JoVE Journal > Developmental Biology
Summary
Abstract
Introduction
Protocol
Resultados
Discussion
Divulgaciones
Acknowledgements
Materials
Referencias
Biología del desarrollo

Imaging Cleared Embryonic and Postnatal Hearts at Single-cell Resolution

Published: October 07, 2016
doi:
10.3791/54303
, , , , , , , ,
1Department of Molecular and Cellular Physiology,Albany Medical College, 2Department of Neuroscience and Experimental Therapeutics,Albany Medical College

Summary

We describe a protocol to volumetrically image fluorescent protein labeled cells deep inside intact embryonic and postnatal hearts. Utilizing tissue-clearing methods in combination with whole mount staining, single fluorescent protein-labeled cells inside an embryonic or postnatal heart can be imaged clearly and accurately.

Abstract

Single clonal tracing and analysis at the whole-heart level can determine cardiac progenitor cell behavior and differentiation during cardiac development, and allow for the study of the cellular and molecular basis of normal and abnormal cardiac morphogenesis. Recent emerging technologies of retrospective single clonal analyses make the study of cardiac morphogenesis at single cell resolution feasible. However, tissue opacity and light scattering of the heart as imaging depth is increased hinder whole-heart imaging at single cell resolution. To overcome these obstacles, a whole-embryo clearing system that can render the heart highly transparent for both illumination and detection must be developed. Fortunately, in the last several years, many methodologies for whole-organism clearing systems such as CLARITY, Scale, SeeDB, ClearT, 3DISCO, CUBIC, DBE, BABB and PACT have been reported. This lab is interested in the cellular and molecular mechanisms of cardiac morphogenesis. Recently, we established single cell lineage tracing via the ROSA26-CreERT2; ROSA26-Confetti system to sparsely label cells during cardiac development. We adapted several whole embryo-clearing methodologies including Scale and CUBIC (clear, unobstructed brain imaging cocktails and computational analysis) to clear the embryo in combination with whole mount staining to image single clones inside the heart. The heart was successfully imaged at single cell resolution. We found that Scale can clear the embryonic heart, but cannot effectively clear the postnatal heart, while CUBIC can clear the postnatal heart, but damages the embryonic heart by dissolving the tissue. The methods described here will permit the study of gene function at a single clone resolution during cardiac morphogenesis, which, in turn, can reveal the cellular and molecular basis of congenital heart defects.

Introduction

Cardiac morphogenesis is a sequential event that requires the spatiotemporal organization of four different types of cardiac progenitor cells into distinct sectors of the heart, and also requires multiple genetic regulatory networks to orchestrate this process to form the functional heart1,2. Cardiac specification, differentiation, patterning, and chamber maturation are regulated by cardiogenic transcription factors3. Genetic mutation or posttranscriptional aberration of these factors in cardiac progenitor cells could result in either embryonic lethality or congenital heart defects (CHD)4. The study of cardiac morphogenesis requires an understanding of inherent structural details in three dimensions (3D) and single labeled cardiac progenitor cell lineage tracing during cardiac development will promote the understanding of cardiac morphogenesis. A number of high-resolution section based tomography methods have been developed in the past few decades to image organ structure5,6; however, these methods require expensive, specialized instruments, extensive labor, and lack detailed structural organization at single cell resolution in the final volumetric reconstructed image7,8.

3D volumetric imaging at the single cell level provides a means to study progenitor cell differentiation and cellular behavior in vivo7. However, tissue light scattering remains the primary obstacle to imaging cells and structures in 3D deep inside the intact heart. Lipids are a major source of light scattering, and the removal of lipids and/or adjustment of the refractive index difference between lipids and their surrounding areas are potential approaches for increasing tissue transparency8. In the past several years, a number of tissue clearing methods were developed, which reduce tissue opacity and light scattering, like BABB (benzyl alcohol and benzyl benzoate mixture) and DBE (tetrahydrofuran and dibenzylether); but in these methods, fluorescence quenching remains an issue8-10. The solvent based hydrophilic methods, such as SeeDB (fructose/thioglycerol) and 3DISCO (dichloromethane/dibenzylether), preserve fluorescent signals, but do not render the whole organ transparent7,8,11. In comparison, the CLARITY tissue-clearing method renders the organ transparent, but it requires a specialized electrophoresis device to remove lipids8,12, as does PACT (passive clarity technique), which also requires hydrogel embedding7,13. For detailed information regarding all available tissue-clearing methods, refer to Table 1 in Richardson and Lichtman, et al.7.

