Summary

High-Resolution 3D Imaging of Rabies Virus Infection in Solvent-Cleared Brain Tissue

Published: April 30, 2019
doi:

Summary

Novel, immunostaining-compatible tissue clearing techniques like the ultimate 3D imaging of solvent-cleared organs allow the 3D visualization of rabies virus brain infection and its complex cellular environment. Thick, antibody-labeled brain tissue slices are made optically transparent to increase imaging depth and to enable 3D analysis by confocal laser scanning microscopy.

Abstract

The visualization of infection processes in tissues and organs by immunolabeling is a key method in modern infection biology. The ability to observe and study the distribution, tropism, and abundance of pathogens inside of organ tissues provides pivotal data on disease development and progression. Using conventional microscopy methods, immunolabeling is mostly restricted to thin sections obtained from paraffin-embedded or frozen samples. However, the limited 2D image plane of these thin sections may lead to the loss of crucial information on the complex structure of an infected organ and the cellular context of the infection. Modern multicolor, immunostaining-compatible tissue clearing techniques now provide a relatively fast and inexpensive way to study high-volume 3D image stacks of virus-infected organ tissue. By exposing the tissue to organic solvents, it becomes optically transparent. This matches the sample’s refractive indices and eventually leads to a significant reduction of light scattering. Thus, in combination with long free working distance objectives, large tissue sections up to 1 mm in size can be imaged by conventional confocal laser scanning microscopy (CLSM) at high resolution. Here, we describe a protocol to apply deep-tissue imaging after tissue clearing to visualize rabies virus distribution in infected brains in order to study topics like virus pathogenesis, spread, tropism, and neuroinvasion.

Introduction

Conventional histology techniques mostly rely on thin sections of organ tissues, which can inherently provide only 2D insights into a complex 3D environment. Although feasible in principle, 3D reconstruction from serial thin sections requires demanding technical pipelines for both slicing and subsequent in silico alignment of the acquired images1. Moreover, seamless reconstruction of z-volumes after microtome slicing is critical as both mechanical and computational artifacts can remain because of suboptimal image registration caused by nonoverlapping image planes, staining variations, and physical destruction of tissue by, for instance, the microtome blade. In contrast, pure optical slicing of intact thick tissue samples allows the acquisition of overlapping image planes (oversampling) and, thereby, facilitates 3D reconstruction. This, in turn, is highly beneficial for the analysis of infection processes in complex cell populations (e.g., neuronal networks in the context of the surrounding glial and immune cells). However, inherent obstacles of thick tissue sections include light scattering and limited antibody penetration into the tissue. In recent years, a variety of techniques has been developed and optimized to overcome these issues2,3,4,5,6,7,8,9,10,11,12,13. Essentially, target tissues are turned optically transparent by treatment with either aqueous2,3,4,5,6,7,8,9 or organic solvent-based10,11,12,13 solutions. The introduction of 3DISCO (3D imaging of solvent-cleared organs)11,12 and its successor uDISCO (ultimate 3D imaging of solvent-cleared organs)13 provided a relatively fast, simple, and inexpensive tool with excellent clearing capabilities. The main constituents of the clearing protocol are the organic solvents tert-butanol (TBA), benzyl alcohol (BA), benzyl benzoate (BB), and diphenyl ether (DPE). The development and addition of iDISCO (immunolabeling-enabled 3D imaging of solvent-cleared organs)14, a compatible immunostaining protocol, constituted another advantage over existing methods and enabled the deep-tissue labeling of antigens of interest, as well as the long-term storage of immunostained samples. Thus, the combination of iDISCO14 and uDISCO13 allows for the high-resolution imaging of antibody-labeled proteins in large tissue sections (up to 1 mm) using conventional CLSM.

The preservation of an organ’s complex structure in all three dimensions is particularly important for brain tissue. Neurons comprise a very heterogeneous cellular subpopulation with highly diverse 3D morphologies based on their neurite projections (reviewed by Masland15). Furthermore, the brain consists of a number of compartments and subcompartments, each composed of different cellular subpopulations and ratios thereof, including glial cells and neurons (reviewed by von Bartheld et al.16). As a neurotropic virus, the rabies virus (RABV, reviewed by Fooks et al.17) primarily infects neurons, using their transport machinery to travel in retrograde direction along axons from the primary site of infection to the central nervous system (CNS). The protocol described here (Figure 1A) allows for the immunostaining-assisted detection and visualization of RABV and RABV-infected cells in large, coherent image stacks obtained from infected brain tissue. This enables an unbiased, 3D high-resolution assessment of the infection environment. It is applicable to brain tissue from a variety of species, can be performed immediately after fixation or after the long-term storage of samples in paraformaldehyde (PFA), and allows the storage and reimaging of stained and cleared samples for months.

