Summary

Serial Block-Face Scanning Electron Microscopy (SBEM) for the Study of Dendritic Spines

Published: October 02, 2021
doi:

Summary

Serial Block-Face Scanning Electron Microscopy (SBEM) is applied to image and analyze dendritic spines in the murine hippocampus.

Abstract

Three-dimensional electron microscopy (3D EM) gives a possibility to analyze morphological parameters of dendritic spines with nanoscale resolution. In addition, some features of dendritic spines, such as volume of the spine and post-synaptic density (PSD) (representing post-synaptic part of the synapse), presence of presynaptic terminal, and smooth endoplasmic reticulum or atypical form of PSD (e.g., multi-innervated spines), can be observed only with 3D EM. By employing serial block-face scanning electron microscopy (SBEM) it is possible to obtain 3D EM data easier and in a more reproducible manner than when performing traditional serial sectioning. Here we show how to prepare mouse hippocampal samples for SBEM analysis and how this protocol can be combined with immunofluorescence study of dendritic spines. Mild fixation perfusion allows us to perform immunofluorescence studies with light microscopy on one half of the brain, while the other half was prepared for SBEM. This approach reduces the number of animals to be used for the study.

Introduction

Most of the excitatory synapses in the central nervous system are located on dendritic spines – small protrusions of a neuronal membrane. These protrusions form confined biochemical compartments that control intracellular signal transduction. Structural plasticity of dendritic spines and synapses is closely related to the functional changes in synaptic efficacy that underlie such important processes as learning and memory1,2. It is important to note that electron microscopy (EM) is the only technique that allows to determine if a dendritic spine has a presynaptic input. EM resolution is also needed to study ultrastructural details such as shape of a postsynaptic density (PSD), representing a postsynaptic part of a synapse, or dimensions of a dendritic spine, as well as the size and shape of an axonal bouton. Additionally, with EM it is possible to visualize synapses and their surroundings.

Thanks to advances in imaging and computing technologies it is possible to reconstruct entire neural circuits. Volume electron microscopy techniques, such as serial section transmission electron microscopy (ssTEM), serial block-face scanning electron microscopy (SBEM), and focused ion beam scanning electron microscopy (FIB-SEM) are commonly used for neuronal circuit reconstructions3.

In our studies, the SBEM method is successfully employed to investigate the structural plasticity of dendritic spines and PSDs in samples of the mouse hippocampus and organotypic brain slices 4,5. The SBEM is based on the installation of a miniature ultramicrotome inside the scanning electron microscope chamber6,7,8,9. The top of the sample block is imaged, and then the sample is cut at a specified depth by the ultramicrotome, revealing a new block-face, which is again imaged and then the process is repeated8. As a result, only the image of a block-face is left while the slice which has been cut is lost as debris. That is why SBEM is called a destructive technique, meaning it is not possible to image the same place again. However, the advantage of the destructive on-block methods is that they do not suffer from warping problems and section loss that can significantly affect the data quality and the data analysis3. Moreover, SBEM gives the possibility to image a relatively large field of view ( > 0.5 mm × 0.5 mm) at high resolution3.

To employ SBEM, samples have to be prepared according to a dedicated, highly contrasting protocol due to the backscattered electron detector used for acquiring images. We show here how to perform sample preparation according to the protocol based on a procedure developed by Deerinck10 (National Center for Microscopy and Imaging Research (NCMIR) method), using reduced osmium-thiocarbohydrazide-osmium (rOTO) stains developed in the 1980s8,11. In addition, we introduce a two-step fixation approach, with mild fixation perfusion that allows to use the same brain both for immunofluorescence studies with light microscopy and SBEM.

In the protocol a mouse brain is primarily fixed with a mild fixative, and then cut into halves, and one hemisphere is postfixed and prepared for immunofluorescence (IF), while the other for EM studies (Figure 1).

Figure 1
Figure 1. Schematic representation of the workflow for the dendritic spines preparation for the analysis with SBEM. Mice were sacrificed and perfused with a mild primary fixative. The brain was cut into halves, and one hemisphere was postfixed with immunofluorescence (IF)-dedicated fixative, cryoprotected, sliced using a cryostat and processed for IF studies, while the other hemisphere was postfixed with EM fixative, sliced with the vibratome and prepared for EM studies. Brain slices for SBEM studies were contrasted, flat embedded in resin, then a CA1 region of the hippocampus was mounted to the pin, and imaged with SBEM (Figure 1). The part of the protocol highlighted in a yellow box was featured in the video. Please click here to view a larger version of this figure.

Protocol

The research was performed in compliance with Nencki Institute guidelines and permission of the Local Ethical Committee. The studies were carried out in accordance with the European Communities Council Directive of 24 November 1986 (86/609/EEC), Animal Protection Act of Poland and approved by the first Local Ethics Committee in Warsaw. All efforts were made to minimize the number of animals used and their suffering.

CAUTION: All procedures described below must be carried out in a laboratory fume hood. Due to the hazardous nature of the reagents used. Personal safety measures such as gloves, lab coat, safety glasses and a face mask are required.

1. Preparation of the fixative for perfusion (2% wt/vol paraformaldehyde (PFA) and 0.5% vol/vol glutaraldehyde (GA) in 0.1 M phosphate buffer (PB), pH 7.4)

NOTE: Prepare the fixative solution on the same day as it will be used and do not store it longer than for 3 hours. In case of time shortage, prepare 2% PFA in 0.1 M PB the day before, store it at 4 °C and add fresh GA shortly before the perfusion.