In 2011, Hama et al. serendipitously discovered a hydrophilic mixture 'Scale' (urea, glycerol and Triton X-100 mixture) that renders the mouse brain and embryo transparent while completely preserving fluorescent signals from labeled clones14. This allows for the imaging of the intact brain at a depth of several millimeters and large-scale reconstruction of neuronal populations and projections at a subcellular resolution. Susaki et al. further improved Scale by adding aminoalcohols and developed the 'CUBIC' (clear, unobstructed brain imaging cocktails and computational analysis) tissue clearing method, which increased phospholipid solubilization, reduced clearing time, and allowed for multicolor fluorescent imaging8. In the present study, taking advantage of the Scale and CUBIC tissue clearing techniques and high resolution 3D optical sectioning, individual clones inside the heart during cardiogenesis were traced using Rosa26CreERT2 15, R26R-Confetti16, αMHC-Cre17, cTnT-Cre18, Nfatc1-Cre19, and Rosa26-mTmG (mTmG)20 mouse lines. The combination of the whole mount staining (WMS) method developed previously21,22 with tissue clearing methods further allowed for the staining of other proteins in labeled clones and for the study of their behavior in a 3D volumetric context. The combination of tissue clearing and WMS allows for a better understanding of the roles of different genes and proteins during cardiac development, and the etiology of congenital heart defects. This protocol can be applied to study other progenitor cell differentiation, cellular behavior, and organ morphogenesis events during development.

Protocol

All animal experiments were approved by the Institutional Animal Care and Use Committee (IACUC) at Albany Medical College and performed according to the NIH Guide for the Care and Use of Laboratory Animals.

1. Solution Preparations

NOTE: The Rosa26CreERT2 15, R26R-Confetti16, αMHC-Cre17,and Rosa26-mTmG (mTmG)20 mouse lines were purchased commercially. cTnT-Cre18 was a gift from Dr. Jiao at University of Alabama. Nfatc1-Cre was a gift from Dr. Bin Zhou at Albert Einstein College of Medicine19. Mice were euthanized by carbon dioxide inhalation in a closed chamber for at least 60 seconds followed by physical means of death verification by bilateral thoracotomy, decapitation or cervical dislocation.

  1. Prepare Tamoxifen. Dissolve 10 mg of Tamoxifen in 10 ml of sunflower seed oil. Once it is completely dissolved, aliquot and store at -20 °C.
  2. Prepare phosphate buffered saline (PBS). Dissolve Na2HPO4 (1.41960 g), KH2PO4 (0.24496 g), NaCl (8.0669 g) and KCl (0.20129 g) in 1 L of distilled water and adjust the pH to 7.4.
  3. Prepare PBST:0.1% Tween-20 solution in PBS by dissolving 100 μl of Tween-20 in 100 ml of PBS.
  4. Prepare blocking buffer. Make 3% bovine serum albumin (BSA) blocking solution by dissolving 3 g of BSA in 100 ml of PBST containing 0.2% Tween-20.
  5. Prepare CUBIC-1 (reagent 1). Mix 25 wt% urea, 25 wt% N, N, N', N'-tetrakis (2-hydroxypropyl) ethylenediamine and 15 wt% Triton X-100 in dH2O.
  6. Prepare CUBIC-2 (reagent 2). Mix 50 wt% sucrose, 25 wt% urea, 10 wt% 2, 2′, 2′'-nitrilotriethanol and 0.1% (v/v) Triton X-100 in dH2O.
  7. Prepare Scale A2: 4 M urea, 10% w/v glycerol and 0.1% w/v Triton X-100 in dH2O. Adjust the pH to 7.7.
  8. Prepare Scale B4: 8 M urea and 0.1% w/v Triton X-100 in dH2O. Adjust the pH to 8.7.
  9. Prepare Scale 70: 4 M urea, 70% w/v glycerol and 0.1% w/v Triton X-100 in dH2O.

2. Tamoxifen Induction, Embryo Isolation and Fixation

  1. Tamoxifen Induction and Embryo Isolation
    1. Using a curved feeding tube approved protocol (ACUP 13-12007), gavage the female R26CreERT2 Confetti mice (plugged by R26CreERT2 male mice) with 10 µg/g of Tamoxifen at embryonic developmental day E7.7533. At embryonic day 9.5 (E9.5) or E10.5, euthanize the female mice with CO2 and cervical dislocation.
    2. After verification of mouse death (see Section 1 Note), open the mouse abdominal cavity with scissors and dissect out the uterine horn, remove the uterine tube layers with the help of scissors and tweezers, and release the embryos from the uterine tube23,24.
      1. Transfer the embryos to a petri dish containing PBS (pH 7.4). Under the dissecting microscope, remove the non-embryonic layers (chorion, yolk sac and amnion) with the help of tweezers.
    3. Using tweezers and scissors, collect the female mouse and embryo tail samples for genotyping as previously reported22. Using a plastic pipette, transfer each embryo to a well of a 48 well plate containing 1 ml of 1x PBS.
    4. Under a fluorescent microscope, identify the GFP/RFP/CFP positive embryos via an inverted microscope with a camera. Peel away the pericardium using tweezers and rotate the heart/embryo with the help of curved tweezers to determine the number of fluorescent clones on both sides of the heart with the GFP/RFP/CFP filters. No cuts are needed.
  2. After identifying GFP/RFP/CFP positive embryos, quickly wash the embryos twice (2 min each) with 1x PBS in the 48 well-plate on a plate shaker at room temperature (RT). This will remove excess blood.
  3. Fix the embryo/embryonic heart using 4% paraformaldehyde (PFA) at RT. The fixation time depends on the embryonic age and tissue size. For E9.5 fix the embryo for 2 hr at RT. The late embryonic stage embryos require longer fixation time, which can even be prolonged to 24 hr for postnatal heart.
    CAUTION: Paraformaldehyde is toxic, avoid contact with skin, eyes and mucous membrane.
  4. After fixation, wash the embryo/heart in the 48 well-plate twice (10 min each) with 1x PBS on a plate shaker at RT. This removes the excess PFA from the embryo/heart. The embryos are then further processed for whole mount staining and tissue clearing.