Protocol

RABV-infected, PFA-fixed archived brain material was used. The respective animal experimental studies were evaluated by the responsible animal care, use, and ethics committee of the State Office for Agriculture, Food Safety, and Fishery in Mecklenburg-Western Pomerania (LALFF M-V) and gained approval with permissions 7221.3-2.1-002/11 (mice) and 7221.3-1-068/16 (ferrets). General care and methods used in the animal experiments were carried out according to the approved guidelines.

CAUTION: This protocol uses various toxic and/or harmful substances, including PFA, methanol (MeOH), hydrogen peroxide (H2O2), sodium azide (NaN3), TBA, BA, BB, and DPE. MeOH and TBA are highly flammable. Avoid exposure by wearing appropriate personal protective equipment (a lab coat, gloves, and eye protection) and conducting experiments in a fume hood. Collect waste separately in appropriate containers and dispose of it according to local regulations. Rabies virus is classified as a biosafety level (BSL)-2 pathogen and can, therefore, generally be handled under BSL-2 conditions. Some activities, including procedures that may generate aerosols, work with high virus concentrations, or work with novel lyssaviruses, may require BSL-3 classification. Pre-exposure prophylaxis is recommended for high-risk personnel, including animal caretakers and laboratory workers18,19. Refer to local authority regulations.

1. Fixation of brain tissue and sectioning

  1. Fix brain samples in an appropriate volume of 4% PFA in phosphate-buffered saline (PBS [pH 7.4]) for at least 48 h at 4 °C (with an approximate tissue-to-fixative ratio of 1:10 [v/v]).
  2. Wash the tissue samples 3x in PBS for at least 30 min each wash and store them in 0.02% NaN3/PBS at 4 °C until use.
  3. Section the tissue into 1 mm-thick sections using a vibratome (blade feed rate: 0.3–0.5 mm/s, amplitude: 1 mm, slice thickness: 1,000 µm).
  4. To retain the correct slice sequence, store each tissue section separately in a well of a multiwell cell culture plate. Add 0.02% NaN3/PBS and store the tissue sections at 4 °C until use.

2. Sample pretreatment with methanol

NOTE: Perform all incubation steps with gentle oscillation and, if not indicated otherwise, at room temperature. Protect the samples from light. The sample pretreatment serves the overall purpose of improving antibody diffusion and reducing tissue autofluorescence by exposure to MeOH and H2O2, respectively14.

  1. Prepare 20% (v/v), 40%, 60%, and 80% MeOH solutions in distilled water. For instance, for 20% MeOH, add 10 mL of 100% MeOH to 40 mL of distilled water in an appropriate sealable vessel and mix by inverting it.
  2. Transfer the samples to reasonably sized vessels (e.g., 5 mL reaction tubes). Take care to use materials chemically resistant to the reagents used in this protocol. For instance, note that while polypropylene is suitable, polystyrene is not.
    NOTE: The volume specifications in this protocol refer to 5 mL reaction tubes. If a different vessel is used, adjust the volumes accordingly.
  3. Incubate the samples in 4 mL of each concentration of the prepared series of MeOH solutions in ascending order for 1 h each.
  4. Incubate the samples 2x for 1 h each in pure (100%) MeOH.
  5. Cool the samples to 4 °C (e.g., in a laboratory-safe refrigerator).
  6. Prepare bleaching solution (5% H2O2 in MeOH) by, for instance, diluting a 30% H2O2 stock solution at 1:6 in pure (100%) MeOH, and chill it at 4 °C.
  7. Remove the 100% MeOH from the refrigerated samples and add 4 mL of prechilled bleaching solution (5% H2O2 in MeOH). Incubate overnight at 4 °C.
  8. Exchange the bleaching solution for 4 mL of 80% MeOH and incubate for 1 h. Continue using the prepared series of MeOH solutions in descending order for 1 h each until the samples have been incubated for 1 h in 4 mL of 20% MeOH.
  9. Wash the samples 1x for 1 h with 4 mL of PBS.

3. Immunostaining

NOTE: Perform all incubation steps with gentle oscillation and, if not indicated otherwise, at room temperature. Protect the samples from light. To prevent microbial growth, add NaN3 to a final concentration of 0.02% to the solutions in this section. Tissue samples are further permeabilized by treatment with nonionic detergents Triton X-100 and Tween 20. Normal serum is used to block unspecific antibody binding. Glycine and heparin are added to reduce the immunolabeling background14.