  1. Take 400 mL of sterile double distilled water (ddH2O) and heat it to 60 °C using a stirring hot plate. Then add 20 g of PFA. Add drops of 1 M NaOH until PFA is fully dissolved and allow the mixture to cool down.
  2. Add 500 mL of 0.2 M PB (pH 7.4).
  3. Filter the solution to remove any deposit and cool it to 4 °C.
  4. Just before perfusion, add 20 mL of 25% GA to the solution and then top up the volume with ddH2O to 1 L.

2. Preparation of postperfusion fixative for SBEM (2% wt/vol PFA and 2.5% vol/vol GA in 0.1 M PB, pH 7.4)

  1. Take 50 mL of the fixative for perfusion (2% PFA and 0.5% GA in 0.1 M PB).
  2. Add 5 mL of 25% GA.

3. Preparation of postperfusion fixative for IF staining (4% PFA in phosphate buffered saline (PBS))

  1. Dissolve a tablet of 1x PBS (pH 7.4) in a purified and deionized water (H2O) according to manufacturer instructions.
  2. Use a stirring hot plate to heat the solution to 60 °C and add 40 g of PFA.
  3. Add drops of 1 M NaOH until the PFA is fully dissolved and allow the mixture to cool.
  4. Adjust the pH of the solution to 7.5 with 1 M HCl then top up the volume with H2O to 1 L.
  5. Filter the solution to remove any deposits.

4. Transcardial perfusion of animals

NOTE: All PFA and GA wastes must be collected and stored for disposal according to the local regulations. Anesthesia and perfusion should follow the local regulations. In the described protocol adult 3-month-old and 20±1-month-old female Thy1-GFP(M) mice (Thy1-GFP +/-)12 expressing green fluorescence protein (GFP) in a sparsely distributed population of glutamatergic neurons were used but any other can be used as well. Animals were bred as heterozygotes with the C57BL/6J background in the Animal House of the Nencki Institute of Experimental Biology.

  1. Before perfusion anesthetize a mouse by administration of a ketamine/xylazine mixture (up to 90 mg/kg body weight ketamine and 10 mg/kg body weight xylazine) via intraperitoneal injection (27-gauge needle).
    1. Assess whether the depth of anesthesia is sufficient by checking the reflex to pain stimuli (pinching) and the corneal reflex (squinting).
  2. After 20 minutes perform an intraperitoneal injection (27-gauge needle) of sodium pentobarbital (50 mg/kg body weight).
  3. Perfuse a mouse according to a perfusion surgery protocol described by Gage et al.13 (see point 4; Figure 5-6). Using a perfusion pump start with a 0.1 M phosphate buffer, pH 7.4 (30 mL) for 3 minutes and continue with 2% PFA and 0.5% GA in 0.1 M PB, pH 7.4 for 6 minutes (80 mL).
    1. Gently dissect the brain from the skull and divide it in half (see Figure 9-10 in Gage et al., 201213). Place one piece in a vial containing fixative for SBEM and the second into the vial with 4% PFA/PBS for IF staining.
    2. Keep the hemispheres in the fixative at 4 °C overnight.

5. Brain slices preparation for electron microscopy

  1. Choose the vibratome settings (blade travel speed: 0.075 mm/s, cutting frequency: 80 Hz).
  2. Place the slice chamber into the holder, attach it to the vibratome and surround it with ice. Then place a razor blade into the vibratome blade holder.
  3. Use a spoon, or similar object and place the chilled brain (dorsal surface up) on a tough cutting surface (e.g., a glass Petri dish lid). To prepare a coronal slice of the hippocampus make a perpendicular cut between the cerebral hemisphere and the cerebellum with a razor blade or scalpel, thus removing the cerebellum. The olfactory bulb can also be removed.
  4. Apply cyanoacrylate glue on the dry platform of the vibratome.
  5. Pick up the brain with forceps and carefully dry it on filter paper.
  6. Glue the hemisphere to the platform close to the cutting blade with the rostral tip upwards. Attach the platform to the holder and immediately fill it up with ice-cold 0.1 M PB, pH 7.4. If the perpendicular cut is properly made, the hemisphere will stand straight up providing 90° angle required to make a symmetric coronal cut containing the hippocampus. Assure that the brain is covered with PB.
  7. Position the vibratome blade in front of the hemisphere and lower it to the coronal side of the hemisphere. Lower the blade to 400 µm further in the caudal direction and start slicing. Continue slicing until the first two slices are completely separated from the tissue block.
  8. Retract the blade and lower another 100 µm, then slice again.
  9. When the hippocampus becomes visible (use the mouse brain atlas Paxinos and Franklin, 200414) collect the slices with the small paintbrush or widened plastic Pasteur pipette.
  10. Transfer the slices into a 12-well plate filled with cold 0.1 M PB, pH 7.4.
  11. Dissect the hippocampus in a glass Petri dish filled with 0.1 M PB, pH 7.4 using a razor blade or scalpel, and put it into glass vials with the same phosphate buffer.
    ​NOTE: For long-term storage of the slices supplement 0.1 M PB with 0.05% sodium azide (NaN3).

