Millisecond single-molecule localization microscopy combined with convolution analysis and automated image segmentation to determine protein concentrations in complexly structured, functional cells, one cell at a time

Wollman, Adam J. M.; Leake, Mark C.

doi:10.1039/c5fd00077g

Cited by 76 publications

(117 citation statements)

References 49 publications

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“…We estimate that our calibration yields an axial resolution of ~100 nm, roughly 2-3 times poorer than our measured lateral resolution of ~40 nm under comparable imaging conditions [31]. This reduction in spatial resolution from lateral to axial is similar to other previously implemented 3D light microscopes [25] and compares favorably with other astigmatism based microscopes.…”

Section: Calibration and Performance Of The Microscopesupporting

confidence: 77%

Mapping the 3D genome through high speed single-molecule tracking of functional transcription factors in single living cells

Wollman

Hedlund

Shashkova

et al. 2019

Preprint

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How genomic DNA is organized within the cell nucleus is a long-standing question. We describe a single-molecule bioimaging method with super-resolution localization precision and very rapid millisecond temporal resolution, coupled to fully quantitative image analysis tools, to help to determine genome organization and dynamics using budding yeast Saccharomyces cerevisiae as a model eukaryotic organism. We utilize astigmatism imaging, a robust technique that enables extraction of 3D position data, on genomically encoded fluorescent protein reporters that bind to DNA. Our relatively straightforward method enables snapshot reconstructions of 3D architectures of single genome conformations directly in single functional living cells.1 Abbreviations

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Section: Calibration and Performance Of The Microscopesupporting

confidence: 77%

Mapping the 3D genome through high speed single-molecule tracking of functional transcription factors in single living cells

Wollman

Hedlund

Shashkova

et al. 2019

Preprint

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“…3 A and Supplemental Movie S4). We monitored the spatiotemporal dynamics of foci in the planar membrane regions using automated tracking software (38), which allowed foci to be tracked for up to 18 s to a spatial precision of ∼40 nm (52) below the diffraction limit, thus enabling super-resolution localization data to be obtained. The measured width of the focal waist (defined as the half-width at half-maximum, determined from their pixel-intensity profile) was in the range of 200–300 nm, consistent with the PSF width of our microscope (Supplemental Fig.…”

Section: Resultsmentioning

confidence: 99%

Staphylococcus aureus toxin LukSF dissociates from its membrane receptor target to enable renewed ligand sequestration

et al. 2018

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Staphylococcus aureus Panton-Valentine leukocidin is a pore-forming toxin targeting the human C5a receptor (hC5aR), enabling this pathogen to battle the immune response by destroying phagocytes through targeted lysis. The mechanisms that contribute to rapid cell lysis are largely unexplored. Here, we show that cell lysis may be enabled by a process of toxins targeting receptor clusters and present indirect evidence for receptor “recycling” that allows multiple toxin pores to be formed close together. With the use of live cell single-molecule super-resolution imaging, Förster resonance energy transfer and nanoscale total internal reflection fluorescence colocalization microscopy, we visualized toxin pore formation in the presence of its natural docking ligand. We demonstrate disassociation of hC5aR from toxin complexes and simultaneous binding of new ligands. This effect may free mobile receptors to amplify hyperinflammatory reactions in early stages of microbial infections and have implications for several other similar bicomponent toxins and the design of new antibiotics.—Haapasalo, K., Wollman, A. J. M., de Haas, C. J. C., van Kessel, K. P. M., van Strijp, J. A. G., Leake, M. C. Staphylococcus aureus toxin LukSF dissociates from its membrane receptor target to enable renewed ligand sequestration.

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“…Such methods can enable tracking of single fluorescent proteins over very rapid millisecond time scales which significantly reduces motion blur of diffusing fluorescently labelled molecules in different compartments of live cells (Figure 2A), especially in the cytoplasm in which the viscosity is relatively low and so the rate of diffusion is relatively high [33]. These rapid imaging single-molecule fluorescence microscopy techniques may also be combined with convolution analysis of live cell fluorescence images to determine the copy number of proteins in a single cell, and indeed in separate cellular compartments [97]. Most super-resolution techniques, however, are mainly based on conventional fluorescence and confocal microscopy principles [98], but have resulted in huge advances in our knowledge of the biosciences, in particular concerning how processes operate in functional, living cells.…”

Section: Main Techniques and Applications Of Single-molecule Fluorescmentioning

confidence: 99%

Single-molecule fluorescence microscopy review: shedding new light on old problems

2017

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Fluorescence microscopy is an invaluable tool in the biosciences, a genuine workhorse technique offering exceptional contrast in conjunction with high specificity of labelling with relatively minimal perturbation to biological samples compared with many competing biophysical techniques. Improvements in detector and dye technologies coupled to advances in image analysis methods have fuelled recent development towards single-molecule fluorescence microscopy, which can utilize light microscopy tools to enable the faithful detection and analysis of single fluorescent molecules used as reporter tags in biological samples. For example, the discovery of GFP, initiating the so-called ‘green revolution’, has pushed experimental tools in the biosciences to a completely new level of functional imaging of living samples, culminating in single fluorescent protein molecule detection. Today, fluorescence microscopy is an indispensable tool in single-molecule investigations, providing a high signal-to-noise ratio for visualization while still retaining the key features in the physiological context of native biological systems. In this review, we discuss some of the recent discoveries in the life sciences which have been enabled using single-molecule fluorescence microscopy, paying particular attention to the so-called ‘super-resolution’ fluorescence microscopy techniques in live cells, which are at the cutting-edge of these methods. In particular, how these tools can reveal new insights into long-standing puzzles in biology: old problems, which have been impossible to tackle using other more traditional tools until the emergence of new single-molecule fluorescence microscopy techniques.

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Millisecond single-molecule localization microscopy combined with convolution analysis and automated image segmentation to determine protein concentrations in complexly structured, functional cells, one cell at a time

Cited by 76 publications

References 49 publications

Mapping the 3D genome through high speed single-molecule tracking of functional transcription factors in single living cells

Mapping the 3D genome through high speed single-molecule tracking of functional transcription factors in single living cells

Staphylococcus aureus toxin LukSF dissociates from its membrane receptor target to enable renewed ligand sequestration

Single-molecule fluorescence microscopy review: shedding new light on old problems

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