3. Whole Mount Staining

NOTE: After PFA fixation the embryo/heart is subjected to whole mount staining as follows.

  1. Permeabilize the embryo/heart in a 48 well-plate using 1 ml of 0.1% PBST for 2 hr on plate shaker at RT.
  2. Following permeabilization, immerse the embryo/heart in 1 ml of blocking buffer, for 2 hr or overnight on a plate shaker at 4 ºC.
  3. Immerse the embryo/heart to the endothelial cell-specific antibody PECAM (CD31), diluted (1:100) in 0.3 ml blocking buffer for 48 hr on plate shaker at 4 ºC.
  4. Wash the embryo/heart using PBST 5 times, 30 min each at RT on plate shaker. This removes the excess non-specific bound primary antibody from the tissue.
  5. Immerse the embryo/heart in Alexa Fluor 647 goat anti-rat secondary antibody, diluted (1:1,000) in 1 ml blocking buffer for 48 hr on plate shaker at 4 ºC.
  6. Repeat step 3.4 to wash the secondary antibody.
  7. Post-fix the embryo/heart with 4% PFA for 1 hr at RT on plate shaker and wash twice with PBS 5 min each.
  8. Stain the embryo/heart with the nuclear stain 4′,6-diamidino-2-phenylindole (DAPI) (diluted in PBST at a concentration of 0.01 mg/mL) for 10 min on plate shaker at RT. Follow with two PBS washes of 5 min each.

4. Embryo/heart Clearing with Scale or CUBIC Method

NOTE: After whole mount staining, the embryo/heart is subjected to either the Scale or CUBIC tissue clearing method. The choice of method depends on the tissue size and embryonic age. For E11.5 or earlier age embryos, use Scale tissue clearing method, while for older embryos or postnatal hearts the CUBIC tissue clearing method is preferred.

  1. Scale Tissue Clearing Method
    1. Incubate the embryo/heart with 1 ml of Scale A2 solution in a scintillation vial (wrapped in aluminum foil) with occasional gentle shaking (by hand) for 48 hr at 4 °C.
    2. After Scale A2 incubation, incubate the embryo/heart with 1 mL of Scale B4 solution at 4 °C in the same vial with occasional gentle shaking for another 48 hr.
    3. Incubate the embryo/heart for another 48 hr with 1 ml Scale 70 at 4 °C with occasional gentle shaking. Mount embryo using 90% glycerol (see section 5.1).
  2. CUBIC Tissue Clearing Method
    1. For whole embryo/heart CUBIC clearing, immerse each embryo/heart in 1 ml of CUBIC-1 with occasional gentle shaking for 48 hr at 37 ºC7. After 48 hr, replace the solution with the same volume of fresh CUBIC reagent 1, and incubate the sample for an additional 48 hr at 37 °C with occasional shaking with hand.
    2. Wash the CUBIC-1 treated heart/embryo with 1x PBS several times at room temperature with gentle shaking with hand. This removes the excess CUBIC-1 solution.
    3. After washing out CUBIC-1 with PBS, immerse the embryos/hearts in CUBIC-2 solution (1 g per embryo/heart) for 48 hr at 37 ºC with occasional gentle shaking with hand. This follows embryo/heart mounting using glycerol (see section 5.2).

5. Sample Mounting and Imaging

NOTE: The cleared embryos or organs in Scale 70 or CUBIC-2 solution can be imaged directly with Scale 70 and CUBIC-2 solution as the imaging medium, respectively. However, considering the vulnerability of the embryonic samples to clearing reagents, if the samples are not be imaged immediately, but stored long-term, store the samples in 90% glycerol following the protocol below.