6. Brain sample preparation for immunostaining

  1. After overnight fixation in 4% PFA/PBS solution in a fume hood, put the brain tissue into the cryopreservation solution (30% sucrose in PBS with 0.05% NaN3) and keep it at 4 °C for 2 days (until sunk).
  2. Prepare an antifreeze solution (15% sucrose/30% ethylene glycol/0.05% NaN3/PBS).
  3. Set the cabinet temperature of the cryostat at -19 °C and make sure that the temperature is reached before proceeding further. During sectioning, ensure that the cabinet temperature remains between -18 °C and -20 °C.
  4. Use a spoon, or similar object and place the chilled brain (dorsal surface up) on a tough cutting surface (e.g., a glass Petri dish lid). To prepare a coronal slice of the hippocampus make a perpendicular cut between the cerebral hemisphere and the cerebellum with a razor blade or scalpel, thus removing the cerebellum.
  5. Select a pre-cooled specimen disc, cover it with a medium for freezing on a freeing shelf and using forceps fix the hemisphere to the disc with a rostral tip upwards and wait until the specimen is completely frozen. Insert the specimen disc into a specimen head.
  6. Install a blade in a blade holder inside the cryo-chamber and cut 40 µm thick slices.
  7. Transfer slices with a small paintbrush to the 96-well plate filled with cold anti-freeze solution and gently unroll the sections (collect a slice after each round of slicing to prevent them from getting lost in the slice chamber).
    ​NOTE: Brains or sections can be stored in an antifreeze solution at -20 °C for a long time.

7. Immunostaining of brain slices

NOTE: All staining steps were performed in a 24-well plate on a platform shaker.

  1. Wash the slices with PBS three times, each time for 6 minutes.
  2. Incubate slices in 300 µL of blocking solution (5% normal donkey serum (NDS)/0.3% Triton X-100) for 1 hour with gentle shaking on a rotator.
  3. Incubate the slices with the primary antibody against PSD-95 diluted 1:500 in 5% NDS/0.3% Triton X-100/PBS (300 µL per well) overnight at 4 °C. The final concentration of the primary antibody is 2 µg/mL.
  4. Wash the slices with 0.3% Triton X-100/PBS at room temperature (RT) three times, each time for 6 minutes.
  5. Incubate slices with the secondary antibody diluted 1:500 in 300 µL of 0.3% Triton X-100/PBS for 90 minutes. The final concentration of the secondary antibody is 4 µg /mL.
  6. Wash the slices with PBS three times, each time for 6 minutes.
  7. Mount the slices on slides using a mounting medium and then close them with a cover slide.
  8. Examine the specimens using a confocal microscope (63 × oil objective, NA 1.4, pixel size 0.13 µm × 0.13 µm).
    ​NOTE: For long-term storage: keep the samples at 4 °C, protect them from light.

8. SBEM sample preparation

CAUTION: Due to the hazardous nature of reagents used all the procedures described below must be carried out in a laboratory fume hood. Before using these chemicals read carefully the Material Safety Data Sheets provided by the manufacturers and ask the safety officer about the local rules to ensure safe handling and waste disposal.

  1. Sample contrasting
    NOTE: Slices washings and room temperature incubation should be carried out with mild shaking (e.g., on a platform shaker). Autoclave degassed water was used.
    1. Wash the slices with cold 0.1 M PB, pH 7.4 five times, each time for 3 minutes.
    2. Prepare a 1:1 mixture of 4% aqueous osmium tetroxide and 3% potassium ferrocyanide (1:1 by vol). The final product will turn brown. Immerse the samples in this mixture, place them on ice, and from this stage onwards it is important to protect them from light. Incubate them with gentle shaking for 1 hour.
    3. Meanwhile prepare a thiocarbohydrazide (TCH) solution. Mix 10 mL of double-distilled H2O (ddH2O) and 0.1 g of TCH and place it into an oven set at 60 °C for 1 hour. It is important to swirl the solution from time to time (e.g., every 10 minutes). When ready, cool it to room temperature.
    4. Wash the slices with ddH2O five times, each time for 3 minutes.
    5. Filter TCH solution using a 0.22 µm syringe filter and immerse the sample in filtered solution. The slices will turn black. Incubate them for 20 minutes at room temperature.
    6. Wash the samples with ddH2O five times, each time for 3 minutes.
    7. Incubate the samples with a 2% aqueous solution of OsO4 for 30 minutes at room temperature.
    8. Wash the samples with ddH2O five times, each time for 3 minutes.
    9. Place the samples in filtered 1% aqueous uranyl acetate and incubate them at 4 °C overnight. Use 0.22 µm syringe filter for filtration.
    10. Prepare L-aspartic acid solution by mixing 0.4 g of L-aspartic acid and 80 mL of ddH2O, adjust the pH to 3.8 for easier dissolving, and then top up with water to 100 mL.
    11. Next day, begin with Walton's lead aspartate15 preparation. Mix 0.066 g of lead nitrate with 10 mL of L-aspartic acid solution (point 8.1.10) pre-warmed to 60 °C and adjust pH to 5.5 (measured at 60 °C) with 1 M NaOH. Close the vial with lead aspartate and leave it at 60 °C for 30 minutes in a water bath. The solution should be clear. If it turns cloudy, it must be discarded and a new one needs to be prepared.
    12. In the meantime, wash the samples with degassed ddH2O five times, each time for 3 minutes. Then keep them in the oven set at 60 °C for 30 minutes.
    13. Immerse the samples in the freshly prepared lead aspartate solution and incubate them in the oven set at 60 °C for 20 minutes.
    14. Wash the samples with degassed ddH2O five times, each time for 3 minutes.
  2. Dehydration and resin embedding
    1. Prepare epoxy resin. Weigh the ingredients (33.3 g of component A/M, 33.3 g of component B, and 1 g of component D) and mix the resin well (e.g., shake it on a rotary shaker in a 15 mL tube) for at least 30 minutes before adding 16 drops of accelerator DMP 30. Stir again for another 10 minutes.
      NOTE: Weigh the ingredients under the fume hood. This amount of components gives approximately 60 mL of resin what is enough for 15 vials with samples. You can prepare less or store the rest of the resin in a syringe at 4 °C and utilize it the next day. Remember to seal the tip of the syringe.
    2. Prepare vials with graded dilutions of ethanol (30%, 50%, 70%, 90%, 100%, 100% ethanol in water and 100% dried on a molecular sieve).
    3. Mix the resin with 100% ethanol in 1:1 proportion to obtain 50% resin. Mix it well.
    4. Dehydrate the samples for 5 minutes in each dilution of ethanol starting from 30% and ending with 100% anhydrous ethanol dried on molecular sieve. Remember, the samples must never dry completely.
    5. Infiltrate the samples first in 50% resin for 30 minutes, next in 100% resin for one hour, and then again in 100% resin overnight. Perform all infiltration steps with constant slow shaking.
    6. The next day, place the samples in fresh 100% resin for one hour and then embed them between fluoropolymer embedding sheets. Degrease pieces of embedding sheet with ethanol, and flat embed the samples between two layers of it, using two glass slides as support. Try to avoid air bubbles in resin on or close to the sample.
    7. Cure the samples in the oven at 70 °C for at least 48 hours.
  3. Trimming and mounting
    1. Separate embedding sheets and cut a piece of the embedded sample (approximately 1 mm x 1 mm) with a razor blade. Transfer it to a parafilm. This will minimize the danger of losing the sample due to electrostatics.
    2. Take an aluminum pin that has been degreased with ethanol. Mix a conductive epoxy well and use a little amount of it to mount the sample to the pin. Cure conductive epoxy at 70 °C for 10 minutes.
    3. Trim each side of the sample block with the diamond knife and then polish the face of the block until the tissue is exposed.
      NOTE: At this step, confirm the presence of a region of interest by collecting some sections and performing toluidine blue staining16 or checking under the electron microscope.
    4. Reduce the size of the sample as much as possible. Then ground the sample to the pin with conductive paint and cure it (for 24 hours at room temperature or in the oven at 65 °C for 40 minutes).
    5. To minimize charging artifacts, sputter coat the samples with a thin layer of gold or gold/palladium.

