JoVE Journal > Bioengineering
Summary
Abstract
Introduction
Protocol
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Biotechnik

Generation of Human Blood Vessel Organoids from Pluripotent Stem Cells

Published: January 20, 2023
doi:
10.3791/64715
,
1School of Biomedical Engineering,University of British Columbia, 2Life Sciences Institute,University of British Columbia, 3Department of Medical Genetics,University of British Columbia, 4Institute of Molecular Biotechnology of the Austrian Academy of Sciences (IMBA)

Summary

This protocol describes the generation of self-organizing blood vessels from human pluripotent and induced pluripotent stem cells. These blood vessel networks exhibit an extensive and connected endothelial network surrounded by pericytes, smooth muscle actin, and a continuous basement membrane.

Abstract

An organoid is defined as an engineered multicellular in vitro tissue that mimics its corresponding in vivo organ such that it can be used to study defined aspects of that organ in a tissue culture dish. The breadth and application of human pluripotent stem cell (hPSC)-derived organoid research have advanced significantly to include the brain, retina, tear duct, heart, lung, intestine, pancreas, kidney, and blood vessels, among several other tissues. The development of methods for the generation of human microvessels, specifically, has opened the way for modeling human blood vessel development and disease in vitro and for the testing and analysis of new drugs or tissue tropism in virus infections, including SARS-CoV-2. Complex and lengthy protocols lacking visual guidance hamper the reproducibility of many stem cell-derived organoids. Additionally, the inherent stochasticity of organoid formation processes and self-organization necessitates the generation of optical protocols to advance the understanding of cell fate acquisition and programming. Here, a visually guided protocol is presented for the generation of 3D human blood vessel organoids (BVOs) engineered from hPSCs. Presenting a continuous basement membrane, vascular endothelial cells, and organized articulation with mural cells, BVOs exhibit the functional, morphological, and molecular features of human microvasculature. BVO formation is initiated through aggregate formation, followed by mesoderm and vascular induction. Vascular maturation and network formation are initiated and supported by embedding aggregates in a 3D collagen and solubilized basement membrane matrix. Human vessel networks form within 2-3 weeks and can be further grown in scalable culture systems. Importantly, BVOs transplanted into immunocompromised mice anastomose with the endogenous mouse circulation and specify into functional arteries, veins, and arterioles. The present visually guided protocol will advance human organoid research, particularly in relation to blood vessels in normal development, tissue vascularization, and disease.

Introduction

Vascular dysfunction and blood vessel diseases present with marked complications in organ functions. Cardiovascular disease (CVD) is the leading cause of death worldwide1 and is also the primary contributing factor to increasing healthcare costs in the United States. CVD case numbers are increasing annually, and rising numbers of these cases are occurring in younger age groups (20-45 years)2. Multiple in vivo models have been developed to explore the development and maturation of blood vessels, vascular disease, and endothelial dysfunction3,4. Currently, methods combining single and multiple lineage-defined cells either derived from stem cells or isolated from adult tissues in vivo can create vascular networks that replicate aspects of human vascular function and anatomy5,6. Blood vessels have emerged as one of the first functional systems during development from the mesoderm, and they organize either through a process of assembly called "vasculogenesis" or by expansion and branching from pre-existing vessels, which is termed "angiogenesis"7.

Leveraging the power of developmental biology and self-directed assembly, Wimmer et al. reported the first self-organizing 3D human blood vessel organoids from hPSCs that exhibit the functional, morphological, and molecular characteristics of human microvasculature8. Similar to human vasculature9, these hBVOs are generated and present with an endothelium, a continuous basement membrane, and surrounding mural cells8,10. The hBVOs can be transplanted in vivo and anastomosed with the endogenous circulation. They can also undergo maturation in vitro and serve as models for cardiovascular diseases (i.e., diabetes)8 or tissue tropism in virus infections such as SARS-CoV-211. While we previously published a written protocol10, there exists no available video protocol for this otherwise complex technique.

Through a concise stepwise progression, hBVO formation is accomplished through aggregate formation, mesoderm induction using a WNT agonist, Chiron (CHIR99021), and bone morphogenic protein – 4 (BMP4)12,13, vascular induction via vascular endothelial growth factor A (VEGFA) and Forskolin (Fors)12, and embedding in a custom sprouting matrix8,10. Vascular maturation and network formation follow the embedding of the aggregates in the sprouting matrix. These human vessel networks form within 2-3 weeks and can be removed from the sprouting matrix and further grown in scalable culture systems for up to 6 months. Here, optically guided procedures are provided for the formation and application of human stem cell-derived vasculature.

Protocol

All experiments performed herein used the commercially available H9 human iPSC line. Common commercially and non-commercially available human pluripotent stem cell lines (i.e., H9, NC8) have also been tested and proven effective for the generation of human blood vessel organoids using this protocol. For details, please refer to our previously published reports8,10.

