Summary

Staining and High-Resolution Imaging of Three-Dimensional Organoid and Spheroid Models

Published: March 27, 2021
doi:

Summary

Here, we provide detailed, robust, and complementary protocols to perform staining and subcellular resolution imaging of fixed three-dimensional cell culture models ranging from 100 µm to several millimeters, thus enabling the visualization of their morphology, cell-type composition, and interactions.

Abstract

In vitro three-dimensional (3D) cell culture models, such as organoids and spheroids, are valuable tools for many applications including development and disease modeling, drug discovery, and regenerative medicine. To fully exploit these models, it is crucial to study them at cellular and subcellular levels. However, characterizing such in vitro 3D cell culture models can be technically challenging and requires specific expertise to perform effective analyses. Here, this paper provides detailed, robust, and complementary protocols to perform staining and subcellular resolution imaging of fixed in vitro 3D cell culture models ranging from 100 µm to several millimeters. These protocols are applicable to a wide variety of organoids and spheroids that differ in their cell-of-origin, morphology, and culture conditions. From 3D structure harvesting to image analysis, these protocols can be completed within 4-5 days. Briefly, 3D structures are collected, fixed, and can then be processed either through paraffin-embedding and histological/immunohistochemical staining, or directly immunolabeled and prepared for optical clearing and 3D reconstruction (200 µm depth) by confocal microscopy.

Introduction

Over the past decades, advances in stem cell biology and in vitro 3D culture technologies have heralded a revolution in biology and medicine. Higher complexity cell models in 3D have become very popular as they allow cells to grow and interact with a surrounding extracellular framework, closely recapitulating aspects of living tissues including their architecture, cell organization and interactions, or even diffusion characteristics. As such, 3D cell culture models can provide unique insights into the behavior of cells in developing or diseased tissues in vitro. Organoids and spheroids are both multicellular 3D structures, ranging from several micrometers to millimeters, and are the most prominent in vitro 3D structures. Both may be cultured within a supporting scaffold including (i) hydrogels derived from animals (basement membrane extract, collagen), plants (alginate/agarose), or synthesized from chemicals, or (ii) inert matrices containing pores to promote cell proliferation and growth.

Organoids and spheroids can also develop without the presence of a supporting scaffold by relying on cells to self-assemble into clusters. This relies on different techniques such as the use of non-adhesive materials to inhibit cell attachment, surface tension and gravitational force (e.g., hanging drop techniques), or constant circular rotation of vessels (e.g., spinner culture). In all cases, these techniques facilitate cell-cell and cell-matrix interactions to overcome the limitations of traditional monolayer cell culture1. The terms "organoids" and "spheroids" have been used interchangeably in the past, but there are key differences between these two 3D cell culture models. Organoids are in vitro 3D cellular clusters derived from pluripotent stem cells or tissue-specific stem cells, in which cells spontaneously self-organize into progenitors and differentiated cell types and which recapitulate at least some functions of the organ of interest2. Spheroids comprise a broader range of multicellular 3D structures formed under non-adherent conditions and can arise from a large diversity of cell types such as immortalized cell lines or primary cells3. Hence, inherent to their intrinsic stem cell origins, organoids have a higher propensity for self-assembly, viability, and stability than spheroids.

Nevertheless, in essence, these two models are 3D structures composed of multiple cells, and the techniques developed to study them are thus very similar. For example, powerful imaging approaches at the single-cell resolution level are necessary for probing the cellular complexity of both organoids and spheroids. Here, by summarizing this group's expertise and that of leaders in the field of organoids4, this paper describes detailed procedures to perform two-dimensional (2D) and 3D whole-mount staining, imaging, and analyses of the cellular and subcellular composition and spatial organization of organoids and spheroids ranging from 100 µm to several millimeters. Indeed, this procedure presents two different and complementary types of staining and imaging acquisition to analyze a large variety of sizes and types of in vitro 3D cell culture models. The use of one (3D whole-mount analysis) or the other (2D section analysis) will depend on the model studied and the answers sought. 3D whole-mount analysis by confocal microscopy can, for instance, be applied to visualize cells in 3D culture up to 200 µm in depth, irrespective of the overall size of the 3D structure, whereas the analysis of 2D sections provides insights into samples of any size, albeit at the 2D level. This procedure has been successfully applied across a variety of organoids4,5 and spheroids derived from human and murine cells, originating from different embryonic germ layers. The overview of the procedure is shown in Figure 1. The major stages, the relationships between them, decisive steps, and the expected timing are indicated.

Figure 1
Figure 1: Schematic overview of the procedure. In vitro 3D cell culture models are collected and fixed, then either prepared for 3D whole mount staining (option a) or embedded in paraffin for 2D sectioning and staining (option b). For 3D whole-mount staining experiments, fixed 3D structures are immunolabeled following the fixation step. An optional optical-clearing step can be performed to improve imaging quality and depth of optical microscopy by reducing light scattering during image processing. Images are captured on an inverted confocal microscope or a confocal high content system and analyzed using the appropriate software. For paraffin embedding, 3D structures are directly processed (option b.1 for large structures 400 µm) or included in a gel (b.2; small structures 400 µm) for dehydration and paraffin embedding. Paraffin blocks are then cut and stained (histological or immunochemical staining). Images of 2D sections are obtained on a digital slide scanner or an upright microscope and analyzed on an image analysis platform using fast digital quantitative analysis. Please click here to view a larger version of this figure.

