Your search keyword '"DNA-PAINT"' showing total 261 results

1. Analysis of binding site dependent labelling efficiency for DNA-PAINT using particle fusion

Author

Heydarian, Hamidreza, Stallinga, Sjoerd, and Rieger, Bernd

Published

2024

2. Label-free (fluorescence-free) sensing of a single DNA molecule on DNA origami using a plasmon-enhanced WGM sensor.

Author

Ghamari, Shahin, Chiarelli, Germán, Kołątaj, Karol, Subramanian, Sivaraman, Acuna, Guillermo P., and Vollmer, Frank

Subjects

WHISPERING gallery modes, NUCLEIC acid hybridization, DNA folding, DNA structure, SINGLE molecules

Abstract

The integration of DNA origami structures with opto-plasmonic whispering gallery mode (WGM) sensors offers a significant advancement in label-free biosensing, overcoming the limitations of traditional fluorescence-based techniques, and providing enhanced sensitivity and specificity for detecting DNA hybridization events. In this study, DNA origami acts as a scaffold for the precise assembly of plasmonic dimers, composed of gold nanorods (AuNRs), which amplify detection sensitivity by generating strong near-field enhancements in the nanogap between the nanorods. By leveraging the strong electromagnetic fields generated within the nanogap of the plasmonic dimer, this platform enables the detection of transient hybridization events between DNA docking strands and freely diffusing complementary sequences. Our findings demonstrate that the salt concentration critically influences DNA hybridization kinetics. Higher ionic strengths reduce electrostatic repulsion between negatively charged DNA strands, thereby stabilizing duplex formation and prolonging interaction times. These effects are most pronounced at salt concentrations around 300–500 mM, where optimal conditions for duplex stability and reduced dissociation rates are achieved. By thoroughly investigating the hybridization kinetics under varying environmental conditions, this study contributes to a deeper understanding of DNA interactions and offers a robust tool for single-molecule detection with real-time capabilities. [ABSTRACT FROM AUTHOR]

Published

2025

3. Multicolor single-molecule localization microscopy: review and prospect

Author

Xi Chen, Xiangyu Wang, Fang Huang, and Donghan Ma

Subjects

Super-resolution microscopy, Singe-molecule localization microscopy, Multicolor imaging, DNA-PAINT, Ratiometric imaging, Spectroscopic imaging, Applied optics. Photonics, TA1501-1820

Abstract

Abstract Single-molecule localization microscopy (SMLM) surpasses the diffraction limit by randomly switching fluorophores between fluorescent and dark states, precisely pinpointing the resulted isolated emission patterns, thereby reconstructing the super-resolution images based on the accumulated locations of thousands to millions of single molecules. This technique achieves a ten-fold improvement in resolution, unveiling the intricate details of molecular activities and structures in cells and tissues. Multicolor SMLM extends this capability by imaging distinct protein species labeled with various fluorescent probes, providing insights into structural intricacies and spatial relationships among different targets. This review explores recent advancements in multicolor SMLM, evaluates the strengths and limitations of each variant, and discusses the future prospects.

Published

2024

4. Multicolor single-molecule localization microscopy: review and prospect.

Author

Chen, Xi, Wang, Xiangyu, Huang, Fang, and Ma, Donghan

Subjects

HIGH resolution imaging, SPECTROSCOPIC imaging, MOLECULAR structure, FLUORESCENT probes, SINGLE molecules

Abstract

Single-molecule localization microscopy (SMLM) surpasses the diffraction limit by randomly switching fluorophores between fluorescent and dark states, precisely pinpointing the resulted isolated emission patterns, thereby reconstructing the super-resolution images based on the accumulated locations of thousands to millions of single molecules. This technique achieves a ten-fold improvement in resolution, unveiling the intricate details of molecular activities and structures in cells and tissues. Multicolor SMLM extends this capability by imaging distinct protein species labeled with various fluorescent probes, providing insights into structural intricacies and spatial relationships among different targets. This review explores recent advancements in multicolor SMLM, evaluates the strengths and limitations of each variant, and discusses the future prospects. [ABSTRACT FROM AUTHOR]

Published

2024

5. Distinct SAP102 and PSD-95 Nano-organization Defines Multiple Types of Synaptic Scaffold Protein Domains at Single Synapses.

Author

Metzbower, Sarah R., Levy, Aaron D., Dharmasri, Poorna A., Anderson, Michael C., and Blanpied, Thomas A.

Subjects

*SCAFFOLD proteins, *PROTEIN domains, *SYNAPSES, *NEURAL transmission, *SYNAPTOGENESIS, *NEURONS

Abstract

MAGUK scaffold proteins play a central role in maintaining and modulating synaptic signaling, providing a framework to retain and position receptors, signaling molecules, and other synaptic components. In particular, the MAGUKs SAP102 and PSD-95 are essential for synaptic function at distinct developmental timepoints and perform both overlapping and unique roles. While their similar structures allow for common binding partners, SAP102 is expressed earlier in synapse development and is required for synaptogenesis, whereas PSD-95 expression peaks later and is associated with synapse maturation. PSD-95 and other key synaptic proteins organize into subsynaptic nanodomains that have a significant impact on synaptic transmission, but the nanoscale organization of SAP102 is unknown. How SAP102 is organized within the synapse, and how it relates spatially to PSD-95 on a nanometer scale, could underlie its unique functions and impact how SAP102 scaffolds synaptic proteins. Here we used DNA-PAINT super-resolution microscopy to measure SAP102 nanoorganization and its spatial relationship to PSD-95 at individual synapses in mixed-sex rat cultured neurons. We found that like PSD-95, SAP102 accumulates in high-density subsynaptic nanoclusters (NCs). However, SAP102 NCs were smaller and denser than PSD-95 NCs across development. Additionally, only a subset of SAP102 NCs co-organized with PSD-95, revealing MAGUK nanodomains within individual synapses containing either one or both proteins. These MAGUK nanodomain types had distinct NC properties and were differentially enriched with the presynaptic release protein Munc13-1. This organization into both shared and distinct subsynaptic nanodomains may underlie the ability of SAP102 and PSD-95 to perform both common and unique synaptic functions. [ABSTRACT FROM AUTHOR]

Published

2024

6. PvdL Orchestrates the Assembly of the Nonribosomal Peptide Synthetases Involved in Pyoverdine Biosynthesis in Pseudomonas aeruginosa.

Author

Manko, Hanna, Steffan, Tania, Gasser, Véronique, Mély, Yves, Schalk, Isabelle, and Godet, Julien

Subjects

*NONRIBOSOMAL peptide synthetases, *PSEUDOMONAS aeruginosa, *BIOSYNTHESIS, *SPATIAL arrangement, *PEPTIDES, *RHAMNOLIPIDS

Abstract

The pyoverdine siderophore is produced by Pseudomonas aeruginosa to access iron. Its synthesis involves the complex coordination of four nonribosomal peptide synthetases (NRPSs), which are responsible for assembling the pyoverdine peptide backbone. The precise cellular organization of these NRPSs and their mechanisms of interaction remain unclear. Here, we used a combination of several single-molecule microscopy techniques to elucidate the spatial arrangement of NRPSs within pyoverdine-producing cells. Our findings reveal that PvdL differs from the three other NRPSs in terms of localization and mobility patterns. PvdL is predominantly located in the inner membrane, while the others also explore the cytoplasmic compartment. Leveraging the power of multicolor single-molecule localization, we further reveal co-localization between PvdL and the other NRPSs, suggesting a pivotal role for PvdL in orchestrating the intricate biosynthetic pathway. Our observations strongly indicates that PvdL serves as a central orchestrator in the assembly of NRPSs involved in pyoverdine biosynthesis, assuming a critical regulatory function. [ABSTRACT FROM AUTHOR]

Published

2024

7. Single-Molecule Microscopy Methods to Study Mitochondrial Processes

Author

Dellmann, Timo, Kostina, Anna, Garcia Saéz, Ana J., Pedras, Bruno, Series Editor, Šachl, Radek, editor, and Amaro, Mariana, editor

Published

2023

8. Clathrin packets move in slow axonal transport and deliver functional payloads to synapses

Author

Ganguly, Archan, Sharma, Rohan, Boyer, Nicholas P, Wernert, Florian, Phan, Sébastien, Boassa, Daniela, Parra, Leonardo, Das, Utpal, Caillol, Ghislaine, Han, Xuemei, Yates, John R, Ellisman, Mark H, Leterrier, Christophe, and Roy, Subhojit

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Neurosciences, Psychology, 1.1 Normal biological development and functioning, Neurological, Generic health relevance, Animals, Animals, Newborn, Axonal Transport, Cells, Cultured, Clathrin, Clathrin-Coated Vesicles, Hippocampus, Mice, Protein Transport, Rats, Rats, Wistar, Synapses, Time-Lapse Imaging, Apex, DNA-PAINT, FKBP-FRB, FRAP, axonal transport, clathrin, endocytosis, mass spectrometry, super-resolution, superpool, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology

Abstract

In non-neuronal cells, clathrin has established roles in endocytosis, with clathrin cages enclosing plasma membrane infoldings, followed by rapid disassembly and reuse of monomers. However, in neurons, clathrin is conveyed in slow axonal transport over days to weeks, and the underlying transport/targeting mechanisms, mobile cargo structures, and even its precise presynaptic localization and physiologic role are unclear. Combining live imaging, photobleaching/conversion, mass spectrometry, electron microscopy, and super-resolution imaging, we found that unlike in dendrites, where clathrin cages rapidly assemble and disassemble, in axons, clathrin and related proteins organize into stable "transport packets" that are unrelated to endocytosis and move intermittently on microtubules, generating an overall slow anterograde flow. At synapses, multiple clathrin packets abut synaptic vesicle (SV) clusters, and clathrin packets also exchange between synaptic boutons in a microtubule-dependent "superpool." Within synaptic boundaries, clathrin is surprisingly dynamic, continuously exchanging between local clathrin assemblies, and its depletion impairs SV recycling. Our data provide a conceptual framework for understanding clathrin trafficking and presynaptic targeting that has functional implications.

