Summary

Isolation of Endocardial and Coronary Endothelial Cells from the Ventricular Free Wall of the Rat Heart

Published: April 15, 2020
doi:

Summary

We present a protocol for the isolation of endocardial and coronary endothelial cells from rat hearts through sequential tissue digestion in a digestion buffer, cell collection from recurrent centrifuge cycles, and cell purification using anti-rat CD31 microbeads.

Abstract

It has been shown that endocardial endothelial cells (EECs) and coronary endothelial cells (CECs) differ in origin, development, markers, and functions. Consequently, these two cell populations play unique roles in cardiac diseases. Current studies involving isolated endothelial cells investigate cell populations consisting of both EECs and CECs. This protocol outlines a method to independently isolate these two cell populations for cell-specific characterization. Following the collection of the left and right ventricular free wall, endothelial cells from the outer surface and inner surface are separately liberated using a digestion buffer solution. The sequential digestion of the outer surface and the inner endocardial layer retained separation of the two endothelial cell populations. The separate isolation of EECs and CECs is further verified through the identification of markers specific to each population. Based on previously published single cell RNA profiling in the mouse heart, the Npr3, Hapln1, and Cdh11 gene expression is unique to EECs; while Fabp4, Mgll, and Cd36 gene expression is unique to CECs. qPCR data revealed enriched expression of these characteristic markers in their respective samples, indicating successful EEC and CEC isolation, as well as maintenance of cell phenotype, enabling further cell-specific functional analysis.

Introduction

This article provides a detailed protocol (modified from Gladka et al.1) for the dissection and subsequent isolation of endocardial endothelial cells (EECs) and coronary endothelial cells (CECs) from rat hearts. The ability to investigate these cell populations independently would enable the exploration of cell type-specific mechanisms underlying a variety of heart diseases that could serve as potential therapeutic targets. A successful method for the collection of these cell populations independently has yet to be published, however.

CECs differ from EECs in regards to their origin, markers, and functions during heart development and disease1,2,3,4,5,6,7. EECs stem from the ventral surface of the cardiac mesoderm3. They arise from Flk1+ progenitor cells in response to VEGF and HIF signaling and form the innermost layer of the three discrete regions of the developing heart: the atrium, ventricle, and sinus venosus3,6. Genetic lineage tracing suggests that the pluripotent endocardial cells of the sinus venosus derive venous cells, which migrate to form the subepicardial layer3. Subsequently, the subepicardial layer differentiates into coronary arteries and veins, including CECs, which remain across the peripheral ventricular free wall3,4. This endocardial to endothelial pathway is regulated by VEGFC, ELA/APJ, and SOX17 signaling3,4,6,8,9. The ventricular endocardium derives the fewer CECs of the interventricular septum by an unknown mechanism3. Subsequently, localized differentiation between EECs and CECs is suggested by markers specific to these two cell populations, including Mgll, Fabp4, and Cd36 expression in CECs, or Npr3, Cdh11, and Hapln1 expression in EECs3,5,10.

EECs and CECs play different roles in cardiac function. Endocardial to mesenchymal transition, valve formation, chamber maturation, outflow tract regulation, and atrioventricular canal development are contingent on EECs6. Alternatively, CECs contribute to vasomotor tone and inflammation of coronary arteries11. These variances in function result in individualized roles in disease development4,12. For instance, evidence suggests that malfunctioning EECs may lead to congenital valve disease6, noncompaction myocardium6, atrioventricular septal effect6, endocardial fibroelastosis13, hypoplastic left heart syndrome13, ventricular hypoplasia13, and cardiac hypertrophy12. Similarly, studies have found that abnormal CECs contribute to coronary artery disease14 and thrombosis11.

Successful isolation of EECs and CECs is necessary to achieve comprehensive knowledge of these two cell populations, which could be utilized in both the research and clinical settings. Determining the growth and differentiation factors of these cell populations would provide a reference for the differentiation of endothelial subtypes from induced pluripotent stem cells (iPSCs). Further, complete identification of the variances in the development, regulation, and function of EECs and CECs is vital for understanding the genomic and epigenomic factors responsible for numerous heart diseases in a cell type-specific manner. This article outlines steps for the successful collection of EECs and CECs independently, and provides evidence of separation by assessing the gene expression levels of cell type-specific markers.