9. SBEM imaging

  1. Place the pin with a sample into the chamber of the serial block-face scanning electron microscope. Align the sample to the knife. Close the chamber and set the parameters.
  2. Collect a stack of images at desired magnification, pixel size, slice thickness, accelerated voltage (EHT), aperture, pressure, etc.
    ​NOTE: The parameters depend on the sample and the goal of the experiment. Exemplary initial imaging settings are included in the table of materials.

10. 3D reconstructions

NOTE: For the steps mentioned below we use open-access software e.g. FijiJ17 (ImageJ version 1.49b), Microscopy Image Browser (MIB)18 and Reconstruct19 but various other software can be employed.

  1. Convert digital micrograph (dm) files into TIFF format. First import the image sequence (in FijiJ: File > Import > Image sequence > Choose 8 Bit Format) and then save as TIFF (in FijiJ: File > Save As > Image Sequence > Choose Tiff).
  2. Adjust brightness and contrast of the stack of images (in FijiJ: Image > Adjust > Brightness/Contrast) and, if necessary, denoise it (use DenoisEM plugin for FijJ20 : Plugins > DenoiseEM > Denoise).
  3. Align the stack (in FijiJ: Plugins > StagReg or MIB: Dataset > Alignment Tools).
  4. Segment dendritic spines and synapses (In MIB or Reconstruct software, comprehensive tutorials are available (See Table of Materials for details).

Representative Results

Using the method described above high contrast, good resolution images of the mouse brain tissue can be obtained. A large field of view provided by the SBEM technique facilitates precise selection of the region of interest. The large image of the CA1 region of the hippocampus was taken to measure the length of stratum radiatum (SR) (Figure 2A) and to set the imaging precisely in the center (Figure 2B). Next, the stack of images was acquired and the objects of interest, such as dendrites, dendritic spines, postsynaptic densities of the synapses were segmented (Figure 2C,D).

The use of the SBEM technique gives the possibility to analyze a relatively large volume of tissue and to recognize rare events such as a multi-innervated dendritic spine (Figure 2E) – a particular type of synapses that is characterized by several presynaptic terminals contacting the same postsynaptic spine21.

Figure 2
Figure 2. Dendritic spines in mouse hippocampus CA1 region. Representative image of mouse hippocampal CA1 region. Stratum radiatum (SR) is shown with a white arrow (A). The region in the middle of SR was chosen for imaging (B). Reconstruction of a piece of dendrite with dendritic spines (C). Reconstruction of dendritic spines in a volume of tissue (D). Reconstruction of a multi-innervated dendritic spine (E). Two presynaptic terminals contacting the same postsynaptic spine are shown (in magenta and green). Please click here to view a larger version of this figure.

The presented protocol for SBEM sample preparation allowed us to obtain high-quality images of the brain tissue with heavily contrasted membranes, which enables easier segmentation and reconstruction of membrane surrounded structures. The standard fixation with the higher concentration of PFA (Figure 3B) and the two-step fixation approach resulted in similar tissue morphology (Figure 3A).