Published

2021

9. A Novel Method to Map Small RNAs with High Resolution.

Author

Huang, Kun, Demirci, Feray, Meyers, Blake, and Caplan, Jeffrey

Subjects

DNA-PAINT, In situ hybridization, LNA, Microscopy, RNA detection, Single molecule, Small RNA, Super-resolution, sRNA

Abstract

Analyzing cellular structures and the relative location of molecules is essential for addressing biological questions. Super-resolution microscopy techniques that bypass the light diffraction limit have become increasingly popular to study cellular molecule dynamics in situ. However, the application of super-resolution imaging techniques to detect small RNAs (sRNAs) is limited by the choice of proper fluorophores, autofluorescence of samples, and failure to multiplex. Here, we describe an sRNA-PAINT protocol for the detection of sRNAs at nanometer resolution. The method combines the specificity of locked nucleic acid probes and the low background, precise quantitation, and multiplexable characteristics of DNA Point Accumulation for Imaging in Nanoscale Topography (DNA-PAINT). Using this method, we successfully located sRNA targets that are important for development in maize anthers at sub-20 nm resolution and quantitated their exact copy numbers. Graphic abstract: Multiplexed sRNA-PAINT. Multiple Vetting and Analysis of RNA for In Situ Hybridization (VARNISH) probes with different docking strands (i.e., a, b, …) will be hybridized to samples. The first probe will be imaged with the a* imager. The a* imager will be washed off with buffer C, and then the sample will be imaged with b* imager. The wash and image steps can be repeated sequentially for multiplexing.

Published

2021

10. Quantitative super-resolution imaging of cell polarity proteins using DNA-PAINT

Author

Dzafic, Edo and St Johnston, Daniel

Subjects

570.285, super-resolution imaging, DNA-PAINT, qPAINT, cell polarity, polarity proteins, aPKC, Par6, Crumbs, protein clustering, quantitative imaging, Drosophila melanogaster, fruit fly, single-molecule localisation microscopy, molecular counting

Abstract

Knowing the localisation and spatial organisation of proteins is crucial for understanding their function. The development of super-resolution imaging has improved our ability to garner this information, but counting individual molecules in densely-packed assemblies is still challenging. DNA-based point accumulation for imaging in nanoscale topography (DNA-PAINT) is one of the most recently developed imaging techniques in super-resolution microscopy. It uses fluorescently-labelled DNA to visualise the molecules of interest with nanometre precision. DNA-PAINT was initially reliant on antibody labelling of in vitro protein targets, however, there is need for an alternative labelling strategy as good antibodies do not exist for many target proteins. Moreover, it is impossible to quantify antibody labelling efficiency, which is a crucial parameter for quantitative imaging. In order to address these issues, I present here an optimised imaging pipeline for protein counting in a thick tissue sample, tens of microns away from the coverslip, for which cell polarity proteins in epithelial cells of the fruit fly (Drosophila melanogaster) egg chambers are given as an example. Firstly, I established an alternative labelling strategy to label polarity proteins for DNA-PAINT imaging using genetically-encoded Halo and SNAP self-labelling enzymes in fruit fly tissue. In this approach, the Halo and SNAP ligands conjugated to DNA react with their respective enzymes to form a covalent bond with the protein of interest in a 1:1 stoichiometry. I then optimised the labelling protocol for imaging the fixed fruit fly tissue and analysed non-specific signal to reduce background during image post-processing. A quantitative Western blot-based gel band shift assay was developed to determine the labelling efficiency of target proteins. Moreover, I used nucleoporin proteins in the nuclear pore complex to calibrate the influx rate of fluorescently-labelled DNA to quantify the number of molecules in super-resolution images. Additionally, I used nucleoporin-160 and nucleoporin-188 to benchmark two-colour super-resolution imaging using DNA-PAINT. Super-resolution imaging of three apical polarity proteins (aPKC, Crumbs, Par6) in the fruit fly egg chambers revealed that they form mesoscopic-sized clusters along the cell junctions. In order to analyse these clusters in a quantitative manner, I collaborated with Leila Muresan to develop an image analysis pipeline. My analysis demonstrated that apical polarity proteins are less concentrated in the cytosol by approximately one order of magnitude. To expand on these observations, the junctional clusters were identified by a mean-shift algorithm and classified according to size, i.e. the number of molecules. The cluster size distribution was then approximated by a mathematical function. The model selection was performed by Bayesian information criteria that was tested on simulated data beforehand. This work provides an optimised imaging pipeline for quantifying the number of protein molecules in a thick biological sample using DNA-PAINT, and proposes a post-processing approach to identify and mathematically describe molecular clustering. These data will prove useful for modelling the spatial organisation of polarity proteins, and provide a framework for greater insight into the biological function of individual proteins.

Published

2020

11. Self‐quenched Fluorophore Dimers for DNA‐PAINT and STED Microscopy.

Author

Kessler, Laurell F., Balakrishnan, Ashwin, Deußner‐Helfmann, Nina S., Li, Yunqing, Mantel, Maximilian, Glogger, Marius, Barth, Hans‐Dieter, Dietz, Marina S., and Heilemann, Mike

Subjects

*THERMODYNAMICS, *MICROSCOPY, *STIMULATED emission, *HIGH resolution imaging, *BOUND states, *SINGLE-stranded DNA, *OLIGONUCLEOTIDES, *DIMERS

Abstract

Super‐resolution techniques like single‐molecule localisation microscopy (SMLM) and stimulated emission depletion (STED) microscopy have been extended by the use of non‐covalent, weak affinity‐based transient labelling systems. DNA‐based hybrid systems are a prominent example among these transient labelling systems, offering excellent opportunities for multi‐target fluorescence imaging. However, these techniques suffer from higher background relative to covalently bound fluorophores, originating from unbound fluorophore‐labelled single‐stranded oligonucleotides. Here, we introduce short‐distance self‐quenching in fluorophore dimers as an efficient mechanism to reduce background fluorescence signal, while at the same time increasing the photon budget in the bound state by almost 2‐fold. We characterise the optical and thermodynamic properties of fluorophore‐dimer single‐stranded DNA, and show super‐resolution imaging applications with STED and SMLM with increased spatial resolution and reduced background. [ABSTRACT FROM AUTHOR]

Published

2023

12. Super‐Resolved FRET Imaging by Confocal Fluorescence‐Lifetime Single‐Molecule Localization Microscopy.

Author

Zaza, Cecilia, Chiarelli, Germán, Zweifel, Ludovit P., Pilo‐Pais, Mauricio, Sisamakis, Evangelos, Barachati, Fabio, Stefani, Fernando D., and Acuna, Guillermo P.

Subjects

*FLUORESCENCE resonance energy transfer, *MICROSCOPY

Abstract

Fluorescence Resonance Energy Transfer (FRET)‐based approaches are unique tools for sensing the immediate surroundings and interactions of (bio)molecules. FRET imaging and Fluorescence Lifetime Imaging Microscopy (FLIM) enable the visualization of the spatial distribution of molecular interactions and functional states. However, conventional FLIM and FRET imaging provide average information over an ensemble of molecules within a diffraction‐limited volume, which limits the spatial information, accuracy, and dynamic range of the observed signals. Here, an approach to obtain super‐resolved FRET imaging based on single‐molecule localization microscopy using an early prototype of a commercial time‐resolved confocal microscope is demonstrated. DNA Points Accumulation for Imaging in Nanoscale Topography with fluorogenic probes provides a suitable combination of background reduction and binding kinetics compatible with the scanning speed of usual confocal microscopes. A single laser is used to excite the donor, a broad detection band is employed to retrieve both donor and acceptor emission, and FRET events are detected from lifetime information. [ABSTRACT FROM AUTHOR]

Published

2023

13. Using polarization sensitive SMLM to infer the interaction strength of dye-plasmonic nanosphere systems.

Author

Novák, T., Bíró, P., Ferenc, Gy., Ungor, D., Czvik, E., Deák, Á., Janovák, L., and Erdélyi, M.

Subjects

*MIE scattering, *NANOPARTICLE size, *FLUOROPHORES, *MICROSCOPY, *PLASMONICS

Abstract

Single-molecule microscopy is an effective tool for the characterization of fluorophore–plasmonic structure interaction. However, sophisticated evaluation is required as specific information is hidden in the emission. Here, we theoretically and experimentally investigated the emission polarization of rotationally mobile fluorophores near plasmonic Au–Ag alloy nanospheres. We developed an elaborate calculation based on the Mie theory, which considers the rotational mobility of dyes near spherical plasmonic nanoparticles of any size. Furthermore, we have created a simplified model that describes the emission's degree of polarization within 10% accuracy in the case of small nanoparticles, when dipole approximation is valid. Our results indicate the close relation of the polarization degree of the emission, which can reach up to be ∼ 0. 8 in the resonant case, to fluorescence scattering. DNA-PAINT single-molecule localization microscopy experiments conducted using AF488 and Atto647N dyes revealed that the measured polarization degree distribution followed the tendency predicted by calculations. [ABSTRACT FROM AUTHOR]

Published

2025

14. Quantitative single molecule analysis of podoplanin clustering in fibroblastic reticular cells uncovers CD44 function

Author

Shu En Lim, Megan D. Joseph, Charlotte M. de Winde, Sophie E. Acton, and Sabrina Simoncelli

Subjects

super-resolution, DNA-PAINT, qPAINT, podoplanin, CLEC-2, CD44, Biology (General), QH301-705.5

Abstract

Upon initial immune challenge, dendritic cells (DCs) migrate to lymph nodes and interact with fibroblastic reticular cells (FRCs) via C-type lectin-like receptor 2 (CLEC-2). CLEC-2 binds to the membrane glycoprotein podoplanin (PDPN) on FRCs, inhibiting actomyosin contractility through the FRC network and permitting lymph node expansion. The hyaluronic acid receptor CD44 is known to be required for FRCs to respond to DCs but the mechanism of action is not fully elucidated. Here, we use DNA-PAINT, a quantitative single molecule super-resolution technique, to visualize and quantify how PDPN clustering is regulated in the plasma membrane of FRCs. Our results indicate that CLEC-2 interaction leads to the formation of large PDPN clusters (i.e. more than 12 proteins per cluster) in a CD44-dependent manner. These results suggest that CD44 expression is required to stabilize large pools of PDPN at the membrane of FRCs upon CLEC-2 interaction, revealing the molecular mechanism through which CD44 facilitates cellular crosstalk between FRCs and DCs.