Protocol

NOTE: A loss of ≤25% of the initial number of 3D structures should be expected during the steps involving reagent changes and washing in the following procedure. Plan to use a final number of at least ten 3D structures, with a size ranging from 100 to 500 µm, per tested condition to perform qualitative and quantitative image analyses. If necessary, for larger structures, cut the ends of 1 mL pipette tips to avoid breaking the structures. For all steps, if 3D structure sedimentation is too long, cells can be gently spun at 50 × g for 5 min at room temperature (RT). Depending on the issue investigated, advantages/disadvantages of such a spinning step should be considered, as centrifugation can compromise the shape of the 3D structures. Avoid spinning at >100 × g.

1. Collection and fixation of 3D cell culture models

NOTE: Be careful not to aspirate the 3D structures, which will be only loosely attached to the tube wall.

  1. Harvesting of 3D cell culture models embedded in a matrix
    NOTE: This section describes the recovery of 3D structures grown in drops of a basement membrane extract from murine Engelbreth-Holm-Swarm sarcoma (BME), but may be adapted to other matrices. See the discussion for crucial points regarding ECM.
    1. Remove the culture medium from the wells without disrupting the 3D matrix. Precoat the inside and outside of a 1 mL pipette tip with protein (called precoated 1 mL tip hereafter) by dipping the full length of the tip in 0.1% bovine serum albumin (BSA) in phosphate-buffered saline (PBS) (called PBS-BSA 0.1% solution hereafter) and pipetting 1 mL of this solution up and down twice.
      NOTE: This precoating will prevent the cells from sticking to the tip and minimize any loss.
    2. Precoat the inside of a centrifuge (15 mL) tube with protein (called precoated centrifuge tube hereafter) by repeatedly filling with PBS-BSA 0.1% solution and emptying the tube.
      NOTE: This will prevent the cells from sticking to the tube and minimize any loss.
    3. Using the precoated 1 mL tip, carefully resuspend the 3D structures of the well using 1 mL of ice-cold 1x PBS, and gently transfer the suspension containing the 3D structures to the precoated centrifuge tube.
    4. Gently add 13 mL of ice-cold 1x PBS, and allow the 3D structures to sediment on ice for at least 10 min.
      NOTE: If required, spin for 5 min at 50 × g at 4 °C. Avoid spinning >100 × g, as this will compromise the shape of the 3D structures.
    5. Remove the supernatant. Using a precoated 1 mL tip, gently resuspend the 3D structures in 1 mL of ice-cold 1x PBS. Repeat steps 1.1.4 to 1.1.5 to obtain a homogenous pellet without any 3D matrix residue.
      NOTE: Efficient matrix removal is influenced by the type of matrix, the number, and size of 3D structures and requires optimization for different culture conditions. For 3D structures grown in BME, recovery from the matrix removal typically takes 45-60 min.
    6. Using a precoated 1 mL tip, transfer the 1 mL 1x PBS suspension containing the 3D structures to a precoated 1.5 mL centrifuge tube, and proceed with section 1.3.
  2. Harvesting floating 3D cell culture models
    1. Using a precoated 1 mL tip, carefully collect and transfer the 3D structures to a precoated 1.5 mL centrifuge tube. Allow the 3D structures to sediment, or spin for 5 min at 50 × g at RT.
    2. Remove the supernatant. Using a precoated 1 mL tip, resuspend the 3D structures in 1 mL of 1x PBS. Proceed with section 1.3.
  3. Fixation of 3D cell culture models
    1. Allow the 3D structures to sediment. Carefully remove the supernatant; under a fume hood, gently resuspend the 3D structures in 1 mL of formalin using a precoated 1 mL tip.
      NOTE: Formalin contains formaldehyde, which is hazardous. Manipulate the chemical in a chemical hood. Wear rubber gloves and safety eye goggles.
    2. Incubate the 3D structures for 30 min at RT.
      NOTE: A 30 min fixation step with formalin is required for immunostaining of a wide range of 3D structures (varying in size, shape, and origin). However, in general, longer fixation times (>3 h) are better suited to preserve the fluorescence of reporter proteins.
    3. Allow the 3D structures to sediment, or spin for 5 min at 50 × g at RT. Gently remove the formalin, and replace it with 1 mL of 1x PBS. Repeat this washing step in 1x PBS twice. Store the samples at 4 °C, and proceed with section 2 or section 3.
      ​NOTE: The protocol can be paused here, and the cells can be maintained at 4 °C for long-term storage (>1 year).

2. 3D whole mount staining, imaging, and analysis of 3D cell culture models

NOTE: As the organoids are loosely attached to the tube wall, handle them gently as all following reagent changes can cause sample loss. Before starting, ensure the availability of the correct controls for staining. Positive and negative controls can be cells, in which the protein of interest is known to be either overexpressed or absent, respectively. Incubate samples without the primary antibody to determine if the observed signal is due to non-specific binding of the secondary antibody. As some cells tend to display high levels of autofluorescence, use controls devoid of secondary antibody to determine if the observed fluorescence is coming from background autofluorescence. Immunolabeling and fluorescent reporter visualization can be combined.