Protocol

All animal procedures were approved by the Administrative Panel on Laboratory Animal Care (APLAC31608) at Stanford University.

1. Preparation of buffers

  1. Prepare the digestion buffer using the reagents listed in Table 1.
    1. Prepare the DNase I stock solution: Dissolve DNase I in RNase-free water for a stock solution of 2,000 units/mL (1 mg/mL). Aliquot and store the stock solution at -20 ˚C.
    2. Prepare the liberase solution: Dissolve liberase with RNase-free water for a stock solution of 5 mg/mL. Rotate it on a roller bank at 4 ˚C for 30 min. Aliquot and store the stock solution at -20 ˚C.
  2. Prepare the sorting buffer by diluting 0.5 M ethylenediaminetetraacetic acid (EDTA) and 10% bovine serum albumin (BSA) stock solution with 1x phosphate buffered saline (PBS) for a final concentration of 2 mM of EDTA and 0.5% of BSA.

2. Heart collection

NOTE: Six Sprague Dawley rats weighing 50–100 g were used in this protocol. No gender difference was observed.

  1. Euthanize the rat with CO2 and place it in a supine position on a dissecting platform. Pin the extremities down and sterilize both the abdomen and chest with 70% ethanol.
  2. Open the abdomen with scissors and insert a 21 G needle into the portion of the posterior vena cava located behind the intestines. Pull the syringe plunger back, withdrawing the blood from the vein until the liver appears lighter in color and no more blood can be withdrawn, indicating sufficient blood removal.
  3. Using scissors, open the chest carefully to avoid damaging the lung and the heart. Lift the aorta arch/atrium with the forceps and cut the aorta, pulmonary artery, pulmonary veins, and vena cava to liberate and remove the heart.
  4. Wash the heart with 50 mL of cold 1x Hanks' balanced salt solution (HBSS) buffer 3x to remove excessive blood.
  5. Under a microdissection microscope, remove the right ventricular free wall into a 5 mL tube containing Dulbecco's modified Eagle medium (DMEM) (Figure 1A,B).
    1. Lay the heart on its flatter, posterior face to identify the left and right side.
    2. Locate the pulmonary artery, the most anterior of the veins and arteries branching from the top of the heart and cut through the pulmonary artery down to the right ventricular chamber. On the anterior face of the heart, cut along the septum until reaching the apex. Continue cutting from the apex up the posterior side of the heart along the septum until the pulmonary artery and right ventricular chamber junction point (Figure 1A).
    3. Starting from the pulmonary artery and right ventricular junction point, cut both the anterior and posterior side of the heart perpendicularly to the previous dissection and away from the septum, until the right ventricular free wall is liberated from the rest of the heart (Figure 1B).
  6. Under the microdissection microscope, remove the left ventricular free wall into a 5 mL tube containing DMEM (Figure 1C,D).
    1. Locate the aorta, branching from the top of the heart behind the pulmonary artery, and repeat the method described in step 2.5 to cut off the left ventricular free wall.

3. EEC digestion

  1. Place both right and left ventricular free wall tissues in a 60 cm culture dish with the inner surface lying flat, facing down (Figure 2).
    NOTE: The inner surface is the interior face of the slightly concave shaped ventricle as shown in Figure 2A,C.
  2. Add 0.5–1 mL of digestion buffer to the dish, placing the tip of the pipette directly under the tissue. Continue until only the inner surface is immersed.
  3. Incubate the dish in a 5% CO2, 37 ˚C incubator for 5 min.
  4. Add EC medium to the culture dish to stop the digestion.
    NOTE: Keep the amount of digestion buffer to EC medium as a 1:5 ratio.
  5. Use a 1 mL pipette to flush the inner surface of the ventricles with EC medium and transfer the runoff into a 50 mL collection tube through a 40 mm strainer (Figure 2E). Keep the collections on ice for downstream purification.