1. Media and reagent formulation for the generation of human blood vessel organoids

  1. Prepare the aggregation medium.
    1. Mix 40 mL of knock-out DMEM/F12 (low osmolality medium without L-glutamine or HEPES buffer optimized for human ESC and iPSC growth), 10 mL of knock-out serum replacer (KOSR), 0.5 mL of 200 mM L-alanyl-L-glutamine dipeptide in 0.85% NaCl, 0.5 mL of non-essential amino acids (NEAA), 35 µL of beta-mercaptoethanol (BME, 100 µL of 2-mercaptoethanol in 10 mL of sterile PBS), and Y-27632 (cell-permeable and selective inhibitor of Rho-associated, coiled-coil containing protein kinase [ROCK]14 [10 mM] at 1:200) (see Table of Materials).
  2. Prepare N2B27 (N2 and B27 supplemented basic medium).
    1. Mix 25 mL of DMEM/F12, 25 mL of neurobasal media, 1 mL of B27 supplement, 0.5 mL of N2 supplement, 250 µL of 200 mM L-alanyl-L-glutamine dipeptide in 0.85% NaCl, and 35 µL of beta-mercaptoethanol (see Table of Materials).
  3. Prepare the mesoderm induction medium.
    1. Supplement N2B27 medium with ChiR (12 µM, GSK3a/b inhibitor stimulating mesoderm induction) and BMP-4 (30 ng/mL, MSX2 activator inducing mesoderm lineage).
      NOTE: Stock (ChiR): 10 mM (use 1:833, or 1.2 µL/mL N2B27). Stock (BMP-4): 100 µg/mL (use 1:3333, or 0.3 µL/mL N2B27) (see Table of Materials).
  4. Prepare vascular induction medium.
    1. Supplement N2B27 medium with VEGFA (100 ng/mL) and forskolin (2 µM) (see Table of Materials).
  5. Prepare the extracellular matrix (ECM).
    1. Use 1 mL of ECM for one well of a 12-well plate (for embedding 30-50 aggregates). Of the 1 mL of ECM solution used for each well, use 0.5 mL to create a bottom layer, "layer 1", which will serve as an ECM foundation, and 0.5 mL plus aggregates for the top layer, "layer 2". Using this approach provides, through the ECM suspension, sufficient space and support for the human blood vessel networks to sprout in all directions.
      NOTE: Overall, 1 mL of ECM contains 500 µL of purified bovine collagen type I, 250 µL of solubilized basement membrane matrix secreted by Engelbreth-Holm-Swarm mouse sarcoma cells (see Table of Materials), and 250 µL of basic matrix solution (step 1.5.2). Prepare it fresh and keep on ice until ready to use.
    2. To prepare the basic matrix solution for four 12-well plates (48 wells), mix 5.627 mL of 0.1 N NaOH, 2.498 mL of 10x DMEM, 473 µL of HEPES, 368 µL of 7.5% sodium bicarbonate, 233 µL of 200 mM L-alanyl-L-glutamine dipeptide in 0.85% NaCl, and 3.451 mL of Ham's F-12 (see Table of Materials).
      NOTE: The leftover basic matrix solution can be placed in a capped 50 mL high-clarity polypropylene conical tube and stored at 4 ˚C for use for up to 2 months.
  6. Prepare the sprouting medium.
    1. Specifically formulate 50 mL of flexible serum-free medium (SFM) to support the development of human hematopoietic cells, a 1.3 mL aliquot of the flexible serum-free medium nutrient supplement, 15% fetal bovine serum (FBS), 250 µL of penicillin-streptomycin, 500 µL of 200 mM L-alanyl-L-glutamine dipeptide in 0.85% NaCl, VEGFA (100 ng/mL), and FGF2 (100 ng/mL) (see Table of Materials).
  7. Prepare the blocking buffer.
    1. Mix 0.5 g of bovine serum albumin, 1.5 mL of fetal bovine serum, 250 µL of Tween 20, 250 µL of Triton X-100, 500 µL of sodium deoxycholate (1% wt/vol stock), and 47.5 mL of 1x phosphate-buffered saline (see Table of Materials). Pipette up and down until all the components are well incorporated and the solution is clear.

2. Maintenance and culture of human pluripotent and induced pluripotent stem cell

  1. Perform cell culture using LDEV-free reduced growth factor basement membrane matrix (1:50 dilution)-coated 6-well tissue culture plates with stem cell culture medium (see Table of Materials).
  2. Once the cells reach ~70% confluency, passage them using 1 mL of mammalian cell dissociating enzyme (see Table of Materials) for 3-4 min at 37 ˚C.
    NOTE: Splitting the cells at a ratio of 1:6 enhances the cell viability and achieves confluency within 2-4 days for most human stem cell lines. To increase the cell viability, ROCK inhibitor Y-27632-supplemented (10 mM, 1:1,000) culture medium is used for 24 h post passaging.
  3. Change the culture medium daily until a confluency of 70% is reached.
    NOTE: For the present study, at 70% confluency, one well of a 6-well cell culture plate contains around 1 million H9 hPSCs.

3. Day 0 – Generation of pluripotent aggregates from a single-cell suspension

NOTE: A confluency of 70% in two wells of a 6-well culture plate will yield approximately 175 hBVOs.