  1. 3D whole mount staining
    1. Prepare the permeabilization-blocking (PB) solution by supplementing 1x PBS with 0.1%-1% of a non-ionic surfactant (see the Table of Materials), 1% dimethylsulfoxide, 1% BSA, and 1% donkey serum (or from the animal in which the secondary antibodies were raised).
      NOTE: Carefully optimize the concentration of the non-ionic surfactant depending on the localization of the target: membrane (0-0.5%), cytoplasm (0.5-1%), and nucleus (1%). This solution can be stored at 4°C for up to 1 month. BSA usually works well for the blocking step, but in case of high background noise, perform an empirical test to obtain the best possible results for a given combination of antibodies.
    2. Transfer the organoids from the 1.5 mL centrifuge tube to a 0.5 mL tube using a precoated 1 mL tip. Let the organoids sediment, gently remove the 1x PBS, and replace it with 0.5 mL of PB solution. Incubate the organoids with gentle horizontal agitation (30-50 rpm) for 1 h at RT.
    3. Let the organoids sediment, gently remove the PB solution, and wash twice in 1 mL PBS-BSA 0.1% for 3 min.
      NOTE: Waiting for 3 min allows the structures to sediment at the bottom of the tube.
    4. Gently remove the PBS-BSA 0.1%, and add 250 µL of primary antibody diluted at the appropriate concentration in PB:1x PBS (1:10) solution. To prepare 10 mL of PB:1x PBS (1:10) solution, dilute 1 mL of PB solution in 9 mL of 1x PBS. Incubate for 2-3 days with gentle horizontal agitation (30-50 rpm) at 4 °C.
      NOTE: An appropriate antibody incubation time is crucial for a suitable antibody penetration as 3D structures can sometimes reach large sizes.
    5. Let the organoids sediment, and gently remove the primary antibody solution. Wash 5x in PBS-BSA 0.1% for 3 min per wash and then 2x in 1 mL PBS-BSA 0.1% for 15 min per wash with gentle horizontal agitation.
    6. Add 250 µL of secondary antibody diluted at 1:250 in PB:1x PBS (1:10) solution. Incubate for 24 h at 4°C with gentle horizontal agitation (30-50 rpm). For this step, protect the samples from light.
    7. Add 250 µL of Hoechst 33342 (20 µM stock solution) diluted at 1:1000 in PB:1x PBS (1:10) solution, and incubate for another 2 h at 4 °C with gentle horizontal agitation (30-50 rpm).
    8. Let the organoids sediment, and gently remove the solution containing secondary antibody + Hoechst 33342. Wash the organoids 5x in 1 mL of 1x PBS for 3 min per wash and then 2x in 1 mL of 1x PBS for 15 min per wash with gentle horizontal agitation (30-50 rpm).
      NOTE: It is crucial to extensively wash the samples to avoid background noise or loss of signal.
    9. Store the samples in PBS at 4 °C until image acquisition. Proceed with section 2.2.
      NOTE: The protocol can be paused here, and the samples can be stored at 4 °C for several months, protected from light.
  2. Sample preparation for confocal imaging
    1. Using a precoated 1 mL tip, carefully transfer the organoids into 50 µL of the 1x PBS per well in a 96-well black polystyrene microplate. Proceed with step 2.2.3 or section 2.3.
      NOTE: At this stage, the sample can be protected from light and stored at 4 °C for many weeks.
    2. Clearing
      ​NOTE: The clearing step is optional and can be used to either immunolabel organoids or to detect endogenous fluorescence. Clearing can cause 3D structure shrinkage, but does not change the general morphology except for spherical mono-layered organoids with large lumens4. For these cystic organoids, skip the clearing step, and perform deep-tissue imaging6.
      1. Prepare 2.5 M glycerol-fructose clearing solution containing 50% v/v glycerol, 11% v/v of distilled water, and 45% w/v fructose by mixing on a magnetic stirrer at least overnight until the solution is completely solubilized and homogenous. Store at 4 °C in the dark for up to 1 month.
      2. Remove as much 1x PBS as possible without touching the organoids. Add 200 µL of the clearing solution using a 1 mL pipette tip after removing the end, and resuspend gently to prevent the formation of bubbles. Incubate at RT for at least 12 h, and proceed with section 3.
        NOTE: As the clearing solution is viscous, small volumes are difficult to handle. To facilitate handling, make sure the solution is at RT, and pipette slowly. For optimal clearing, allow the sample to sediment in the clearing solution for at least 24 h before imaging. If 3D structures are floating at the time of acquisition, perform an optional spin for 10 min at <100 × g at RT, or allow more time (one to several days) to let them sediment. The protocol can be paused at this step before proceeding to imaging if it is protected from light and stored at 4 °C (for weeks) or -20 °C (for months).
  3. Image acquisition and analysis
    ​NOTE: Image sectioning technology will be required to image 3D structures.
    1. Use confocal microscopes, and favor immersion objectives with higher numerical aperture (NA) compared to air. Choose magnification objectives (10x, 20x, 40x) according to the size of 3D structures, image reconstruction (stitching), and solutions used for the analysis.
    2. When selecting the acquisition mode, take into consideration the depth of focus of the objective used to define the step for Z stacking; allow for optimal 3D rendering.
      NOTE: Image analysis solutions vary, and the analysis will need to be adjusted to the software used. For instance, this analysis protocol was established on a high-content analysis software (see Table of Materials and Supplementary Figure 1 for details) and provides data on object segmentation, calculation of properties, and cell population selection within a 3D reconstructed object.