  1. Wash the samples 2x for 1 h each in 4 mL of 0.2% Triton X-100/PBS.
  2. Permeabilize the samples for 2 days at 37 °C with 4 mL of 0.2% Triton X-100/20% DMSO/0.3 M glycine/PBS.
  3. Block the unspecific binding of antibodies by incubating the samples for 2 days at 37 °C in 4 mL of 0.2% Triton X-100/10% DMSO/6% normal serum/PBS.
    NOTE: Use normal serum from the same species the secondary antibody was raised in to achieve ideal blocking results.
  4. Incubate the samples in 2 mL of primary antibody solution (3% normal serum/5% DMSO/PTwH [PBS-Tween 20 with heparin] + primary antibody/antibodies) for 5 days at 37 °C. Refresh the primary antibody solution after 2.5 days.
    1. For PTwH, reconstitute the heparin sodium salt in distilled water to make a 10 mg/mL stock solution (store this solution, aliquoted, at 4 °C). Add the stock solution to 0.2% Tween 20/PBS to a final concentration of 10 µg/mL.
      NOTE: Choosing the correct antibody dilution may require optimization. Generally, standard immunohistochemistry concentrations are a good starting point.
  5. Wash the samples for 1 day in 4 mL of PTwH, exchanging the wash buffer at least 4x–5x during the course of the day and leaving the final wash on overnight.
  6. Incubate the samples in 2 mL of secondary antibody solution (3% normal serum/PTwH + secondary antibody/antibodies) for 5 days at 37 °C. Refresh the secondary antibody solution after 2.5 days.
    1. Dilute the secondary antibody/antibodies at 1:500 in secondary antibody solution (i.e., 4 µL in 2 mL).
  7. Wash the samples for 1 day as described in step 3.5, leaving the final wash on overnight.

4. Nuclear staining

NOTE: Perform all incubation steps with gentle oscillation and, if not indicated otherwise, at room temperature. Protect the samples from light. If no nuclear staining is required or the excitation wavelength/emission spectrum of TO-PRO-3 is required for the excitation or detection of another fluorophore, skip this step.

  1. Dilute the nucleic acid stain TO-PRO-3 at 1:1,000 in PTwH and incubate the samples in 4 mL of nuclear staining solution for 5 h.
  2. Wash the samples for 1 day as described in step 3.5, leaving the final wash on overnight.
    NOTE: Following the washes, the samples can be stored in PBS at 4 °C until optical clearing.

5. Tissue clearing

NOTE: Perform all incubation steps with gentle oscillation and, if not indicated otherwise, at room temperature. Protect the samples from light. The tissue samples are dehydrated in a graded series of TBA solutions. As immunostaining requires aqueous solutions, all staining procedures have to be finished prior to tissue clearing. Optical clearance and refractive index matching are achieved by treatment with a mixture of BA, BB, and DPE. The clearing solution is supplemented with DL-α-tocopherol as an antioxidant13.

  1. Prepare 30% (v/v), 50%, 70%, 80%, 90%, and 96% TBA solutions in distilled water. For instance, for 30% TBA, add 15 mL of 100% TBA to 35 mL of distilled water in an appropriate sealable vessel and mix by inverting.
    NOTE: TBA has a melting point of 25–26 °C; thus, it tends to be solid at room temperature. In order to prepare TBA solutions, heat the well-sealed bottle at 37 °C in an incubator or water bath.
  2. Dehydrate the samples with 4 mL of each concentration of the prepared series of TBA solutions in ascending order for 2 h each. Leave the 96% TBA on overnight.
  3. Dehydrate the samples further in pure (100%) TBA for 2 h.
  4. Prepare clearing solution BABB-D15.
    NOTE: BABB-D15 is a combination of BA and BB (BABB) which is mixed with DPE at a ratio of x:1, where x is specified in the solution’s name, in this case 15.
    1. For BABB, mix one-part BA with two parts BB.
    2. Mix BABB and DPE at a ratio of 15:1.
    3. Add 0.4 vol% DL-α-tocopherol (vitamin E).
      NOTE: For example, for 20 mL of BABB-D15, mix 6.25 mL of BA with 12.5 mL of BB. Add 1.25 mL of DPE and supplement it with 0.08 mL of DL-α-tocopherol.
  5. Clear the samples in clearing solution until they are optically transparent (2–6 h).
  6. The samples can be stored at 4 °C in BABB-D15, protected from light, until mounting and imaging.

