A rapid way to conduct immunostaining of zebrafish embryonic heart is described. Compared to the whole mount immunostaining approach, this method dramatically increases the penetration of the antibodies, which allows obtaining high resolution images that reveal cellular/subcellular structures in the heart within a much reduced processing time.
Zebrafish embryo becomes a popular in vivo vertebrate model for studying cardiac development and human heart diseases due to its advantageous embryology and genetics 1,2. About 100-200 embryos are readily available every week from a single pair of adult fish. The transparent embryos that develop ex utero make them ideal for assessing cardiac defects 3. The expression of any gene can be manipulated via morpholino technology or RNA injection 4. Moreover, forward genetic screens have already generated a list of mutants that affect different perspectives of cardiogenesis 5.
Whole mount immunostaining is an important technique in this animal model to reveal the expression pattern of the targeted protein to a particular tissue 6. However, high resolution images that can reveal cellular or subcellular structures have been difficult, mainly due to the physical location of the heart and the poor penetration of the antibodies.
Here, we present a method to address these bottlenecks by dissecting heart first and then conducting the staining process on the surface of a microscope slide. To prevent the loss of small heart samples and to facilitate solution handling, we restricted the heart samples within a circle on the surface of the microscope slides drawn by an immEdge pen. After the staining, the fluorescence signals can be directly observed by a compound microscope.
Our new method significantly improves the penetration for antibodies, since a heart from an embryonic fish only consists of few cell layers. High quality images from intact hearts can be obtained within a much reduced procession time for zebrafish embryos aged from day 2 to day 6. Our method can be potentially extended to stain other organs dissected from either zebrafish or other small animals.
1. Preparation of slides and humidified chamber
2. Dissection of embryonic heart
3. Immunostaining
4. Imaging
5. Representative Results
An example of an image which reveals membrane and nuclei of all zebrafish cardiomyocytes is shown in Fig. 1. mef2c and β-catenin antibodies were used together to stain heart samples dissected from 52 hpf zebrafish embryo. While mef2c antibody stains the nuclei of cardiomyocytes, β-catenin antibody reveals the border of each cell 8-10. By adjusting the stage of the compound microscope, images of the heart samples can be adjusted to the same orientation, which will allow the observation of outer curvature and inner curvature in the heart 11. The total cardiomyocyte number, cardiomyocyte cell size, and circularity can then be measured.
Another example which reveals the sarcomeric structure of an embryonic heart is shown in Fig. 2. We performed immunostaining using F59, a myosin antibody, in a dissected embryonic heart. The myofibril network in a whole embryonic heart can be clearly revealed at lower magnification, while the striated band of thick filament can be revealed at higher magnification (Fig 2) 6.
Figure 1. Immunostaining of mef2 (red) and β-catenin (green) to show the nuclei and outlines of cardiomyocytes in a zebrafish ventricle. Scale bar=10μm
Figure 2. Immnostaining of myosin to show the thick filament in a zebrafish ventricle at either low magnification (A) or high magnification (B).scale bar=10μm
Compared to classic whole mount immunostaining methods, our method has the following advantages. First, much stronger fluorescent signals can be consistently obtained due to improved penetration. In the whole mount immunostaining method, the dense skin tissue surrounding the heart significantly reduced the penetration of many antibodies, resulting in high background in the whole body. This problem is especially severe for embryos older than 3-day post-fertilization (dpf). In contrast, the dissected hearts only consist of a few cell layers, rendering much better penetration. Secondly, because of the much improved penetration, the whole process of immunostaining can be reduced from 1 day to just several hours. We have successfully reduced the incubation time from 1 hour to 30 minutes for some antibodies such as Actinin, Integin-linked kinase (Ilk), and β-catenin specific antibodies. Third, high-resolution images can be consistently obtained from intact hearts to reveal cellular/subcellular information. Because of the localization of the heart inside the pericardiac sac that is next to the yolk, higher magnification objective lenses cannot be used to image intact embryos. Therefore, the heart will need to be dissected if images of an intact heart are needed. However, detergents such as triton-x-100 that are used to improve penetration in the whole mount staining procedure weaken the embryos. As a consequence, hearts are easily broken during the dissection procedure. In contrast, a live heart is much stronger, which can be easily separated from its neighboring tissues. Therefore, intact morphology are more easily maintained using the proposed method. Although dissecting a small zebrafish heart might appear challenging, most people can easily conduct this procedure after several practices.
We have utilized this method to stain hearts aged from 2 dpf to 6 dpf. Because of its physical location, hearts from even earlier staged embryos are difficult to dissect. It remains to be determined whether this method can be adjusted for larva or adult hearts. It is worthwhile to point out that local damage to the heart might result during the dissection process, which involves physical force. This complication can be overcome by assessing several hearts, and then selecting images with consistent results and the best maintained morphology.
Because of much improved resolution, this method can be used to reveal both cellular and subcellular structures of a developing zebrafish heart. For example, we have already applied this method to count total number of cardiomyocytes, to quantify individual cardiomyocyte size, to assess proliferation and apoptosis, and to reveal the process of sarcomere assembly 6,12. Together with unique genetic tools in zebrafish, the present method will facilitate the study of cardiovascular biology in this in vivo model.
The authors have nothing to disclose.
We thank Beninio Jomok for his help in zebrafish husbandry. This work is funded by NIH HL81753.
Name of the reagent | Company | Catalogue number |
tricaine | Research organics | 3007T |
Formaldehyde | Polysciences | 04018 |
Insulin syringe | Becton Dickinson | 329461 |
Triton-X-100 | Sigma | T8532 |
Anti-β-catenin antibody | Sigma | C7207 |
Anti-Mef2c antibody | Santa Cruz Biotech | SC313 |
F59 | Zfin | |
Anti-α-actinin antibody | Sigma | A7811 |
Anti-Ilk antibody | Cell signaling | #3862 |
Alexa fluor 568 Goat anti rabbit IgG | Invitrogen | A11011 |
Alexa fluor 488 Goat anti mouse IgG1 | Invitrogen | A21121 |
Mounting medium for fluorescence | Vector | H-1200 |
ImmEdge pen | Vector | H-4000 |
Poly-L-lysin coated slides | Electron microscopy sciences | 63410-01 |
Microscope cover glass | Fisher | 12-543-D |
Concaved microscope slides | Fisher | 7-1305-8 |
Dissection microscope | Leica MZ95 | |
Compound microscope | Zeiss | Axioplan2 |
ApoTome | Zeiss |
PBST:
1 x PBS
0.5% Triton-X 100
25X Tricaine:
400 mg Tricaine
97.9 mL ddH2O
2.1 mL (1M Tris pH9)
Adjust pH to 7.0