3. 2D sectioning, staining, imaging, and analysis of 3D cell culture models

NOTE: 3D cell culture models vary in size. Proceed with section 3.1 or 3.2 for efficient paraffin embedding (Figure 2). Allow sufficient time for 3D structure sedimentation before any washes and reagent changes. Be careful not to aspirate the organoids that will be floating at the bottom of the tube. For paraffin embedding, refer to Figure 2 for guidance.

  1. Paraffin embedding of large (Ø ≥ 400 µm) 3D cell culture models
    1. On the day before embedding, prewarm two 150 mL flasks filled with paraffin (paraffin baths), a small metal embedding mold per sample, and fine forceps to 65 °C.
    2. Using a precoated 1 mL tip, carefully transfer the organoids in 1x PBS to a flat-bottom glass tube with a polytetrafluoroethylene-lined bottle cap. Let the organoids sediment, carefully remove the 1x PBS, and replace it with 70% ethanol. Incubate for at least 30 min.
    3. Let the organoids sediment, and carefully remove the 70% ethanol. Replace it with 1 mL of ready-to-use eosin Y solution. Flick the tube, and stain for at least 30 min. Carefully remove the eosin solution, and dehydrate the organoids in three successive washes with 1 mL of 100% ethanol for ~30 min each.
      NOTE: Ethanol, a flammable and volatile liquid, causes severe eye and respiratory tract irritation. Manipulate it in a fume hood, and wear protective eye goggles.
    4. Carefully remove the 100% ethanol, and under a chemical hood, clear the organoids in 3 successive washes with 1 mL of xylene for ~30 min each.
      NOTE: Xylene is a toxic, liquid flammable whose vapors may cause irritation. Manipulate it in a fume hood. Avoid direct contact with skin, and wear rubber gloves and protective eye goggles.
    5. Under a chemical hood, prepare a white microtwin tissue cassette by placing a piece of biopsy pad (previously soaked in xylene) inside one of the compartments of the cassette. Carefully transfer the 3D structures using a precoated 2 mL plastic Pasteur pipette to the biopsy pad. Cover them with another biopsy pad soaked in xylene to prevent the organoids from moving, and close the cassette.
    6. If several samples are processed, place the cassette in a xylene bath to await further processing. Once all samples are transferred into cassettes, place the cassettes in a prewarmed paraffin bath for 30 min at 65 °C. Transfer the cassettes to a fresh prewarmed paraffin bath overnight.
    7. After paraffin impregnation, take a prewarmed embedding mold, and add the heated paraffin to it. Place the biopsy pad containing the 3D structures into the mold, and gently agitate it until all of the organoids drop to the bottom of the mold. Very carefully place the 3D structures at the center of the mold using prewarmed fine forceps. Proceed with section 3.3.
      NOTE: Be careful not to disrupt the 3D structures with the forceps; push, but do not pinch them.
  2. Paraffin embedding of small (Ø ≤ 400 µm) 3D cell culture models
    1. On the day before embedding, prewarm two 150 mL flasks filled with paraffin (paraffin baths), a small metal embedding mold per sample, and fine forceps to 65 °C.
    2. Carefully remove the 1x PBS from the organoid suspension. Gently perform 3 washes in 1 mL of 1x Tris-buffered saline (TBS). Remove as much 1x TBS as possible without touching the organoids.
      ​NOTE: Be careful not to aspirate the sample. If necessary, perform a 5 min spin at 50 x g at RT. Remaining traces of phosphate will interfere with the following steps, notably preventing gel polymerization. Therefore, do not use PBS solutions during any processing step. For this step, a commercial kit, containing cassettes, Reagent #1 (clear fluid), and Reagent #2 (colored fluid), was used to facilitate the paraffin-embedded procedure without potentially loosing tiny fragments (see Table of Materials). Follow kit instructions. The cassettes are preassembled with backing papers and board inserts already in place.
    3. Add 2 drops of Reagent #2 into the tube, and mix gently by tapping the tube. Add 2 drops of Reagent #1, and mix again by tapping to make the gel solidify. Using the fine forceps, remove the gel from the tube, and place it in the well of the cassette.
    4. Under the fume hood, dehydrate the sample by placing the cassette in successive baths as follows (use the 150 mL flasks, and use fresh ethanol or xylene for each bath): ethanol 70%, 30 min; ethanol 96%, 30 min; ethanol 100%, three washes, 30 min each; xylene, three washes, 30 min each.
    5. Place the cassettes in a prewarmed paraffin bath for 30 min at 65 °C, and transfer them to a fresh prewarmed paraffin bath overnight. After paraffin impregnation, take a prewarmed embedding mold, and add heated paraffin into it. Open the cassette, carefully dislodge the gel with fine forceps, and place the gel containing the 3D structures onto the center of the embedding mold. Proceed with section 3.3.
  3. Common steps for paraffin embedding
    1. Gently transfer the mold to a cold area to let the paraffin solidify in a thin layer, which will maintain the 3D structures in the appropriate position. Add a tissue cassette on top of the mold, and add hot paraffin to cover this plastic cassette. Remove the mold once it is completely solidified, and proceed with section 3.4.
      NOTE: Paraffin blocks can be stored at room temperature for years.