Figure 3
Figure 3. Morphological details. With the use of the protocol presented here good quality images showing the morphology of synaptic vesicles, PSD and mitochondria were obtained. Brain tissue fixed with two-step approach (A) or with a standard fixative (B). Scale bar 2 µm. Please click here to view a larger version of this figure.

The results are reproducible, meaning that every specimen prepared using this protocol, not only brain tissue but also the monolayer of cultured cells, was well contrasted.

The use of mild primary fixation offers the opportunity to use the tissue also for immunofluorescence studies involving a light microscope. In the case of the PSD-95 antibody, we did not observe the difference in immunostaining results between the samples fixed with two-step fixation (mild primary and then secondary with a traditional fixative) and the one obtained using traditional fixation with 4% PFA only (Figure 4A and 4B, respectively).

Figure 4
Figure 4. Comparison of PSD-95 immunofluorescence in samples fixed with various protocols. Representative microphotographs of PSD-95 immunostaining in the stratum radiatum layer of CA1 area in the dorsal hippocampus. (A) Confocal image after mild primary fixation followed by postfixation with a standard fixative. (B) Confocal image after standard, stronger fixation. Scale bars: 5 µm. Please click here to view a larger version of this figure.

Discussion

There are many variations of the primary NCMIR method described by Deerinck in 201010. The basic principles remain the same but, depending on the type of material studied, slight changes are implemented. It was described previously that different resins can be used to embed specimens for SBEM and for example in the case of plants, Spurr's is the resin of choice due to its low viscosity that allows better infiltration through the cell walls22,23. Moreover, various buffers can be applied for fixation (e.g., cacodylate buffer, HEPES, or phosphate buffer as well as a different concentration of glutaraldehyde (2-3%) and paraformaldehyde (2-4%)23,24,25,26,27,28). The use of tannic acid to enhance staining of samples rich in extracellular matrix29 or ruthenium red to improve staining of plant material23,30 are another amendments that can be used. As far as dehydration is concerned usually ethanol and/or acetone are recommended for epoxy resin24,28.

The same protocol as described here, or very similar, has been successfully used before by our team and other groups4,5,24. Samples processed according to this method are compatible with TEM imaging31. In comparison with the original NCMIR protocol published in 201010 we introduce some minor changes such as replacement of toxic cacodylate buffer during fixation and osmium post-fixation step with a phosphate buffer. As mentioned above, diverse buffers can be used during EM preparation, and according to our experience, non-toxic PB gives satisfactory results.

Another change is a replacement of acetone with less user-harmful ethanol during the last step of dehydration. Ethanol was also used as a resin solvent during the embedding process. Moreover, DMP-30 was used instead of epoxy resin component C, as published before32,33.

Due to the need to use the same brains for immunofluorescence studies the two-step fixation approach was introduced. First, the animals were perfused with a buffer containing a lower concentration of glutaraldehyde (mild primary fixation by perfusion with a buffer containing 2% PFA and 0.5% GA) and after that only half of the brain dedicated to EM was further postfixed with a higher concentration of glutaraldehyde (2% PFA and 2.5% GA), while the other half of the brain was postfixed with a standard fixative for immunostaining (4% PFA). The use of EM fixative with a lower concentration of PFA was published before by others and our group4,5,31,34. The two-step fixation presented here is as sufficient as a traditional one-step approach (Figure 3 and Figure 4). However, since we propose that each half of the brain can be processed separately, our protocol allows to reduce the number of animals used. Mild primary fixation successfully maintains tissue antigenicity, enabling further immunofluorescence as demonstrated for the antibody against PSD-95 protein. It has to be emphasized, however, that the utility of our approach has to be validated for other antibodies.

The presented method results in high contrast images of the brain tissue with clearly visible membranes. It is worth mentioning, however, that there are the same steps prone to failure, as in the case of any other method of SBEM sample preparation, and particular attention needs to be paid to them. The quality of the tissue morphology itself depends mostly on the perfusion. It is a critical step, as only successfully fixed specimens give satisfactory results. Unfortunately, fixation perfusion is influenced by individual variability among animals, thus the quality of images may vary from one animal to another. Moreover, one has to be careful not to dry the specimen during dehydration; otherwise, the sample will not be infiltrated properly with the resin. Another important aspect is sample mounting to the pin. The epoxy resins are nonconductive, and therefore they accumulate electrons during imaging what causes charging artifacts. To reduce the charging effect in SBEM, it is necessary to carefully remove excess of resin at every side of the specimen and accurately ground the sample with silver paint and sputter coating.

The current protocol focuses on brain tissue; however, it can be adapted for cell monolayer, organotypic slices, or other tissues. Like the original NCMIR protocol, the one presented here results in highly contrasted samples that are suitable not only for SBEM, but also for FIB-SEM and ATUM-SEM experiments.

Disclosures

The authors have nothing to disclose.

Acknowledgements

SBEM imaging, light microscopy imaging and electron microscopy sample preparation were performed with the use of the equipment of Laboratory of Imaging Tissue and Function which serves as an imaging core facility at the Nencki Institute of Experimental Biology.

For preparation of Figure 1, the image of a mouse (Souris_02), and a vial from the https://smart.servier.com/ was used.

This work was supported by the National Science Centre (Poland) Grant Opus (UMO-2018/31/B/NZ4/01603) awarded to KR.

