An Alternative Approach for Sample Preparation with Low Cell Number for TEM Analysis

Podsumowanie

Here, we present a protocol to prepare samples with low cell numbers for transmission electron microscopy (TEM) analysis.

Streszczenie

Transmission electron microscopy (TEM) provides details of the cellular organization and ultrastructure. However, TEM analysis of rare cell populations, especially cells in suspension such as hematopoietic stem cells (HSCs), remains limited due to the requirement of a high cell number during sample preparation. There are a few cytospin or monolayer approaches for TEM analysis from scarce samples, but these approaches fail to get significant quantitative data from the limited number of cells. Here, an alternative and novel approach for sample preparation in TEM studies is described for rare cell populations that enables quantitative analysis.

A relatively low cell number, i.e., 10,000 HSCs, was successfully used for TEM analysis compared to the millions of cells typically used for TEM studies. In particular, Evans blue staining was performed after paraformaldehyde-glutaraldehyde (PFA-GA) fixation to visualize the tiny cell pellet, which facilitated embedding in agarose. Clusters of numerous cells were observed in ultra-thin sections. The cells had a well preserved morphology, and the ultra-structural details of the Golgi complex and several mitochondria were visible. This efficient, easy and reproducible protocol allows sample preparation from a low cell number and can be used for qualitative and quantitative TEM analysis on rare cell populations from limited biological samples.

Wprowadzenie

Ultra-structural and sub-organelle details of cells have been mainly revealed by transmission electron microscopy (TEM) studies from tissues or cell pellets^1,2. Solid pieces of tissues can be easily utilized for electron microscopy studies. However, TEM analyses^1,3 on cells in suspension remain challenging and necessitate high cell numbers, i.e., millions of cells. Because of this, ultra-structural analyses of rare cell populations in suspension, e.g., hematopoietic stem cells (HSCs), are not easily assessed. Multiple attempts for TEM analysis from scarce samples using cytospin or monolayer approaches fail to get significant quantitative data from the limited number of cells. Thus, the requirement of a high cell number limits the use of this powerful tool to understand the subcellular ultrastructural details of rare cell populations.

A key limitation for TEM studies with a limited number of cells in suspension is the localization of the cells for processing and thus, TEM studies from limited cells with particularly small sizes remain challenging. Several alternative approaches have been adopted to counter this limitation: the BSA/bisacrylamide (BSA-BA) mediated polymerization of cell suspension, the staining of cells with a dye to make them visible on a thin film support including coverslips, and TEM analyses from cytospin preparations^4-6. However, very limited success was achieved, as very few cells were found in the sections after ultra-sectioning. The key challenge of identifying sparse cells persists because the cell monolayer remains mostly invisible in the solidified gel for sectioning. Furthermore, cytospin preparation of cells may alter their cellular organization due to cell spreading and the fragility of the cell structure. Hence, these inherent drawbacks warrant a novel approach to perform TEM studies from rare cell populations with more consistency. To overcome this problem, we have described a novel and alternative sample preparation method for TEM studies from rare cell populations⁷.

Here, we report an efficient sample preparation protocol to perform TEM from scarce biological samples with consistent qualitative and quantitative results. Evans blue staining was performed after fixation to localize a tiny cell pellet from low number cells, i.e., 10,000 bone marrow hematopoietic stem and progenitor cells that would otherwise have remained invisible, and the pellet was embedded into agarose before dehydration and resin embedding processes. This method clusters the cells together and enables the efficient analysis of the ultrastructure and subcellular organization of hematopoietic stem cells (identified as Lin^- Sca-1⁺ c-Kit⁺ Flt3^- CD34^-; HSC), a rare 0.2 - 0.5% cell population in the bone marrow. This experimental protocol can be useful to perform ultra-structural studies and obtain quantitative results on many rare but highly important populations.

Protokół

All experimental procedures were approved by the institutional animal committee at the Cincinnati Children's Research Foundation. For this study, hematopoietic stem cells were isolated from the bone marrow of C57Bl/6 inbred mice aged 2 - 4 months. Cell sorting using FACS after staining of BM with different surface makers including Lineage, c-Kit, Sca-1, Flt3 and CD34 was used for purification of HSC based on Lin- Sca-1⁺ c-Kit⁺ Flt3^- CD34^- gating strategy as standard protocol described before⁸.

CAUTION: Several highly toxic chemicals are used during this procedure. These are toxic by inhalation and skin contact. Please wear gloves and protective clothing. Work in fume hood while working with these chemicals.