Figure 2
Figure 2: Overview of the procedure for paraffin embedding of large and small in vitro 3D cell culture models.
(A) Standard procedure for paraffin embedding. After fixation and dehydration, 3D structures are stained with eosin to facilitate their visualization (top and bottom left). 3D structures are carefully placed on the biopsy pad (blue) in the cassette using a 2 mL Pasteur pipet (middle). After paraffin impregnation, the 3D structures are gently dropped into the liquid paraffin using forceps and gently agitated in the biopsy pad. Small 3D structures are lost during this step as they cannot be released from the pad (bottom right: failed embedding). Only large 3D structures will be embedded (top right: successful embedding). Arrowheads point to 3D cultures. (B) Alternative to the standard paraffin embedding protocol. After having fixed small 3D structures, a commercial kit is used to maintain cells in a gel and facilitate their transfer to the mold after paraffin impregnation (right: successful embedding). Please click here to view a larger version of this figure.

  1. Block sectioning and staining
    1. Cut 4 µm sections using a standard microtome, and perform standard histological and immunohistochemical techniques. Proceed with section 3.5.
      NOTE: Specific slides (see Table of Materials) were used for a better adhesion of sections. The slides can be stored at room temperature or at 4 °C for years.
  2. Image acquisition and analysis
    1. Perform imaging using a digital slide scanner or upright microscope, and analyze data using a platform for fast digital quantitative analysis that reports morphological and multiplexed expression data on a cell-by-cell basis across entire 3D structure sections (see Supplementary Figure 2 for details).
      NOTE: The 20x objective is used routinely by this group.

Representative Results

This protocol provides an overview of the critical steps for 2D and 3D whole-mount staining, as well as imaging and quantitative analyses of 3D cell culture models (Figure 3 and Figure 4). It is applicable to a wide range of 3D cell culture models-from spheroids to organoids from different host species or tissues-and enables the acquisition of accurate and quantitative information on architecture, cell organization, and interactions at cellular and subcellular levels (Figure 3 and Figure 4). Laboratories may need to optimize 2D histological and immunohistochemical techniques and antibody concentrations according to their own needs.

Both methods yield valuable biological information. 3D whole-mount staining and confocal microscopy provide visual information on cellular composition and spatial position with a field of depth of up to 200 µm (Figure 3B). However, 2D sectioning is convenient for larger 3D structures to reveal detailed cellular morphological traits in the entire section of 3D structures that can be otherwise challenging to observe in situ due to light scattering that compromises resolution in larger samples. Moreover, both techniques can provide quantitative data. Indeed, the resolution obtained allows the application of cellular and subcellular segmentation algorithms for the quantification of the number of cells and the detection of the presence of various cell markers in different cellular subtypes (Figure 3F and Figure 4). In summary, the imaging techniques described here are reproducible, simple, and complementary and represent valuable tools for studying cellular heterogeneity.

Figure 3
Figure 3: Representative results for 3D whole mount, imaging, and analyses of 3D and 2D optical sections. (A) Confocal images of human (h) high-grade glioma spheroid cultured for a week and labeled with Hoechst (blue), Olig2 (yellow), and Actin (red) (20x water objective). For all acquired images, microscope settings were established using a positive control (top), and then the negative control was imaged using identical settings to control the lack of fluorescence in the absence of primary antibody (bottom). (B) Orthogonal 3D whole-mount representation of Ki67 staining performed in (h) high-grade glioma spheroid cultured for a week (glycerol-fructose clearing; 20x water objective, confocal). (C) Confocal images of (h) high-grade glioma spheroid cultured for a week and labeled with Hoechst (blue), Olig2 (yellow), and Phalloidine-488 (green) (glycerol-fructose clearing; 20x water objective). (D) Confocal images of human (h) rhabdomyosarcoma (top) and mouse (m) neural crest cell (bottom) spheroids cultured for a week and labeled with Hoechst (blue), Actin (red), and Ki67 (green), respectively (glycerol-fructose clearing; 20x dry objective). (E) Confocal images of (h) high-grade glioma spheroid cultured for a week and labeled with Hoechst (blue) and Ki67 (green) (glycerol-fructose clearing; 40x water objective) (top left). Segmented images on the Hoechst channel and Ki67-positive (+) nuclear regions on the green channel were generated using high-content analysis software (see Supplementary Figure 1 and Table of materials) (bottom). Output given is the percentage of Ki67+ nuclei per segmented 3D structure (top right). Scale bar = 100 µm. Please click here to view a larger version of this figure.