Published

2023

15. Correlative super-resolution analysis of cardiac calcium sparks and their molecular origins in health and disease

Author

Miriam E. Hurley, Ed White, Thomas M. D. Sheard, Derek Steele, and Izzy Jayasinghe

Subjects

ryanodine receptor, nanodomains, calcium signalling, DNA-PAINT, correlative light microscopy, Biology (General), QH301-705.5

Abstract

Rapid release of calcium from internal stores via ryanodine receptors (RyRs) is one of the fastest types of cytoplasmic second messenger signalling in excitable cells. In the heart, rapid summation of the elementary events of calcium release, 'calcium sparks', determine the contraction of the myocardium. We adapted a correlative super-resolution microscopy protocol to correlate sub-plasmalemmal spontaneous calcium sparks in rat right ventricular myocytes with the local nanoscale RyR2 positions. This revealed a steep relationship between the integral of a calcium spark and the sum of the local RyR2s. Segmentation of recurring spark sites showed evidence of repeated and triggered saltatory activation of multiple local RyR2 clusters. In myocytes taken from failing right ventricles, RyR2 clusters themselves showed a dissipated morphology and fragmented (smaller) clusters. They also featured greater heterogeneity in both the spark properties and the relationship between the integral of the calcium spark and the local ensemble of RyR2s. While fragmented (smaller) RyR2 clusters were rarely observed directly underlying the larger sparks or the recurring spark sites, local interrogation of the channel-to-channel distances confirmed a clear link between the positions of each calcium spark and the tight, non-random clustering of the local RyR2 in both healthy and failing ventricles.

Published

2023

16. Super‐Resolution Tension PAINT Imaging with a Molecular Beacon.

Author

Kim, Seong Ho and Li, Isaac T. S.

Subjects

*HIGH resolution imaging, *SINGLE-stranded DNA, *MOLECULAR probes, *FLUORESCENCE, *PRESSURE-sensitive paint, *DNA

Abstract

DNA‐PAINT enabled super‐resolution imaging through the transient binding of fluorescently‐labelled single‐stranded DNA (ssDNA) imagers to target ssDNA. However, its performance is constrained by imager background fluorescence, resulting in relatively long image acquisition and potential artifacts. We designed a molecular beacon (MB) as the PAINT imager. Unbound MB in solution reduces the background fluorescence due to its natively quenched state. They are fluorogenic upon binding to target DNA to create individual fluorescence events. We demonstrate that MB‐PAINT provides localization precision similar to traditional linear imager DNA‐PAINT. We also show that MB‐PAINT is ideally suited for fast super‐resolution imaging of molecular tension probes in living cells, eliminating the potential of artifacts from free‐diffusing imagers in traditional DNA‐PAINT at the cell‐substrate interface. [ABSTRACT FROM AUTHOR]

Published

2023

17. Monitoring Dynamic Conformations of a Single Fluorescent Molecule Inside a Protein Cavity.

Author

Sosa S, Szalai AM, Lopez LF, Prieto JM, Zaza C, Adamczyk AK, Bonomi HR, Marti MA, Acuna GP, Goldbaum FA, and Stefani FD

Abstract

Fluorescence nanoscopy and single-molecule methods are entering the realm of structural biology, breaking new ground for dynamic structural measurements at room temperature and liquid environments. Here, single-molecule localization microscopy, polarization-dependent single-molecule excitation, and protein engineering are combined to determine the orientation of a fluorophore forming hydrogen bonds inside a protein cavity. The observed conformations are in good agreement with molecular dynamics simulations, enabling a new, more realistic interplay between experiments and simulations to identify stable conformations and the key interactions involved. Furthermore, jumps between conformations can be monitored with a precision of 3° and a time resolution of a few seconds, confirming the potential of this methodology for retrieving dynamic structural information of nanoscopic biological systems under physiologically compatible conditions., (© 2025 Wiley‐VCH GmbH.)

Published

2025

18. Super-Resolution Goes Viral: T4 Virus Particles as Versatile 3D-Bio-NanoRulers.

Author

Gallea JI, Nevskyi O, Kaźmierczak Z, Gligonov I, Chen T, Miernikiewicz P, Chizhik AM, Reinkensmeier L, Dąbrowska K, Bates M, and Enderlein J

Abstract

In the burgeoning field of super-resolution fluorescence microscopy, significant efforts are being dedicated to expanding its applications into the 3D domain. Various methodologies have been developed that enable isotropic resolution at the nanometer scale, facilitating the visualization of 3D subcellular structures with unprecedented clarity. Central to this progress is the need for reliable 3D structures that are biologically compatible for validating resolution capabilities. Choosing the optimal standard poses a considerable challenge, necessitating, among other attributes, precisely defined geometry and the capability for specific labeling at sub-diffraction-limit distances. In this context, the use of the non-human-infecting virus, bacteriophage T4 is introduced as an effective and straightforward bio-ruler for 3D super-resolution imaging. Employing DNA point accumulation for imaging in nanoscale topography (DNA-PAINT) along with the technique of astigmatic imaging, the icosahedral capsid of the bacteriophage T4, measuring 120 nm in length and 86 nm in width, and its hollow viral tail is uncovered. This level of detail in light microscopy represents a significant advancement in T4 imaging. A simple protocol for the production and preparation of samples is further outlined. Moreover, the extensive potential of bacteriophage T4 as a multifaceted 3D bio-ruler, proposing its application as a novel benchmark for 3D super-resolution imaging in biological studies is explored., (© 2025 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2025

19. Purinergic GPCR-integrin interactions drive pancreatic cancer cell invasion

Author

Elena Tomas Bort, Megan D Joseph, Qiaoying Wang, Edward P Carter, Nicolas J Roth, Jessica Gibson, Ariana Samadi, Hemant M Kocher, Sabrina Simoncelli, Peter J McCormick, and Richard P Grose

Subjects

pancreatic cancer, purinergic signalling, invasion, DNA-PAINT, 3D modelling, Medicine, Science, Biology (General), QH301-705.5

Abstract

Pancreatic ductal adenocarcinoma (PDAC) continues to show no improvement in survival rates. One aspect of PDAC is elevated ATP levels, pointing to the purinergic axis as a potential attractive therapeutic target. Mediated in part by highly druggable extracellular proteins, this axis plays essential roles in fibrosis, inflammation response, and immune function. Analyzing the main members of the PDAC extracellular purinome using publicly available databases discerned which members may impact patient survival. P2RY2 presents as the purinergic gene with the strongest association with hypoxia, the highest cancer cell-specific expression, and the strongest impact on overall survival. Invasion assays using a 3D spheroid model revealed P2Y2 to be critical in facilitating invasion driven by extracellular ATP. Using genetic modification and pharmacological strategies, we demonstrate mechanistically that this ATP-driven invasion requires direct protein-protein interactions between P2Y2 and αV integrins. DNA-PAINT super-resolution fluorescence microscopy reveals that P2Y2 regulates the amount and distribution of integrin αV in the plasma membrane. Moreover, receptor-integrin interactions were required for effective downstream signaling, leading to cancer cell invasion. This work elucidates a novel GPCR-integrin interaction in cancer invasion, highlighting its potential for therapeutic targeting.

Published

2023

20. Quantitative DNA-PAINT imaging of AMPA receptors in live neurons

Author

Yeoan Youn, Gloria W. Lau, Yongjae Lee, Barun Kumar Maity, Eric Gouaux, Hee Jung Chung, and Paul R. Selvin

Subjects

AMPAR, DNA-PAINT, live cell imaging, Biotechnology, TP248.13-248.65, Biochemistry, QD415-436, Science

Abstract

Summary: DNA-point accumulation for imaging at nanoscale topography (DNA-PAINT) can image fixed biological specimens with nanometer resolution and absolute stoichiometry. In living systems, however, the usage of DNA-PAINT has been limited due to high salt concentration in the buffer required for specific binding of the imager to the docker attached to the target. Here, we used multiple binding motifs of the docker, from 2 to 16, to accelerate the binding speed of the imager under physiological buffer conditions without compromising spatial resolution and maintaining the basal level homeostasis during the measurement. We imaged endogenous α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (AMPAR) in cultured neurons—critical proteins involved in nerve communication—by DNA-PAINT in 3-dimensions using a monovalent single-chain variable fragment (scFv) to the GluA1 subunit of AMPAR. We found a heterogeneous distribution of synaptic AMPARs: ≈60% are immobile, primarily in nanodomains, defined as AMPARs that are within 0.3 μm of the Homer1 protein in the postsynaptic density; the other ∼40% of AMPARs have restricted mobility and trajectory. Motivation: Single-molecule localization microscopy can provide nanoscale resolution of molecular structure of biological samples, yet the application of the technique in live samples is limited. Here, we developed a live-cell DNA-PAINT technique to image and quantify neuronal receptor molecules in live hippocampal neurons.