Materials

Anesthetic:
Ketamine/xylazine mixture (Ketamina/Sedazin) Biowet Pulawy, Pulawy, Poland
Sodium pentobarbital (Morbital) Biowet Pulawy, Pulawy, Poland
Fixatives:
Glutaraldehyde (GA) Sigma-Aldrich,St. Louis, MI, USA G5882 Grade I, 25% in H2O, specially purified for use as an electron microscopy fixative
Hydrochloric acid (HCl) POCH, Gliwice, Poland 575283115 pure p.a.
Paraformaldehyde (PFA) Sigma-Aldrich,St. Louis, MI, USA 441244 prilled, 95%
Phosphate buffered saline (PBS), pH 7.4 Sigma-Aldrich,St. Louis, MI, USA P4417-50TAB tablets
Sodium hydroxide (NaOH) Sigma-Aldrich,St. Louis, MI, USA S5881 reagent grade, Equation98%, pellets (anhydrous)
Sodium phosphate dibasic (Na2HPO4) Sigma-Aldrich,St. Louis, MI, USA S3264
Sodium phosphate monobasic (NaH2PO4) Sigma-Aldrich,St. Louis, MI, USA S3139
Perfusion:
Large blunt/blunt curved scissors (~14.5 cm) Fine Science Tools, Foster City, CA, USA 14519-14
Micro-spatula (double 2" flat ends, one rounded, one tapered to 1/8") Fine Science Tools, Foster City, CA, USA 10091-12
Needle tip, 15 GA, blunt (perfusion needle) KD Medical GmbH Hospital Products, Berlin, Germany KD-FINE 900413 1.80 x 40 mm
Pair of fine (Graefe) tweezers Fine Science Tools, Foster City, CA, USA 11050-10
Perfusion pump Lead Fluid BQ80S
Plastic vials Profilab, Warsaw, Poland 534.02 plastic vials with blue cap for tissue storage, 20 ml, 31 x 48 mm
Straight iris scissors (~9 cm) Fine Science Tools, Foster City, CA, USA 14058-11
Brain slices preparation for EM:
12-well plate NEST, Rahway, NJ, USA 712001
Cyanoacrylic glue Fenedur, Montevideo, Uruguay
Glass vials Electron Microscopy Sciences, Hatfield, PA, USA 72632 20 ml Scintillation Vial, a pack of 100
Pasteur pipette VWR, Radnor, PA, USA 612-4545 LDPE, disposable, 7.5 ml
Razor blade Wilkinson Sword, London, UK Classic double edge safety razor blades
Scalpel blade Swann-Morton, Sheffield, UK No. 20
Vibratome Leica Microsystems, Vienna, Austria Leica VT1000 S
Brain slices preparation for IF:
96-well plate NEST, Rahway, NJ, USA 701101
Criostat Leica Microsystems, Vienna, Austria Leica CM 1950
Ethylene glycol Bioshop, Burlington, Canada ETH001
Low-profile disposable blade 819 Leica Biosystems Inc., USA 14035838925
Scalpel blade Swann-Morton, Sheffield, UK No. 20
Sodium azide (NaN3) POCH, Gliwice, Poland 792770426
Sucrose POCH, Gliwice, Poland 772090110
Tissue freezing medium for cryosectioning, OCT-Compound Leica Biosystems, Switzerland 14020108926
Immunostaining:
24-well plate NEST, Rahway, NJ, USA 702001
Anti-Post Synaptic Density Protein 95 Antibody Merck-Millipore, Burlington, MA, USA MAB1598
Confocal microscope Zeiss, Göttingen, Germany Zeiss Spinning Disc microscope (63 × oil objective, NA 1.4, pixel size 0.13 µm × 0.13 µm)
Cover slide Menzel Glaser, Braunschweig, Germany B-1231 24 x 60 mm
Donkey anti-Mouse IgG (H+L) Highly Cross-Adsorbed Secondary Antibody, Alexa Fluor 555 Invitrogen, Carlsbad, CA, USA A31570
Fluoromount-G Mounting Medium, with DAPI Invitrogen, Carlsbad, CA, USA 00-4959-52
Microscope slide Thermo Scientific, Waltham, MA, USA AGAA00008 SuperFrost
Normal donkey serum (NDS) Jackson ImmunoResearch Laboratories, West Grove, PA, USA 017-000-121
Shaker JWElectronic, Warsaw, Poland KL-942
TritonT X-100 Reagent Grade Bioshop, Burlington, Canada TRX506
Electron microsocpy sample preparation
Potassium hexacyanoferrate(II) trihydrate POCH, Gliwice, Poland 746980113
Aclar 33C Film Electron Microscopy Sciences, Hatfield, PA, USA 50425 Fluoropolymer Film embedding sheet
