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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

An advanced microscope that permit fast and high-resolution imaging of both, the isolated plasma membrane and the surrounding intracellular volume, will be presented. The integration of spinning disk and total internal reflection fluorescence microscopy in one setup allows live imaging experiments at high acquisition rates up to 3.5 s per image stack.

Abstract

In living cells, processes such as adhesion formation involve extensive structural changes in the plasma membrane and the cell interior. In order to visualize these highly dynamic events, two complementary light microscopy techniques that allow fast imaging of live samples were combined: spinning disk microscopy (SD) for fast and high-resolution volume recording and total internal reflection fluorescence (TIRF) microscopy for precise localization and visualization of the plasma membrane. A comprehensive and complete imaging protocol will be shown for guiding through sample preparation, microscope calibration, image formation and acquisition, resulting in multi-color SD-TIRF live imaging series with high spatio-temporal resolution. All necessary image post-processing steps to generate multi-dimensional live imaging datasets, i.e. registration and combination of the individual channels, are provided in a self-written macro for the open source software ImageJ. The imaging of fluorescent proteins during initiation and maturation of adhesion complexes, as well as the formation of the actin cytoskeletal network, was used as a proof of principle for this novel approach. The combination of high resolution 3D microscopy and TIRF provided a detailed description of these complex processes within the cellular environment and, at the same time, precise localization of the membrane-associated molecules detected with a high signal-to-background ratio.

Introduction

Our days, light microscopy techniques providing high/super resolution imaging in fixed and living specimen are developing rapidly. Super-resolution techniques such as stimulated emission depletion (STED), structured illumination microscopy (SIM) and photo-activation localization microscopy (PALM) or direct stochastic optical reconstruction microscopy (STORM), respectively, are commercially available and enable imaging of subcellular structures showing details almost on the molecular scale1,2,3,4,5,6. However, these approaches still have limited applicability for live imaging experiments in which large volumes need to be visualized with multiple frames per second acquisition speed. Varieties of highly dynamic processes regulated via the plasma membrane, e.g. endo-/exocytosis, adhesion, migration or signaling, occur with high speed within large cellular volumes. Recently, in order to fill up this gap, an integrated microscopy technique was proposed called spinning disk-TIRF (SD-TIRF)7. In detail, TIRF microscopy permits to specifically isolate and localize the plasma membrane8,9, while SD microscopy is one of the most sensitive and fast live imaging techniques for the visualization and tracking of subcellular organelles in the cytoplasm10,11. The combination of both imaging techniques in a single setup has already been realized in the past12,13, however, the microscope presented here (Figure 1) finally meets the criteria to perform live imaging SD-TIRF experiments of the aforementioned processes at 3 frames per second speed. Since this microscope is commercially available, the goal of this manuscript is to describe in details and provide open source tools and protocols for image acquisition, registration, and visualization associated with SD-TIRF microscopy.

The setup is based on an inverted microscope connected to two scan units via independent ports - the left port is linked to the SD unit and the back port to scanner unit for TIRF and photo-activation/-bleaching experiments. Up to 6 lasers (405/445/488/515/561/640 nm) can be used for excitation. For excitation and detection of the fluorescence signal, either a 100x/NA1.45 oil or 60x/NA1.49 oil TIRF objective, respectively, have been employed. The emitted light is split by a dichroic mirror (561 nm long-pass or 514 nm long-pass) and filtered by various band-pass filters (55 nm wide centered at 525 nm, 54 nm wide centered at 609 nm for green and red fluorescence, respectively) placed in front of the two EM-CCD cameras. Please note that more technical details about the setup are listed in Zobiak et al.7. In TIRF configuration, the SD unit is moved out of the light path within circa 0.5 s so that the same two cameras can be used for detection, allowing faster switching between the two imaging modalities compared to circa 1 s that was reported in the past13. This feature enables dual-channel simultaneous acquisition, thus 4 channels SD-TIRF imaging at previously unmatched speed and accuracy can be performed. Moreover, alignment between SD and TIRF images is unnecessary. Image alignment between the two cameras, however, has to be checked before starting the experiment and corrected if necessary. In the following protocol, a registration correction routine was implemented in a self-written ImageJ macro. Moreover, the macro was mainly designed to allow a simultaneous visualization of SD- and TIRF datasets despite their different dimensionality. The acquisition software itself did not provide these features.