Published

2023

21. Nanobodies combined with DNA-PAINT super-resolution reveal a staggered titin nanoarchitecture in flight muscles

Author

Florian Schueder, Pierre Mangeol, Eunice HoYee Chan, Renate Rees, Jürgen Schünemann, Ralf Jungmann, Dirk Görlich, and Frank Schnorrer

Subjects

muscle, sarcomere, Drosophila, DNA-PAINT, super-resolution, titin, Medicine, Science, Biology (General), QH301-705.5

Abstract

Sarcomeres are the force-producing units of all striated muscles. Their nanoarchitecture critically depends on the large titin protein, which in vertebrates spans from the sarcomeric Z-disc to the M-band and hence links actin and myosin filaments stably together. This ensures sarcomeric integrity and determines the length of vertebrate sarcomeres. However, the instructive role of titins for sarcomeric architecture outside of vertebrates is not as well understood. Here, we used a series of nanobodies, the Drosophila titin nanobody toolbox, recognising specific domains of the two Drosophila titin homologs Sallimus and Projectin to determine their precise location in intact flight muscles. By combining nanobodies with DNA-PAINT super-resolution microscopy, we found that, similar to vertebrate titin, Sallimus bridges across the flight muscle I-band, whereas Projectin is located at the beginning of the A-band. Interestingly, the ends of both proteins overlap at the I-band/A-band border, revealing a staggered organisation of the two Drosophila titin homologs. This architecture may help to stably anchor Sallimus at the myosin filament and hence ensure efficient force transduction during flight.

Published

2023

22. Fluorescence Super-Resolution Imaging Chip for Gene Silencing Exosomes

Author

Gaoqiang Yin, Tongsheng Qi, Jinxiu Wei, Tingyu Wang, Zhuyuan Wang, Yiping Cui, and Shenfei Zong

Subjects

exosomes, immunotherapy, PD-L1, microfluidic chip, DNA-PAINT, integrated platform, Chemical technology, TP1-1185

Abstract

Tumor cell-derived extracellular vesicles and their cargo of bioactive substances have gradually been recognized as novel biomarkers for cancer diagnosis. Meanwhile, the PD-L1 (Programmed Death-Ligand 1) protein, as an immune checkpoint molecule, is highly expressed on certain tumor cells and holds significant potential in immune therapy. In comparison to PD-L1 monoclonal antibodies, the inhibitory effect of PD-L1 siRNA (small interfering RNA) is more advantageous. In this article, we introduced a microfluidic chip integrating cell cultivation and exosome detection modules, which were intended for the investigation of the gene silencing effect of PD-L1 siRNA. Basically, cells were first cultured with PD-L1 siRNA in the chip. Then, the secreted exosomes were detected via super-resolution imaging, to validate the inhibitory effect of siRNA on PD-L1 expression. To be specific, a “sandwich” immunological structure was employed to detect exosomes secreted from HeLa cells. Immunofluorescence staining and DNA-PAINT (DNA Point Accumulation for Imaging in Nanoscale Topography) techniques were utilized to quantitatively analyze the PD-L1 proteins on HeLa exosomes, which enabled precise structural and content analysis of the exosomes. Compared with other existing PD-L1 detection methods, the advantages of our work include, first, the integration of microfluidic chips greatly simplifying the cell culture, gene silencing, and PD-L1 detection procedures. Second, the utilization of DNA-PAINT can provide an ultra-high spatial resolution, which is beneficial for exosomes due to their small sizes. Third, qPAINT could allow quantitative detection of PD-L1 with better precision. Hence, the combination of the microfluidic chip with DNA-PAINT could provide a more powerful integrated platform for the study of PD-L1-related tumor immunotherapy.

Published

2023

23. Optimisation and comparison of dSTORM and DNA-PAINT super-resolution for quantitative cardiac protein imaging

Author

Clowsley, Alexander Harrington, Soeller, Christian, and Winlove, Peter

Subjects

530, DNA-PAINT, Cardiac, Ryanodine Receptor

Abstract

Fluorescence microscopy techniques, restricted by the diffraction limit of light, have seen a remarkable advancement in recent years. An approach called dSTORM (direct stochastic optical reconstruction microscopy) utilises the photoswitching capabilities of organic fluorophores when in the presence of special mounting media, the solution within which the sample is placed, to detect single molecule fluorescing events over time. The image that can be reconstructed from these events is not diffraction limited, but instead is limited by how well each event can be precisely localised. In Chapter 3 the importance of using a suitable mounting buffer in order to achieve super-resolution dSTORM is discussed in detail. A quantitative method for determining the reactivity of thiol dSTORM switching mountants was developed for use within the lab. Every fluorescent probe has different photophysical properties which can be manipulated by varying the composition of the switching buffer to enhance desirable qualities, such as; increased photon counts, faster switching rates, and longer survivability. In addition to investigating the effects of buffer composition the use of a near UV light-source was also explored as a means of manipulating the same properties to improve overall resolution and quality of the resulting images. A range of photoswitchable fluorescent dyes were tested including Alexa Fluor 660 which is a dye that to my knowledge has not been greatly tested for use in single molecule localisation microscopy by others to date. This dye performed strongly alongside the traditional Alexa Fluor 647 used for dSTORM imaging in optimal conditions. A relatively new approach to single molecule imaging which does not require the fluorophore to photoswitch, called DNA-PAINT (point accumulation for imaging in nanoscale topography), has been investigated throughout this thesis. This approach relies on the transient binding of small oligonucleotide sequences, called “Imagers”, to target docking strands anchored in positions of interest. These imagers have a photostable and bright fluorophore conjugated to the oligonucleotide. It is the transient immobilisation of the imager strand, as it binds to a fixed docking strand, which appears as stochastic blinks. The duration of these events, which can be extended by increasing the number of overlapping base pairs, is primarily responsible for improved localisation precision and therefore potentially overall resolution. At the end of Chapter 3 I compare this new pointillism microscopy approach, DNA-PAINT, with dSTORM using a set of custom-designed oligonucleotide sequences that allow both formats to be employed on the same target. The transient binding of small strands of oligonucleotides offers a far more controllable system for stochastic imaging. In Chapter 4 I use this superior approach to achieve greater resolution than other fluorescence techniques in biological samples, sufficient to visualise single ryanodine receptors (RyR). The RyR are extremely important in the contraction of muscle cells as they are capable of detecting transient changes to calcium concentration and are responsible for releasing large stores of calcium from the sarcoplasmic reticulum. With DNA-PAINT I observed that RyRs cluster into irregular arrays which contain significant gaps that are occupied by other proteins, including junctophilin (JPH). The stoichiometry of JPH with RyR varied cluster to cluster, exposing a new complexity in the regulation of RyRs. In Chapter 5, quantitative super-resolution is reliably achieved through the implementation of quantitative DNA-PAINT (qPAINT) within the Python Microscopy Environment (PYME) software. Quantitative measurements are possible because of the statistical predictability of DNA hybridisation and the near constant influx of fresh imager strands by diffusion. This results in limited photobleaching, a permanent dark state. The frequency with which a region of interest blinks is proportional to the number of binding sites available, and therefore the mean dark time between detected events is also inversely proportional. I validate my approach to qPAINT, which maintains the spatial information of individual structures, by using a DNA-origami test slide. Two distinguishable structures were present and an estimate for the ratio of available docking sites between them was satisfactorily established. I conclude that with this tool, molecule densities can be inferred and information about biological samples can be probed to new levels. The results of the full methodological approach to accomplish dual-colour super-resolution imaging of optically thick cardiac tissue, using both dSTORM and DNA PAINT techniques, is discussed in detail in Chapter 6. The current range of photoswitchable fluorophores limits the possible combination of molecular dyes for use with dSTORM and some compromise is made in their selection. For DNA-PAINT, the prospect of chromatic aberration is removed by imaging the same dye in subsequent rounds of imaging. The process, called Exchange-PAINT, allows the user to remove previously imaged imager strands, through a series of washes, and replace them with a complementary sequence for another target. I introduce the concept of using quencher strands to eliminate signal from unwanted imager sequences, accelerating their removal in samples of reduced diffusion and decreasing the risk of sample disturbance, in a process we termed Quencher Exchange-PAINT. Using this technique, I achieve superior super resolution results in optically thick samples. The results presented in this thesis are expected to (1) lead to a better understanding of the variables associated with single molecule localisation microscopy, (2) further reveal the complexity in cardiac protein distribution, (3) quantify relationships between co-localising proteins and other targets, and (4) apply DNA-PAINT to imaging in optically thick biological samples. This study shows promise for the future applications of the DNA-PAINT pointillism super-resolution method and its ability to investigate a multitude of biological questions.

Published

2017

24. DNA‐PAINT Super‐Resolution Imaging for Characterization of Nucleic Acid Nanostructures.

Author

Dai, Zheze, Xie, Xiaodong, Gao, Zhaoshuai, and Li, Qian

Subjects

*HIGH resolution imaging, *NANOSTRUCTURES, *ATOMIC force microscopy, *ELECTRON microscopy

Abstract

Numerous nucleic acid nanostructures of unique addressability and programmability have been fabricated for emerging applications. Structural characterization with atomic force microscopy and electron microscopy can provide information on the structural morphology and precision of these nanostructures. However, either structural information of native nucleic acid nanostructures in hydrated environment or the availability of addressable sites on these nanostructures could not be determined. Alternatively, DNA points accumulation for imaging in nanoscale topography (DNA‐PAINT) enables direct optical visualization of nucleic acid nanostructures in native forms, as well as evaluation of the accessibility of addressable sites on them. In this Review, the working principle of DNA‐PAINT is introduced, followed by the summary on advances of DNA‐PAINT characterization of various nucleic acid nanostructures. Finally, the current challenges and prospects for DNA‐PAINT characterization are presented. We envision DNA‐PAINT to be a potent characterization tool for functional nanomaterials. [ABSTRACT FROM AUTHOR]

Published

2022

25. Nanoscopic Spatial Association between Ras and Phosphatidylserine on the Cell Membrane Studied with Multicolor Super Resolution Microscopy.