  1. Using either a pipette or vacuum system, aspirate the culture medium, replace it with 1 mL of cell dissociation reagent (see Table of Materials), and incubate for 5 min at 37 ˚C.
  2. While the cells are under the cell dissociation reagent, prepare the necessary volume of aggregation medium (step 1.1) in a 15 mL conical tube as needed for the desired number of wells in a 6-well ultra-low attachment culture plate (see Table of Materials).
  3. Aspirate the 1 mL of cell dissociation reagent, and suspend the cells in 1 mL of aggregation medium. Create a single-cell suspension with gentle up-down pipetting prior to counting the samples.
    CAUTION: hPSCs are quite sensitive to mechanical stress and cannot tolerate aggressive pipetting.
  4. Count the cells using an automated cell counting device10 or a standardized system under a microscope. Calculate the cell number needed for the experiment.
    NOTE: Depending on the cell line, 200,000 cells/well to 300,000 cells/well is considered ideal for aggregate formation (i.e., 4 wells = 800,000 to 1,200,000 cells in total).
  5. Add the appropriate volume of the cell suspension to the aggregation medium in the 15 mL high-clarity polypropylene conical tube. Gently pipette the diluted cell suspension up and down to ensure a homogenous cell distribution.
  6. Pipette 3 mL of the diluted cell suspension into each desired well of the 6-well ultra-low attachment culture plate.
  7. Place the plate in the incubator (37 ˚C, 5% CO2, >90% humidity), and avoid opening and closing the incubator doors as much as possible.
    NOTE: This initial step is best completed in the evenings or during low incubator traffic. Even slight vibrations can affect the size and shape of the aggregates, which can impair the results.

4. Day 1 – Mesoderm induction of aggregates

  1. Ensure that 24 h post seeding, small aggregates comprising 2-10 cells are visible under the microscope. Collect the aggregates, and allow them to settle prior to changing the medium to the mesoderm induction medium (step 1.3).
  2. Set up one 15 mL high-clarity polypropylene conical tube per well of the 6-well ultra-low attachment culture plate.
  3. Use a circular motion (i.e., like an orbital shaker) to gather the aggregates in the center of each well, use a 1 mL pipette to gently collect the aggregates and the surrounding medium from each well, place them into their corresponding 15 mL high-clarity polypropylene conical tubes, and allow the aggregates to sediment at room temperature.
  4. Once collected, set a timer for 1 h, which is the time required for most cell lines/aggregates to sediment at this stage.
    NOTE: If the time is less than 1 h, one might lose any aggregates that may not have settled to the bottom of the 15 mL conical tube.
  5. Once the hour has passed, with caution, aspirate the supernatant with a pipette or a high-sensitivity aspirating pump. Ensure the aggregates remain undisturbed at the bottom of the 15 mL conical tube.
  6. Resuspend the aggregates of each 15 mL conical tube in 2 mL of mesoderm induction medium, and place them back in their respective wells of the 6-well ultra-low attachment culture plate.
  7. Place the plate back in the incubator (37 ˚C), and leave it until day 4.
    NOTE: If the aggregates attach and grow onto or into one another, using a 1 mL pipette, gently pipette each well of aggregates up and down once per day to keep the aggregates similar in size.

5. Day 4 – Vascular induction and priming of the aggregates

  1. Collect the aggregates, and allow them to settle prior to changing the medium to the vascular induction medium (step 1.4).
  2. Set up one 15 mL conical tube per well of the 6-well ultra-low attachment culture plate.
  3. Use a circular motion (i.e., like an orbital shaker) to gather the aggregates in the center of each well, use a 1 mL pipette to gently collect the aggregates and the surrounding medium from each well, and place them into their corresponding 15 mL conical tubes.
  4. Once collected, set a timer for 30 min to allow the aggregates to sediment.
    NOTE: A time of 30 min is required for most cell lines at this stage. If the time is less than 30 min, there is a risk of losing any aggregates that may not have settled to the bottom of the 15 mL conical tube.
  5. After 30 min, with caution, aspirate the supernatant with a pipette or a high-sensitivity aspirating pump. Ensure the aggregates remain undisturbed at the bottom of the 15 mL conical tube.
  6. Resuspend the aggregates of each 15 mL conical tube in 2 mL of vascular induction medium, and place them back in their respective wells of the 6-well ultra-low attachment culture plate.
  7. Place the plate back in the incubator (37 ˚C), and leave it until day 6.
    NOTE: Using a 1 mL pipette, gently pipette each well of aggregates up and down once per day to keep the aggregates similar in size and prevent them from growing into or attaching to one another.