Protocol

1. Preparation of cells

  1. Two days prior to the experiment, seed 3*105 HeLa or NIH3T3 cells in 2 mL of full growth medium per well of a 6-well cell-culture plate. Ensure that cells are handled in a laminar flow hood throughout this protocol.
  2. One day prior to the experiment, prepare the transfection reagents according to the manufacturer’s recommendations or an empirically determined protocol, e.g.:
    1. Dilute 1 µg of RFP-Lifeact and 1 µg of YFP-Vinculin in a total of 200 µL reduced serum medium. Vortex the transfection reagent briefly, add 4 µL to 200 µL DNA and vortex again. Incubate the transfection mix for 15-20 min at room temperature.
    2. Add the entire transfection mix dropwise directly to the cells. Mix by shaking the plate and place it back into the incubator.
  3. On the day of the experiment, prepare the sample for live imaging:
    1. Prepare a 10 µg/mL solution of fibronectin in PBS to coat the glass surface of a 35 mm glass bottom dish. Use only high quality 0.17 mm glass coverslips for optimal TIRF performance and avoid plastic bottom dishes. Leave the solution on the glass surface for 30 min at room temperature, then remove it and let the dish air-dry.
    2. Dilute a 0.1 µm multi-fluorescent beads solution to a density of 1.8 x 109 particles per mL in distilled water and add the solution for 30-60 s to the fibronectin-coated glass surface. Immediately remove the solution and let the dish air-dry.
      NOTE: This step is necessary only if the TIRF plane should be found before seeding cells and/or to acquire a 2-color reference image for bead-based image registration.
    3. Prepare a 0.1 M ascorbic acid (AA) solution and dilute it to a final concentration of 0.1 mM in growth medium (AA-medium). Place the solution in a 37 °C water bath.
      NOTE: Use fluorescence-optimized cell culture medium if possible, such as phenolred-free and (ribo-) flavin-reduced medium. AA is an anti-oxidizing agent that can reduce phototoxic effects during live imaging14. We have tested it successfully in this assay, i.e. more cells appeared healthy under the conditions applied than without AA addition. However, the pH of the medium was lowered by 0.17 pH units.
    4. Wash the cells with 2 mL PBS, add 250 µL Trypsin-EDTA and wait until the cells are fully detached (2-3 min in a 37 °C incubator). Resuspend the cells carefully in 1 mL pre-warmed AA-medium with a pipette and add it to 4 mL AA-medium in a 15 mL cell culture tube. Place the cell suspension with a slightly opened lid in an incubator set to 37 °C and 5% CO2 in the vicinity of the microscope.
    5. Add 1 mL pre-warmed AA-medium to the glass bottom dish and place it in the holder of the pre-heated microscope (see next paragraph).

2. Live imaging

  1. Start the environmental control of the microscope to achieve a stable 37 °C, 5% CO2 and humid atmosphere.
    NOTE: Here, a small stage top incubation chamber has been used that allowed stable settings within about 15min. Larger incubators will need more time to achieve stable conditions.
  2. Fix all acquisition settings at the microscope before the cell suspension is applied:
    1. Set the time-interval to 30 s and the duration to 60-90 min. Activate the auto-focusing function of the hardware-based auto-focus for every time point (value “1”).
    2. Adjust the camera exposure and gain, as well as the laser power for every channel. High gain levels, low exposure time and low laser power are recommendable to reduce photo-toxicity.
      NOTE: The data presented here was acquired with 200 ms exposure, gain level 500 and 20% laser power that equals excitation intensities of 0.5 W/cm² for 488 nm and 1 W/cm² for 561 nm, respectively.
    3. Set the z-stack for the spinning-disk channels to 10 µm with 0.4 µm spacing. De-activate z-stacks for the TIRF channels. Set the bottom-offset to “0”, i.e. the lowest plane will be the focus position of the hardware auto-focus.
    4. Activate the multi-point function “stage positions”.
      NOTE: Up to 3 positions can be recorded in a 30 s time interval.
  3. Find the fluorescent beads with epi-fluorescent illumination at the ocular or on the computer screen, then activate one TIRF channel and set the illumination angle to a value that denotes TIRF illumination. Activate the auto-focus by pushing the button at the microscope panel and adjust the focus with the offset wheel. Acquire a 2-color dataset, i.e. TIRF-488 and TIRF-561, for subsequent bead-based image registration (see point 3.1).
    1. Optional: To ensure TIRF illumination, add a few microliters of the freely floating fluorescent multicolor beads suspension (see point 1.3.2.). Activate the live view of a TIRF channel and increase the illumination angle. The non-adherent beads will disappear beyond the critical angle, ensuring a correct TIRF illumination8.
  4. Mix the cell suspension again by inverting the closed tube 2-3 times, and apply 1 mL of the cells to the imaging dish.
  5. Quickly find double-transfected cells with low level epi-fluorescent illumination. Center the cells in the live camera preview using bright field illumination and mark the position. Find another 1-2 points of interest and save them to the positions list.
    NOTE: At the beginning, the cells easily can detach due to stage movement, hence set 4-5 positions and re-check all before starting image acquisition. Afterwards, discard 1-2 positions.
  6. Start data acquisition by clicking on the “Sequence” button.