Author

Koester, Anna M., Tao, Kai, Szczepaniak, Malwina, Rames, Matthew J., and Nan, Xiaolin

Subjects

*PHOSPHATIDYLSERINES, *RAS proteins, *CYTOSKELETON, *MICROSCOPY, *SPATIAL resolution

Abstract

Recent work suggests that Ras small GTPases interact with the anionic lipid phosphatidylserine (PS) in an isoform-specific manner, with direct implications for their biological functions. Studies on PS-Ras associations in cells, however, have relied on immuno-EM imaging of membrane sheets. To study their spatial relationships in intact cells, we have combined the use of Lact-C2-GFP, a biosensor for PS, with multicolor super resolution imaging based on DNA-PAINT. At ~20 nm spatial resolution, the resulting super resolution images clearly show the nonuniform molecular distribution of PS on the cell membrane and its co-enrichment with caveolae, as well as with unidentified membrane structures. Two-color imaging followed by spatial analysis shows that KRas-G12D and HRas-G12V both co-enrich with PS in model U2OS cells, confirming previous observations, yet exhibit clear differences in their association patterns. Whereas HRas-G12V is almost always co-enriched with PS, KRas-G12D is strongly co-enriched with PS in about half of the cells, with the other half exhibiting a more moderate association. In addition, perturbations to the actin cytoskeleton differentially impact PS association with the two Ras isoforms. These results suggest that PS-Ras association is context-dependent and demonstrate the utility of multiplexed super resolution imaging in defining the complex interplay between Ras and the membrane. [ABSTRACT FROM AUTHOR]

Published

2022

26. Strategies for Controlling the Spatial Orientation of Single Molecules Tethered on DNA Origami Templates Physisorbed on Glass Substrates: Intercalation and Stretching.

Author

Cervantes-Salguero, Keitel, Biaggne, Austin, Youngsman, John M., Ward, Brett M., Kim, Young C., Li, Lan, Hall, John A., Knowlton, William B., Graugnard, Elton, and Kuang, Wan

Subjects

*SINGLE molecules, *DNA folding, *SPATIAL orientation, *MOLECULAR dynamics, *MOLECULAR theory, *MOLECULAR orientation

Abstract

Nanoarchitectural control of matter is crucial for next-generation technologies. DNA origami templates are harnessed to accurately position single molecules; however, direct single molecule evidence is lacking regarding how well DNA origami can control the orientation of such molecules in three-dimensional space, as well as the factors affecting control. Here, we present two strategies for controlling the polar (θ) and in-plane azimuthal (ϕ) angular orientations of cyanine Cy5 single molecules tethered on rationally-designed DNA origami templates that are physically adsorbed (physisorbed) on glass substrates. By using dipolar imaging to evaluate Cy5′s orientation and super-resolution microscopy, the absolute spatial orientation of Cy5 is calculated relative to the DNA template. The sequence-dependent partial intercalation of Cy5 is discovered and supported theoretically using density functional theory and molecular dynamics simulations, and it is harnessed as our first strategy to achieve θ control for a full revolution with dispersion as small as ±4.5°. In our second strategy, ϕ control is achieved by mechanically stretching the Cy5 from its two tethers, being the dispersion ±10.3° for full stretching. These results can in principle be applied to any single molecule, expanding in this way the capabilities of DNA as a functional templating material for single-molecule orientation control. The experimental and modeling insights provided herein will help engineer similar self-assembling molecular systems based on polymers, such as RNA and proteins. [ABSTRACT FROM AUTHOR]

Published

2022

27. Point-Spread Function Deformations Unlock 3D Localization Microscopy on Spherical Nanoparticles

Author

Huijben, Teun A.P.M., Mahajan, Sarojini, Fahim, Masih, Zijlstra, Peter, Marie, Rodolphe, Mortensen, Kim I., Huijben, Teun A.P.M., Mahajan, Sarojini, Fahim, Masih, Zijlstra, Peter, Marie, Rodolphe, and Mortensen, Kim I.

Abstract

Nanoparticles (NPs) have proven their applicability in biosensing, drug delivery, and photothermal therapy, but their performance depends critically on the distribution and number of functional groups on their surface. When studying surface functionalization using super-resolution microscopy, the NP modifies the fluorophore’s point-spread function (PSF). This leads to systematic mislocalizations in conventional analyses employing Gaussian PSFs. Here, we address this shortcoming by deriving the analytical PSF model for a fluorophore near a spherical NP. Its calculation is four orders of magnitude faster than numerical approaches and thus feasible for direct use in localization algorithms. We fit this model to individual 2D images from DNA-PAINT experiments on DNA-coated gold NPs and demonstrate extraction of the 3D positions of functional groups with <5 nm precision, revealing inhomogeneous surface coverage. Our method is exact, fast, accessible, and poised to become the standard in super-resolution imaging of NPs for biosensing and drug delivery applications.

Published

2024

28. Revealing Spatial Molecular Heterogeneity of High-Density Biofunctionalized Surfaces Using DNA-PAINT

Author

Tan, Wei Shan, de Jong, Arthur M., Prins, Menno W.J., Tan, Wei Shan, de Jong, Arthur M., and Prins, Menno W.J.

Published

2024

29. 2D Temperature Mapping of Single Particles at the nanoscale by DNA Point Accumulation for Imaging in Nanoscale Topography

Author

Dyberg, Olle and Dyberg, Olle

Abstract

The heating of gold nanoparticles (AuNPs) holds significant potential within photothermal cancer therapy, where it can be used for the removal of tumors, and within plasmon-assisted chemistry to perform reactions requiring a localized temperature increase at the nanoscale. However, precise knowledge of the temperature distribution around the particles given the present experimental conditions is essential for these methods. Traditional thermometry methods either lack the necessary spatial resolution or are too invasive for measuring this gradient. To overcome these limitations, this thesis employs DNA point accumulation for imaging in nanoscale topography (DNA-PAINT), a super-resolution technique that surpasses the classical diffraction limit of light. DNA-PAINT is inherently non-invasive and temperature dependent, making quantification of temperature possible at the nanoscale following a system characterization. The DNA-PAINT thermometry approach used in this work begins with a characterization of the system's kinetics—the rate of reactions and processes—as a function of laser power and temperature. These characterizations reveal the nature of the experiments' kinetics and the temperature sensitivity of the system at hand. This temperature sensitivity depends on the highly configurable DNA-PAINT setup, which allows for adjustments in temperature resolution. The work presented in this thesis began with a study of various imaging buffers to determine the best experimental conditions for DNA-PAINT. The ``best'' buffer was chosen by investigating the buffers' effect on the photon distributions and kinetics of the experiments. Thereafter, with the chosen buffer and experimental components, the DNA-PAINT system was characterized by measuring the kinetics as a function of laser power and temperature. Finally, the DNA-PAINT kinetics were measured in the presence of a temperature gradient induced by a heated AuNP. Measurements could be done within tens of na

Published

2024

30. DNA-PAINT Imaging Accelerated by Machine Learning

Author

Min Zhu, Luhao Zhang, Luhong Jin, Jincheng Chen, Yongdeng Zhang, and Yingke Xu

Subjects

DNA-PAINT, machine learning, super-resolution imaging, U-Net, single-molecule localization microscopy, Chemistry, QD1-999

Abstract

DNA point accumulation in nanoscale topography (DNA-PAINT) is an easy-to-implement approach for localization-based super-resolution imaging. Conventional DNA-PAINT imaging typically requires tens of thousands of frames of raw data to reconstruct one super-resolution image, which prevents its potential application for live imaging. Here, we introduce a new DNA-PAINT labeling method that allows for imaging of microtubules with both DNA-PAINT and widefield illumination. We develop a U-Net-based neural network, namely, U-PAINT to accelerate DNA-PAINT imaging from a widefield fluorescent image and a sparse single-molecule localization image. Compared with the conventional method, U-PAINT only requires one-tenth of the original raw data, which permits fast imaging and reconstruction of super-resolution microtubules and can be adopted to analyze other SMLM datasets. We anticipate that this machine learning method enables faster and even live-cell DNA-PAINT imaging in the future.

Published

2022

31. Reduced Non-Specific Binding of Super-Resolution DNA-PAINT Markers by Shielded DNA-PAINT Labeling Protocols.

Author

Lučinskaitė E, Bokhobza AFE, Stannard A, Meletiou A, Estell C, West S, Michele LD, Soeller C, and Clowsley AH

Subjects

Staining and Labeling methods, Humans, DNA Probes chemistry, DNA chemistry

Abstract

The DNA-based single molecule super-resolution imaging approach, DNA-PAINT, can achieve nanometer resolution of single targets. However, the approach can suffer from significant non-specific background signals originating from non-specifically bound DNA-conjugated DNA-PAINT secondary antibodies as shown here. Using dye-modified oligonucleotides the location of DNA-PAINT secondary antibody probes can easily be observed with widefield imaging prior to beginning a super-resolution measurement. This reveals that a substantial proportion of DNA probes can accumulate, non-specifically, within the nucleus, as well as across the cytoplasm, of cells. Here, Shielded DNA-PAINT labeling is introduced, a method using partially or fully double-stranded docking strand sequences, prior to labeling, in buffers with increased ionic strength to greatly reduce non-specific interactions in the nucleus as well as the cytoplasm. This new labeling approach is evaluated against various conditions and it is shown that applying Shielded DNA-PAINT can reduce non-specific events approximately five-fold within the nucleus. This marked reduction in non-specific binding of probes during the labeling procedure is comparable to results obtained with unnatural left-handed DNA albeit at a fraction of the cost. Shielded DNA-PAINT is a straightforward adaption of current DNA-PAINT protocols and enables nanometer precision imaging of nuclear targets with low non-specific backgrounds., (© 2024 The Author(s). Small published by Wiley‐VCH GmbH.)

