The present protocol describes an optimized 3D neural retina induction system that reduces the adhesion and fusion of retinal organoids with high repeatability and efficiency.
Retinopathy is one of the main causes of blindness worldwide. Investigating its pathogenesis is essential for the early diagnosis and timely treatment of retinopathy. Unfortunately, ethical barriers hinder the collection of evidence from humans. Recently, numerous studies have shown that human pluripotent stem cells (PSCs) can be differentiated into retinal organoids (ROs) using different induction protocols, which have enormous potential in retinopathy for disease modeling, drug screening, and stem cell-based therapies. This study describes an optimized induction protocol to generate neural retina (NR) that significantly reduces the probability of vesiculation and fusion, increasing the success rate of production until day 60. Based on the ability of PSCs to self-reorganize after dissociation, combined with certain complementary factors, this new method can specifically drive NR differentiation. Furthermore, the approach is uncomplicated, cost-effective, exhibits notable repeatability and efficiency, presents encouraging prospects for personalized models of retinal diseases, and supplies a plentiful cell reservoir for applications such as cell therapy, drug screening, and gene therapy testing.
The eye serves as the primary source of information among human sensory organs, with the retina being the principal visual sensory tissue in mammalian eyes1. Retinopathy stands as one of the primary global causes of eye diseases, leading to blindness2. Approximately 2.85 million people worldwide suffer from varying degrees of vision impairment due to retinopathy3. Consequently, investigating its pathogenesis is crucial for early diagnosis and timely treatment. Most studies on human retinopathy have primarily focused on animal models4,5,6. However, the human retina is a complex, multi-layered tissue comprising various cell types. Traditional two-dimensional (2D) cell culture and animal model systems typically fail to faithfully recapitulate the normal spatiotemporal development and drug metabolism of the native human retina7,8.
Recently, 3D culture techniques have evolved to generate tissue-like organs from pluripotent stem cells (PSCs)9,10. Retinal organoids (ROs) generated from human PSCs in a 3D suspension culture system not only contain seven retinal cell types but also exhibit a distinct stratified structure similar to the human retina in vivo11,12,13. Human PSC-derived ROs have gained popularity and widespread availability and are currently the best in vitro models for studying the development and disease of the human retina14,15. Over the past few decades, numerous researchers have demonstrated that human PSCs, including embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs), can differentiate into ROs using various induction protocols. These advancements hold enormous potential in retinopathy for disease modeling, drug screening, and stem cell-based therapies16,17,18.
However, the generation of neural retina (NR) from human pluripotent stem cells (PSCs) is a complex, cumbersome, and time-consuming process. Furthermore, batch-to-batch variations in tissue organoids may lead to lower reproducibility of results19,20. Numerous intrinsic and extrinsic factors can influence the yield of retinal organoids (ROs), such as the number or species of starting cells and the use of transcription factors and small-molecule compounds21,22,23. Since the first human RO was generated by the Sasai laboratory11, multiple modifications have been proposed over the years to enhance the ease and effectiveness of the induction process13,21,24,25. Unfortunately, to date, no gold standard protocol has been established for generating ROs in all laboratories. Indeed, there is a certain degree of discrepancy in ROs resulting from different induction methods, as well as wide variation in the expression of retinal markers and the robustness of their structure22,26. These issues may severely complicate sample collection and the interpretation of study findings. Therefore, a more consolidated and robust differentiation protocol is needed to maximize efficiency with minimal heterogeneity of RO generation.
This study describes an optimized induction protocol based on a combination of Kuwahara et al.12 and Döpper et al.27 with detailed instructions. The new method significantly reduces the probability of organoid vesiculation and fusion, increasing the success rate of generating NR. This development holds great promise for disease modeling, drug screening, and cell therapy applications for retinal disorders.
This study was conducted in accordance with the Tenets of the Declaration of Helsinki and approved by the Institutional Ethics Committee of the Chinese PLA General Hospital. The WA09 (H9) ESC line was obtained from the WiCell Research Institute.