6. Sample mounting

  1. Using a 3D printer, print the imaging chamber and the lid (material: copolyester [CPE], nozzle: 0.25 mm, layer height: 0.06 mm, wall thickness: 0.88 mm, wall count: 4, infill: 100%, no support structure; the corresponding .STL file can be found in the Supplementary Materials of this protocol).
  2. Assemble the imaging chamber (Figure 2).
    1. Mount a round coverslip (diameter: 30 mm) on the imaging chamber with RTV-1 (one-component room-temperature-vulcanizing) silicone rubber. Remove the excess silicone rubber with a water-wetted cotton swab and cure overnight.
    2. Mount a round coverslip (diameter: 22 mm) on the lid with RTV-1 silicone rubber. Remove the excess silicone rubber with a water-wetted cotton swab and cure overnight.
  3. Place the sample in an imaging chamber, add a small volume of BABB-D15, and insert the lid. Fill the chamber up with BABB-D15 through the inlet, using a hypodermic needle (27 G x 3/4 inch [0.40 mm x 20 mm]).
  4. Plug the inlet and seal the imaging chamber with RTV-1 silicone rubber. Cure overnight in the dark.

7. Imaging and image processing

  1. Set up the image acquisition by selecting the respective laser lines to match the fluorophores used. Adjust the detection ranges of each detector to prevent signal overlap between channels.
    NOTE: Exemplary detection ranges for Alexa Fluor 488, Alexa Fluor 568, and TO-PRO-3 are 500–550 nm, 590–620 nm, and 645–700 nm, respectively.
  2. Choose the acquisition parameters, define the upper and lower border of the z-stack, and acquire the image stack.
    NOTE: Exemplary acquisition parameters are a sequential scan with a pixel size of 60-90 nm, a z-step size of 0.5 µm, a line average of 1, a scan speed of 400 Hz, and a pinhole size of 1 Airy unit.
  3. Process the image stack using appropriate image analysis software (e.g., Fiji) to generate 3D projections or perform in-depth analyses.
    NOTE: Because of the large size of the acquired image files, the use of a workstation is usually necessary.
    1. Open the acquisition or image file(s) in Fiji (File | Open | Select files).
      1. If using, for instance, .LIF files, select or deselect the desired options in the Bio-Formats dialog window. View stack with Hyperstack. Other than that, no specific selections or ticks are necessary. Press OK.
      2. If the file contains multiple image stacks, select the ones to be analyzed and confirm by pressing OK.
    2. Perform bleach correction by splitting the merged image into individual channels (Image | Color | Channels Tool, then select Più | Split Channels). For each channel, select bleach correction (Image | Adjust | Bleach Correction) and choose Simple Ratio (background intensity: 0.0).
      NOTE: In some cases, for instance, when there is no linear decay of the signal or the signal is too weak overall, Simple Ratio may fail. Alternatively, try Exponential Fit or skip the bleach correction.
    3. Adjust the brightness and contrast for each channel using the sliders (Image | Adjust | Brightness | Contrast).
    4. Merge the channels (Image | Color | Merge Channels), make a composite (Image | Color | Channels Tool, then select Più | Make Composite), and convert it to RGB format (Image | Color | Channels Tool, then select Più | Convert to RGB).
    5. If necessary, resize the image stack to reduce the computation time and file size (Image | Adjust | Size, both options ticked plus bilinear interpolation).
    6. Generate a 3D projection (Image | Stacks | 3D Project). Choose Brightest Point as projection method and set the slice spacing to match the z-step size of the acquired image stack. For maximum quality, set the rotation angle increment to 1 and enable interpolation. Modify the total rotation, transparency thresholds, and opacity as needed.
    7. If necessary, readjust the contrast and brightness by converting the 3D projection back to 8-bit format (Image | Tipo | 8-bit). Use the respective sliders (Image | Adjust | Brightness | Contrast) and reconvert the image stack to RGB format as described in step 7.3.4.
    8. Save the 3D projection as .TIF file (image file format) and .AVI file (video file format).

Representative Results

The combination of iDISCO14 and uDISCO13 coupled with high-resolution CLSM provides deep insights into the spatiotemporal resolution and plasticity of RABV infection of brain tissue and the surrounding cellular context.

Using immunostaining of RABV phosphoprotein (P), complex layers of infected neuronal cells can be visualized in thick sections of mouse brains (Figure 3). Subsequently, seamless 3D projections of the acquired image stacks can be reconstructed (Figure 3A, B, right panel; Animated Figure 1). Care has to be taken when using primary antibodies from and secondary antibodies against the species the organ material originates from. The use of anti-mouse IgG antibodies on mouse brain tissue resulted in a distinct staining of the vascular system (Figure 3B, left panel). Because of the high resolution the image stacks are acquired with, infection can be assessed up to a single-cell level (Figure 4), allowing assertions on, for instance, the abundance and distribution of antigen within the cell (Figure 4C).