DMP-30, 2,4,6-Tris(dimethylaminomethyl)phenol Sigma-Aldrich,St. Louis, MI, USA T58203 Epoxy embedding medium accelerator
Durcupan ACM single component A, M Sigma-Aldrich,St. Louis, MI, USA 44611 Durcupan ACM single component A, M epoxy resin
Durcupan ACM single component B Sigma-Aldrich,St. Louis, MI, USA 44612 Durcupan ACM single component B, hardener 964
Durcupan ACM single component D Sigma-Aldrich,St. Louis, MI, USA 44614 Durcupan ACM single component D , plasticizer
Ethyl alcohol absolute POCH, Gliwice, Poland 64-17-5 Ethyl alcohol absolute 99.8 % pure P.A.-BASIC
Genlab laboratory oven Wolflabs, York, UK Mino/18/SS Oven Genlab MINO/18/SS 18l volume, no fan circulation, no digital display, standard temperature gradient, standard recovery rate, no timer, 250°C maximum temperature, 240V electrical supply
L-Aspartic acid Sigma-Aldrich,St. Louis, MI, USA A-9256 reagent grade, Equation98% (HPLC)
Lead (II) nitrate Sigma-Aldrich,St. Louis, MI, USA 467790 Equation99.95% trace metals basis
Osmium tetroxide Sigma-Aldrich,St. Louis, MI, USA 75632 for electron microscopy, 4% in H2O
pH meter Elmetron, Zabrze, Poland CP-5-5
Rotator BioSan, Józefów, Poland Multi Bio RS-24 rotator Multi Bio RS-24
Sodium hydroxide (NaOH) Sigma-Aldrich,St. Louis, MI, USA S5881 reagent grade, Equation98%, pellets (anhydrous)
Sunflower mini shaker Grant bio, Shepreth,UK PD-3D
Syringe filter Millipore, Burlington, MA, USA SLGP033NB 0,22 µm pore size
Thiocarbohydrazide Sigma-Aldrich,St. Louis, MI, USA 88535 purum p.a., for electron microscopy, Equation99.0% (N)
Uranyl acetate Serva, Heidelberg, Germany 77870 Uranyl acetate·2H2O, research grade
Water bath WSL, Swietochlowice, Poland LWT
Specimen mounting for SBEM
96-well culture plate VWR, Radnor, PA, USA 734-2782 96-well plates, round bottom, non treated
AM Gatan 3View stub handling tweezers Micro to Nano, Haarlem, Netherlands
Netherlands
50-001521
Binocular OPTA-TECH, Warsaw, Poland X2000
Conductive glue Chemtronics, Georgia, USA CW2400 conductive eopxy
Gatan 3View sample pin stubs Micro to Nano, Haarlem, Netherlands
Netherlands
10-006003
Parafilm Sigma-Aldrich,St. Louis, MI, USA P7793 roll size 20 in. × 50 ft
Pelco conductive silver paint Ted Pella, Redding, CA, USA 16062-15 PELCO® Conductive Silver Paint, 15g
Razor blades double edge Electron Microscopy Sciences, Hatfield, PA, USA 72000 Stainless Steel "PTFE" coated. PERSONNA brand .004" thick, wrapped individually, 250 blades in a box.
Scanning Electron Microscope Zeiss, Oberkochen, Germany Sigma VP with Gatan 3View2 chamber, acceleration voltage 2.5 kV, variable pressure 5 Pa, aperture 20 µm, dwell time 6 µs, slice thickness 60 nm, magnification 15 000 x, image resolution 2048 x 2048 pixels, pixel size 7.3 nm
trim 90° diamond knife Diatome Ltd., Nidau, Switzerland DTB90
Ultramicrotome Leica Microsystems, Vienna, Austria Leica ultracutR
Software webpage tutorials
FijiJ https://fiji.sc/
Microscopy Image Browser http://mib.helsinki.fi/ http://mib.helsinki.fi/tutorials.html
Reconstruct https://synapseweb.clm.utexas.edu/software-0 https://synapseweb.clm.utexas.edu/software-0)
Animals
Mice Adult 3-month old and 20±1 month old female Thy1-GFP(M) mice (Thy1-GFP +/-) (Feng et al.,2000) which express GFP in a sparsely distributed population of glutamatergic neurons. Animals were bred as heterozygotes with the C57BL/6J background in the Animal House of the Nencki Institute of Experimental Biology.