  1. Directly immerse the Scale cleared sample in 1 ml of 90% glycerol and store at 4 °C until imaging.
  2. Wash the CUBIC treated sample with 1x PBS twice, 5 min each and sequentially incubate the sample with 1 ml of 30%, 50%, 70% and 90% glycerol solution each for 30 min.
  3. For imaging, transfer the sample to glass bottom Petri dish with a minimal amount of 90% glycerol and image clones with a confocal microscope equipped with two photon capabilities.
  4. Image the heart or embryo in the glycerol with a 10X/0.3 NA, a 25X/0.8 NA immersion, or a 40X/1.2 NA water corrective objective lens. Image DAPI using 2-photon excitation from a coherent titanium:sapphire chameleon laser. The choice of microscope and objective lens will depend on the purpose of the experiments, e.g. for super-resolution, a light sheet fluorescent microscope could be utilized.

Representative Results

Imaging the cleared embryonic heart

Vertebrate heart formation is a spatiotemporally regulated morphogenic process and depends on the organization and differentiation of progenitor cells from four different sources1. Cells from the first heart field of the cardiac crescent will fold toward the ventral midline to form a linear heart tube. The cells from the second heart field, initially residing dorsomedially to the first heart field, subsequently translocate to the pharyngeal and splanchnic mesoderm, from where they migrate to the pre-existing scaffold of the linear heart tube. The cells of second heart field will contribute to the right ventricle, outflow tract (OFT) myocardium and to some endocardium25-28. Cardiac neural crest cells (CNCC), originating from postotic rhombomeres 6, 7 and 8, will migrate to the caudal pharynx and contribute significantly to the smooth muscle layer and endocardial cushions in the OFT. They also contribute to the formation of the aorticopulmonary septum29,30. The fourth population consists of epicardial cells derived from the pro-epicardial organ (PEO), and contributes to fibroblasts, smooth muscle cells and potentially other cardiac cell types31. The epicardium regulates coronary vascular development, cardiac growth and morphogenesis21.

The most important concept about cardiac morphogenesis is that during heart development, abnormal cell migration/differentiation of the four progenitor cell populations will result in malformations or congenital heart defects4,22,32, which is the number one cause of birth defects in the world. Determining the mechanisms of cardiac morphogenesis at the cellular and molecular level is an essential step toward improving diagnosis and potential treatments for CHDs. Therefore, it is critical to image the process of heart morphogenesis at the whole heart level with single cell resolution. To achieve that, we labeled the cardiomyocytes by crossing the Cre line under the control of cardiac specific troponin T (cTnT), which is specifically expressed in cardiomyocytes18, with mTmG reporter line. The embryos at E8.5 were harvested and stained for PECAM to distinguish endocardial and endothelial cells from cardiomyocytes. The embryos were then cleared by Scale and the heart was imaged. The myocardium was labeled by GFP due to cTnT-driven Cre-mediated recombination of the mTmG reporter, and the endocardium was labeled with PECAM (Figure 1A and Supplementary Movie 1). The cardiomyocytes can be observed at a single cell resolution (Figure 1A). The heart structures of the imaged portion, such as the primitive ventricle and OFT can be clearly identified after 3D reconstruction using 3D reconstruction software (Figure 1B and Supplementary Movie 2).

Imaging single clones of the cleared embryonic heart

Cardiac morphogenesis depends on cardiac lineage differentiation and individual cell organization at the whole heart level22, and thus, it is essential to image single cardiac progenitor cell differentiation to different cardiac cell types and to also image cell morphology at single cell resolution. To achieve that, Rosa26CreERT2 15 was crossed to R26R-Confetti16, and the pregnant female was gavaged with Tamoxifen at a low concentration. After 48 hr, the embryo was harvested at E9.5, and whole mount stained for PECAM, and then the whole heart was imaged. We found that there was only one cluster of cells, localized to the OFT, and this clone had 8 cells based on the reconstructed image and consecutive sections (Figures 2A, 2B and Supplementary Movie 3), indicating that these cells are derived from a single progenitor cell. The cellular morphology and cellular behavior such as cellular proliferation and migration can be inferred from the ultimate positioning of the cells (Figure 2A). We also applied the CUBIC method to clear the embryonic heart at E9.5 and E10.5, and found that even after only 24 hr of incubation with reagent 1, the embryos were subtly dissolved and the tissue structure was adversely affected (Data not shown).

Imaging of cleared postnatal and late embryonic hearts

We applied both Scale and CUBIC to clear postnatal hearts. P2 hearts with the genotype of αMHC-Cre; mTmG (αMHC-Cre is specifically expressed in cardiomyocytes17) were cleared with Scale for 48 hr, but did not display any more transparency than the hearts treated with PBS only (Data not shown), indicating that Scale clearing is not effective for postnatal hearts. When P2 hearts were cleared with CUBIC reagent 1 for 48 hr, and reagent 2 for 96 hr, they were much more transparent than the hearts cleared with reagent 1 for 48 hr and reagent 2 for 48 hr. The imaging depth was significantly increased with 96 hr of reagent 2 incubation (Supplementary Movies 4 and 5), indicating that longer incubation with the CUBIC reagents promotes transparency and provides for an increase in imaging depth. The shape and size of each cardiomyocyte can be identified by the membrane localized GFP (Figure 3A), which can be used to identify hypertrophy.