Published

2024

32. Revealing Spatial Molecular Heterogeneity of High-Density Biofunctionalized Surfaces Using DNA-PAINT.

Author

Tan WS, de Jong AM, and Prins MWJ

Subjects

DNA, Single-Stranded chemistry, DNA chemistry, Polyethylene Glycols chemistry, Surface Properties

Abstract

The quantification and control of molecular densities and distributions on biofunctionalized surfaces are key for enabling reproducible functions in biosciences. Here, we describe an analysis methodology for quantifying the density and spatial distribution of high-density biofunctionalized surfaces, with densities in the order of 10 2 -10 5 biomolecules per μm 2 area, in a short measurement time. The methodology is based on single-molecule DNA-PAINT imaging combined with simulation models that compensate for lifetime and spatial undersampling effects, resulting in three distinct molecule counting methods and a statistical test for spatial distribution. The analysis methodology is exemplified for a surface with ssDNA affinity binder molecules coupled to a PLL- g -PEG antifouling coating. The results provide insights into the biofunctionalization efficiency, yield, and homogeneity. Furthermore, the data reveal that heterogeneity is inherent to the biofunctionalization process and shed light on the underlying molecular mechanisms. We envision that DNA-PAINT imaging with the developed analysis framework will become a versatile tool to study spatial heterogeneity of densely biofunctionalized surfaces for a wide range of applications.

Published

2024

33. Quantitative Analysis of Protein-Protein Equilibrium Constants in Cellular Environments Using Single-Molecule Localization Microscopy.

Author

Marcano-García LF, Zaza C, Dalby OPL, Joseph MD, Cappellari MV, Simoncelli S, and Aramendía PF

Subjects

Humans, Protein Binding, T-Lymphocytes metabolism, T-Lymphocytes chemistry, Jurkat Cells, CD3 Complex metabolism, CD3 Complex chemistry, Receptors, Antigen, T-Cell metabolism, Receptors, Antigen, T-Cell chemistry, Single Molecule Imaging methods

Abstract

Current methods for determining equilibrium constants often operate in three-dimensional environments, which may not accurately reflect interactions with membrane-bound proteins. With our technique, based on single-molecule localization microscopy (SMLM), we directly determine protein-protein association ( K a ) and dissociation ( K d ) constants in cellular environments by quantifying associated and isolated molecules and their interaction area. We introduce Kernel Surface Density (ks-density,) a novel method for determining the accessible area for interacting molecules, eliminating the need for user-defined parameters. Simulation studies validate our method's accuracy across various density and affinity conditions. Applying this technique to T cell signaling proteins, we determine the 2D association constant of T cell receptors (TCRs) in resting cells and the pseudo-3D dissociation constant of pZAP70 molecules from phosphorylated intracellular tyrosine-based activation motifs on the TCR-CD3 complex. We address challenges of multiple detection and molecular labeling efficiency. This method enhances our understanding of protein interactions in cellular environments, advancing our knowledge of complex biological processes.

Published

2024

34. Point-Spread Function Deformations Unlock 3D Localization Microscopy on Spherical Nanoparticles.

Author

Huijben TAPM, Mahajan S, Fahim M, Zijlstra P, Marie R, and Mortensen KI

Subjects

Nanoparticles chemistry, Imaging, Three-Dimensional, Metal Nanoparticles chemistry, Microscopy, Fluorescence, Fluorescent Dyes chemistry, Surface Properties, Particle Size, Algorithms, Gold chemistry, DNA chemistry

Abstract

Nanoparticles (NPs) have proven their applicability in biosensing, drug delivery, and photothermal therapy, but their performance depends critically on the distribution and number of functional groups on their surface. When studying surface functionalization using super-resolution microscopy, the NP modifies the fluorophore's point-spread function (PSF). This leads to systematic mislocalizations in conventional analyses employing Gaussian PSFs. Here, we address this shortcoming by deriving the analytical PSF model for a fluorophore near a spherical NP. Its calculation is four orders of magnitude faster than numerical approaches and thus feasible for direct use in localization algorithms. We fit this model to individual 2D images from DNA-PAINT experiments on DNA-coated gold NPs and demonstrate extraction of the 3D positions of functional groups with <5 nm precision, revealing inhomogeneous surface coverage. Our method is exact, fast, accessible, and poised to become the standard in super-resolution imaging of NPs for biosensing and drug delivery applications.

Published

2024

35. Single-Molecule Assessment of DNA Hybridization Kinetics on Dye-Loaded DNA Nanostructures.

Author

Li C, Xie Y, Cheng X, Xu L, Yao G, Li Q, Shen J, Fan C, and Li M

Subjects

Kinetics, Coloring Agents chemistry, DNA, Single-Stranded chemistry, Nanostructures chemistry, Nucleic Acid Hybridization, DNA chemistry

Abstract

DNA nanostructures offer a versatile platform for precise dye assembly, making them promising templates for creating photonic complexes with applications in photonics and bioimaging. However, despite these advancements, the effect of dye loading on the hybridization kinetics of single-stranded DNA protruding from DNA nanostructures remains unexplored. In this study, the DNA points accumulation for imaging in the nanoscale topography (DNA-PAINT) technique is employed to investigate the accessibility of functional binding sites on DNA-templated excitonic wires. The results indicate that positively charged dyes on DNA frameworks can accelerate the hybridization kinetics of protruded ssDNA through long-range electrostatic interactions. Furthermore, the impacts of various charged dyes and binding sites are explored on diverse DNA frameworks with varying cross-sizes. The research underscores the crucial role of electrostatic interactions in DNA hybridization kinetics within DNA-dye complexes, offering valuable insights for the functionalization and assembly of biomimetic photonic systems., (© 2024 Wiley‐VCH GmbH.)

Published

2024

36. Quantitative Imaging With DNA-PAINT for Applications in Synaptic Neuroscience

Author

Eduard M. Unterauer and Ralf Jungmann

Subjects

DNA-PAINT, DNA nanotechnology, neuronal target, fluorescence microscopy, super-resolution microscopy, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Super-resolution (SR) microscopy techniques have been advancing the understanding of neuronal protein networks and interactions. Unraveling the arrangement of proteins with molecular resolution provided novel insights into neuron cytoskeleton structure and actin polymerization dynamics in synaptic spines. Recent improvements in quantitative SR imaging have been applied to synaptic protein clusters and with improved multiplexing technology, the interplay of multiple protein partners in synaptic active zones has been elucidated. While all SR techniques come with benefits and drawbacks, true molecular quantification is a major challenge with the most complex requirements for labeling reagents and careful experimental design. In this perspective, we provide an overview of quantitative SR multiplexing and discuss in greater detail the quantification and multiplexing capabilities of the SR technique DNA-PAINT. Using predictable binding kinetics of short oligonucleotides, DNA-PAINT provides two unique approaches to address multiplexed molecular quantification: qPAINT and Exchange-PAINT. With precise and accurate quantification and spectrally unlimited multiplexing, DNA-PAINT offers an attractive route to unravel complex protein interaction networks in neurons. Finally, while the SR community has been pushing technological advances from an imaging technique perspective, the development of universally available, small, efficient, and quantitative labels remains a major challenge in the field.

Published

2022

37. A single-molecule localization microscopy method for tissues reveals nonrandom nuclear pore distribution in Drosophila.

Author

Jinmei Cheng, Allgeyer, Edward S., Richens, Jennifer H., Dzafic, Edo, Palandri, Amandine, Lewków, Bohdan, Sirinakis, George, and St Johnston, Daniel

Subjects

*DROSOPHILA, *MICROSCOPY, *OPTICAL aberrations, *CLUSTER theory (Nuclear physics), *NUCLEOPORINS

Abstract

Single-molecule localization microscopy (SMLM) can provide nanoscale resolution in thin samples but has rarely been applied to tissues because of high background from out-of-focus emitters and optical aberrations. Here, we describe a line scanning microscope that provides optical sectioning for SMLM in tissues. Imaging endogenously-tagged nucleoporins and F-actin on this system using DNA- and peptide-point accumulation for imaging in nanoscale topography (PAINT) routinely gives 30 nm resolution or better at depths greater than 20 αm. This revealed that the nuclear pores are nonrandomly distributed in most Drosophila tissues, in contrast to what is seen in cultured cells. Lamin Dm0 shows a complementary localization to the nuclear pores, suggesting that it corrals the pores. Furthermore, ectopic expression of the tissue-specific Lamin C causes the nuclear pores to distribute more randomly, whereas lamin C mutants enhance nuclear pore clustering, particularly in muscle nuclei. Given that nucleoporins interact with specific chromatin domains, nuclear pore clustering could regulate local chromatin organization and contribute to the disease phenotypes caused by human lamin A/C laminopathies. [ABSTRACT FROM AUTHOR]

Published

2021

38. Telomerase detection using a DNA-PAINT strategy.

Author

Zong, Shenfei, Ye, Xiangyu, Zong, Junzhu, Li, Jia, Wang, Zhuyuan, and Cui, Yiping