1. Cells, Fixation, Staining and Pre-embedding

1. Sort 10,000 hematopoietic stem cells (using Lin^- Sca-1⁺ c-Kit⁺ Flt3^- CD34^- gating strategy; LT-HSC population) in a 1.5 ml microcentrifuge tube containing 600 µl Iscove's Modified Dulbecco's Medium (IMDM) with 10% fetal bovine serum using FACS.
2. Spin down sorted HSCs at 1,000 x g for 10 min in a 1.5 ml microcentrifuge tube using a centrifuge with swing-out buckets. Remove medium by gentle aspiration and leave 200 µl medium in the tubes at each step. At this stage, the cell pellet remains invisible in the tube.
3. Fix the cells by adding 0.2 ml of 2x fixative solution at room temperature (RT) for 1 hr^1,9.
   1. Make the fixative solution fresh before use. At 1x, the solution is comprised of 3% paraformaldehyde and 2.5% glutaraldehyde in 0.1 M cacodylate buffer.
4. Centrifuge the cells at 1,000 x g for 10 min at 30 °C using a centrifuge with swing-out buckets.
5. Wash cells with 600 µl of 0.1 M cacodylate buffer using centrifugation and leave 200 µl buffer in the tube after centrifugation.
6. Stain the fixed cells by adding 200 µl of 2 mg/ml solution of Evans Blue in cacodylate buffer and incubate for 20 min at RT. The cells will be colored blue.
7. Wash cells 3 times with 600 µl of 0.1 M cacodylate buffer using centrifugation and leave 200 µl buffer in the tube each time.
8. Re-suspend the cells in 200 µl buffer and transfer the cell suspension to a 0.5 ml tube. Centrifuge at 1,000 x g for 10 min using a table top centrifuge. Remove buffer gently without disturbing the now visible tiny cell pellet, and leave 50 µl buffer in the tube.
9. Add 200 mg low melting agarose to 5 ml of 0.1 M cacodylate buffer in the 15 ml tube for a 4% agarose solution. Melt the agarose by transferring the tube to boiling water in a 100 ml glass bottle and keep lukewarm until used.
10. Add 200 µl of 4% low melting agarose dissolved in 0.1 M cacodylate buffer to the cell suspension in 0.5 ml tube and immediately centrifuge at 1,000 x g for 10 min at 30 °C using a table top centrifuge.
11. After confirming that cells pelleted at bottom of the 0.5 ml tube into the semi-solid agarose after centrifugation, immediately transfer the tube to 4 °C or ice for 20 min to solidify the agarose. This step is a very critical, as a small visible cell pellet at this step results in a good cluster of cells under the electron microscope.
12. Carefully transfer the solidified agarose containing the cell pellet from the tube to a 35 mm plastic Petri dish containing buffer using a 27 G needle^3,10.
13. Trim the solidified agarose containing the cell pellet into one piece of about 1 - 2 mm with a scalpel. Transfer the agarose piece containing the cell pellet to a new 1.5 ml tube.
14. Wash 2 - 3 times using 600 µl of 0.1 M cacodylate buffer by adding and removing buffer using pipette without centrifugation. Use this agarose piece containing the cell pellet for the next step. At this step, the sample can be stored at 4 °C overnight before moving to next step.

2. Osmification, Dehydration, Embedding

1. Remove the cacodylate buffer from the 1.5 ml tube with the cell pellet containing agarose using a pipette. Add 1.0 ml of 1% osmium tetraoxide (OsO₄) solution in a fume hood, and incubate for 1 hr at 4 °C.
2. Wash three times with 600 µl of 0.1 M cacodylate buffer and transfer the sample to a 20 ml glass scintillation vial with a cap.
3. Process the sample for dehydration, infiltration and embedding into resin (e.g., LX-112) with serial changes of the following solutions in a 6 well plate. Move the cell-pellet agarose piece using forceps.
   1. Immerse the sample in 25% ethanol at RT for 15 min.
   2. Immerse the sample in 50% ethanol at RT for 15 min.
   3. Immerse the sample in 75% ethanol at RT for 15 min.
   4. Immerse the sample in 95% ethanol at RT for 15 min.
   5. Immerse the sample in 100% ethanol at RT for 15 min, twice.
   6. Immerse the sample in ethanol: resin (3:1) at RT for 30 min.
   7. Immerse the sample in ethanol: resin (1:1) at RT for 30 min.
   8. Immerse the sample in ethanol: resin (1:3) at RT for 30 min.
   9. Immerse the sample in pure resin at RT for 60 min, twice.
4. Transfer the sample to the bottom of pyramid tip shaped rubber mold using forceps carefully and add more pure resin on top of the sample to fill the mold. Incubate the sample at 60 °C for 72 hr for resin polymerization.
5. Remove the polymerized resin pyramid from the molds by twisting the rubber mold. A small black cluster of cells should be visible in the polymerized resin pyramid, as described earlier⁷. Attach the polymerized resin pyramid on the mounting cylinder using cyanoacrylate.