1. Culture media and reagent preparation
2. Culturing of H9-ESCs
3. Generation of human NRs
NOTE: Once the colonies achieve approximately 70% confluence, they can be directed towards differentiation into retinal organoids (ROs) using the procedural steps outlined in Figure 1.
4. Analysis of human NRs
A graphical overview of the modified protocol is shown in Figure 1. H9-ESCs were used to generate ROs when the cells were grown to a density of 70%-80%. Single-cell suspensions of H9-ESCs in 96 V-bottomed conical wells aggregated on day 1 and formed well-circumscribed round EBs by day 6. As the culture time increased, the volume of EBs gradually increased. On day 30, neuroepithelial-like structures were clearly formed and thickened during long-term NR differentiation.
In addition, the modified method was compared with two other methods (Kuwahara et al.12 and Döpper et al.27) to evaluate its repeatability and efficiency (Supplementary Figure 1). This study also observed that the morphology of EBs on day 1 following the modified method was slightly worse than in the other two methods. However, the neuroepithelial structures that formed using the modified method were more continuous on day 18 (Figure 2). On day 30, the early NRs obtained using the modified method were similar in shape and size and showed a regular round shape (Figure 3). Compared to the other two methods, the NRs formed by the modified method had a lower incidence of vesiculation and adhesion. Furthermore, based on the H9-ESCs, the success rate of generating NRs using the modified method increased to 87.39% from the 26.9% and 69.24% for the Kuwahara et al.'s and Döpper et al.'s methods12,27, respectively (Figure 3M).
Immunofluorescence staining was performed on paraffin-embedded sections of the NRs to evaluate the expression of markers related to retinal development (Figure 4). The results showed the expression of human genes associated with the retina in NRs derived from H9-ESCs using a modified method. The first cell subtype to appear is the retinal ganglion cell, which mainly accumulated on the basal side of the NRs. TUJ1 staining was used to identify the axons of the retinal ganglion cells (Figure 4I-L). Moreover, markers of retinal progenitor cells were detected in both the inner (PAX6+) and outer (CHX10+) layers (Figure 4A-H). Cells positive for the proliferation marker KI67 were distributed in the outer layer (Figure 4A-D).
Figure 1: Schematic overview. The schematic overview of the modified culture protocol shows the addition of different factors at specific time points and the representative images of the neural retina development. SFEBq: serum-free floating culture of embryoid body-like aggregates with quick reaggregation; KSR: knockout serum replacement; gfCDM: growth factor-free chemically defined medium; NRDM: neural retina differentiation medium; BMP4: bone morphogenetic protein 4.Scale bars: 200 µm. Please click here to view a larger version of this figure.
Figure 2: The representative brightfield images of retinal organoids derived from three different protocols in the early stage. On day 1, only the modified method did not from the EBs (A,E,I). On day 6, EBs formed in all three methods (B,F,J). On day 18, early neural retinas were formed, and different morphology was found among the three induction methods (C,G,K). On day 21, neural retina generated by the modified method showed continuous neuroepithelial structure (D,H,L). Scale bars: 200 µm. Please click here to view a larger version of this figure.
Figure 3: Mature 3D neural retina in suspension culture at days 30, 45, 60. On day 30, neural retina formed in all three methods (A,E,I). Arrows indicate cystic structures in Kuwahara et al.'s method (B). White dotted boxes represent the region of organoids adhesion and fusion to each other (D,F,H). Retinal organoids generated from the modified protocol are similar in size and morphology compared to the other two methods (C,G,J,K,L). Scale bars: 100 µm (white); 200 µm (black). Statistical chart of induction success rate by the three methods using H9-ESCs (M). One-way analysis of variance was used to test the significance (error bars shows standard error, n = 864, **P < 0.01, ***P < 0.001). Please click here to view a larger version of this figure.
Figure 4: Characterization of neural retina in the modified protocol. Immunostaining images of neural retina at day 6, day 18, day 30 and day 60. Green stains are for KI67 (proliferating cell), PAX6 (retinal progenitor cell), and NESTIN (neural stem cell). Red stains are for CHX10 (retinal progenitor cell), SOX2 (neural progenitor cell), and TUJ1 (retinal ganglion cell). Scale bars: 100 µm (A,B,E,F,I,J); 200 µm (C,D,G,H,K,L). Please click here to view a larger version of this figure.