Aside from mouse brain tissue, the protocol can also be applied to brain tissue from other animal species (e.g., ferrets) (Figure 5; Animated Figure 2). Sections taken from different compartments of an infected ferret brain revealed a varying degree of RABV infection (Figure 5A-D).

As the brain comprises many different cellular subpopulations, differentiation between these populations is vital. Using antibodies directed against cell markers, assessment of the cellular identity of infected and neighboring cells is possible. For instance, astrocytes can be differentiated via the expression of glial fibrillary acidic protein (GFAP) (Figure 6A,C; Animated Figure 3), while neurites can be specifically stained for microtubule-associated protein 2 (MAP2) (Figure 6B,D; Animated Figure 4). Simultaneously, viral proteins, in this case, RABV nucleoprotein (N), can be costained to assess the relation between infected cells and the highlighted cellular subpopulation.

Figure 1
Figure 1: Basic principle and workflow of the protocol. (A) Graphical representation of the workflow based on the protocols from Renier et al.14 and Pan et al.13. (B) Two exemplary ferret brain slices, one before (left panel) and one after treatment with organic solvents (right panel). Clearing turns the tissue optically transparent as observable by the then readable text. The cleared brain slice is embedded in a 3D-printed imaging chamber (right panel). Please click here to view a larger version of this figure.

Figure 2
Figure 2: Technical illustration of the 3D-printed imaging chamber. (A) Exploded view drawing of the imaging chamber. The dot-dashed lines highlight components that have to be mounted on each other using RTV-1 silicone rubber. The dashed lines represent instructions for the subsequent assembly of the chamber. (B) CAD (computer-aided design) file of the imaging chamber. The corresponding .STL file to print the imaging chamber can be found in the Supplementary Materials. (C) Fully assembled imaging chamber. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Deep-tissue imaging of RABV-infected mouse brain tissue. (A and B) Mice were infected with a recombinant vulpine street virus. RABV P staining (green) reveals infected neuronal layers with large, entangled neurite projections inside the cleared brain tissue. Nuclei were counterstained with TO-PRO-3 (blue). (B) The use of fluorophore-labeled anti-mouse IgG secondary antibodies (red) on mouse tissue results in a distinct labeling of the vascular system. The 3D reconstruction of the acquired image stacks enables observation from different viewing angles (A and B, right panels). Scale bars = 60 µm. Please click here to view a larger version of this figure.

Figure 4
Figure 4: High-resolution image acquisition enables complex assessments up to a single-cell level. The brain was dissected from an SAD L16-infected mouse. (A) RABV P staining (green) highlights an individually infected neuron. (B and C) Detail images and projections demonstrate that in-depth analyses of antigen abundance, distribution, and localization can be performed. Nuclei were counterstained with TO-PRO-3 (blue). Scale bars = 20 µm (A), 5 µm (C). Please click here to view a larger version of this figure.

Figure 5
Figure 5: Deep-tissue imaging of RABV-infected ferret brain tissue. Ferrets were infected with canine street RABV. (AD) Slices from specified areas of the brain were taken, immunostained for RABV P (green), and optically cleared. Projections demonstrate that the infected cells in different parts of the brain differ in amount and morphology. Furthermore, they highlight the applicability of the protocol to tissues other than mouse-derived. Nuclei were counterstained with TO-PRO-3 (blue). Scale bars = 60 µm. Please click here to view a larger version of this figure.

Figure 6
Figure 6: Multicolor immunofluorescence allows the costaining of cellular markers. Brain tissue slices from ferrets infected with canine street RABV were used and coimmunostained for RABV N (red) and either (A and C) GFAP (green) or (B and D) MAP2 (green). Whereas GFAP is an astrocyte marker, MAP2 specifically highlights neurites. Nuclei were counterstained with TO-PRO-3 (blue). (C and D) At the bottom, single slice extractions of the enumerated detail views from the merged projections are depicted. Scale bars = 15 µm (A and B) 10 µm (C and D). Please click here to view a larger version of this figure.

Animated Figure 1
Animated Figure 1: 3D reconstructions and detail projections of image stacks from RABV-infected mouse brains. The projections were generated from the image stacks described in Figure 3. (A and C) Animations of the entire respective z-stacks. (B) A detailed projection of a 3D reconstruction of a part of the z-stack of the areas highlighted at the beginning of the video. (D) A detailed projection of a tomogram of a part of the z-stack of the areas highlighted at the beginning of the video. Green = RABV P; red = mouse IgG; blue = nuclei. Please click here to view this video. (Right-click to download.)

Animated Figure 2
Animated Figure 2: 3D reconstructions of image stacks acquired from an RABV-infected ferret brain. The projections were generated from the image stacks described in Figure 5. (AD) The annotations refer to the same figure and describe the respective areas of the brain the slices were taken from. Green = RABV P; blue = nuclei. Please click here to view this video. (Right-click to download.)

