In this protocol, we demonstrate the application of serial-section electron tomography to elucidate mitochondrial structure in Drosophila indirect flight muscle.
Mitochondria are cellular powerhouses that produce ATP, lipids, and metabolites, as well as regulate calcium homeostasis and cell death. The unique cristae-rich double membrane ultrastructure of this organelle is elegantly arranged to carry out multiple functions by partitioning biomolecules. Mitochondrial ultrastructure is intimately linked with various functions; however, the fine details of these structure-function relationships are only beginning to be described. Here, we demonstrate the application of serial-section electron tomography to elucidate mitochondrial structure in Drosophila indirect flight muscle. Serial-section electron tomography may be adapted to study any cellular structure in three-dimensions.
Electron microscopy is a valuable tool to study the structural context of subcellular assemblies and organelles that perform cellular processes. Methods have been developed to preserve the ultrastructure of tissues or cells either by chemical fixation with aldehydes or by high pressure freezing (HPF) followed by freeze substitution (FS)1,2. The embedded specimen blocks may then be sectioned, stained, and observed with a transmission electron microscope (TEM). The HPF specimen could also be processed under cryo-condition, such as by cryo-sectioning or by focused ion beam (FIB) milling, and observed by cryo-EM3,4.
Although thin-section EM provides informative morphological insights, the resulting 2D images can only reveal the ultrastructure of a particular cross-section. How ultrastructure is organized in a 3D volume remains obscured. In order to visualize cellular ultrastructure in three dimensions, an electron tomography method was developed where series of tilt images were acquired and back projected to generate a tomographic reconstruction5 (Figure 1). A double tilt series can be collected by rotating the sample 90° and acquiring a second tilt series. This will minimize missing-wedge artifacts that result from limited sampling angles and improve resolution of the tomogram.
Here, we describe the application of serial-section electron tomography to study mitochondrial ultrastructure of Drosophila indirect flight muscle (IFM)6,7,8,9. In order to obtain 3D reconstructions covering entire mitochondria (approximately 2.5 µm-thick), serial sections were obtained from Drosophila IFM tissue blocks. Tomograms of each section were collected individually using automatic data collection software. Tomographic reconstructions were generated and serial tomograms were joined with the IMOD package to obtain a reconstructed volume of an entire mitochondrion. The joined tomograms were analyzed by 3D software. The densities of mitochondrial cristae were segmented to generate a segmentation model that revealed the organization in three-dimensions.
1. Section Drosophila Tissues Using a Vibrating Blade Microtome
2. Prepare EM Specimens by the High-pressure Freezing and Freeze Substitution (HPF/FS) Method
3. Prepare Serial-sections of the Specimens for Electron Tomography
4. Collect Double-tilt Electron Tomography
5. Reconstruct 3D Tomograms and Segment Sub-volumes Using Software
We applied serial-section electron tomography to analyze structural features of mitochondrial cristae that reflects its energetic state and aging. We showed that mitochondria of Drosophila IFM form an integrated cristae and matrix network in 3D (Figure 4)7. In addition, mutant flies with mitochondrial DNA replication defect and an accelerated aging phenotype accumulated mitochondria that contained subsections of onion-like swirling core (Figure 5)7.
Figure 1: Illustration of electron tomography reconstruction from a tilt series. In the experiment, an electron beam is passed through a 3D object as the object is tilted to various degrees. For each tilt condition, a 2D projection is generated and captured with a camera. The 2D projections are then back projected to reconstruct the 3D object based on the central slice theorem. In the illustration, the same process is shown for an original 2D image that is projected into a single dimension under various tilt angles. The 1D projections are then used to reconstruct the 2D image. Please click here to view a larger version of this figure.
Figure 2: Automatic data collection. An image viewer display of software showing the atlas of a slot grid containing serial sections, multi-scale targeting of mitochondria and acquired tilt images. Scale bar = 500 µm (left top panel), 100 µm (left bottom panel), 1 µm (right panel). Please click here to view a larger version of this figure.
Figure 3: Serial-section electron tomography of a single mitochondrion in Drosophila indirect flight muscle. (A) 2D micrographs and (B) 3D tomograms from serial sections covering the entire volume of a mitochondrion. (C) The joined serial-section tomograms are projected to create a longitudinal section, with the z-axis shown vertically. Notably, tissue sectioning led to loss of material, leaving gaps between joined tomograms. Scale bar = 500 nm. Please click here to view a larger version of this figure.
Figure 4: Integrated intra-mitochondria cristae and matrix network revealed in 3D. (A) Slices of mitochondrial electron tomographic reconstructions showing switches between lamellar membranes through the z-axis. (B) Illustrations of the observed cristae switching patterns of right handed and/or left-handed spirals. (C) Tomographic segmentation illustrating a left-handed spiral in 3D (D) Cristae switching patterns were analyzed and color-rendered on the segmentation model (E, F). Tomographic slice showing lateral matrix confluency (dark densities, marked red) across cristae membranes (white densities). (G) Segmentation model of the tomogram in (E) showing lateral matrix confluency (in red) and representative cristae (in gray). Scale bar = 50 nm (A), 200 nm (C), and 300 nm (D, E, F, G). The figure was the reprint from Jiang et al.7 Please click here to view a larger version of this figure.