Supplementary Figure 1: Comparison of flow charts for the three retinal organoid induction protocols. SFEBq: serum-free floating culture of embryoid body-like aggregates with quick reaggregation; KSR: knockout serum replacement; gfCDM: growth factor-free chemically defined medium; NRDM: neural retina differentiation medium; BMP4: bone morphogenetic protein 4. Please click here to download this File.
Supplementary Figure 2: The morphology of embryoid body (EB) induced by Kuwaharaet al.'s method. The gradual appearance of dead cell clumps was observed around EBs after the addition of BMP4 on day 6 (A–D, black arrows). Large morphological differences were observed, after day 6 (E–L), and some EBs were even completely inactivated (H,L). ESC: embryonic stem cell, PBMC: peripheral blood mononuclear cell, IPSC: induced pluripotent stem cell. Scale bars: 200 µm. Please click here to download this File.
Human ROs can spatially and temporally recapitulate the development of the fetal retina, and early ROs exhibit a high degree of similarity to the fetal retina at equivalent stages of development15. In terms of tissue morphology and molecular expression, human RO closely mirror the actual growth status of the retinal tissue, providing tremendous and unprecedented opportunities in the fields of disease modeling, drug screening, and regenerative medicine. Currently, several different methods have been established to generate ROs from human PSCs in vitro, and continuous modifications and optimizations are underway to further improve efficiency9. The Sasai laboratory reported for the first time the generation of PSC-derived ROs from human ESCs11. Human ESCs were first prepared into single-cell suspensions, and then equal numbers of cells were seeded in 96 V-bottomed conical wells, with rapid aggregation to form circular-like EBs. The external addition of key cell signaling pathways promoted the formation of optic vesicles in EBs, which subsequently matured into laminated ROs in suspension culture. The NR contains one glial cell type and six different neuronal cell types, representing many aspects of retinal development, such as cell morphogenesis, neuron differentiation, and apical-basal polarity9. Although only 10% of the aggregates formed a double-walled optic cup structure, this was a major milestone in the evolution of producing more advanced ROs11.
Subsequently, Zhong et al. introduced a new alternative, in which hiPSCs were first grown close to confluences, followed by chemical or mechanical disintegration into floating small aggregates13. Then, the small aggregates formed EBs in suspension culture, which detached separately from the bottom of the plate, further differentiating in the neural direction. Zhong et al. demonstrated a completely laminated 3D retina with relatively well-developed photoreceptor outer segments that responded to light stimulation. This method required less external regulation of cell signaling pathways and was primarily performed in a self-directed manner9. The third technological revolution was the introduction of the embedding method by Lowe group25. This involved embedding hESC aggregates in ECM to form a single-lumen epithelial structure. After enzymatic dispersion, the aggregates were maintained in a suspension culture to form mature ROs. Although all three methods can successfully induce ROs with comparable structure and function, large-scale applications have the disadvantages of being time-consuming and laborious because of their high heterogeneity and low success rate23.
In addition to the above methods, Kuwahara et al. proposed a new induction method, namely, the key factor gradient decline method12. They found that NR could be generated by the addition of BMP4 at diminishing concentration from day 6. This induction system used fewer external factors to form ROs with increased uniformity of size and morphology. However, studies have reported that the formed EBs were prone to cystic lesions, and the induction success rate of this method was approximately 40%12,28. Döpper et al. modified this protocol to improve the success rate by combining a commercial medium with three small molecule inhibitors at the early stage of induction to stabilize the EBs27. In contrast, cells of the neural epithelium of the retina more easily adhere to each other, necessitating separate culture of each RO during long-term suspension culture. Döpper et al.'s method increases the complications and costs of experimental operations and is not suitable for large-scale induction27. The optimized RO production protocol improved induction efficiency. The current modified method was compared with the methods of Kuwahara et al. and Döpper et al.