Figure 4
Figure 4: Representative results for imaging and analyses of 2D optical sections. (A, D) 2D section images of a 3D cell model (human rhabdomyosarcoma spheroids cultured for a month) obtained with a digital slide scanner and analyzed on a platform for fast digital quantitative analysis. (A) H&E staining and detection of cells according to their size. Scale bar = 500 µm. (B) Histogram shows percentage of cells < 100 µm2 and > 100 µm2 detected using software for fast digital quantitative analysis (left: Halo) or manual counting (right: MC). (C) Ki67 staining and detection of cells according to the intensity of their 3,3'-diaminobenzidine (DAB) signal. Negative (blue), weakly positive (yellow), positive (red). Scale bar = 500 µm. (D) Histogram shows percentage of Ki67-negative, weakly positive, and positive cells. Abbreviations: H&E = hematoxylin and eosin; MC = manual counting. Please click here to view a larger version of this figure.

Supplementary Figure 1: Overview of the steps in the imaging analysis software. Analyses are based on the association of building blocks. Each building block corresponding to a function-segmentation, calculation, association, output definition-and offers multiple algorithms and variable selections to match the biological sample being imaged. The software provides multiple RMS (Ready Made Solution) analysis protocols that can easily be used and modified. Integrated image analysis protocols can be saved, applied to different datasets, and shared between users. Briefly, the analysis protocol implies sequential object segmentation: spheroid, nuclei and finally, Ki67 pockets (A488). Then, the mean intensity of the Ki67 pockets is calculated to further discriminate the positive events. Finally, nuclei encompassing Ki67 positive pockets are positively selected. Please click here to download this File.

Supplementary Figure 2: Overview of the procedure steps of the quantitative analysis software. Step 1. Upload the files using the Studies tab. Files will be opened in the Image Actions section. Step 2. Open the Annotations tab, then click on Layer Actions to design a new layer all around the structure using the circle tool of the toolbar. For non-circular structures, the pen tool can be used instead. Step 3. The toolbar can be used to design annotations and visualize the quantification with the Equation 1tool. Step 4. Open the Analysis tab, and select the best conditions for the analysis of the sample (several trials may be necessary here). Step 4.1. Use the Stain Selection section to set up the staining condition. In the event of several stains, these can be added and renamed, and the virtual color can be modified. The localization detection can be specified-nuclear or cytoplasm staining. Step 4.2. Use the Cell Detection section to set up the cell detection. This section will be the most important for the analysis. The Nuclear Contrast Threshold section will enable detection of all nuclei. Attention must be paid in case there are multiple population sizes, the software can detect several cells instead of a unique big one. Nuclear Size and Nuclear segmentation aggressiveness sections can be used to quantify cell size population ranges. Step 5. Description on how to run sample analysis. Follow steps shown in the figure. Annotation Layer section will run the setting only on this slide. The quantification can be visualized using the Equation 1tool. Repeat steps 4.1-5 until suitable quantification is achieved. Steps 6-6.1. These steps enable you to draw a figure using the software. Step 7. Quantification graphics obtained via software can be saved. Step 8. Data can be exported. Please click here to download this File.

Discussion

Cell culture is an indispensable tool to uncover fundamental biological mechanisms involved in tissue and organ development, function, regeneration and disruption, and disease. Although monolayered 2D cell culture has predominated, recent research has shifted towards cultures generating 3D structures more reflective of in vivo cellular responses, owing notably to additional spatial organization and cell-cell contacts that influence gene expression and cellular behavior and could thus provide more predictive data7. Nevertheless, many challenges remain, including the need for user-friendly staining and imaging techniques for detailed microscopic visualization and evaluation of complex 3D structures at the cellular and subcellular levels. In that context, detailed, robust, and complementary protocols have been provided to perform staining and cellular and subcellular resolution imaging of fixed in vitro 3D cell culture models ranging from 100 µm to several millimeters in size.

This procedure presents two different strategies to deal with a large variety of sizes and types of in vitro 3D cell culture models. The choice of one (3D whole-mount analysis) or the other (2D sectioning analysis) will depend on the model used and issue investigated. 3D whole-mount analysis by confocal microscopy enables the visualization of cells with a field of depth of up to 200 µm, irrespective of the overall size of the 3D structure, whereas 2D sectioning is applicable to samples of any size, but visualization remains 2D dimensional. Below are some suggestions for troubleshooting and technical considerations.

Loss of 3D structures during the workflow is the most common drawback. They can remain adherent to the tips and tubes, which is why precoating tips and tubes with PBS-BSA 0.1% solution is key. Moreover, it is crucial to let the 3D structures sediment between reagent changes and to perform all pipetting very carefully. As mentioned in the procedure, for all steps, if 3D structure sedimentation is too long, cells can be gently spun at 50 × g for 5 min at RT. Depending on the aim of the study, the advantages/disadvantages of such a spinning step should be considered as centrifugation can compromise the shape of the 3D structures. Moreover, care should be taken to preserve this morphology during the fixation step because cystic organoids tend to collapse. Fixing structures under 400 µm in size should prevent structural changes.

For optimal immunolabeling, recovery of organoids from their 3D matrices is a crucial step. The 3D matrix can impede adequate antibody penetration or lead to high background staining because of non-specific binding to the matrix. ECM removal may alter the morphology of the outer segments of organoids (notably in case of small cellular protrusions extending from studied 3D structures) and partially hamper analyses. For such 3D structures, the matrix can be retained throughout the procedure; however, culture conditions should be carefully adapted to grow cells in a minimum amount of matrix to prevent insufficient penetration of solutions and antibodies and to avoid successive washing steps aimed at reducing excessive background noise6,8.