6. Day 6 – Aggregate embedding and vessel sprout induction

  1. While working on ice, prepare the desired final volume of the ECM solution (step 1.5).
    NOTE: The following is the protocol for one well of a 12-well plate (30-50 aggregates), which can be adjusted as necessary.
    1. For one well of a 12-well plate, apply 0.5 mL of ECM as the bottom layer, and use 0.5 mL of ECM plus aggregates on the top layer. This creates the ECM "sandwich" necessary for effective 3D aggregate sprouting.
  2. Pipette 500 µL of ECM into one well of a 12-well plate. Ensure that no bubbles are formed and the well bottom and side meniscus are completely coated. This comprises layer 1 of the ECM sandwich.
  3. Place the plate back at 37 ˚C for 2 h.
    NOTE: A time of 2 h is necessary for effective polymerization. Any shorter time risks compromising the ECM integrity.
  4. Toward the end of layer 1 polymerization, use a circular motion to gather the aggregates in the center of each well, use a 1 mL pipette to gently collect the aggregates and surrounding medium from each well, and place them into their corresponding 15 mL conical tubes.
  5. Allow the aggregates to settle for 10-15 min, and aspirate the supernatant.
  6. Place the aggregates in the 15 mL conical tube on ice for 5 min. While cooling, take the 12-well plate with the now polymerized layer 1 out of the incubator.
    NOTE: Cooling the aggregates helps prevent early polymerization of the layer 2 ECM.
  7. Working swiftly and carefully to prevent bubble formation, resuspend the aggregates in 500 µL of ECM, and pipette the ECM-aggregate suspension atop the already polymerized layer 1. Being cautious not to touch layer 1, use a 200 µL pipette tip to gently distribute layer 2 and the aggregates around the well.
  8. Place the plate back at 37 ˚C for 2 h.
    NOTE: An incubation time of 2 h is necessary for effective ECM polymerization. Any shorter time risks compromising the ECM integrity and may prevent strong adhesion between layer 1 and layer 2.
  9. Add 1 mL of pre-warmed (37 °C) sprouting medium (step 1.6) to induce blood vessel differentiation. Sprouting vessels must appear 1 day to 3 days post embedding. Change the medium after 3 days and then every other day.
    NOTE: The sprouting medium must be pre-warmed; otherwise, layer detachment may occur, and the ECM integrity may be impacted.

7. Day 11 – Isolation and maturation of the BVOs

  1. Working under sterile conditions, use the rounded end of a sterile spatula to loosen the ECM sprouting matrix containing the vascular networks. At this stage, the gel must resemble a free-floating disk.
    1. Using sterile forceps and the rounded end of a sterile spatula, carefully transfer the gel disk (including the vascular networks) to the lid of a 10 cm culture dish.
  2. Place the lid plus gel under a stereomicroscope adjusted to the desired magnification and focus, and use sterile needles to cut out single blood vessel networks, trying to limit the amount of non-vascularized ECM obtained in the process.
    NOTE: The cells naturally degrade the surrounding ECM over time; however, reducing the amount cut out with each organoid increases the image quality and the freestanding vessel network integrity.
  3. Once all the organoids have been isolated from the gel, gently transfer them back into one well of an ultra-low attachment 6-well plate with 3 mL of sprouting medium . At this stage, the organoids can be left overnight, or one may immediately continue to step 7.4.
  4. Use a 1 mL pipette to transfer single organoids from the 6-well plate to the wells of an ultra-low attachment 96-well plate. Once transferred, add 200 µL of pre-warmed (37 °C) sprouting medium to each well of the 96-well plate.
    NOTE: One well of vascular organoids from a 12-well plate must fill 30-40 wells of a 96-well plate.
  5. At 4-6 days post isolation in the 96-well plates, ensure that the organoids possess a round and healthy morphology. At this stage, the organoids are ready to be fixed and prepared for staining.

8. Day 15 – Fixation, blocking, and staining of the BVOs

  1. Using a cut 1 mL tip, transfer the organoids into a 1.5 mL microcentrifuge tube.
  2. Being careful to avoid the aspiration of any BVOs, use a 200 µL or 1,000 µL pipette to remove the remaining sprouting medium in the microcentrifuge tube, and then add 1 mL of 4% PFA in PBS for 1 h.
    NOTE: Fixation on an orbital shaker (125 rpm) at room temperature is recommended. A maximum of 60 BVOs/microcentrifuge tube is acceptable. Any more BVOs will impair the fixation and wash efficacy.
    CAUTION: PFA is a harmful chemical. Use it with caution in a fume hood, and follow the manufacturer's directions for use and appropriate disposal methods.
  3. Wash the newly fixed BVOs 3x for 15 min each time with 0.25% PBS-Tween.
  4. If the organoids are larger than 1 mm in diameter, permeabilize the BVOs with 1% Triton X-100 in PBS for 30-60 min at room temperature.
  5. Aspirate all the 0.25% PBS-Tween, and add 1 mL of blocking buffer (step 1.7).
    NOTE: Although antibody-dependant, 2 h at room temperature on an orbital shaker (125 rpm) is sufficient to reduce non-specific antibody binding during the staining process. The organoids can be left in the blocking buffer at 4 ˚C for up to 2 weeks.
  6. Remove the blocking buffer, and add the primary antibody (1:100) diluted in 1 mL of the blocking buffer. Keep overnight at 4 ˚C on an orbital shaker (12 rpm), ensuring the organoid(s) remain submerged in the primary antibody solution.
    NOTE: Overnight primary antibody incubation is suitable for the antibodies used for this study. The necessary primary and secondary antibodies and their respective dilutions are provided in the Table of Materials.
  7. Following overnight primary antibody incubation, remove the primary antibody solution and wash 3x for 15 min each time with 0.25% PBS-Tween.
  8. Add the secondary antibody (1:250) plus DAPI (1:1,000) diluted in 1 mL of blocking buffer, and incubate for 2 h at room temperature or at 4 ˚C overnight.
    NOTE: If the samples are prepared correctly (as described above), incubation for 2 h at room temperature or at 4 ˚C overnight is suitable for the antibodies used in the present study.
  9. Following incubation, remove the secondary antibody solution, and wash 3x for 15 min each time with 0.25% PBS-Tween.
    ​NOTE: Following the staining, the organoids can be kept in PBS for up to 2 weeks.