4. CEC digestion

  1. Cut along the outer surface of the left ventricle without contamination from the inner layer (Figure 2B,D) and place each in a separate 5 mL tube containing 1 mL of the digestion buffer.
    NOTE: The left ventricle can be identified as the thicker ventricle, and the outer surface can be determined as the exterior face of the slightly concave ventricle.
  2. Using dissection scissors, mince the ventricular wall into small, 1 mm3 pieces.
  3. Incubate the tube in a 37 ˚C water bath for about 15–20 min. Vortex every 2–3 min.
  4. Pipette 4 mL of EC medium into the 5 mL tube to terminate the digestion.
  5. Transfer the solution with a 5 mL serological pipette into a 50 mL tube through a 40 mm strainer (Figure 2E). Keep the collections on ice for downstream purification.

5. Cell collection

  1. Centrifuge the tubes at 300 x g for 10 min at room temperature (RT) and then aspirate the supernatant.
  2. If the pellet appears red, resuspend the pellet in 1–2 mL of 1x red blood cell (RBC) lysing buffer (Figure 2F).
    NOTE: If there are no RBCs, proceed to step 6.
  3. Incubate the tubes in a 37 ˚C water bath for 5 min.
  4. Pipette 10 mL of PBS into the 50 mL tubes to stop the lysis.
  5. Centrifuge the tubes at 300 x g for 10 min at RT, and then aspirate the supernatant.

6. EC sorting

  1. Add 90 μL of sorting buffer and 10 μL of anti-CD31 PE antibody into the 50 mL tubes.
  2. Vortex the tubes and then incubate them for 10 min in a 4 ˚C fridge.
  3. Add 10 mL of sorting buffer into the tubes, mix thoroughly, and then centrifuge at 300 x g for 10 min at RT.
  4. Aspirate the supernatant and resuspend the pellet in 80 µL of sorting buffer and 20 µL of anti-PE microbeads.
  5. Vortex the tubes and incubate at 4 ˚C for 15 min.
  6. Wash the cells by adding 10 mL of sorting buffer into the tubes, mix thoroughly, and then centrifuge them at 300 x g for 10 min at RT.
  7. Aspirate the supernatant and resuspend the pellet in 500 μL of sorting buffer.
  8. Place a column containing superparamagnetic spheres into a magnetic separator and rinse the column with 3 mL of sorting buffer.
  9. After the column are “flow stop”, pipette 500 μL of the cell suspension into the columns and then wash the columns with sorting buffer. Repeat the wash 3x, each with 3 mL of sorting buffer (Figure 2G).
  10. Remove the columns from the separator and place them on top of a new 15 mL collection tube.
  11. With a pipette, add 5 mL of EC medium to the columns, and propel the solution through using a column plunger.
  12. Centrifuge the collection tubes at 300 x g for 10 min at RT and then aspirate the supernatant.
  13. Extract the RNA from the cell pellet of the EEC and CEC samples using a kit, following the manufacturer’s instructions. A minimum of 500 ng of RNA can be obtained.
    NOTE: After RNA extraction, the sample can be stored at -80 ˚C.
  14. Reverse transcribe 500 ng of RNA to get cDNA using a random primer and a kit, following the manufacturer’s instructions.
  15. Perform quantitative PCR for the validation of endocardial and endothelial populations (Figure 2H). Primer sequences are listed in Table 2.
    1. Add 5 μL of EEC or CEC cDNA (1 ng/μL) into the wells of a 384 qPCR plate. Add the EEC or CEC cDNA into enough wells so that there are three wells per number of primers.
    2. Mix 6 μL of 2x qPCR SYBR green buffer with 0.5 μL of each 10 μM primer, including both forward and reverse primers, and add them into a single well corresponding to each candidate gene.
    3. Seal the plate with plastic film and centrifuge for 1 min at 300 x g at RT.
    4. Place the plate into a qPCR machine and then start the program at 95 ˚C for 3 min, followed by 95 ˚C for 15 s, and then 55 ˚C for 60 s. Repeat the subsequent two steps for 45 cycles.

Representative Results

The process of EEC and CEC isolation is described in Figure 2. The successful isolation of EECs and CECs was determined by assessing the presence of pan-endothelial cell markers, as well as those distinct to the two subtype populations. As predicted, qPCR revealed that relative to β-actin, EECs expressed higher levels of endocardial markers Npr3, Hapln1, and Cdh11 compared to CECs (Figure 3A). Likewise, CECs expressed higher levels of coronary markers Fabp4, Mgll, and Cd36 compared to EECs (Figure 3B). Additionally, both EECs and CECs expressed the pan-EC marker gene Cdh5, with slightly higher levels in CEC (Figure 3C).