3. Image post-processing in ImageJ

  1. In order to generate a registration-free hyperstack in FIJI15, a macro named “SD-TIRF_helper” has been written that can be applied to 2-4 channel SD-TIRF timelapse datasets. Save the file “SD-TIRF_helper_JoVE.ijm” in the FIJI sub-folder “macros” and run the macro by clicking on the menu command “Plugins>Macros>Run…”.
    1. If the color channels need registration correction, select the option and create a new bead-based registration reference (landmark file) or use an existing file that was created before.
      NOTE: The turboreg plugin16 will be applied to fluorescence beads reference images. Install the plugin in FIJI software according to general guidelines for plugin installations.
    2. Import the data with the bio-formats importer and choose hyperstack as a viewing option. Load the image dataset, select the SD-series in the first step, and the TIRF-series in the second step. FIJI will display the data sorted by channel and stage position, i.e. normally all SD-channels and all TIRF-channels show up as one hyperstack for every stage position that has been selected.
      NOTE: Data import is possible from various file types, for example TIFF-series or platform-dependent file types such as *.nd. The file type cannot be recognized only if it was not exported by the acquisition software as independent, compression-less TIFF format.
    3. Apply the registration correction to the respective channels by loading the pre-determined landmarks file.
    4. Select the desired color look-up table (LUT) for every SD- and TIRF channel and merge them into a single, multi-dimensional hyperstack.
      NOTE: During processing of the TIRF channels, a number of z-planes with zero intensity values are added on top of the bottom plane that matches with the number of z-planes in the SD dataset. This step is important for the visualization of the final hyperstack. This methodology is correct, since the depth of the TIRF illumination (less than 200nm7) is smaller than the z-step size of the SD stack (400 nm).

Results

In order to show the potential of SD-TIRF imaging, an assay was developed that should reveal the spatio-temporal organization of cell-matrix adhesion complexes and their interaction with the cytoskeleton during cellular adhesion. Therefore, adherent HeLa or, alternatively, NIH3T3 cells were transfected with YFP-Vinculin and RFP-Lifeact for 18-24 h, trypsinized and seeded onto fibronectin-coated glass bottom dishes. These cell lines were chosen for their pronounced cytoskeleton and higher ...

Discussion

In this paper was presented the first successful implementation of SD and TIRF microscopy in a configuration suitable for performing live cell imaging experiments, i.e. high acquisition rates such as 2 SD-TIRF image stacks per minute at 3 different stage positions, corresponding to a total of 168 frames (circa 3 frames per second), were acquired. The few SD-TIRF microscopes that were described previously12,13, mainly lack of sufficiently high imaging spe...

Disclosures

The authors have nothing to disclose.

Acknowledgements

We greatly thank the scientific community of the University Medical Center Hamburg-Eppendorf for supporting us with samples for evaluation. Namely, we thank Sabine Windhorst for NIH3T3 cells, Andrea Mordhorst for YFP-Vinculin and Maren Rudolph for RFP-Lifeact.

Materials

NameCompanyCatalog NumberComments
Microscope and accessories
SD-TIRF microscopeVisitron Systems
Ti with perfect focus systemNikonInverted microscope stand
CSU-W1 T2YokogawaSpinning disk unit in dual-camera configuration
iLAS2 Roper ScientificTIRF/FRAP scanner
Evolve PhotometrixEM-CCD cameras
PiezoZ stageLudl Electronic ProductsMotorized Z stage
Bioprecision2 XY stageLudl Electronic ProductsMotorized XY stage
Stage top incubation chamberOkolabBold LineTemperature, CO2 and humidity supply
Cell culture
HeLa cervical cancer cellsDSMZACC-57
NIH3T3 fibroblastsDSMZACC-59
Dulbecco's phosphate buffered saline (PBS)Gibco14190144
Trypsin-EDTA 0.05%Gibco25300054
Dulbecco's Modified Eagle Medium + GlutaMAX-I (DMEM)Gibco31966-021
OptiMEMGibco31985070Reduced serum medium
Fetal calf serum (FCS)Gibco10500064
Penicillin/Streptomycin (PenStrep)Gibco15140148
Full growth medium (DMEM supplemented with 10% FCS and 1% PenStrep)
TurboFectThermoFisher ScientificR0531Transfection reagent
Ascorbic acid (AA)SigmaA544-25G
6-well cell culture plateSarstedt83.392
Glass bottom dishesMatTekP35G-1.5-10-C35mm, 0.17mm glass coverslip
Fibronectin, bovine plasmaThermoFisher Scientific33010018
Neubauer improved chamberVWR631-0696
TetraSpeck beadsThermoFisher ScientificT7279
Plasmids
RFP-LifeactMaren Rudolph, Institute of Medical Microbiology, University Medical Center Hamburg Eppendorf, Germany
YFP-VinculinAndrea Mordhorst, Institute of Medical Microbiology, University Medical Center Hamburg Eppendorf, Germany
Software and plugins
VisiViewVisitron SystemsVersion 3
ImageJVersion 1.52c
Turboreg pluginhttp://bigwww.epfl.ch/thevenaz/turboreg/
Macro "SD-TIRF_helper_JoVE.ijm"this publicationhttps://github.com/bzobiak/ImageJ
VolocityPerkinElmerVersion 6.2.2

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