References

  1. Bosch, M., Hayashi, Y. Structural plasticity dendritic spines. Current Opinion in Neurobiology. 22 (3), 383-388 (2012).
  2. Borczyk, M., Radwanska, K., Giese, K. P. The importance of ultrastructural analysis of memory. Brain Research Bulletin. 173, 28-36 (2021).
  3. Wanner, A. A., Kirschmann, M. A., Genoud, C. Challenges of microtome-based serial block-face scanning electron microscopy in neuroscience: challenges of SBEM in neuroscience. Journal of Microscopy. 259 (2), 137-142 (2015).
  4. Śliwińska, M. A., et al. Long-term Memory Upscales Volume of Postsynaptic Densities in the Process that Requires Autophosphorylation of αCaMKII. Cerebral Cortex. 30 (4), 2573-2585 (2020).
  5. Borczyk, M., Śliwińska, M. A., Caly, A., Bernas, T., Radwanska, K. Neuronal plasticity affects correlation between the size of dendritic spine and its postsynaptic density. Scientific Reports. 9 (1), 1693 (2019).
  6. Leighton, S. B. SEM images of block faces, cut by a miniature microtome within the SEM – a technical note. Scanning Electron Microscopy. , 73-76 (1981).
  7. Denk, W., Horstmann, H. Serial Block-Face Scanning Electron Microscopy to Reconstruct Three-Dimensional Tissue Nanostructure. PLoS Biology. 2 (11), 329 (2004).
  8. Smith, D., Starborg, T. Serial block face scanning electron microscopy in cell biology: Applications and technology. Tissue and Cell. 57, 111-122 (2019).
  9. Titze, B., Genoud, C. Volume scanning electron microscopy for imaging biological ultrastructure: Volume scanning electron microscopy. Biology of the Cell. 108 (11), 307-323 (2016).
  10. Deerinck, T. J., Bushong, E. A., Thor, A., Ellisman, M. H. . NCMIR methods for 3D EM: A new protocol for preparation of biological specimens for serial block face scanning electron microscopy. , 6-8 (2010).
  11. Willingham, M. C., Rutherford, A. V. The use of osmium-thiocarbohydrazide-osmium (OTO) and ferrocyanide-reduced osmium methods to enhance membrane contrast and preservation in cultured cells. Journal of Histochemistry & Cytochemistry. 32 (4), 455-460 (1984).
  12. Feng, G., et al. Imaging Neuronal Subsets in Transgenic Mice Expressing Multiple Spectral Variants of GFP. Neuron. 28 (1), 41-51 (2000).
  13. Gage, G. J., Kipke, D. R., Shain, W. Whole Animal Perfusion Fixation for Rodents. Journal of Visualized Experiments. (65), e3564 (2012).
  14. Paxinos, G., Franklin, K. B. J. . The mouse brain in stereotaxic coordinates. , (2004).
  15. Walton, J. Lead aspartate, an en bloc contrast stain particularly useful for ultrastructural enzymology. Journal of Histochemistry & Cytochemistry. 27 (10), 1337-1342 (1979).
  16. Mercer, E. H. a scheme for section staining in electron microscopy. Journal of the Royal Microscopical Society. 81 (3-4), 179-186 (1963).
  17. Schindelin, J., et al. Fiji: an open-source platform for biological-image analysis. Nature Methods. 9 (7), 676-682 (2012).
  18. Belevich, I., Joensuu, M., Kumar, D., Vihinen, H., Jokitalo, E. Microscopy Image Browser: A Platform for Segmentation and Analysis of Multidimensional Datasets. PLOS Biology. 14 (1), 1002340 (2016).
  19. Fiala, J. C. Reconstruct: a free editor for serial section microscopy. Journal of Microscopy. 218 (1), 52-61 (2005).
  20. Roels, J., et al. An interactive ImageJ plugin for semi-automated image denoising in electron microscopy. Nature Communications. 11 (1), 771 (2020).
  21. Radwanska, K., et al. Mechanism for long-term memory formation when synaptic strengthening is impaired. Proceedings of the National Academy of Sciences. 108 (45), 18471-18475 (2011).
  22. Kittelmann, M., Hawes, C., Hughes, L. Serial block face scanning electron microscopy and the reconstruction of plant cell membrane systems: SBFSEM Methods for Plant Cells. Journal of Microscopy. 263 (2), 200-211 (2016).
  23. Fendrych, M., et al. Programmed Cell Death Controlled by ANAC033/SOMBRERO Determines Root Cap Organ Size in Arabidopsis. Current Biology. 24 (9), 931-940 (2014).
  24. Russell, M. R. G., et al. 3D correlative light and electron microscopy of cultured cells using serial blockface scanning electron microscopy. Journal of Cell Science. 130 (1), 278-291 (2017).
  25. Płachno, B. J., Świątek, P., Jobson, R. W., Małota, K., Brutkowski, W. Serial block face SEM visualization of unusual plant nuclear tubular extensions in a carnivorous plant (Utricularia, Lentibulariaceae). Annals of Botany. 120 (5), 673-680 (2017).
  26. Genoud, C., Titze, B., Graff-Meyer, A., Friedrich, R. W. Fast Homogeneous En Bloc Staining of Large Tissue Samples for Volume Electron Microscopy. Frontiers in Neuroanatomy. 12, (2018).
  27. Puhka, M., Joensuu, M., Vihinen, H., Belevich, I., Jokitalo, E. Progressive sheet-to-tubule transformation is a general mechanism for endoplasmic reticulum partitioning in dividing mammalian cells. Molecular Biology of the Cell. 23 (13), 2424-2432 (2012).
  28. Gluenz, E., Wheeler, R. J., Hughes, L., Vaughan, S. Scanning and three-dimensional electron microscopy methods for the study of Trypanosoma brucei and Leishmania mexicana flagella. Methods in Cell Biology. 127, 509-542 (2015).
  29. Starborg, T., et al. Using transmission electron microscopy and 3View to determine collagen fibril size and three-dimensional organization. Nature Protocols. 8 (7), 1433-1448 (2013).
  30. Hughes, L., Borrett, S., Towers, K., Starborg, T., Vaughan, S. Patterns of organelle ontogeny through a cell cycle revealed by whole-cell reconstructions using 3D electron microscopy. Journal of Cell Science. 130 (3), 637-647 (2017).
  31. Bojko, A., et al. Improved Autophagic Flux in Escapers from Doxorubicin-Induced Senescence/Polyploidy of Breast Cancer Cells. International Journal of Molecular Sciences. 21 (17), 6084 (2020).
  32. Knott, G. W., Holtmaat, A., Trachtenberg, J. T., Svoboda, K., Welker, E. A protocol for preparing GFP-labeled neurons previously imaged in vivo and in slice preparations for light and electron microscopic analysis. Nature Protocols. 4 (8), 1145-1156 (2009).
  33. Glauert, A. M., Lewis, P. R. . Biological specimen preparation for transmission electron microscopy. , (2014).
  34. Genoud, C. Altered Synapse Formation in the Adult Somatosensory Cortex of Brain-Derived Neurotrophic Factor Heterozygote Mice. Journal of Neuroscience. 24 (10), 2394-2400 (2004).

Play Video

Cite This Article
Śliwińska, M. A., Cały, A., Szymański, J., Radwańska, K. Serial Block-Face Scanning Electron Microscopy (SBEM) for the Study of Dendritic Spines. J. Vis. Exp. (176), e62712, doi:10.3791/62712 (2021).

View Video