Animated Figure 3
Animated Figure 3: Gradual projection of the different channels of a 3D reconstruction of an RABV-infected ferret brain costained with astrocyte marker GFAP. Projections were generated from the image stack described in Figure 6A. The gradual addition of channels starts with RABV N (red), after which follow the cell nuclei (blue) and, finally, GFAP (green), while the subtraction first removes RABV N, then the cell nuclei, and eventually GFAP. Please click here to view this video. (Right-click to download.)

Animated Figure 4
Animated Figure 4: Gradual projection of the different channels of a 3D reconstruction of an RABV-infected ferret brain costained with neuronal marker MAP2. Projections were generated from the image stack described in Figure 6B. The gradual addition of channels starts with RABV N (red), after which follow the cell nuclei (blue) and, finally, MAP2 (green), while the subtraction first removes RABV N, then the cell nuclei, and eventually MAP2. Please click here to view this video. (Right-click to download.)

Discussion

The resurgence and further development of tissue clearing techniques in recent years2,3,4,5,6,7,8,9,10,11,12,13,14 have opened up many new possibilities to obtain high-volume image stacks of organ tissue. This provided an unparalleled and powerful tool to study, among many other topics, virus infection. The subsequent 3D reconstruction of these image stacks enables sophisticated assertions on, for instance, virus tropism, abundance, and the time course of infection. This protocol describes the immunolabeling-assisted visualization of RABV infection in solvent-cleared brain tissue.

There are several critical steps in the preparation and acquisition of the image stacks of immunolabeled, solvent-cleared tissue. Prolonged exposure to PFA can mask epitopes and, thus, result in decreased antigenicity20,21,22. It is, therefore, important to limit the fixation times to the necessary minimum and transfer the samples to an appropriate solution (e.g., PBS supplemented with 0.02% NaN3 for long-term storage). However, all representative images and projections provided here have been acquired from archived brain samples, some of which had been stored in PFA for weeks, highlighting the applicability of the technique to organ material that has been exposed to PFA for extended periods of time. Similar results have been shown for human brain samples13. Another, if not the most, critical step is the antibody incubation. Antibody concentrations have to be chosen carefully. While in most cases, standard IHC concentrations are a good starting point for deep-tissue antibody labeling, some antigens may require additional optimization of the antibody concentration. This protocol demonstrates that both RABV N and P are readily detectable by the used antibodies. While MeOH pretreatment usually improves immunolabeling, some antigens are incompatible with this treatment. For those, Renier and colleagues14 provided an alternative MeOH-free sample pretreatment. Analysis of the acquired image stacks requires adequate computational power. Because of the large file sizes of up to several gigabytes per stack, powerful computers are needed to process the images. Postprocessing often includes the subtraction of background noise and a bleach correction to compensate for acquisition-associated bleaching effects. When measuring distances, it has to be kept in mind that, as a side effect, the tissue is shrinking during the clearing process.

In comparison to other microscopy platforms, like light sheet fluorescence microscopy (LSFM) or two-photon laser scanning microscopy (2PLSM), CLSM has the most limited working distance. Therefore, it is necessary to preslice organs to 1 mm in thickness for imaging. Additionally, CLSM has the slowest acquisition speed because of its high imaging resolution. The use of a light sheet microscope would allow for faster imaging of larger volumes up to whole-brain imaging, while simultaneously sacrificing image resolution. Another limitation is the inherent increase of tissue autofluorescence with decreasing wavelength. This renders the use of fluorophores and dyes excited by the laser line at 405 nm, including Hoechst dyes, impractical to impossible.

With respect to other tissue clearing techniques, the hybrid of iDISCO14 and uDISCO13 combines the most positive attributes: it is highly compatible with immunostaining, highly versatile, comparatively fast and inexpensive, it has excellent clearing capabilities, and it is feasible with a standard confocal microscope. Moreover, this protocol is not restricted to the immunostaining and clearing of brain tissue but can also be applied to a variety of other soft tissues and pathogens, both neuroinvasive and non-neuroinvasive. In conclusion, the protocol described here represents a pipeline for high-resolution 3D imaging of RABV-infected brain tissue. The 3D reconstructions of infected brain tissue can be used to answer a variety of questions concerning RABV disease progression, pathogenesis, and neuroinvasion.

Divulgazioni

The authors have nothing to disclose.