9. Mounting of the blood vessel organoids (BVOs)

  1. Glue mounting spacers onto the desired imaging coverslips (see Table of Materials).
  2. Using a cut 1 mm pipette tip, use a 1 mL pipette to transfer single organoids into the spacer wells, and aspirate the remaining PBS.
  3. Fill the well with 150-200 µL of clearing solution (see Table of Materials) heated to 75 ˚C, fully submerging the organoid.
    NOTE: The samples should become clear within 1 h of exposure to the warmed clearing solution.
    1. Leave the organoids to become clear in a covered box in the dark at room temperature for 6 h to overnight if the 1 h clearing time is insufficient. If leaving the sample overnight, ensure it has enough clearing solution to avoid drying out.
  4. After clearing, carefully aspirate the clearing solution with a 100-200 µL pipette tip. Gently maneuver the organoid to the center of the spacer well, and add drops of mounting gel (see Table of Materials) (warmed to 75 ˚C in a controlled heating block) until the well is full.
  5. Gently place the second coverslip on top of the mounting spacer to seal the samples in the space between the bottom and top coverslips. Let the mounting gel cure in the dark at 4 ˚C overnight.
    NOTE: Following the curing, topcoat nail polish can be used to further seal the mounted samples.

Representative Results

The steps described in this protocol were developed specifically to yield a controlled and precise method for the generation of human blood vessel organoids from hPSCs. The generation of aggregates of 30-100 µm in diameter from hPSC cultures marks the starting point of the protocol (Figure 1, Figure 2B). The aggregates are led through stepwise inductions toward mesoderm (day 1-day 4) and vascular lineages (day 4-day 6) prior to embedding (day 6) (Figure 2AD), which is necessary for vessel network formation. Near-radially symmetric vessel sprouting must be visible by d7 or d8 (Figure 2E) and continue through d10 (Figure 2F,G). The explantation of the hBVOs from the ECM to the 96-well ultra-low attachment plates reduces the fragility of the sprouting networks and allows for continued maintenance in suspension culture (Figure 2H) conditions for up to 6 months. By d15, the hBVOs exhibit an extensive and connected endothelial (CD31+) network surrounded by pericytes (PDGFR-ß+) and smooth muscle actin (SMA+) (Figure 3AD). A continuous collagen IV (ColIV+) basement membrane envelopes the vessel networks (Figure 3E). Endothelial cells (CD31+, VE-Cadherin+) and pericytes (PDGFR-ß+) comprise approximately 30%-35% and 60%-65% of the organoid cell populations, respectively8. The active sprouting of the vessels occurs under the direction of an endogenously organized tip cell (CD31+) population that presents with typical tip cell morphology, such as excessive filipodia8,10. The presentation of PDGFR-ß+ and SMA+ mural cells encapsulating the endothelial vessel networks can be seen by d15 of the organoid maturation process (Figure 3A,C). Following removal from the ECM and maturation in suspension culture (i.e., d15), the hBVOs are tenable for respective analyses or transplantation under the mouse kidney capsule.

Figure 1
Figure 1: Schematic of the hBVO protocol highlighting the timing and stepwise progression. From seemingly homogenous hPSC or hiPSC cultures, aggregate formation occurs in the presence of the Rho-kinase inhibitor Y27632. BMP4 and CHiR-supplemented medium is used to instruct the aggregates toward the mesodermal fate. Mesoderm induction medium is replaced by VEGFA and forskolin-supplemented medium to stimulate the aggregates toward a vascular lineage. Mechanical and chemical queues achieved through the embedding of the aggregates in a collagen I and solubilized basement membrane matrix and exposure to VEGFA and FGF2-containing medium results in near-radially symmetric vascular sprouting from the aggregate body. The vessel networks generated can be removed from the collagen I and solubilized basement membrane and placed in suspension culture for further maturation, analysis, or transplantation in vivo. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Stepwise progression of the hBVO generation captured under brightfield. (A) Typical morphology of hPSC (H9) colonies at day −1. (B) Generation of hPSC aggregates (day 0) on 6-well ultra-low attachment plates in the presence of Y-27632. (C) The mesodermal induction of aggregates using BMP4 and ChiR-supplemented medium (day 1). Subtle changes in the aggregate size and shape can also be observed. (D) Day 4 aggregates primed toward a vascular lineage using VEGFA and forskolin-supplemented medium. (E) Early vessel sprouting on day 7, one day after embedding the aggregates in the sprouting matrix and exposure to VEGFA and FGF2-supplemented sprouting medium (day 7). (F) Healthy organoid morphology and continued vessel sprouting on day 9. (G) Late-stage vessel sprouting at day 10. Ideally, the dense cell structures at the organoid center have disappeared by this time. (H) Typical morphology of mature (day 15) human blood vessel organoids. The removal of the surrounding matrix by cutting and maturation in ultra-low attachment 96-well culture plates shapes the organoids spherically, with the vessel networks housed internally. Scale bars: (A,B,E,F) 250 µm; (C,D) 500 µm; (G,H) 200 µm. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Whole-mount staining of mature (day 15) human blood vessel organoids. (A) Presentation of mature (day 15) human blood vessel organoids with self-organized endothelial (CD31+, magenta) networks and surrounding pericyte (PDGFR-β+, cyan) and alpha-smooth muscle actin (SMA+, yellow) coverage. (B) Higher magnification of A detailing the SMA+ (yellow) and PDGFR-β+ (cyan) expression of the vessel networks. (C) Detailed presentation of endothelial (CD31+, magenta), pericyte (PDGFR-β+, cyan), and alpha-smooth muscle actin (SMA+, yellow) interaction. (D) Whole-mount staining of the vessel endothelial (CD31+, magenta)-smooth muscle (SMA+, yellow) interaction in a cross-section (left) and a higher magnification (right) of mature blood vessel organoids. (E) Self-directed formation of a vascular basement membrane (Col IV+, grayscale) through the close association of the mural cells and endothelial tubes. Scale bars: (A,D[left]) 100 µm; (B,D[right],E) 25 µm. Please click here to view a larger version of this figure.