3. Sectioning and Transmission Electron Microscopy

1. Trim the pyramid block with a razor blade and a diamond knife after mounting the block on an ultra-microtome. Make a short wide trapezoidal shape with the top and the bottom of block parallel to each other, and with evenly angled sides. This shape of the pyramid helps for serial sectioning.
2. Further, trim the block around the cell pellet with the diamond knife and remove the plastic sections around the cell pellet agarose piece.
3. Cut 1 µm sections using an ultra-microtome. Move the 1 µm sections from the water boat to a glass slide using an eyelash tool and a metal loop tool as previously reported⁷. Transfer sections on slides and transfer slides to the hot plate (37 °C) for drying.
4. Add a drop of toluidine blue solution to the sections using a syringe equipped with 0.22 µm filter and incubate for 3 min. Rinse the slides with distilled water and let the sections dry. Check with a light microscope to identify the position of the cells.
5. Cut ultra-thin sections (70 - 100 nm) using a diamond knife. Move 2 - 3 sections on 200-mesh grids from the water boat to a glass Petri dish using an eyelash tool.
6. Transfer the glass Petri dish containing grids with sections to a hot plate at 30 °C to dry sections for 30 min.
7. Stain the grids with drops of 1% uranyl acetate at RT for 10 min and then rinse in distilled water 6 - 8 times. Stain with Reynolds lead citrate, at RT for 5 min and rinse in distilled water 6 - 8 times. Transfer the glass Petri dish containing the grids to a hot plate at 37 °C to dry sections.
8. Analyze the sections with an electron microscope, at 80 kV⁷.

Wyniki

An efficient and consistent protocol for sample preparation to perform TEM analysis from low number of cells is described. Post-fixation staining with Evans blue and the transfer of cells to a 0.5 ml microcentrifuge tube helped visualize the tiny cell pellet⁷. Osmification with osmium tetraoxide in agarose led to an easy detection of the dark cell pellet during the dehydration and embedding.

Semi-thin sections from th...

Dyskusje

This method enables TEM analysis on low cell numbers, by using Evans blue staining and agarose embedding to localize a tiny cell pellet during the dehydration, resin embedding and sectioning processes. Importantly, it maintains cell clusters together and preserves the cell ultra-structure, which is desirable to examine multiple cells for quantification of data.

In TEM studies, a cell pellet containing millions of cells is often required for efficient embedment into an agarose/gelatin matrix an...

Materiały

Name	Company	Catalog Number	Comments
Paraformaldehyde 20% Aqueous Soln	Electron microscopy Sciences	15713	CAUTION Toxic via inhalation, skin contact. Wear gloves, use fume hood.
Gluteraldehyde 70% Aqueous Soln	Electron microscopy Sciences	16350	CAUTION Toxic via inhalation, skin contact. Wear gloves, use fume hood.
Cacodyladate buffer	Electron microscopy Sciences	12300	Make 0.1 M Cacodyladate buffer (pH 7.4) in distilled water, store at 4 °C. CAUTION Irritant by inhalation or skin contact, wear gloves and work in fume hood.
Evans Blue	Sigma	E-2129
Low melting agarose	Sigma Aldrich	A-5030
Osmium tetraoxide	Electron microscopy Sciences	19130	1 g in 50 ml of 0.1 M cacodyladate buffer to make 2% OsO4 stock, CAUTION Very toxic by inhalation or skin contact, strong oxidizer, wear protective clothing, eye protection, use fume hood.
LX-112 Embedding Kits (LADD®)
DDSA (Dodecenylsuccinic anhydride)	LADD	21340	Mix 16% DDSA; 30% NMA; 54% LX-112 together and then add 1.4% DMP-30
NMA (Nadic methyl anhydride)	LADD	21350
Epoxy Resins Epon 812 (LX-112)	LADD	21310	CAUTION Toxic by inhalation, skin contact. Wear gloves, protective clothing, use fume hood.
DMP-30 (2,4,6-Tri(dimethylaminomethyl)phenol)	LADD	21370
Reynolds lead citrate (EM Stain II)	Leica		CAUTION Toxic by inhalation, avoid contact with skin or eyes.
Uranyl acetate (EM Stain I)	Leica	8072820	CAUTION Toxic by inhalation, avoid contact with skin or eyes.
Iscove's Modified Dulbecco's Medium (IMDM)	ATCC	30-2005	composition: NaCl, NaHCO3, HEPES, Glucose, Ca, Mg, sod pyruvate etc. For details https://www.atcc.org/~/media/Attachments/E/9/7/E/4893.ashx
Pyramid tip mold	Ted Pella	10585
mounting cylinders	Ted Pella	10580
Ultra-microtome	(Leica EM UC7)
200 mesh grids (nikil)	Electron microscopy Sciences	G-200 Ni
Electron Microscope	Hitachi model H-7650
Image capture engine software	AMT-600
35 mm plastic Petri dishes	Fisher scientific
Quick Bond Super glue Cyanoacrylate	Electron microscopy Sciences	72588
Razor blades
Glass scintillation vials	Fisher scientific	03-337-14
Glass slides
Eyelash tool
Metal Loop tool