We also cleared Nfatc1-Cre;Confetti (Confetti female plugged with Nfatc1Cre male) E17.5 hearts (Nfatc1-Cre is expressed in cardiac endocardial cells19) with CUBIC reagent 1 for 48 hr and reagent 2 for 48 hr. The hearts are transparent, and fluorescent proteins including GFP, YFP, CFP and RFP were expected to label the endocardial cells and their derived cells; however, only GFP and YFP could be imaged through the whole heart (Figures 3B, 3C and Supplementary Movies 6 and 7), and the CFP and RFP could not be detected (Data not shown). The staining for PECAM (Alexia Fluor 647) also could not be detected (Data not shown), suggesting that the CUBIC reagent quenches the CFP, RFP and the antibody conjugated fluorophore in this protocol.

Figure 1
Figure 1: Imaging the Sac/e cleared embryonic heart. (A) One optical slice of an E8.75 heart (cTnT-Cre;mTmG) is shown. V: ventricle; OFT: outflow tract. (B) Shows the reconstructed heart structure of 93 consecutive optical slices with a total depth of 110.4 µm. Scale bar = 20 µm in A. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Imaging single clone of Sca/e cleared embryonic heart. (A) One optical section of a clone from an E9.5 heart with the genotype of ROSA26-CreERT2; ROSA26-Confetti. The arrow points to a cellular protrusion of a cardiomyocyte. (B) Shows the reconstructed clone in the OFT region of the E9.5 heart with 10 optical slices and 36 µm total depth. Scale bar = 20 µm in A. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Imaging the CUBIC cleared postnatal and late embryonic hearts. (A) Shows one optical section of a P2 heart with the genotype of αMHC-Cre;mTmG; all of the optical sections are shown in Supplementary Movie 5. (B) Shows one section of an E17.5 heart with the genotype of Nfatc1-Cre;ROSA26-Confetti. (C) Shows the reconstructed heart structure from 106 optical slices with a total depth of 630 µm. The Scale bar = 20 µm in A and is 100 µm in B. Please click here to view a larger version of this figure.

Movie 1
Supplementary Movie 1: Imaging the Scale cleared embryonic heart (Right click to download). Movie 1 shows optical sections of a Scale treated E8.75 heart (cTnT-Cre;mTmG) from heart surface to heart lumen. The depth is 110.4 µm and there are 93 slices in total.

Movie 2
Supplementary Movie 2: Imaging the Scale cleared embryonic heart (Right click to download). Movie 2 shows the 3D surface picture of the reconstructed heart in Movie 1, reconstructed via the 3D reconstruction software. Yellow marks the PECAM expression and green labels all the cardiomyocytes.

Movie 3
Supplementary Movie 3: Imaging a single clone of the Scale cleared embryonic heart (Right click to download). Movie 3 shows sections of a clone from an E9.5 heart with the genotype of ROSA26-CreERT2.

Movie 4
Supplementary Movie 4: Imaging the CUBIC cleared postnatal hearts (Right click to download). Movie 4 shows sections of a CUBIC treated P2 heart (αMHC-Cre;mTmG) from heart surface to heart lumen. This P2 heart was cleared with CUBIC reagent 1 for 48 hr, and CUBIC reagent 2 for 96 hr.

Movie 5
Supplementary Movie 5: Imaging the CUBIC cleared postnatal hearts (Right click to download). Movie 5 shows a heart that was cleared with reagent CUBIC 1 for 48 hr and reagent CUBIC 2 for 48 hr. The depth is 136 µm with 6 µm per section in movie 4 and the thickness is 76 µm with 6 µm per section in movie 5.

Movie 6
Supplementary Movie 6: Imaging the CUBIC cleared late embryonic heart (Right click to download). Movie 6 shows sections of a CUBIC treated E17.5 heart (Nfatc1-Cre;ROSA26-Confetti) from heart surface to heart lumen. The depth is 630 µm with 6 µm per section.

Movie 7
Supplementary Movie 7: Imaging the CUBIC cleared late embryonic heart (Right click to download). Movie 7 shows the 3D surface picture of the heart in Movie 6, reconstructed via the 3D reconstruction software.