Discussion

Recent breakthroughs in stem cell-derived organoid cultures have provided the framework for more advanced and physiologically relevant models of human vasculature. The human blood vessel organoid (hBVO) model presented here, developed in our laboratory8,10, provides a powerful means of exploring not only further aspects of human vasculogenesis but also new avenues of disease modeling and regenerative therapy8,10,11. Multiple in vivo models have been employed to explore the development and maturation of blood vessels, vascular disease, and endothelial dysfunction3,4. Varying approaches combine single and multiple lineage-defined cells either derived from stem cells or isolated from adult tissues in vivo to create replicative human vascular networks5,6. The protocol presented here leverages the principle of developmental biology and self-organization to yield the first ever multi-cell lineage human blood vessel networks that can be generated, in essence, from a single hPSC8,10.

Each stem cell line has a unique genetic makeup and differs from others in terms of its sourcing, function, and responsiveness15. Therefore, the protocol for human blood vessel organoids (hBVOs) was developed and optimized to ensure a robust and reproducible protocol compatibility with multiple (>12) different hPSC lines8,10. The method described here generates hPSC-derived blood vessel organoids over 2 weeks. However, changes to the media composition and or the techniques in hBVO generation may lead to ineffective vessel network and organoid generation. The varying proliferation rates of individual stem cell lines also markedly impact the reproducibility of stem cell experimentation15 and, thus, organoid cultures. For example, in generating the BVOs, more proliferative cells or higher numbers of large day 1 aggregates are inherently subject to different metabolic environments and gas and nutrient diffusion parameters. This, in turn, changes the growth factor exposure times and efficiencies, the degree of differentiation and vascular priming, and, most importantly, the ability to form vessel networks upon embedding the aggregates in the collagen 1 and solubilized basement membrane matrix.

The passive diffusion of oxygen and the administration of essential nutrients from an external environment is not ideal for the long-term cell growth of 3D organoids and tissue morphogenesis in vitro16. Although dependant on several factors (i.e., the tissue metabolic rate, the nutrient and gas bioavailability, a static or dynamic environment), a general 150 µm O2 and nutrient diffusion limit has been established for tissues cultured in vitro, considering that, physiologically, human tissues present cords of living cells within 150 µm of perfused blood vessels17. Although effective gas and nutrient diffusion distances of 70-200 µm have also been proposed18,19,20,21, the construct density, temperature, pH, and media composition significantly impact the diffusion efficacy. Due to the surface area optimization and integrin-beta receptor communication following day 6 embedding, aggregates of 250-300 µm in diameter perform better than those >500-600 µm in diameter, resulting in a complete vessel sprouting process and a minimally condensed organoid core. Thus, the aggregate size is crucial and can be affected by both the number of cells used during the initial seeding and the time allotted for aggregate formation. Microwell plates that allow for control over the aggregate size and number22 are a viable alternative to the otherwise stochastic aggregate formation technique resulting from the use of ultra-low attachment 6-well plates in this protocol. Consistency in timing and managing the aggregate sizes during the first 6 days of the hBVO protocol is one of, if not the most, crucial indicators of successfully developing bona fide blood vessel organoids.

Medium changes on day 1 (mesoderm induction) and day 4 (vascular induction) must be completed in combination with the sedimentation of the aggregates. Although centrifugation is a tempting alternative, the additional forces applied to the weakly assembled aggerates can cause unwanted clumping, assembly, and shearing, which negatively impact differentiation, maturation, and sprouting efficacy in the later stages of the protocol. Working on ice during the day 6 embedding process is critical for preserving proper ECM polymerization and layer formation. During the aggregate embedding and sprouting induction, exposing the ECM to temperatures above 4˚C and/or an ECM pH other than 7.4 will affect not only the polymerization rates and ECM layer integrity but also the sprouting efficiency of the embedded aggregates. The elastic nature of the ECM sprouting matrix allows for easy detachment and transport from the 12-well culture dish to the sterile cutting surface. Individual organoids removed from the matrix and transferred to ultra-low attachment 96-well plates will consume the remaining surrounding ECM and retain self-organized mural cell-coated endothelial microvessel networks with a continuous basement membrane.

While not covered in this proposal, alterations to the media compositions can replicate diseases that, in turn, provoke pathological responses in hBVOs8,11. The boundaries of disease modeling using the hBVO system are far from well-known, and this is certainly an area that needs exploration. The application of our blood vessel organoid technology in the vascularization of previously avascular organoid constructs23 is also of significant impact and interest.

Offenlegungen

The authors have nothing to disclose.