Subjects

*TELOMERASE, *SPATIAL resolution, *POLYMERASE chain reaction, *SIGNAL-to-noise ratio, *CELL division

Abstract

Telomerase plays an important role in maintaining the length of telomere during cell division and is recognized as a new kind of biomarkers for cancer diagnosis. In this work, we present a brand new telomerase detection strategy based on a DNA points accumulation for imaging in nanoscale topography (DNA-PAINT) like strategy. With an extraordinary spatial resolution (∼10 nm), the DNA-PAINT based strategy offers several advantages. First, it avoids complicated polymerase chain reaction and electrophoresis procedures. Second, it enables super resolution imaging of the reaction products with a high signal-to-noise ratio and facilitates the location of telomeric elongation sites on the single particle level, which results in a high sensitivity. Third, the detection scheme of the DNA-PAINT strategy allows direct in situ visualization of the telomeric elongation process, which has never been achieved before. All these advantages make the DNA-PAINT telomerase detection strategy significant for dynamic investigation of telomerase related physiological processes as well as cancer diagnosis. [ABSTRACT FROM AUTHOR]

Published

2021

39. Completing the canvas: advances and challenges for DNA-PAINT super-resolution imaging.

Author

van Wee, Raman, Filius, Mike, and Joo, Chirlmin

Subjects

*HIGH resolution imaging, *DNA probes, *BIOLOGICAL systems, *LIGHT in art, *CANVAS

Abstract

Single-molecule localization microscopy (SMLM) is a potent tool to examine biological systems with unprecedented resolution, enabling the investigation of increasingly smaller structures. At the forefront of these developments is DNA-based point accumulation for imaging in nanoscale topography (DNA-PAINT), which exploits the stochastic and transient binding of fluorescently labeled DNA probes. In its early stages the implementation of DNA-PAINT was burdened by low-throughput, excessive acquisition time, and difficult integration with live-cell imaging. However, recent advances are addressing these challenges and expanding the range of applications of DNA-PAINT. We review the current state of the art of DNA-PAINT in light of these advances and contemplate what further developments remain indispensable to realize live-cell imaging. In recent years the performance, utility, and ease-of-use of DNA-based point accumulation in nanoscale topography (DNA-PAINT) have greatly improved by increasing compatibility with existing technology and diversifying the usable probes. Multiplexing with DNA-PAINT has become possible, which allows users to probe many targets simultaneously and paves the way for high-throughput methods. Advances have alleviated the limiting factors that govern the binding frequency, thereby accelerating imaging acquisition and enabling DNA-PAINT imaging to be performed in several minutes. The complex environment in living cells creates numerous challenges for standard DNA-PAINT imaging. These challenges are being addressed through improved probe design such as using modified DNA nucleotides or amino acid-based backbones for the imager and docking probes. [ABSTRACT FROM AUTHOR]

Published

2021

40. Imaging the fibroblast growth factor receptor network on the plasma membrane with DNA-assisted single-molecule super-resolution microscopy.

Author

Schröder, Mark S., Harwardt, Marie-Lena I.E., Rahm, Johanna V., Li, Yunqing, Freund, Petra, Dietz, Marina S., and Heilemann, Mike

Subjects

*FIBROBLAST growth factor receptors, *MEMBRANE proteins, *HIGH resolution imaging, *MICROSCOPY, *STEREOLOGY, *FIBROBLAST growth factors

Abstract

[Display omitted] • DNA nanotechnology was correlated with multiplexed single-molecule super-resolution imaging. • A procedure for near-molecular visualization and analysis of membrane receptor networks was established. • This approach enabled quantitative microscopy of the FGFR1-4 receptor network at the native cellular expression level. • Information on receptor clustering and distance relationships was extracted. • The imaging and analysis pipeline can be easily adapted to other protein networks. Fibroblast growth factor receptors (FGFRs) are a subfamily of receptor tyrosine kinases and central players in health and disease. Following ligand binding and the formation of homo- and heteromeric complexes, FGFRs initiate a cellular response. Challenges in studying FGFR activation are inner-subfamily interactions and a complex heterogeneity of these in the cell membrane, which demand for observation techniques that can resolve individual protein complexes and that are compatible with endogenous protein levels. Here, we established an imaging and analysis pipeline for multiplexed single-molecule localization microscopy (SMLM) of the FGFR network at the plasma membrane. Using DNA-labeled primary antibodies, we visualize all four FGFRs in the same cell with near-molecular spatial resolution. From the super-resolution imaging data, we extract information on FGFR density, spatial distribution, and inner-subfamily colocalization. Our approach is straightforward and easily adaptable to other multiplexed SMLM data of membrane proteins. [ABSTRACT FROM AUTHOR]

Published

2021

41. A correlative super-resolution protocol to visualise structural underpinnings of fast second-messenger signalling in primary cell types.

Author

Hurley, Miriam E., Sheard, Thomas M.D., Norman, Ruth, Kirton, Hannah M., Shah, Shihab S., Pervolaraki, Eleftheria, Yang, Zhaokang, Gamper, Nikita, White, Ed, Steele, Derek, and Jayasinghe, Izzy

Subjects

*CELL communication, *IMAGE registration, *INTRACELLULAR calcium, *IMAGE analysis, *CALCIUM channels, *RYANODINE receptors, *PRIMARY cell culture

Abstract

• The imaging protocol visualises intracellular calcium signals and their sources. • It correlates calcium spark TIRF images with DNA-PAINT images of RyR channels. • It is a powerful method for studying nanoscale structure-function relationship. Nanometre-scale cellular information obtained through super-resolution microscopies are often unaccompanied by functional information, particularly transient and diffusible signals through which life is orchestrated in the nano-micrometre spatial scale. We describe a correlative imaging protocol which allows the ubiquitous intracellular second messenger, calcium (Ca2+), to be directly visualised against nanoscale patterns of the ryanodine receptor (RyR) Ca2+ channels which give rise to these Ca2+ signals in wildtype primary cells. This was achieved by combining total internal reflection fluorescence (TIRF) imaging of the elementary Ca2+ signals, with the subsequent DNA-PAINT imaging of the RyRs. We report a straightforward image analysis protocol of feature extraction and image alignment between correlative datasets and demonstrate how such data can be used to visually identify the ensembles of Ca2+ channels that are locally activated during the genesis of cytoplasmic Ca2+ signals. [ABSTRACT FROM AUTHOR]

Published

2021

42. Visualizing Synaptic Multi-Protein Patterns of Neuronal Tissue With DNA-Assisted Single-Molecule Localization Microscopy

Author

Kaarjel K. Narayanasamy, Aleksandar Stojic, Yunqing Li, Steffen Sass, Marina R. Hesse, Nina S. Deussner-Helfmann, Marina S. Dietz, Thomas Kuner, Maja Klevanski, and Mike Heilemann

Subjects

single-molecule localization microscopy, super-resolution microscopy, DNA-PAINT, neuronal synapse, multiplexing, Exchange PAINT, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The development of super-resolution microscopy (SRM) has widened our understanding of biomolecular structure and function in biological materials. Imaging multiple targets within a single area would elucidate their spatial localization relative to the cell matrix and neighboring biomolecules, revealing multi-protein macromolecular structures and their functional co-dependencies. SRM methods are, however, limited to the number of suitable fluorophores that can be imaged during a single acquisition as well as the loss of antigens during antibody washing and restaining for organic dye multiplexing. We report the visualization of multiple protein targets within the pre- and postsynapse in 350–400 nm thick neuronal tissue sections using DNA-assisted single-molecule localization microscopy (SMLM). In a single labeling step, antibodies conjugated with short DNA oligonucleotides visualized multiple targets by sequential exchange of fluorophore-labeled complementary oligonucleotides present in the imaging buffer. This approach avoids potential effects on structural integrity when using multiple rounds of immunolabeling and eliminates chromatic aberration, because all targets are imaged using a single excitation laser wavelength. This method proved robust for multi-target imaging in semi-thin tissue sections with a lateral resolution better than 25 nm, paving the way toward structural cell biology with single-molecule SRM.

Published

2021

43. DNA-PAINT Probe Modifications Support High-Resolution Imaging with Shorter Binding Domains.

Author

Piantanida L, Dickinson GD, Majikes JM, Clay W, Liddle JA, Andersen T, Hayden EJ, Kuang W, and Hughes WL

Subjects

DNA Probes chemistry, Nanostructures chemistry, Nucleic Acid Hybridization, DNA chemistry

Abstract

DNA-based Points Accumulation for Imaging in Nanoscale Topography (DNA-PAINT) is an effective super resolution microscopy technique, and its optimization is key to improve nanoscale detection. The state-of-the-art improvements that are at the base of this optimization have been first routinely validated on DNA nanostructure devices before being tested on biological samples. This allows researchers to finely tune DNA-PAINT imaging features in a more controllable in vitro environment. Dye-labeled oligonucleotide probes with short hybridization domains can expand DNA-PAINT's detection by targeting short nucleotide sequences and improving resolution, speed, and multiplexing. However, developing these probes is challenging as their brief bound state makes them difficult to capture under routine imaging conditions. To extend dwell binding times and promote duplex stability, we introduced structural and chemical modifications to our imager probes. The modifications included mini-hairpins and/or Bridged Nucleic Acids (BNA); both of which increase the thermomechanical stability of a DNA duplex. Using this approach we demonstrate DNA-PAINT imaging with approximately 5 nm resolution using a 4-nucleotide hybridization domain that is 43% shorter than previously reported probes. Imager probes with such short hybridization domains are key for improving detection on DNA nanostructure devices because they have the capability to target a larger number of binding domains per localization unit. This is essential for metrology applications such as Nucleic Acid Memory (NAM) where the information density is dependent on the binding site length. The selected imager probes reported here present imaging resolution equivalent to current state-of-the-art DNA-PAINT probes, creating a strategy to image shorter DNA domains for nanoscience and nanotechnology alike.

