imaging XII, 108840J (22 February 2019); doi:10.1117/12.2507656Event: SPIE BiOS, 2019, San Francisco, California, United StatesDownloaded From: https://www.spiedigitallibrary.org/conference-proceedings-of-spie on 25 Jun 2019  Terms of Use: https://www.spiedigitallibrary.org/terms-of-useLong-term, super-resolution imaging of amyloid structuresusing transient amyloid binding microscopyTianben Dinga, Kevin Speharb, Jan Bieschkec, and Matthew D. Lew*aaDepartment of Electrical and Systems Engineering, Washington University in St. Louis,1 Brookings Drive, St. Louis, MO, USA 63130bDepartment of Biomedical Engineering, Washington University in St. Louis,1 Brookings Drive, St. Louis, MO, USA 63130cMRC Prion Unit, UCL Institute of Prion Diseases, 33 Cleveland St., London, W1W 7FF, UKABSTRACTAmyloid fibrils and tangles are signatures of Alzheimer disease, but nanometer-sized aggregation intermediatesare hypothesized to be the structures most toxic to neurons. The structures of these oligomers are too small tobe resolved by conventional light microscopy. We have developed a simple and versatile method, called transientamyloid binding (TAB), to image amyloid structures with nanoscale resolution using amyloidophilic dyes, suchas Thioflavin T, without the need for covalent labeling or immunostaining of the amyloid protein. Transientbinding of ThT molecules to amyloid structures over time generates photon bursts that are used to localizesingle fluorophores with nanometer precision. Continuous replenishment of fluorophores from the surroundingsolution minimizes photobleaching, allowing us to visualize a single amyloid structure for hours to days. Weshow that TAB microscopy can image both the oligomeric and fibrillar stages of amyloid-β aggregation. We alsodemonstrate that TAB microscopy can image the structural remodeling of amyloid fibrils by epi-gallocatechingallate. Finally, we utilize TAB imaging to observe the non-linear growth of amyloid fibrils.Keywords: Single-molecule localization microscopy, amyloid-beta peptides, amyloid aggregation, binding-activated fluorescence1. INTRODUCTIONAmyloids, aggregates of misfolded short proteins, cause various aging-related human diseases, such as Alzheimerdisease (AD) and Parkinson disease. The 42 amino-acid residue amyloid-beta peptide (Aβ42) forms extracellularplaques in the brains of AD patients that are a pathological signature of the disease. Protein misfolding andfibril formation from monomeric structures are unique characteristics of amyloids including Aβ42, and nanometer-sized aggregation intermediates, termed oligomers, are typically considered to be the most toxic structures.1–3Amyloid aggregation, including the formation of oligomers, is dynamic, transitory, and heterogeneous, and itsmechanisms are still not fully understood. A new imaging methodology with single-molecule sensitivity andlong-term measurement capability is required for quantitatively studying the nanometer-scale inhomogeneitiesand dynamics of the aggregates.Conventional fluorescence microscopy is ubiquitous in studies of dynamics in living systems due to its speci-ficity from its molecular tags and its relatively non-invasive nature from its use of non-ionizing radiation. However,the physical resolution barrier, optical diffraction, bounds its resolution to approximately 250 nm given by theAbbe diffraction limit λ/2NA.4 Single-molecule (SM) super-resolution (SR) fluorescence microscopy techniques,such as (f)PALM5,6 and (d)STORM,7,8 overcome this physical limitation by actively switching densely labeledmolecules between bright and dark states to reduce the concentration of emitters within a sample. The statesof molecules can be switched by using a variety of mechanisms including photoactivation and chemical-inducedphotoswitching.9,10 A SR image can be reconstructed by recording these “blinking” events and localizing eachbright molecule with nanoscale precision.11*mdlew@wustl.edu; phone 1-314-935-6790; fax 1-314-935-7500; lewlab.wustl.eduSingle Molecule Spectroscopy and Superresolution Imaging XII, edited by Zygmunt Karol Gryczynski, Ingo Gregor, Felix Koberling, Proc. of SPIE Vol. 10884, 108840J · © 2019 SPIE CCC code: 1605-7422/19/$18 · doi: 10.1117/12.2507656Proc. of SPIE Vol. 10884  108840J-1Downloaded From: https://www.spiedigitallibrary.org/conference-proceedings-of-spie on 25 Jun 2019Terms of Use: https://www.spiedigitallibrary.org/terms-of-useWe have developed a SR imaging technique to visualize amyloid structures on the nanometer scale, calledTransient Amyloid Binding (TAB) imaging.12 Instead of covalent attachment13 or permanent intercalation14of fluorophores, TAB imaging uses transient binding of standard amyloidophilic dyes to amyloid structures.Amyloidophilic dyes, such as Thioflavin T (ThT), specifically bind to crossed β-sheets that form the fibrillarbackbone and increase their quantum yield upon binding.15 The molecules emit fluorescence until they dissociatefrom the structure or photobleach. We record “blinking” of ThT molecules, localize their positions on amyloidswith nanometer precision, and reconstruct the underlying structures. Our method is similar in concept to PAINT,which was first demonstrated for imaging lipid bilayers using Nile red as an imaging probe.16In this proceeding, we demonstrate a key advantage of TAB imaging, namely its long-term imaging capabilityrelative to traditional super-resolution techniques, and show its suitability for studying dynamics of amyloidstructures. We also show the use of Nile red as a TAB