Discussion

The embryo isolation is a very critical step. E9.5 embryos are very fragile and small in size, so extra care should be taken not to damage the embryo/heart structures during isolation. The non-embryonic extra layers enveloping the embryo/heart should be removed carefully especially when imaging the whole embryo. This allows antibody and clearing mixture penetration deep inside the embryonic tissues, and also helps in removing the background signal when imaging. Multiple antibodies including antibodies against PECAM, acetylated α-tubulin and integrin β1 were examined and all were successfully detected (data not shown)33. This demonstrates that the molecular integrity, cellular integrity and antigen compatibility were not disrupted during this clearing process.

Transfer the embryo/heart using a wide mouth transfer pipette (cut the tip). This avoids damage during handling. The GFP/YFP/RFP/CFP expression pattern and number of clones should be carefully recorded in the heart to determine the appropriate dosage to label one clone per heart or any other organs. Due to the low dosage of Tamoxifen (10 μg/g), sometimes the heart does not contain any clones or is difficult to detect any clones. Therefore, it is recommended to use the yolk sac to determine if the embryo has any GFP/YFP/RFP/CFP clones.

The embryo or heart fixation is a critical step, as over-fixation will result in a high background while under-fixation will result in poor staining. It is recommended to fix the E8.5-E10.5 whole embryo for 2 hr at RT on a plate shaker. While for E11.5-E15.5 embryos, the recommendation is to carefully isolate the heart and fix it with 4% PFA for 2 hr at RT. After ensuring to remove the layers surrounding the heart if processing the whole embryo, the E11.5- E13.5 embryos can also be fixed for 3-4 hr at RT but that requires increased tissue clearing time. The E16.5-P1 (postnatal day 1) hearts are fixed for 3-4 hr at RT on a plate shaker. When fixing the whole embryo, the fore and hind limbs should be removed as they hinder the heart imaging.

The samples should be treated with CUBIC and Scale in scintillation vials to minimize sample drying. We have observed better clearing of samples with the CUBIC tissue clearing method at 37 °C, while Scale clearing is optimally done at 4 °C. After imaging, the samples can be stored short-term in CUBIC-2 or Scale 70. The samples should always be covered with aluminum foil to prevent fluorescence bleaching.

Embryonic tissues and organs have less lipid and extracellular matrix deposition, which results in less clearing time. On the other hand, they are more vulnerable to the clearing reagents. The clearing reagents might affect the integrity of the tissue structure and antigen, resulting in the quenching of CFP, RFP and antibody conjugated fluorophore. Therefore, longer fixation times might prevent the quenching. The quenching of the fluorescent proteins could also be due to their sensitivity to chemicals and pH as previously reported34. Other chemical recipes, pH, fixatives, and incubation length should be explored to minimize the quenching of the fluorescent proteins.

The method of whole organ transparentizing or tissue clearing has revolutionized volumetric 3D imaging. The previous imaging method for cardiac morphogenesis, which involved the manual 2D or 3D reconstruction of serial sections, is time consuming and instrument demanding5,6. High resolution episcopic microscopy (HREM) in conjunction with 3D modeling can be applied to the study of the morphogenesis of the mouse heart and provides for excellent anatomic description of the trabecular architecture in the developing mouse embryo35. However, HREM does not allow the identification of the fluorescent protein labeled cells or antibody stained cells from the rest of cells35. Using the current protocol, with minimal effort and high cost effectiveness, we have successfully preserved the fluorescent signals in the embryonic heart using Scale or CUBIC tissue clearing methods (Figures 13). Combined with a low dose (10 μg/g) of Tamoxifen to induce Cre recombination events and generate a few clones inside the whole embryo and in the heart, this system can be used to trace and study single cardiac progenitor cell differentiation and cellular behaviors in vivo (Figure 2A)33. In addition, combined with Cre mediated gene deletion or overexpression and Cre mediated single cell labeling, this imaging system can be applied to study genetic loss of function or gain of function on progenitor cell differentiation and cellular behavior during cardiac morphogenesis, and thus provides a robust tool to study the etiology of congenital heart defects.

The two-tissue clearing systems Sca/e and CUBIC used in this study showed different clearing efficiencies, which further differentiates the systems based on embryonic age, tissue thickness and duration of tissue clearing time. For early stage embryos E9.5-E10.5, the Sca/e system not only rendered the tissue clear but also protected the embryo morphology and preserved the fluorescent signals, while the CUBIC treatment resulted in embryo dissolution. This might be the result of additional aminoalcohols and a higher concentration of Triton X-100 in the CUBIC solutions8. For older hearts, the Sca/e system failed to clear the tissue completely even with a longer incubation time. The CUBIC clearing solution rendered the older tissue clear (Figure 3). However, increased incubation time resulted in weaker signals and only protected endogenous GFP, while RFP, CFP and antibody conjugated signals were lost. For this reason, a more optimized recipe of the clearing reagents and better incubation time would be required to volumetrically image hearts or organs with a greater spectrum of fluorescent labels.

