Long-term, High-resolution Confocal Time Lapse Imaging of Arabidopsis Cotyledon Epidermis during Germination

Summary

We describe a protocol using chamber slides and media to immobilize plant cotyledons for confocal imaging of the epidermis over several days of development, documenting stomatal differentiation. Fluorophore-tagged proteins can be tracked dynamically by expression and subcellular localization, increasing understanding of their possible roles during cell division and cell-type differentiation.

Abstract

Imaging in vivo dynamics of cellular behavior throughout a developmental sequence can be a powerful technique for understanding the mechanics of tissue patterning. During animal development, key cell proliferation and patterning events occur very quickly. For instance, in Caenorhabditis elegans all cell divisions required for the larval body plan are completed within six hours after fertilization, with seven mitotic cycles¹; the sixteen or more mitoses of Drosophila embryogenesis occur in less than 24 hr². In contrast, cell divisions during plant development are slow, typically on the order of a day ^3,4,5 . This imposes a unique challenge and a need for long-term live imaging for documenting dynamic behaviors of cell division and differentiation events during plant organogenesis. Arabidopsis epidermis is an excellent model system for investigating signaling, cell fate, and development in plants. In the cotyledon, this tissue consists of air- and water-resistant pavement cells interspersed with evenly distributed stomata, valves that open and close to control gas exchange and water loss. Proper spacing of these stomata is critical to their function, and their development follows a sequence of asymmetric division and cell differentiation steps to produce the organized epidermis (Fig. 1).

This protocol allows observation of cells and proteins in the epidermis over several days of development. This time frame enables precise documentation of stem-cell divisions and differentiation of epidermal cells, including stomata and epidermal pavement cells. Fluorescent proteins can be fused to proteins of interest to assess their dynamics during cell division and differentiation processes. This technique allows us to understand the localization of a novel protein, POLAR⁶, during the proliferation stage of stomatal-lineage cells in the Arabidopsis cotyledon epidermis, where it is expressed in cells preceding asymmetric division events and moves to a characteristic area of the cell cortex shortly before division occurs. Images can be registered and streamlined video easily produced using public domain software to visualize dynamic protein localization and cell types as they change over time.

Protocol

1. Seed Sterilization

1. Prepare seed sterilization solution: 33% household bleach, 0.1% Triton X-100.
2. Place seeds carrying desired fluorescent reporter construct(s) and genotype(s) in 1.7 ml tube and apply 1 ml of sterilization solution. Incubate on nutator for 15 min.
3. In a sterile hood, use a pipettor to remove sterilization solution from tube, leaving seeds behind. Rinse with 1 ml sterile water. Repeat four times.
4. Incubate at 4 °C for two days or more.

2. Preparation of Chamber Slide Media

1. Mix 20 ml of 0.5% solution of Bacto Agar (not pure agarose) in water in a 200 ml flask, and microwave until dissolved. Be cautious when boiling the solution.
2. Cool the solution to around 60 °C.
3. Collect 1 ml of agar solution with a pipettor and slowly apply to the cover glass inside the chamber slide (Lab-Tek II Chambered #1.5 German Coverglass System). Solution which is too hot or applied too quickly may melt glue or crack glass.
4. Immediately add a second ml of agar solution. Agar media should now completely cover the bottom of the slide chamber. This minimal media is sufficient to support development in a plant cotyledon, which contains stored nutrients, for four to five days by maintaining moisture and allowing gas diffusion.
5. Cool slide on benchtop with chamber covered. If flask is covered tightly, solution may be saved and reheated for future use.

3. Seed Dissection

1. Remove tube of sterile seed from 4 °C storage.
2. Place a paper tissue on the stage of a dissecting microscope and moisten with water. Adjust tissue to create a smooth surface. Tissue is used to stabilize seeds for dissection.
3. Pipet 20-30 seeds from the tube to the tissue, being careful to place them in the dissecting scope's field of view.
4. Using sharp forceps (Roboz, #5 biology tip), carefully remove the seed coat from the seedling inside. Both outer and inner integuments must be removed.
5. When imaging the cotyledon, it is beneficial to remove the hypocotyl and radicle. Cotyledons contain sufficient nutrients to develop for several days under this protocol. If intact, the hypocotyl will straighten and lengthen dramatically, moving the cotyledon out of the time lapse field of view. Use a scalpel to slice the cotyledons free of the hypocotyl.
6. Hold dissected cotyledons immersed in water, in a microtube or similar.
7. Repeat 3.4-3.6 until the desired number of cotyledons is reached. 15-20 successful dissections are recommended before mounting.