Published

2024

44. Mapping Antibody Domain Exposure on Nanoparticle Surfaces Using DNA-PAINT

Subjects

super-resolution microscopy, antibodies, nanoparticles, heterogeneity, nanomedicine, DNA-PAINT

Abstract

Decorating nanoparticles with antibodies (Ab) is a key strategy for targeted drug delivery and imaging. For this purpose, the orientation of the antibody on the nanoparticle is crucial to maximize fragment antibody-binding (Fab) exposure and thus antigen binding. Moreover, the exposure of the fragment crystallizable (Fc) domain may lead to the engagement of immune cells through one of the Fc receptors. Therefore, the choice of the chemistry for nanoparticle-antibody conjugation is key for the biological performance, and methods have been developed for orientation-selective functionalization. Despite the importance of this issue, there is a lack of direct methods to quantify the antibodies’ orientation on the nanoparticle’s surface. Here, we present a generic methodology that enables for multiplexed, simultaneous imaging of both Fab and Fc exposure on the surface of nanoparticles, based on super-resolution microscopy. Fab-specific Protein M and Fc-specific Protein G probes were conjugated to single stranded DNAs and two-color DNA-PAINT imaging was performed. Hereby, we quantitatively addressed the number of sites per particle and highlight the heterogeneity in the Ab orientation and compared the results with a geometrical computational model to validate data interpretation. Moreover, super-resolution microscopy can resolve particle size, allowing the study of how particle dimensions affect antibody coverage. We show that different conjugation strategies modulate the Fab and Fc exposure which can be tuned depending on the application of choice. Finally, we explored the biomedical importance of antibody domain exposure in antibody dependent cell mediated phagocytosis (ADCP). This method can be used universally to characterize antibody-conjugated nanoparticles, improving the understanding of relationships between structure and targeting capacities in targeted nanomedicine.

Published

2023

45. DNA-PAINT super-resolution imaging data of surface exposed active sites on particles

Author

Pietro Delcanale and Lorenzo Albertazzi

Subjects

Single-molecule localization microscopy, Super-resolution microscopy, DNA-PAINT, Nanoparticles, Functional materials, Computer applications to medicine. Medical informatics, R858-859.7, Science (General), Q1-390

Abstract

Surface functionalization with targeting ligands confers to nanomaterials the ability of selectively recognize a biological target. Therefore, a quantitative characterization of surface functional molecules is critical for the rational development of nanomaterials-based applications, especially in nanomedicine research. Single-molecule localization microscopy can provide visualization of surface molecules at the level of individual particles, preserving the integrity of the material and overcoming the limitations of analytical methods based on ensemble averaging. Here we provide single-molecule localization data obtained on streptavidin-coated polystyrene particles, which can be exploited as a model system for surface-functionalized materials. After loading of the active sites of streptavidin molecules with a biotin-conjugated probe, they were imaged with a DNA-PAINT imaging approach, which can provide single-molecule imaging at subdiffraction resolution and molecule counting. Both raw records and analysed data, consisting in a list of space-time single-molecule coordinates, are shared. Additionally, Matlab functions are provided that analyse the single-molecule coordinates in order to quantify features of individual particles. These data might constitute a valuable reference for applications of similar quantitative imaging methodologies to other types of functionalized nanomaterials.

Published

2020

46. Multi‐Color, Bleaching‐Resistant Super‐Resolution Optical Fluctuation Imaging with Oligonucleotide‐Based Exchangeable Fluorophores.

Author

Glogger, Marius, Spahn, Christoph, Enderlein, Jörg, and Heilemann, Mike

Subjects

*OPTICAL images, *COMPLEMENTARY DNA, *FLUOROPHORES, *NUCLEOTIDE sequence, *CELL imaging, *OLIGONUCLEOTIDES

Abstract

Super‐resolution optical fluctuation imaging (SOFI) is a super‐resolution microscopy technique that overcomes the diffraction limit by analyzing intensity fluctuations of statistically independent emitters in a time series of images. The final images are background‐free and show confocality and enhanced spatial resolution (super‐resolution). Fluorophore photobleaching, however, is a key limitation for recording long time series of images that will allow for the calculation of higher order SOFI results with correspondingly increased resolution. Here, we demonstrate that photobleaching can be circumvented by using fluorophore labels that reversibly and transiently bind to a target, and which are being replenished from a buffer which serves as a reservoir. Using fluorophore‐labeled short DNA oligonucleotides, we labeled cellular structures with target‐specific antibodies that contain complementary DNA sequences and record the fluctuation events caused by transient emitter binding. We show that this concept bypasses extensive photobleaching and facilitates two‐color imaging of cellular structures with SOFI. [ABSTRACT FROM AUTHOR]

Published

2021

47. Pushing the super-resolution limit: recent improvements in microscopy below the diffraction limit.

Author

Nieves, D. J. and Baker, M. A. B.

Subjects

*PROTEIN fractionation, *MICROSCOPY, *BIOLOGICAL systems, *FLUORESCENCE microscopy, *SINGLE molecules

Abstract

Super-resolution microscopy has revolutionised the way we observe biological systems. These methods are now a staple of fluorescence microscopy. Researchers have used super-resolution methods in myriad systems to extract nanoscale spatial information on multiple interacting parts. These methods are continually being extended and reimagined to further push their resolving power and achieve truly single protein resolution. Here, we explore the most recent advances at the frontier of the ‘super-resolution’ limit and what opportunities remain for further improvements in the near future. [ABSTRACT FROM AUTHOR]

Published

2021

48. Super‐Resolution Spatial Proximity Detection with Proximity‐PAINT.

Author

Schueder, Florian, Lara‐Gutiérrez, Juanita, Haas, Daniel, Beckwith, Kai Sandvold, Yin, Peng, Ellenberg, Jan, and Jungmann, Ralf

Subjects

*DNA nanotechnology, *NUCLEIC acids, *PROTEIN-protein interactions, *BIOMOLECULES, *MICROTUBULES, *ALPHA rhythm

Abstract

Visualizing the functional interactions of biomolecules such as proteins and nucleic acids is key to understanding cellular life on the molecular scale. Spatial proximity is often used as a proxy for the direct interaction of biomolecules. However, current techniques to visualize spatial proximity are either limited by spatial resolution, dynamic range, or lack of single‐molecule sensitivity. Here, we introduce Proximity‐PAINT (pPAINT), a variation of the super‐resolution microscopy technique DNA‐PAINT. pPAINT uses a split‐docking‐site configuration to detect spatial proximity with high sensitivity, low false‐positive rates, and tunable detection distances. We benchmark and optimize pPAINT using designer DNA nanostructures and demonstrate its cellular applicability by visualizing the spatial proximity of alpha‐ and beta‐tubulin in microtubules using super‐resolution detection. [ABSTRACT FROM AUTHOR]

Published

2021

49. Superaufgelöste Erkennung räumlicher Nähe mit Proximity‐PAINT.

Author

Schueder, Florian, Lara‐Gutiérrez, Juanita, Haas, Daniel, Beckwith, Kai Sandvold, Yin, Peng, Ellenberg, Jan, and Jungmann, Ralf

Abstract

Die Visualisierung funktionaler Interaktionen von Biomolekülen wie Proteinen und Nukleinsäuren ist der Schlüssel zum Verständnis zellulären Lebens auf molekularer Ebene. Räumliche Nähe wird oft stellvertretend für die direkte Interaktion von Biomolekülen angesehen. Aktuelle Techniken zur Visualisierung räumlicher Nähe sind jedoch entweder durch die erreichbare Auflösung, den dynamischen Bereich oder einen Mangel an Einzelmolekülsensitivität begrenzt. Wir haben Proximity‐PAINT (pPAINT) entwickelt, eine Variante des superauflösenden Mikroskopieverfahrens DNA‐PAINT. pPAINT verwendet eine geteilte DNA‐PAINT‐Bindestelle, um räumliche Nähe mit hoher Empfindlichkeit, wenig Fehlern und präzise einstellbaren Detektionsabständen zu erkennen. Wir testen und optimieren pPAINT mit Hilfe von DNA‐Nanostrukturen und demonstrieren die zelluläre Anwendbarkeit, indem wir die räumliche Nähe von Alpha‐ und Beta‐Tubulin in Mikrotubuli in Zellen superaufgelöst visualisieren. [ABSTRACT FROM AUTHOR]

Published

2021

50. Reductively Caged, Photoactivatable DNA‐PAINT for High‐Throughput Super‐resolution Microscopy.

Author

Jang, Soohyun, Kim, Mingi, and Shim, Sang‐Hee

Subjects

*FLUORESCENT probes, *MICROSCOPY, *HIGH resolution imaging, *CYANINES, *DNA probes

Abstract

In DNA points accumulation in nanoscale topography (DNA‐PAINT), capable of single‐molecule localization microscopy with sub‐10‐nm resolution, the high background stemming from the unbound fluorescent probes in solution limits the imaging speed and throughput. Herein, we reductively cage the fluorescent DNA probes conjugated with a cyanine dye to hydrocyanine, acting as a photoactivatable dark state. The additional dark state from caging lowered the fluorescent background while enabling optically selective activation by total internal reflection (TIR) illumination at 405 nm. These benefits from "reductive caging" helped to increase the localization density or the imaging speed while preserving the image quality. With the aid of high‐density analysis, we could further increase the imaging speed of conventional DNA‐PAINT by two orders of magnitude, making DNA‐PAINT capable of high‐throughput super‐resolution imaging. [ABSTRACT FROM AUTHOR]

Published

2020