This study demonstrated that one can label, trace, and image single cardiac clones in combination with a whole mount staining of endocardial/endothelial cell marker PECAM of the developing heart. The whole mount staining of PECAM and DAPI in this system not only helps to identify the cell types and cell morphology of the labeled cells inside a heart, but also allows the study of the clonal pattern, migration and behavior during cardiac morphogenesis. In Figure 2A we observed a clone with 8 cells in OFT. Using the number of cell present in this clone with reference to the labeling time, the cell proliferation rate can be easily calculated. In another study using this same system we identified the oriented cell division pattern and migration pattern of single cardiomyocyte during trabeculation process33. The application of this protocol to study the effects of genetic loss of function or gain of function spatiotemporally on the labeled cardiac progenitor cell differentiation, clonal pattern and cellular behavior is feasible, and will help in studies of the etiology of congenital heart defects at genetic and molecular level in a 3D context. In addition, this protocol can be applied to study of morphogenesis in other organ systems.

Divulgaciones

The authors have nothing to disclose.

Acknowledgements

We thank M.W. laboratory members for scientific discussion. This work is supported by AHA [13SDG16920099] to M.W., and by National Heart, Lung, and Blood Institute grants [R01HL121700] to M.W. Images were captured in the Imaging Core Facility at the Albany Medical College.

Materials

2,2′,2′’-nitrilotriethanol  Sigma Aldrich 90279
4% Paraformaldehyde in PBS Affymetrix 19943
BSA Fischer Scientific  BP16000
N,N,N’,N’-tetrakis(2-hydroxypropyl) ethylenediamine  Sigma Aldrich 122262
Phosphate Buffer Saline Sigma Aldrich P5368-10PAK
Triton X-100 Sigma Aldrich T8787
Urea Sigma Aldrich U-1250
Sucrose Sigma Aldrich 84097
Glycerol Sigma Aldrich G8773
Tamoxifen Sigma Aldrich T5648
Sunflower seed oil Sigma Aldrich S5007
Tween 20 Sigma Aldrich P1379
PECAM (CD31) BD Pharmingen  550274
Alexa Fluor 647  Invitrogen A-21247
DAPI nuclear stain Sigma Aldrich D9542
37oC Incubator Thermoscientific Fischer Heratherm, Compact Microbiological Incubators
48 well plates Cell Treat 229148
Analytical Balance Metler Toledo PB153-S/FACT
Confocal microscope Zeiss Zeiss 510 confocal microscope
Disecting Microscope Unitron Z850
Fluorescent microscope Zeiss Observer. Z1
Germinator 500 Glass Bead Sterilizer CellPoint Scientific GER-5287-120V
Light Source SCHOTT ACE I
Pair of Scissors Fine Science Tools 14084-08
Petri dish 60x15mm  TPP Techno Plastic Products AG 93060
Rocker II  Platform Rocker Boekel Scientific 260350
Scintillating tubes Fischer Scientific  03-337-26
Transfer pipette Samco Scientific 202
Tweezers Fine Science Tools 11251-20
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Referencias