Figure 5: Mitochondria with onion-like swirling cores accumulated in flies with mitochondrial DNA replication defects during aging. Representative tomographic slices and the corresponding segmentation (right panels) showing a cross-sectional view (top) and a longitudinal-section view (bottom) of a swirling core. Volume segmentation is indicated by arbitrary color rendering to highlight the swirling core. Scale bar: 200 nm. The figure was the reprint from Jiang et al.7 Please click here to view a larger version of this figure.
Step | Temp | Time | Solution | |||
1 | -140 °C to -9 0°C | 30 min | Liquid nitrogen | |||
2 | -90 °C | 96 hr | FS cocktail | |||
3 | -90 °C to -60 °C | 6 hr (5 °C/hr) | FS cocktail | |||
4 | -60 °C | 12 hr | FS cocktail | |||
5 | -60 °C to -25 °C | 7 hr (5 °C/hr) | FS cocktail | |||
6 | -25 °C | 12 hr | FS cocktail | |||
7 | -25 °C to 0 °C | 5 hr (5 °C/hr) | FS cocktail | |||
8 | 0 °C | 1 hr x 3 times | Acetone | |||
9 | Room temp | Resin infiltration |
Table 1: Freeze-substitution protocol.
In this protocol, we describe an optimized workflow for applying serial-section electron tomography to study 3D mitochondrial ultrastructure of Drosophila indirect flight muscle. Preservation of ultrastructure in the sample is the primary technical challenge for this type of analysis. In order to best preserve ultrastructure two methodological steps were included. First, tissue was sampled by sectioning with vibrating blade microtome in order to maintain the tissue architecture as much as possible. Second, a HPF/FS protocol was optimized to preserve organelle ultrastructure during the preparation of embedded specimen blocks. Specimens were frozen under high pressure, which lowers the freezing point of water and reduces the formation of ice crystals that damage ultrastructure1. Specimens as thick as 0.1 mm can be vitrified instantaneously, and then subjected to freeze substitution to generate specimen blocks for EM analysis. The improved preservation of ultrastructure by HPF/FS was noted, when compared to chemical fixation methods. Using this series of steps for sample preparation, preservation of mitochondrial double membranes and cristae membranes was dramatically improved.
Obtaining serial sections of the specimen is the most challenging step of the method. As the electron beam has limited penetration power, the thickness of the section is restricted to either 250 nm or 500 nm using a TEM operating at 200 kV or 300 kV, respectively. Because the thickness of a mitochondrion may be more than 2 µm, serial sections are required to obtain full volume reconstructions. However, recovering a sufficient number of serial sections to span an entire organelle is a technical challenge. Trimming the block face to be as flat as possible between the bases of the trapezoid can allow a slot grid to accommodate more sections and thus cover larger volumes. Additionally, using a perfect loop for thin sections increases the success rate of transferring the serial sections to the grid.
Serial-section electron tomography can be accomplished with standard EM core equipment. However, the method has some inevitable limitations that arise from technical constraints. One is that material is inevitably lost between serial sections, leaving gaps in the joined reconstruction. Second is the missing wedge artifact, which arises due to the limited tilt angles that are achievable. This restriction occurs because the specimen holder cannot be turned in a full rotation without blocking the electron beam. Despite these limitations, serial-section electron tomography provides sufficient resolution to reveal cellular and organelle ultrastructure in 3D.
For smaller scale imaging, cryo-electron tomography is an emerging technology that can be used to obtain the structure of macromolecular complexes and assemblies in situ at nm or sub-angstrom resolution in combination with sub-tomographic reconstruction3. In this application, cells are thinned by sectioning or by focused ion beam milling under liquid nitrogen. The tomograms are collected under cryo-conditions where molecular structures are preserved close to the native state without chemical fixation, dehydration, or embedding. At the other end of scale, to analyze large tissue volumes at the expense of resolution, serial block-face scanning electron microscopy is an appealing modality even though it requires a specific instrument4.
The authors have nothing to disclose.
The studies were performed in the EM core at the Institute of Cellular and Organismic Biology and the cryo-EM core of Academia Sinica, Taipei, Taiwan. The work was supported by Academia Sinica and MOST.
vibrating blade microtome | Leica | VT1200S | Tissue sectioning |
high-pressure freezer | Leica | EM HPM100 | Specimen preparation |
freeze-substitution device | Leica | EM AFS2 | Specimen preparation |
ultramicrotome | Leica | EM UC7 | Ultra-thin sectioning |
dual-axis tomography holder | Fischione | Model 2040 | tomography collection |
transmission electron microscope | FEI | Tecnai F20 | tomography collection |
CCD | Gatan | UltraScan 1000 | tomography collection |
Leginon | NRAMM/AMI | tomography collection | |
IMOD | Boulder Laboratory for 3-D Electron Microscopy of Cells | Tomography reconstruction | |
Avizo 3D | FEI | Tomography analysis |