Figure 3
Figure 1: Diagram of heart dissection. (A) First cut made to separate the right ventricle free wall from the septum. (B) Second cut made to liberate the right ventricle completely. (C) First cut made to separate the left ventricle free wall from the septum. (D) Second cut made to liberate the left ventricle completely. Please click here to view a larger version of this figure.


Figure 3
Figure 2: Diagram of digestion set-up of the CECs and EECs and the following arrangement for cell sorting. (A) Innermost free ventricular wall and (B) outermost ventricular free wall were (C) immersed in digestion buffer or (D) digested in digestion buffer respectively. (E) Collection and filtration of cell solutions followed by (F) red blood cell (RBC) lysis and (G) magnetic-activated cell sorting (MACS) using the CD31 antibody. (h) Purified ECs were processed for gene expression verification using qPCR. Please click here to view a larger version of this figure.


Figure 3
Figure 3: qPCR data verifying isolation of CECs and EECs. (A) Gene expression levels of the EEC markers Npr3, Cdh11, and Hapln1 in EECs and CECs were quantified by real-time PCR. (B) Gene expression levels of the CEC markers Mgll, Fabp4, and Cd36 in EECs and CECs were quantified by real-time PCR. (C) The pan-EC marker Cdh5 was quantified in EECs and CECs by real-time PCR. (n = 3 in each group). Bars represent mean ± SEM. *p < 0.05, **p < 0.01 vs. EEC, unpaired t-test. Please click here to view a larger version of this figure.

Table 1. Digestion Buffer (1.5ml)
  Stock Con. Final Con. Volume
Liberase TM 5 mg/ml 0.5 mg/ml 150 ul
Dnase I 1 mg/ml 20 ug/ml 30 ul
HEPES 1 M 10 mM 15 ul
DMEM 1305 ul

Table 1: Recipe for the digestion buffer.

Table 2. Primer Sequences
Gene Name Forward Reverse
Npr3 TCCTTGCAAATCATGTGGCCTA GGAATCTTCCCGCAGCTCTC
Cdh11 GTGAATGGGACTGGGACTGG GTAATTTCTGGGGCCCTTGC
Hapln1 CCAGCTAAGTGGGACTCGAAG GGGCCATTTTCAGCTTGGATG
Mgll CCCGGGGCCCAAAGAC GAAGATGAGGGCCTTGGGTG
Fabp4 AGAAGTGGGAGTTGGCTTCG ACTCTCTGACCGGATGACGA
Cd36 GCAAAACGACTGCAGGTCAA CCCGGTCACTTGGTTTCTGA
Cdh5 CCATTGAGACAGACCCCGAC TGTGGAACGTGTACTGCTGG
B-actin TCTGTGTGGATTGGTGGCTC CGGACTCATCGTACTCCTGC

Table 2: Primer Sequences

Discussion

CECs and EECs differ in origin, markers, and functions, and thus could play unique roles in development and disease. Existing protocols for endothelial cell isolation are limited to macrovascular tissues, neglecting the collection of EECs, thus restricting the study of CEC- and EEC-specific functions. It is essential to isolate and study these two populations independently, as this knowledge would provide a reference for the differentiation of iPSCs into CECs and EECs for future studies and facilitate the examination of these cell populations for potential therapeutic targets for various cardiac diseases. This novel protocol outlines a method for the isolation of EECs from the inner surface and CECs from the outer surface of the ventricular free wall of adult rats.

It is critical to control the timing for each step very precisely in this protocol. Because the number of EECs is very limited in rat heart tissue, we minimized the digestion time of the inner layer of the heart to prevent cellular damage and more importantly, CEC contamination. Immediate addition of the EC medium solution to terminate the enzymatic reaction is also very important for maintaining high cell viability. A red pellet following cell collection suggests the presence of a large number of RBCs. Depending on the amount of RBC contamination, 1–2 mL of RBC lysis buffer can be added to degrade the RBCs. Incubation must be carefully timed to avoid significant damage to the cells, and PBS is promptly added to terminate the reaction. Using the current protocol, we were able to isolate 105 EECs from six rat hearts. These cells could be seeded onto a cell culture dish for further expansion and characterization.