Acknowledgements

We thank all members of our laboratories for critical input and discussions. JMP received funding from the T. von Zastrow foundation, the FWF Wittgenstein award (Z 271-B19), the Austrian Academy of Sciences, the Innovative Medicines Initiative 2 Joint Undertaking (JU) under grant agreement No 101005026, Leducq Transatlantic Networks of Excellence in Cardiovascular Research, Allen Institute Distinguished Investigator Program, and the Canada 150 Research Chairs Program F18-01336 as well as the Canadian Institutes of Health Research COVID-19 grants F20-02343 and F20-02015.

Materials

1 M HEPES  Gibco 15630080
2-Mercaptoethanol Millipore 60-24-2
7.5% sodium bicarbonate Gibco 5080094
Accutase  Gibco A1110501 cell dissociation reagent 
Albumin fraction V (BSA) AppliChem A1391, 0100
Alexa Fluor 488–anti-rabbit IgG (Fab′)2 fragment Jackson Immuno Research 711-546-152
Alexa Fluor 488–anti-sheep IgG Life Technologies A11015
Alexa Fluor 647–anti-goat IgG (Fab′)2 fragment Jackson Immuno Research 705-606-147
Automated cell counter  Invitrogen Countess II
B27 supplement Gibco 12587010
Biological safety cabinet  Faster SafeFAST Premium 212
BMP4 Miltenyi BioTec 130-111-165
CD31 Endothelial cell DAKO M0823
CD31 Endothelial cell R&D AF806
Cellulose wipes
Centrifuge Heraeus Multifuge 4 KR
CHIR99021 Tocris Bioscience 4423
Clear nail polish (essence, the gel, 01 absolute pure)
CO2 incubator  New Brunswick Galaxy 170S
Collagen type IV Basement membrane Millipore AB769
Confocal microscope (10x, 20x, 63x objectives) Leica SP8
Counting chamber slides- including 0.1% Trypan blue Invitrogen C10283
Coverslips (22 x 50 mm)
Cy3–anti-mouse IgG (Fab′)2 fragment Jackson Immuno Research 715-166-150
DAPI  Sigma D9542
DMEM/F12 Gibco 11330-032
Dulbecco's Modefied Eagle's Medium (DMEM)  Sigma D5648-10L
Eppendorf tubes
Falcon tubes Fisher Scientific 14-432-22
Fetal Bovien Serum (FBS) Gibco 10270-106
FGF2 Miltenyi BioTec 130-093-841
Fine forceps FST 11254-20
Fisherbrand Superfrost Clipped Corner Slides Fisher Scientific 12-550-016
Forskolin  Sigma F3917
Geltrex LDEV-Free, hESC-Qualified, Reduced Growth Factor Basement Membrane Matrix Fisher Scientific A1413302
Glutamax Gibco 35050061
Ham's F12  Gibco 11765054
Horizontal laminar flow station, if stereomicroscope cannot fit in BSC  Thermo Scientific Heraguard
Inverted contrasting tissue culture microscope  Zeiss Vert.A1
iSpacer  SunJinLab IS009
KnockOut DMEM/F12  Gibco 12660012
KnockOut Serum Replacement  Gibco 10828028
N2 supplement  Gibco 17502048
Neurobasal medium Gibco 21103049
non-essential amino acids (NEAAs) Gibco 11140035
Orbital shaker
Parafilm
Paraformaldehyde (4%) in PBS Boston BioProducts BM-155
PDGFR-β Pericyte R&D AF385
PDGFR-β Pericyte Cell Signaling 3169S
Penicillin-streptomycin Gibco 15140122
pH indicator strips (6.5-10) Mquant, Millipore 109543
Phosphate buffered saline (PBS) Gibco 10010023
Pipettes (P1000, P200 and P20) Gilson, Integra Pipetboy
Prime Surface-U 96-well plates  Sumilon MS9096-U
PurCol  Advanced BioMatrix 5005
RapiClear CS gel SunJinLab RCCS005
RapiClear CS mounting solution SunJinLab RCCS002
Serological pipettes (5, 10 and 25 mL) Falcon 357529, 357530, 357515
SMA vSMC/Pericyte Sigma 2547
Sodium deoxycholate Sigma D6750
Sodium hydroxide solution (NaOH, 1.0 N) Sigma S2770
Solubilized Basement Membrane Matrix (i.e., Matrigel) Corning 356231
Stainless steel micro spatula (rounded end) Fisher Scientific 21-401-5
Stainless steel spoon (double-ended) Fisher Scientific BelArt H367290018
Stemflex medium Thermo Scientific A3349401 stem cell culture medium 
StemPro-34 SFM Gibco 10639011 flexible serum-free medium 
Stereomicroscope Zeiss Stemi 2000
Sterile filter pipette tips (1,000, 300 and 20 μL) Biozym, Surphob VT0270, VT0250, VT0220
Tissue culture–treated 12-well plates TC  BD Falcon 353043
Tissue culture–treated 6-well plates  Eppendorf 30720113
Triton X-100  Sigma 93420
Tryple Express Enzyme (1x), Phenol Red Thermo Scientific 12605010 mammalian cell dissociating enzyme 
Tween 20 Sigma P7949
Ultra-low-attachment 6-well plates Corning  3471
VEGFA  Peprotech 100-20
Water bath (37 °C) Fisher Scientific Isotemp 210
Y-27632 Calbiochem 688000
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Referenzen