The optical clearing step described in this protocol in the 3D whole mount staining section is pertinent for the imaging of 3D structures up to 150-200 µm in depth instead of 50-80 µm without clearing. Compared to other clearing methodologies that often requiring several weeks and using toxic clearing agents, a previously published fast and safe clearing step was used in this protocol4,9. In addition, this clearing step is reversible, and new antibodies can be added to the initial staining with no loss of resolution or brightness4. Nevertheless, depending on the 3D cell culture model studied, a depth of 150-200 µm might not be sufficient to image the 3D structure in an informative way, and this clearing protocol can cause changes in the general morphology of spherical, monolayered organoids with large lumens4. Users should carefully design their experiment, and if necessary, optimize the timing of the permeabilization/blocking step (to allow penetration of antibodies and solution), the clearing step (to penetrate deeper than 200 µm, specimens should be totally cleared), and image acquisition. The two most prevalent technologies available in core facilities would be light sheet and confocal microscopy. Users will need to carefully choose a technology based on the size of their 3D structures and their biological question10. However, compared to confocal microscopy, light sheet microscopy resolution obtained for such deep structures remains suboptimal for obtaining subcellular resolution.

Here, a detailed and robust process has been reported that is dedicated to paraffin embedding of single samples. Interestingly, Gabriel et al. recently developed a protocol embedding 3D cell cultures in paraffin with an increased throughput. They used a polydimethylsiloxane (PDMS) mold to confine 96 3D structures in a microarray pattern in one block, providing novel perspectives for studies on 3D tumor models encompassing more groups, time points, treatment conditions, and replicates11. However, this method requires extensive skills and machinery, notably for the fabrication of the premold used to created PDMS molds.

In summary, this paper describes two different, complementary, and adaptable approaches enabling the acquisition of accurate and quantitative information on architectural and cellular composition of 3D cellular models. Both parameters are crucial for studying biological processes such as intratumoral cellular heterogeneity and its role in resistance to treatments.

Divulgations

The authors have nothing to disclose.

Acknowledgements

This work was supported by the St Baldrick's Robert J. Arceci Innovation Award #604303.

Materials

Equipment
Biopsy pad Q Path blue VWR 720-2254
Cassettes macrostar III Blc couv. Char. x1500 VWR 720-2233
Cassette microtwin white VWR 720-2183
Chemical hood Erlab FI82 5585-06
Filter tips 1000 µL Star lab Tip-One S1122-1730
Fine forceps Pyramid innovation R35002-E
Flat-bottom glass tubes with PTFE lined 2 mL Fisher Scientific 11784259 Excellent  for environmental    samples,    pharmaceuticals and diagnostic reagents. PTFE is designed for the ultimate in product safety. PTFE provides totally inert inner seal and surface facing the sample or product.
Glass bottom dish plate 35 mm Ibedi 2018003
Horizontal agitation N-BIOTEK NB-205
Incubator prewarmed to 65 °C Memmert Incubator LAB129
Inox molds 15×15 VWR 720-1918
Microscope Slides Matsunami TOMO-11/90 Roche diagnostics 8082286001 these slides are used for a better adhesion of sections
Microtome Microm Microtech France HM340E
Panoramic scan II 3dhistech 2397612
Paraffin embedding equipment Leica EG1150C
Plastic pipette Pasteur 2 mL VWR 612-1681
Q Path flacon 150mL cape blanc x250 VWR 216-1308 Good for environmental    samples,    pharmaceuticals and diagnostic reagents. Polypropylene (PP) are rigid,  solid, provide excellent  stress  crack  and  impact  resistance and have a  good oil and alcohol barrier and chemical resistance. PE-lined cap is stress crack resistant and offers  excellent  sealing  characteristics. 
Set of micropipettors  (p200, p1000) Thermo Scientific 11877351 (20-200) 11887351(p1000)
OPERA PHENIX PerkinElmer HH14000000
SP5 inverted confocal microscope Leica LSM780
Tissue cassette VWR 720-0228
Zeiss Axiomager microscope Leica SIP 60549
Reagent
Bovine Serum Albumin (BSA) Sigma-Aldrich A7030-100G
Cytoblock (kit) Thermofisher Scientific 10066588
Dimethyl sulfoxide (DMSO) Sigma-Aldrich 57648266 CAUTION: toxic and flammable. Vapors may cause irritation. Manipulate in a fume hood. Avoid direct contact with skin. Wear rubber gloves, protective eye goggles.
Eosin aqueous 1% Sigma-Aldrich HT110316
Ethanol 96% VWR 83804.360 CAUTION: Causes severe eye irritation. Flammable liquid and vapor. Causes respiratory tract irritation. Manipulate in a fume hood. Wear protective eye goggles.
Ethanol 100% VWR 20821.365 CAUTION: Causes severe eye irritation. Flammable liquid and vapor. Causes respiratory tract irritation. Manipulate in a fume hood. Wear protective eye goggles.
Formalin 4% Microm Microtech France F/40877-36 CAUTION: Formalin contains formaldehyde which is hazardous. Manipulate in a fume hood. Avoid direct contact with skin. Wear rubber gloves and protective eye goggles.
Fructose Sigma-Aldrich F0127
Gill hematoxylin type II Microm Microtech France F/CP813
Glycerol Sigma-Aldrich G5516 500 mL
Hoechst 33342 Life Technologies H3570 CAUTION: Suspected of causing genetic defects.  Avoid direct contact with skin. Wear rubber gloves and protective eye goggles.
Normal donkey serum Sigma-Aldrich D9663 10 mL
Paraffin Wax tek III Sakura 4511
Phosphate Buffer Saline (PBS) 1 X Gibco 14190-094
Tris-Buffered Saline (TBS) 10X Microm Microtech France F/00801 100 mL
Triton X-100 Sigma-Aldrich T8532 CAUTION: Triton X­100 is hazardous. Avoid contact with skin and eyes.
Xylene Sigma-Aldrich 534056 CAUTION: Xylene is toxic and flammable. Vapors may cause irritation. Manipulate in a fume hood. Avoid direct contact with skin. Wear rubber gloves, protective eye goggles.
Solutions
Clearing solution Glycerol-Fructose clearing solution is 60% (vol/w) glycerol and 2.5 M fructose. To prepare 10 mL of this solution, mix 6 mL of glycerol and 4.5 g of fructose. Complete to 10 mL with dH2O. Use a magnetic stirrer overnight. Refractive index = 1.4688 at room temperature (RT: 19–23 °C). Store at 4 °C in dark for up to 1 month.
PBS-BSA 0,1% solution To prepare 0,1% (vol/wt) PBS-BSA 0,1% solution, dissolve 500 mg of BSA in 50 mL of PBS-1X (store at 4°C for up to 2 weeks). And dilute 1mL of this solution into 9mL of PBS-1X. This solution can be used to precoat the tip and centrifugation tube. 
Permeabilisation-blocking solution (PB solution) The PBSDT blocking solution is PBS-1X supplemented with 0.1% – 1% Tritonx-100 (depending on the protein localization membrane/nucleus), 1% DMSO, 1% BSA and 1% donkey serum (or from the animal in which the secondary antibodies were raised). This solution can be stored at 4°C for up to 1 month.
PB:PBS-1X  (1:10) solution PB:PBS-1X  (1:10) solution is a 10 time diluted PB solution. To prepare 10 mL of this solution dilute 1 mL of PB solution in 9 mL of PBS-1X.
Software
Halo software Indicalabs NM 87114
Harmony software PerkinElmer HH17000010