When preparing the tissue for free wall collection, the heart was washed with HBSS to remove the majority of the remaining RBCs. HBSS is the recommended medium due to its clear appearance, which enables the visualization of blood cells, in contrast to DMED containing phenol red. The composition of the digestion buffer ensures sufficient liberation of endothelial cells, where liberase digestion enzyme strips the tissue of the exposed cells, DNase I eliminates DNA from the dead cells to promote cell detachment that may be inhibited by DNA’s adhesive quality, HEPES buffer balances the pH, and DMEM is a modified basal medium with a higher concentration of amino acids and vitamins for better cell maintenance and contains the calcium necessary to activate the liberase.

According to the single cell RNA sequencing (scRNA-seq) obtained from both human15 and mouse heart10, several markers attributed to specific EC populations were reported. We selected some of the most enriched genes to examine the purity of isolated EECs (i.e., Npr3, Cdh11, and Hapln1) and EECs (i.e., Mgll, Fabp4, and Cd36). Relative to β-Actin, Npr3, Cdh11, and Hapln1 markers demonstrated increased expression in EECs compared to CECs. Similarly, the expression of Mgll, Fabp4, and Cd36 markers was greater in CECs compared to EECs. The uniquely expressed markers for each sample is in accord with markers characteristic to EECs and CECs respectively, indicating successful isolation.

However, the current protocol cannot rule out cross contamination between the two EC populations during the isolation, even with carefully controlled sequential digestions. Therefore, some cell surface markers can be applied for further purification. For example, NPR3 generally labels the endocardium10, whereas APJ can trace a majority of the CECs16. Because these two markers are expressed on the cell surface, they could be used for fluorescence activated cell sorting (FACS), and antibodies used to further purify distinct EC populations. In addition, human15 and mouse10 heart scRNA-seq can confirm enrichment of Npr3 in EECs, and Cd36 can be potentially used for CEC purification.

In conclusion, the presented protocol outlines the independent isolation of EECs and CECs from the rat heart. The comprehensive identification of cellular properties, enabled by cell isolation, can be utilized for significant downstream applications.

Declarações

The authors have nothing to disclose.

Acknowledgements

The authors greatly appreciate Dr. Lingli Wang for her help with the animal protocol, and the Department of Pediatrics at Stanford for infrastructure support. This work was supported by NIH/NHLBI K99 HL135258 (to M.G.).

Materials

4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES) Gibco 15630080 1M
15ml Tubes Eppendorf 0030122151
50ml Tubes Nunc 339652
5ml Tubes Eppendorf 30119401
ACK Lysing Buffer Gibco A1049201
Anti-CD31 PE Miltenyi Biotec 130-115-505
Anti-PE microbeads Miltenyi Biotec 130-048-801
Bovine serum albumin (BSA) Miltenyi Biotec 130-091-376 10%
CFX384 Touch Real-Time PCR Detection System Bio-rad 1855485 For qPCR
DNAse I Worthington LK 003172 1 mg/mL in water
Dulbecco's Modified Eagle Medium (DMEM) Gibco 10313021
Endothelial Cell Growth Medium-2 (EGM-2) Lonza CC-3162 EC Medium
Ethylendiaminetetraacetic Acid (EDTA) Invitrogen 15575020 0.5 M
Hank's Balanced Salt Solution (HBSS) X1 Gibco 14025092
Hard-Shell 384-Well PCR Plates, thin wall, skirted, clear/white Bio-rad HSP3805 For qPCR
High-Capacity cDNA Reverse Transcription Kit Applied Biosystems 4368813
Liberase TM Sigma Aldrich 5401119001 5 mg/mL
MACS LS Column Miltenyi Biotec 130-042-401 For EC isolation
MACS MultiStand Miltenyi Biotec 130-042-302 For EC isolation
Microseal 'B' PCR Plate Sealing Film, adhesive, optical Bio-rad MSB1001 For qPCR
Narrow Pattern Forceps F.S.T 11002-12 For heart harvest
Nylon Sterile Strainer Falcon 352340 40 mm
Phosphate Buffered Saline (PBS) X1 Gibco 1001023
PowerUp SYBR Green Master Mix Applied Biosystems A25780 For qPCR
Quick-RNA Microprep Kit Zymo Research R1050 For RNA extraction
S&T Forceps – SuperGrip Tips F.S.T 00632-11 For heart harvest
Strabismus Scissors – Tungsten Carbide F.S.T 14574-11 For heart harvest
Vannas Spring Scissors – Microserrated F.S.T 15007-08 For heart harvest