  1. Vincent, S. D., Buckingham, M. E. How to make a heart: the origin and regulation of cardiac progenitor cells. Curr Top Dev Biol. 90, 1-41 (2010).
  2. Olson, E. N. A decade of discoveries in cardiac biology. Nat Med. 10, 467-474 (2004).
  3. Olson, E. N. Gene regulatory networks in the evolution and development of the heart. Science. 313, 1922-1927 (2006).
  4. Bruneau, B. G. The developmental genetics of congenital heart disease. Nature. 451, 943-948 (2008).
  5. Mohun, T. J., Weninger, W. J. Embedding embryos for high-resolution episcopic microscopy (HREM). Cold Spring Harb Protoc. , 678-680 (2012).
  6. Soufan, A. T., et al. Three-dimensional reconstruction of gene expression patterns during cardiac development. Physiol Genomics. 13, 187-195 (2003).
  7. Richardson, D. S., Lichtman, J. W. Clarifying Tissue Clearing. Cell. 162, 246-257 (2015).
  8. Susaki, E. A., et al. Whole-brain imaging with single-cell resolution using chemical cocktails and computational analysis. Cell. 157, 726-739 (2014).
  9. Becker, K., Jahrling, N., Saghafi, S., Weiler, R., Dodt, H. U. Chemical clearing and dehydration of GFP expressing mouse brains. PLoS One. 7, e33916 (2012).
  10. Erturk, A., et al. Three-dimensional imaging of solvent-cleared organs using 3DISCO. Nat Protoc. 7, 1983-1995 (2012).
  11. Ke, M. T., Fujimoto, S., Imai, T. SeeDB: a simple and morphology-preserving optical clearing agent for neuronal circuit reconstruction. Nat Neurosci. 16, 1154-1161 (2013).
  12. Chung, K., et al. Structural and molecular interrogation of intact biological systems. Nature. 497, 332-337 (2013).
  13. Yang, B., et al. Single-cell phenotyping within transparent intact tissue through whole-body clearing. Cell. 158, 945-958 (2014).
  14. Hama, H., et al. Scale: a chemical approach for fluorescence imaging and reconstruction of transparent mouse brain. Nat Neurosci. 14, 1481-1488 (2011).
  15. Badea, T. C., Wang, Y., Nathans, J. A noninvasive genetic/pharmacologic strategy for visualizing cell morphology and clonal relationships in the mouse. J Neurosci. 23, 2314-2322 (2003).
  16. Livet, J., et al. Transgenic strategies for combinatorial expression of fluorescent proteins in the nervous system. Nature. 450, 56-62 (2007).
  17. Agah, R., et al. Gene recombination in postmitotic cells. Targeted expression of Cre recombinase provokes cardiac-restricted, site-specific rearrangement in adult ventricular muscle in vivo. J Clin Invest. 100, 169-179 (1997).
  18. Jiao, K., et al. An essential role of Bmp4 in the atrioventricular septation of the mouse heart. Genes Dev. 17, 2362-2367 (2003).
  19. Wu, B., et al. Endocardial cells form the coronary arteries by angiogenesis through myocardial-endocardial VEGF signaling. Cell. 151, 1083-1096 (2012).
  20. Muzumdar, M. D., Tasic, B., Miyamichi, K., Li, L., Luo, L. A global double-fluorescent Cre reporter mouse. Genesis. 45, 593-605 (2007).
  21. Wu, M., et al. Epicardial spindle orientation controls cell entry into the myocardium. Dev Cell. 19, 114-125 (2010).
  22. Zhao, C., et al. Numb family proteins are essential for cardiac morphogenesis and progenitor differentiation. Development. 141, 281-295 (2014).
  23. Kaufman, M. H., Kaufman, M. H. . The atlas of mouse development. , (1992).
  24. Nagy, A. . Manipulating the mouse embryo : a laboratory manual. , (2003).
  25. Buckingham, M., Meilhac, S., Zaffran, S. Building the mammalian heart from two sources of myocardial cells. Nat Rev Genet. 6, 826-835 (2005).
  26. Kelly, R. G., Buckingham, M. E. The anterior heart-forming field: voyage to the arterial pole of the heart. Trends Genet. 18, 210-216 (2002).
  27. Verzi, M. P., McCulley, D. J., De Val, S., Dodou, E., Black, B. L. The right ventricle, outflow tract, and ventricular septum comprise a restricted expression domain within the secondary/anterior heart field. Dev Biol. 287, 134-145 (2005).
  28. Ward, C., Stadt, H., Hutson, M., Kirby, M. L. Ablation of the secondary heart field leads to tetralogy of Fallot and pulmonary atresia. Dev Biol. 284, 72-83 (2005).
  29. Echelard, Y., Vassileva, G., McMahon, A. P. Cis-acting regulatory sequences governing Wnt-1 expression in the developing mouse CNS. Development. 120, 2213-2224 (1994).
  30. Jiang, X., Rowitch, D. H., Soriano, P., McMahon, A. P., Sucov, H. M. Fate of the mammalian cardiac neural. Developement. 127, 1607-1616 (2000).
  31. Viragh, S., Challice, C. E. The origin of the epicardium and the embryonic myocardial circulation in the mouse. Anat Rec. 201, 157-168 (1981).
  32. Wu, M., Li, J. Numb family proteins: novel players in cardiac morphogenesis and cardiac progenitor cell differentiation. Biomolecular concepts. 6, 137-148 (2015).
  33. Li, J., et al. Single-Cell Lineage Tracing Reveals that Oriented Cell Division Contributes to Trabecular Morphogenesis and Regional Specification. Cell reports. 15, 158-170 (2016).
  34. Alkaabi, K. M., Yafea, A., Ashraf, S. S. Effect of pH on thermal- and chemical-induced denaturation of GFP. Appl Biochem Biotechnol. 126, 149-156 (2005).
  35. Captur, G., et al. Morphogenesis of myocardial trabeculae in the mouse embryo. J Anat. , (2016).

Tags

Single-cell ResolutionCardiac DevelopmentFluorescent ProteinPECAMAlexa Fluor 647DAPICUBICSCALEEmbryonic HeartPostnatal HeartGene FunctionProtein FunctionImagingConfocal Microscopy

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Shaikh Qureshi, W. M., Miao, L., Shieh, D., Li, J., Lu, Y., Hu, S., Barroso, M., Mazurkiewicz, J., Wu, M. Imaging Cleared Embryonic and Postnatal Hearts at Single-cell Resolution. J. Vis. Exp. (116), e54303, doi:10.3791/54303 (2016).
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