imaging probe for long-term observation of fibril growth.2. METHODSUnless stated otherwise, all chemicals were purchased from Sigma-Aldrich and are ACS grade.2.1 Amyloid PreparationAβ42 peptide purchased from ERI Amyloid Laboratory was dissolved in hexafluoro-2-propanol (HFIP), andsonicated at room temperature for one hour in a water bath sonicator. After freezing in liquid nitrogen, HFIPwas removed by lyophilization, and aliquots of the peptide were stored at -20 ◦C. To prepare amyloid aggregates,lyophilized Aβ42 were dissolved in 10 mM NaOH, sonicated for 25 min in a cold water bath, and filtered firstthrough a 0.2 µm and then through a 30 kD centrifugal membrane filter (Millipore) as described previously.17 Toprepare fibrils, we incubated 10 - 50 µM monomeric Aβ42 in PBS (150 mM NaCl, 50 mM Na3PO4, pH 7.4) at 37◦C with 200 rpm shaking for 24 hours. Fibril formation was verified by an atomic force microscope. To prepareoligomers, we incubated 10 - 50 µM monomeric Aβ42 in Dulbecco’s Modified Eagle Medium (DMEM)/NutrientMixture F-12 (ThermoFisher Scientific) at 4 ◦C without agitation for 24 hours. Oligomeric structures were alsoverified by an atomic force microscope.2.2 Imaging Sample PreparationEight-well cell culture chambers with glass coverslip bottoms (Lab Tek, No. 1.5H, 170 ± 5 µm thickness) werecleaned using a UV Ozone Cleaner (Novascan Technologies) for 15 minutes. Amyloid solutions were prepared asdescribed in section 2.1. A solution containing amyloid aggregates (10 µL) was adsorbed to the coverslip for 1hour. The coverslip was rinsed with 200 µL dH2O afterward.2.3 Imaging ProcedureTAB images were captured as follows. A PBS solution (200 µL) containing 1 µM ThT or 500 nM Nile red(Fisher Scientific) was placed into the amyloid-adsorbed chambers. Super-resolution imaging was performed ona home-built microscope12 equipped with an oil-immersion objective (Olympus, 100X, 1.4 NA) and a 488 nmor a 561 nm excitation laser for exciting ThT or Nile red, respectively. The peak intensities of the lasers at thesample were 1.8 kW/cm2 for the 488 nm and 0.45 kW/cm2 for the 561 nm lasers. Stacks of 5,000 images with20 ms camera exposure were recorded for each TAB reconstruction.Time-lapse imaging of amyloid remodeling was captured as follows. Aβ42 fibrils were adsorbed to ozone-cleaned chambers (section 2.1). epi-gallocatechin gallate (EGCG, Taiyo International) was added to an imagingbuffer in the amyloid-adsorbed chambers in order to remodel and dissolve amyloid fibrils.18 After variable-lengthincubations as indicated in Fig. 3 in the presence of 1 mM EGCG at room temperature (21 ◦C), the sample wasrinsed and replaced with the ThT imaging buffer for TAB imaging. This procedure was repeated over 46 hours.Time-lapse imaging of amyloid elongation was captured as follows. Aβ42 fibrils were needle sheared bypulling through a 25G needle ten times to form short seeds.19 The seed sample was then adsorbed onto anozone-cleaned coverslip (Azer Scientific, No. 1.5H, 170 ± 5 µm thickness) as described in section 2.1. A solution(10 µL) containing 20 µM monomeric Aβ42 and 500 nM Nile red in PBS was placed onto the coverslip. Thesolution was sandwiched by another coverslip from the top and sealed with wax to prevent evaporation. TheProc. of SPIE Vol. 10884  108840J-2Downloaded From: https://www.spiedigitallibrary.org/conference-proceedings-of-spie on 25 Jun 2019Terms of Use: https://www.spiedigitallibrary.org/terms-of-use0 450 200 35−0.2 0 0.2051015Distance (mm)Localizations/BinAamyloid fibrildark dye bright dyeOLTLsCMOSDMKLNSNOB C DE F GONNThioflavin TNile redFigure 1. Transient amyloid binding microscopy. A) Inclined laser illumination excites fluorophores transiently bound toamyloid structures, and collected fluorescence is captured by an sCMOS camera. KL: widefield lens, OL: objective lens,DM: dichroic mirror, TL: tube lens. Inset: transient binding, fluorescence activation, and unbinding of amyloidophilicdyes and the chemical structures of Thioflavin T (ThT) and Nile red. B) Diffraction-limited image using Nile red of anAβ42 fibril. C) Nile red TAB SR image of the fibril in (B). Color scale: localizations per bin. D) Cross-section of the whiteline across the fibril in (C). E) ThT blinking on another Aβ42 fibril. Color scale: photons per pixel. F) Diffraction-limitedimaging using ThT of the fibril in (E). G) ThT TAB SR image of the Aβ42 fibril in (E, F). Color scale: localizations perbin. Scale bars: 300 nm.sample was incubated on our microscope stage at room temperature (21 ◦C) without changing any buffers andmeanwhile, Nile red TAB imaging was performed periodically over 21 hours.The captured image stacks were offset-corrected at each pixel by subtracting an averaged dark image. Theimages where then localized using the ThunderSTORM20 plugin within ImageJ using default settings and customcamera parameters. Further post-processing was performed using MATLAB (Mathworks, R2018a) for calculatinglocalization precision and reconstructing SR images as previously described.12Proc. of SPIE Vol. 10884  108840J-3Downloaded From: https://www.spiedigitallibrary.org/conference-proceedings-of-spie on 25 Jun 2019Terms of Use: https://www.spiedigitallibrary.org/terms-of-use

Long-term, super-resolution imaging of amyloid structures using transient amyloid binding microscopy

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Long-term, super-resolution imaging of amyloid structures using transient amyloid binding microscopy

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