Acknowledgements

The authors thank Thomas C. Mettenleiter and Verena te Kamp for critically reading the manuscript. This work was supported by the Federal Excellence Initiative of Mecklenburg Western Pomerania and the European Social Fund (ESF) Grant KoInfekt (ESF/14-BM-A55-0002/16) and an intramural collaborative research grant on Lyssaviruses at the Friedrich-Loeffler-Institute (Ri-0372).

Materials

Reagents
Benzyl alcohol Alfa Aesar 41218 Clearing reagent
Benzyl benzoate Sigma-Aldrich BB6630-500ML Clearing reagent
Dimethyl sulfoxide Carl Roth 4720.2 Various buffers
Diphenyl ether Sigma-Aldrich 240834-100G Clearing reagent
DL-α-Tocopherol Alfa Aesar A17039 Antioxidant
Donkey serum Bio-Rad C06SBZ Blocking reagent
Glycine Carl Roth 3908.2 Background reduction
Goat serum Merck S26-100ML Blocking reagent
Heparin sodium salt Carl Roth 7692.1 Background reduction
Hydrogen peroxide solution (30 %) Carl Roth 8070.2 Sample bleaching
Methanol Carl Roth 4627.4 Sample pretreatment
Paraformaldehyde Carl Roth 0335.3 Crystalline powder to make fixative solution
Sodium azide Carl Roth K305.1 Prevention of microbial growth in stock solutions
tert-Butanol Alfa Aesar 33278 Sample dehydration for tissue clearing
TO-PRO-3 Thermo Fisher T3605 Nucleic acid stain
Triton X-100 Carl Roth 3051.2 Detergent
Tween 20 AppliChem A4974,0500 Detergent
Miscellaneous
5 mL reaction tubes Eppendorf 0030119401 Sample tubes
Coverslip, circular (diameter: 22 mm) Marienfeld 0111620 Part of imaging chamber
Coverslip, circular (diameter: 30 mm) Marienfeld 0111700 Part of imaging chamber
Hypodermic needle (27 G x ¾” [0.40 mm x 20 mm]) B. Braun 4657705 Filling of the imaging chamber with clearing solution
RTV-1 silicone rubber Wacker Elastosil E43 Adhesive for the assembly of the imaging chamber
Ultimaker CPE 2.85 mm transparent Ultimaker 8718836374869 Copolyester filament for 3D printer to print parts of the imaging chamber
Technical equipment and software
3D printer Ultimaker Ultimaker 2+ Printing of imaging chamber
Automated water immersion system Leica 15640019 Software-controlled water pump
Benchtop orbital shaker Elmi DOS-20M Sample incubation at room temperature (~ 150 rpm)
Benchtop orbital shaker, heated New Brunswick Scientific G24 Environmental Shaker Sample incubation at 37 °C (~ 150 rpm)
Confocal laser scanning microscope Leica DMI 6000 TCS SP5 Inverted confocal microscope for sample imaging
Fiji NIH (ImageJ) open source software (v1.52h) Image processing package based on ImageJ
Long working distance water immersion objective Leica 15506360 HC PL APO 40x/1.10 W motCORR CS2
Vibratome Leica VT1200S Sample slicing
Workstation Dell Precision 7920 CPU: Intel Xeon Gold 5118
GPU: Nvidia Quadro P5000
RAM: 128 GB 2666 MHz DDR4
SSD: 2 TB
Primary antibodies
Goat anti-RABV N Friedrich-Loeffler-Institut Monospecific polyclonal goat anti-RABV N serum, generated by goat immunization with baculovirus-expressed and His-tag-purified RABV nucleoprotein N
Dilution: 1:400
Rabbit anti-GFAP Dako Z0334 Polyclonal antibody (RRID:AB_10013382)
Dilution: 1:100
Rabbit anti-MAP2 Abcam ab32454 Polyclonal antibody (RRID:AB_776174)
Dilution: 1:250
Rabbit anti-RABV P 160-5 Friedrich-Loeffler-Institut Monospecific polyclonal rabbit anti-RABV P serum, generated by rabbit immunization with baculovirus-expressed and His-tag-purified RABV phosphoprotein P (see reference 23: Orbanz et al., 2010)
Dilution: 1:1,000
Secondary antibodies
Donkey anti-goat IgG Thermo Fisher Scientific depending on conjugated fluorophore Highly cross-absorbed
Dilution: 1:500
Donkey anti-mouse IgG Thermo Fisher Scientific depending on conjugated fluorophore Highly cross-absorbed
Dilution: 1:500
Donkey anti-rabbit IgG Thermo Fisher Scientific depending on conjugated fluorophore Highly cross-absorbed
Dilution: 1:500
Goat anti-mouse IgG Thermo Fisher Scientific depending on conjugated fluorophore Highly cross-absorbed
Dilution: 1:500
Goat anti-rabbit IgG Thermo Fisher Scientific depending on conjugated fluorophore Highly cross-absorbed
Dilution: 1:500