4. Mounting Cotyledons in the Chamber Slide

1. Using a small (18 mm²) cover slip, cut through the agar media and lift the entire layer up from the chamber slide's glass base.
2. Pipet dissected cotyledons with a minimum of water from holding tube into the chamber slide, under the lifted agar layer.
3. Gently lower the agar onto the cotyledons. If excess water is present, soak it away with a tissue, being careful not to disturb the cotyledons. Specimens should no longer move easily when mount is complete.
4. Place cover on chamber slide and move slide to microscope stage.

5. Time Lapse Imaging

1. Set up inverted confocal microscope to image the desired fluorophore(s). LSM700 parameters used: for GFP, excitation at 488 nm and collection with a band pass filter at 440-530 nm; for RFP, excitation at 555 nm and collection with a band pass filter at 570-610 nm.
2. Inspect mounted specimens for damage. Program the locations of intact, properly mounted cotyledons into microscope software. In Zen 2009: Focus on a cotyledon with 20x objective and move objective to center of chamber slide. Under Acquisition Mode, change Zoom to 0.5 and Frame Size to 48x48 pixels. Select Positions checkbox and Scan overview image... button under Positions, then increase Horizontal and Vertical tile numbers to 30-35. When scan is complete, click the Positions button under the Dimensions tab and place crosshairs at each cotyledon to observe.
3. Set up z series encompassing the cotyledon epidermis of all samples.In Zen 2009: Click the Z-Stack checkbox. Select each position under Position List and click the Move to button. Focus on the uppermost plane of the cotyledon epidermis and click the Set First button under Z-Stack. Focus to the lowest position at which epidermis is usefully visible and click the Set Last button. Click the button next to Optimal, which shows the best z-slice thickness, to set. Check each cotyledon to confirm that these settings encompass all samples; the z parameters cannot be set for individual positions in Zen 2009.
4. Set up time series at desired resolution and length. Intervals of 15-30 min for three days are effective for protein dynamics in epidermal cell division. This interval can be changed as necessary. In Zen 2009: Click the Time Series checkbox. Under Time Series, set Cycles for the number of images desired using the slider or typing in the text field. Set Interval to 30 and use the pull-down menu to select min.
5. Begin xyzt multi-position scan. Note that the number of positions must be limited by the scan specifications; if total scan time is greater than the desired interval, the time points will not be correct. A maximum of six simultaneous positions are possible when imaging GFP and RFP at 59 z-slices in a 30-min interval using our system. In Zen 2009: Change Frame Size to desired resolution and click Start Experiment.

6. Video Editing

1. From the confocal data file, make a maximum intensity z-projection of each time/position combination and export as image files in a lossless format such as TIFF. File names should be in one series per position (e.g., POLAR-GFP_pos1_0001, POLAR-GFP_pos1_0002, etc., not POLAR-GFP_0001_pos1) for software to combine them into a movie. In Zen 2009: Use Copy:Subset under the Processing tab to split positions into separate files, then Maximum Intensity Projection. Finally, export as TIFF (File:Export, Full resolution image window - series).
2. Use FIJI^7,8 to align successive images by running the bUnwarpJ macro⁹(Plugins:Registration:bUnwarpJ). Change Registration Mode to Mono. All Advanced Options can use default values. For long time lapse sequences, download and install the macro "Affine + Consistent Elastic 2D Image Registration," which will apply bUnwarpJ to a series of images automatically, and open your data using File:Import:Image Sequence to use it. Uncheck MOPS landmarks extraction and run.
3. Use FIJI/ImageJ or Quicktime Pro to open the sequence of aligned images and save in the desired video format (AVI is a good choice).

Results

A set of informative time points collected with this method is shown in Figure 3. Cell membranes are labeled with RFP (pm-rb) and GFP is fused to POLAR protein under its native promoter (POLAR::POLAR-GFP)⁶ At the 30-min time scale, we see cell divisions along with the changes in protein localization preceding them. Asymmetric cell divisions in the stomatal lineage form stem-cell-like stomatal precursors called meristemoids, which retain the ability to undergo further asymmetric divisi...

Discussion

This time-lapse confocal technique allows longitudinal studies of fluorescently tagged protein expression and localization in individual cells of the Arabidopsis cotyledon epidermis, which in the case of POLAR and other dynamically changing proteins is critical to a proper understanding of their function. Previously, sustained time lapse imaging has been used to examine Arabidopsis root fungal infection¹¹ and meristem growth^5,12, but adding the cotyledon epidermis expands the vers...

Materials

Name	Company	Catalog Number	Comments
Bacto Agar	BD	214010
One-chamber slide	Nunc (Thermo Scientific)	155360	Or two-chamber (155379)
Laser scanning confocal microscope	Zeiss	LSM700	Zen 2009 software
20x objective lens	Zeiss	420650-9901	NA 0.8, Plan-APOCHROMAT
Dissecting microscope	Benz (National)	431TBL	Illuminates from below
#5 forceps, biology tip	Roboz Surgical Instrument	RS-4978	Very fine tips are critical