References

  1. Ryu, N. E., Lee, S. H., Park, H. Spheroid culture system methods and applications for mesenchymal stem cells. Cells. 8 (12), 1-13 (2019).
  2. Bartfeld, S., Clevers, H. Stem cell-derived organoids and their application for medical research and patient treatment. Journal of Molecular Medicine. 95 (7), 729-738 (2017).
  3. Cui, X., Hartanto, Y., Zhang, H. Advances in multicellular spheroids formation. Journal of the Royal Society, Interface. 14 (127), (2017).
  4. Dekkers, J. F., et al. High-resolution 3D imaging of fixed and cleared organoids. Nature Protocols. 14, 1756-1771 (2019).
  5. Broutier, L., et al. Culture and establishment of self-renewing human and mouse adult liver and pancreas 3D organoids and their genetic manipulation. Nature Protocols. 11 (9), 1724-1743 (2016).
  6. Rezanejad, H., Lock, J. H., Sullivan, B. A., Bonner-Weir, S. Generation of pancreatic ductal organoids and whole-mount immunostaining of intact organoids. Current Protocols in Cell Biology. 83 (1), 82 (2019).
  7. Edmondson, R., Broglie, J. J., Adcock, A. F., Yang, L. Three-dimensional cell culture systems and their applications in drug discovery and cell-based biosensors. Assay and Drug Development Technologies. 12 (4), 207-218 (2014).
  8. McCray, T., Richards, Z., Marsili, J., Prins, G. S., Nonn, L. Handling and assessment of human primary prostate organoid culture. Journal of Visualized Experiments: JoVE. (143), e59051 (2019).
  9. Ueda, H. R., et al. Tissue clearing and its applications in neuroscience. Nature Reviews: Neuroscience. 21 (2), 61-79 (2020).
  10. Lazzari, G., et al. Light sheet fluorescence microscopy versus confocal microscopy: in quest of a suitable tool to assess drug and nanomedicine penetration into multicellular tumor spheroids. European Journal of Pharmaceutics and Biopharmaceutics. 142, 195-203 (2019).
  11. Gabriel, J., Brennan, D., Elisseeff, J. H., Beachley, V. Microarray embedding/sectioning for parallel analysis of 3D cell spheroids. Scientific Reports. 9, 16287 (2019).

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Citer Cet Article
Gonzalez, A. L., Luciana, L., Le Nevé, C., Valantin, J., Francols, L., Gadot, N., Vanbelle, C., Davignon, L., Broutier, L. Staining and High-Resolution Imaging of Three-Dimensional Organoid and Spheroid Models. J. Vis. Exp. (169), e62280, doi:10.3791/62280 (2021).

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