Riferimenti

  1. Pichat, J., Iglesias, J. E., Yousry, T., Ourselin, S., Modat, M. A Survey of Methods for 3D Histology Reconstruction. Medical Image Analysis. 46, 73-105 (2018).
  2. Chung, K., et al. Structural and molecular interrogation of intact biological systems. Nature. 497 (7449), 332-337 (2013).
  3. Hama, H., et al. ScaleS: an optical clearing palette for biological imaging. Nature Neuroscience. 18 (10), 1518-1529 (2015).
  4. Ke, M. T., Fujimoto, S., Imai, T. SeeDB: a simple and morphology-preserving optical clearing agent for neuronal circuit reconstruction. Nature Neuroscience. 16 (8), 1154-1161 (2013).
  5. Kuwajima, T., et al. ClearT: a detergent- and solvent-free clearing method for neuronal and non-neuronal tissue. Development. 140 (6), 1364-1368 (2013).
  6. Susaki, E. A., et al. Whole-brain imaging with single-cell resolution using chemical cocktails and computational analysis. Cell. 157 (3), 726-739 (2014).
  7. Susaki, E. A., et al. Advanced CUBIC protocols for whole-brain and whole-body clearing and imaging. Nature Protocols. 10 (11), 1709-1727 (2015).
  8. Yang, B., et al. Single-cell phenotyping within transparent intact tissue through whole-body clearing. Cell. 158 (4), 945-958 (2014).
  9. Treweek, J. B., et al. Whole-body tissue stabilization and selective extractions via tissue-hydrogel hybrids for high-resolution intact circuit mapping and phenotyping. Nature Protocols. 10 (11), 1860-1896 (2015).
  10. Dodt, H. U., et al. Ultramicroscopy: three-dimensional visualization of neuronal networks in the whole mouse brain. Nature Methods. 4 (4), 331-336 (2007).
  11. Erturk, A., et al. Three-dimensional imaging of the unsectioned adult spinal cord to assess axon regeneration and glial responses after injury. Nature Medicine. 18 (1), 166-171 (2011).
  12. Erturk, A., et al. Three-dimensional imaging of solvent-cleared organs using 3DISCO. Nature Protocols. 7 (11), 1983-1995 (2012).
  13. Pan, C., et al. Shrinkage-mediated imaging of entire organs and organisms using uDISCO. Nature Methods. 13 (10), 859-867 (2016).
  14. Renier, N., et al. iDISCO: a simple, rapid method to immunolabel large tissue samples for volume imaging. Cell. 159 (4), 896-910 (2014).
  15. Masland, R. H. Neuronal cell types. Current Biology. 14 (13), 497-500 (2004).
  16. von Bartheld, C. S., Bahney, J., Herculano-Houzel, S. The search for true numbers of neurons and glial cells in the human brain: A review of 150 years of cell counting. The Journal of Comparative Neurology. 524 (18), 3865-3895 (2016).
  17. Fooks, A. R., et al. Rabies. Nature Reviews Disease Primers. 3, 17091 (2017).
  18. WHO. WHO Expert Consultation on Rabies, Third Report. WHO Technical Report Series. , (2018).
  19. CDC. . Biosafety in Microbiological and Biomedical Laboratories, 5th Edition. US Department of Health and Human Services. , (2009).
  20. Arnold, M. M., et al. Effects of fixation and tissue processing on immunohistochemical demonstration of specific antigens. Biotechnic & Histochemistry. 71 (5), 224-230 (1996).
  21. Webster, J. D., Miller, M. A., Dusold, D., Ramos-Vara, J. Effects of prolonged formalin fixation on diagnostic immunohistochemistry in domestic animals. Journal of Histochemistry and Cytochemistry. 57 (8), 753-761 (2009).
  22. Werner, M., Chott, A., Fabiano, A., Battifora, H. Effect of formalin tissue fixation and processing on immunohistochemistry. The American Journal of Surgical Pathology. 24 (7), 1016-1019 (2000).
  23. Orbanz, J., Finke, S. Generation of recombinant European bat lyssavirus type 1 and inter-genotypic compatibility of lyssavirus genotype 1 and 5 antigenome promoters. Archives of Virology. 155 (10), 1631-1641 (2010).

Play Video

Citazione di questo articolo
Zaeck, L., Potratz, M., Freuling, C. M., Müller, T., Finke, S. High-Resolution 3D Imaging of Rabies Virus Infection in Solvent-Cleared Brain Tissue. J. Vis. Exp. (146), e59402, doi:10.3791/59402 (2019).

View Video