  1. Okwuosa, I. S., Lewsey, S. C., Adesiyun, T., Blumenthal, R. S., Yancy, C. W. Worldwide disparities in cardiovascular disease: Challenges and solutions. International Journal of Cardiology. 202, 433-440 (2016).
  2. Page, R. L., Ghushchyan, V., Nair, K. A call to action: Responding to the future forecasting of cardiovascular disease in America. American Health & Drug Benefits. 4 (5), 280-288 (2011).
  3. Ferrara, N., Davis-Smyth, T. The biology of vascular endothelial growth factor. Endocrine Reviews. 18 (1), 4-25 (1997).
  4. Ishitobi, H., et al. Flk1-GFP BAC Tg mice: An animal model for the study of blood vessel development. Experimental Animals. 59 (5), 615-622 (2010).
  5. Campisi, M., et al. 3D self-organized microvascular model of the human blood-brain barrier with endothelial cells, pericytes and astrocytes. Biomaterials. 180, 117-129 (2018).
  6. Xu, Y., et al. A novel strategy for creating tissue-engineered biomimetic blood vessels using 3D bioprinting technology. Materials. 11 (9), 1581 (2018).
  7. Risau, W. Mechanisms of angiogenesis. Nature. 386 (6626), 671-674 (1997).
  8. Wimmer, R. A., et al. Human blood vessel organoids as a model of diabetic vasculopathy. Nature. 565 (7740), 505-510 (2019).
  9. Fleischer, S., Tavakol, D. N., Vunjak-Novakovic, G. From arteries to capillaries: Approaches to engineering human vasculature. Advanced Functional Materials. 30 (37), 1910811 (2020).
  10. Wimmer, R. A., Leopoldi, A., Aichinger, M., Kerjaschki, D., Penninger, J. M. Generation of blood vessel organoids from human pluripotent stem cells. Nature Protocols. 14 (11), 3082-3100 (2019).
  11. Monteil, V., et al. Inhibition of SARS-CoV-2 infections in engineered human tissues using clinical-grade soluble human ACE2. Cell. 181 (4), 905-913 (2020).
  12. Patsch, C., et al. generation of vascular endothelial and smooth muscle cells from human pluripotent stem cells. Nature Cell Biology. 17 (8), 994-1003 (2015).
  13. Bruveris, F. F., Ng, E. S., Stanley, E. G., Elefanty, A. G. VEGF, FGF2, and BMP4 regulate transitions of mesoderm to endothelium and blood cells in a human model of yolk sac hematopoiesis. Experimental Hematology. 103, 30-39 (2021).
  14. Julian, L., Olson, M. F. Rho-associated coiled-coil containing kinases (ROCK): Structure, regulation, and functions. Small GTPases. 5, 29846 (2014).
  15. Anitua, E., Prado, R. Addressing reproducibility in stem cell and PRP therapies. Trends in Biotechnology. 37 (4), 340-344 (2019).
  16. McMurtrey, R. J. Analytic models of oxygen and nutrient diffusion, metabolism dynamics, and architecture optimization in three-dimensional tissue constructs with applications and insights in cerebral organoids. Tissue Engineering Part C: Methods. 22 (3), 221-249 (2016).
  17. McKeown, S. R. Defining normoxia, physoxia and hypoxia in tumours-Implications for treatment response. The British Journal of Radiology. 87 (1035), 20130676 (2014).
  18. Thomlinson, R. H., Gray, L. H. The histological structure of some human lung cancers and the possible implications for radiotherapy. British Journal of Cancer. 9 (4), 539-549 (1955).
  19. Olive, P. L., Vikse, C., Trotter, M. J. Measurement of oxygen diffusion distance in tumor cubes using a fluorescent hypoxia probe. International Journal of Radiation Oncology. 22 (3), 397-402 (1992).
  20. Torres Filho, I. P., Leunig, M., Yuan, F., Intaglietta, M., Jain, R. K. Noninvasive measurement of microvascular and interstitial oxygen profiles in a human tumor in SCID mice. Proceedings of the National Academy of Sciences of the United States of America. 91 (6), 2081-2085 (1994).
  21. Lanzen, J., et al. Direct demonstration of instabilities in oxygen concentrations within the extravascular compartment of an experimental tumor. Krebsforschung. 66 (4), 2219-2223 (2006).
  22. Ungrin, M. D., Joshi, C., Nica, A., Bauwens, C., Zandstra, P. W. Reproducible, ultra high-throughput formation of multicellular organization from single cell suspension-derived human embryonic stem cell aggregates. PLoS One. 3 (2), 1565 (2008).
  23. Sun, X. Y., et al. generation of vascularized brain organoids to study neurovascular interactions. eLife. 11, 76707 (2022).

Tags

Blood Vessel OrganoidsPluripotent Stem CellsVasculogenesisAngiogenesisVascular DiseaseVascular PathologiesReproducibilityHigh ThroughputStem Cell LinesDiabetic VasculopathyAggregatesCell DissociationAggregation MediumSingle-cell SuspensionCell ViabilityMesoderm Media

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Werschler, N., Penninger, J. Generation of Human Blood Vessel Organoids from Pluripotent Stem Cells. J. Vis. Exp. (191), e64715, doi:10.3791/64715 (2023).
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