Referências

  1. Gladka, M. M., et al. Single-Cell Sequencing of the Healthy and Diseased Heart Reveals Cytoskeleton-Associated Protein 4 as a New Modulator of Fibroblasts Activation. Circulation. 138 (2), 166-180 (2018).
  2. Koren, C. W., Sveinbjornsson, B., Smedsrod, B. Isolation and culture of endocardial endothelial cells from Atlantic salmon (Salmo salar) and Atlantic cod (Gadus morhua). Cell and Tissue Research. 290 (1), 89-99 (1997).
  3. Tian, X., et al. Subepicardial endothelial cells invade the embryonic ventricle wall to form coronary arteries. Cell Research. 23 (9), 1075-1090 (2013).
  4. Wu, B., et al. Endocardial cells form the coronary arteries by angiogenesis through myocardial-endocardial VEGF signaling. Cell. 151 (5), 1083-1096 (2012).
  5. Li, Y., Lui, K. O., Zhou, B. Reassessing endothelial-to-mesenchymal transition in cardiovascular diseases. Nature Reviews in Cardiology. 15 (8), 445-456 (2018).
  6. Zhang, H., Lui, K. O., Zhou, B. Endocardial Cell Plasticity in Cardiac Development, Diseases and Regeneration. Circulation Research. 122 (5), 774-789 (2018).
  7. Yu, S. Y., et al. Isolation and characterization of human coronary artery-derived endothelial cells in vivo from patients undergoing percutaneous coronary interventions. Journal of Vascular Research. 46 (5), 487-494 (2009).
  8. Red-Horse, K., Ueno, H., Weissman, I. L., Krasnow, M. A. Coronary arteries form by developmental reprogramming of venous cells. Nature. 464 (7288), 549-553 (2010).
  9. Kamimura, T., Yamagishi, T., Nakajima, Y. Avian coronary endothelium is a mosaic of sinus venosus- and ventricle-derived endothelial cells in a region-specific manner. Development, Growth and Differentiation. 60 (2), 97-111 (2018).
  10. Zhang, H., et al. Endocardium Minimally Contributes to Coronary Endothelium in the Embryonic Ventricular Free Walls. Circulation Research. 118 (12), 1880-1893 (2016).
  11. Kinlay, S., Libby, P., Ganz, P. Endothelial function and coronary artery disease. Current Opinion in Lipidology. 12 (4), 383-389 (2001).
  12. Jacques, D., Bkaily, G. Endocardial endothelial cell hypertrophy takes place during the development of hereditary cardiomyopathy. Molecular and Cell Biochemistry. 453 (1-2), 157-161 (2019).
  13. Grossfeld, P., Nie, S., Lin, L., Wang, L., Anderson, R. H. Hypoplastic Left Heart Syndrome: A New Paradigm for an Old Disease. Journal of Cardiovascular Development and Disease. 6 (1), (2019).
  14. Li, Y., et al. Down-regulated RGS5 by genetic variants impairs endothelial cell function and contributes to coronary artery disease. Cardiovascular Research. , (2019).
  15. Miao, Y., et al. Single-Cell RNA-Seq Reveals Endocardial Defect in Hypoplastic Left Heart Syndrome. bioRxiv. , (2019).
  16. Chen, H. I., et al. The sinus venosus contributes to coronary vasculature through VEGFC-stimulated angiogenesis. Development. 141 (23), 4500-4512 (2014).

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Klein, A., Bayrau, B., Miao, Y., Gu, M. Isolation of Endocardial and Coronary Endothelial Cells from the Ventricular Free Wall of the Rat Heart. J. Vis. Exp. (158), e61126, doi:10.3791/61126 (2020).

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