4.4 Article

Super-Resolution Live Cell Imaging of Subcellular Structures

Journal

JOVE-JOURNAL OF VISUALIZED EXPERIMENTS
Volume -, Issue 167, Pages -

Publisher

JOURNAL OF VISUALIZED EXPERIMENTS
DOI: 10.3791/61563

Keywords

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Funding

  1. NIGMS/NIH [R35GM127075]
  2. Howard Hughes Medical Institute
  3. David and Lucile Packard Foundation
  4. Johns Hopkins University startup funds

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This study presents a method for conducting super-resolution timelapse fluorescence live cell imaging in situ, compatible with low fluorescent intensity cells and capable of visualizing multiple subcellular structures. Special procedures in sample preparation and immobilizing specimens are necessary for this technique, but it is broadly applicable to various cell types.
There has long been a crucial tradeoff between spatial and temporal resolution in imaging. Imaging beyond the diffraction limit of light has traditionally been restricted to be used only on fixed samples or live cells outside of tissue labeled with strong fluorescent signal. Current super-resolution live cell imaging techniques require the use of special fluorescence probes, high illumination, multiple image acquisitions with post-acquisition processing, or often a combination of these processes. These prerequisites significantly limit the biological samples and contexts that this technique can be applied to. Here we describe a method to perform super-resolution (similar to 140 nm XY-resolution) timelapse fluorescence live cell imaging in situ. This technique is also compatible with low fluorescent intensity, for example, EGFP or mCherry endogenously tagged at lowly expressed genes. As a proof-of-principle, we have used this method to visualize multiple subcellular structures in the Drosophila testis. During tissue preparation, both the cellular structure and tissue morphology are maintained within the dissected testis. Here, we use this technique to image microtubule dynamics, the interactions between microtubules and the nuclear membrane, as well as the attachment of microtubules to centromeres. This technique requires special procedures in sample preparation, sample mounting and immobilizing of specimens. Additionally, the specimens must be maintained for several hours after dissection without compromising cellular function and activity. While we have optimized the conditions for live super-resolution imaging specifically in Drosophila male germline stem cells (GSCs) and progenitor germ cells in dissected testis tissue, this technique is broadly applicable to a variety of different cell types. The ability to observe cells under their physiological conditions without sacrificing either spatial or temporal resolution will serve as an invaluable tool to researchers seeking to address crucial questions in cell biology.

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