This study showed that both Kuwahara et al.'s and Döpper et al.'s methods formed EBs with smooth edges on day 1, whereas the present modified method required a relatively long time to form EBs, approximately until day 6. The volume of the EBs obtained using Kuwahara et al.'s method was larger than that obtained using Döpper et al.'s method, and the EBs obtained using Döpper et al.'s method showed increased fluidity under liquid flow. Notably, dead cell clumps gradually appeared around the EBs after the addition of BMP4 on day 6 when using Kuwahara et al.'s method (Supplementary Figure 2). By day 18, significant morphological differences were observed in the EBs of Kuwahara et al.'s method, and some EBs were completely inactivated (Supplementary Figure 2). In Döpper et al.'s method, the majority of EBs were rounded and well circumscribed, and exhibited only a small number of scattered dead cells around them. The modified method formed tight and well-structured EBs with slight morphological differences, and a few dead cells were observed around them.
Moreover, this study also found that some EBs generated vesicles by Kuwahara et al. in the early stage following transfer to 6-well plates, resulting in a failure to form ROs. Adhesion and fusion of ROs occurred around day 40, which significantly decreased the utility of the experiments. The culture system of Döpper et al.'s method is more complicated, and requires more operational steps and higher cost than Kuwahara et al.'s method. The majority of ROs by Döpper et al. also inevitably developed adhesions and fusions with each other. The modified method in this study successfully generated 3D NRs in vitro that expressed the human retina-related markers CHX10, KI67, PAX6, SOX2, TUJ1, and NESTIN. And most of ROs by the modified method were consistent in size and morphology, and very few vesicles or adhesions developed during the late stages of retinal differentiation.
Compared to the other two methods, the new culture system had a simpler operational steps and lower costs. The critical step in the modified method is to add three small molecule inhibitors into media and ensure that the plate is not moved for the first six days to stabilize the structure of EBs. The movement of plates or any cell manipulation in the early stage might affect the formation of EBs. Compared with the other two methods, the modified method did not change the medium on day 1 and also reduced the use of small molecule inhibitors on day 15. In short, the operation steps of the modified method are simplified to a certain extent, and the experimental cost is saved with less use of media and reagents. However, the modified method still cannot solve the common problems of current organoid culture system. In addition, ROs induction efficiency largely depends on the quality and differentiation ability of hPSCs. In this study, only the efficiency of NR generation using H9-ESC was completely calculated. We successfully induced ROs in different hPSCs lines with the new method in the present study, and achieved the same induction efficiency, including H9, H1 and PBMC-iPSC. There is no statistical difference in induction efficiency among the three cell lines. In the future, more studies need to explore the induction efficiency of different hPSCs using this method.
In conclusion, the optimized retinal induction protocol is simple and inexpensive, has high repeatability and efficiency, offers promising personalized models of retinal diseases, and provides an abundant cell source for cell therapy, drug screening, and gene therapy testing.
The authors have nothing to disclose.
None.
0.01 M TPBS | Servicebio | G0002 | Washing slices |
4% Paraformaldehyde | Servicebio | G1101-500ML | Fix retinal organoids |
5 mL Pasteur pipette | NEST Biotechnology | 318516 | Pipette retinal organoids |
96 V-bottomed conical wells | Sumitomo Bakelit | MS-9096VZ | |
Adhesion Microscope Slides | CITOTEST | 188105 | Fix slices |
AggreWell medium | STEMCELL Technologies | 5893 | Medium |
Anhydrous ethanol | SINOPHARM | 10009218 | Dehydrate |
Anti-CHX10 | Santa Cruz | sc-365519 | Primary antibody |
Antifade Solution | ZSGB-BIO | ZLI-9556 | |
Anti-KI67 | Abcam | ab16667 | Primary antibody |
Anti-NESTIN | Sigma | N5413 | Primary antibody |
Anti-Neuronal Class III β-Tubulin(TUJ1) | Beyotime | AT809 | Primary antibody |
Anti-PAX6 | Abcam | ab195045 | Primary antibody |
Cell dissociation solution(CDS) | STEMCELL Technologies | 7922 | Cell dissociation |
CHIR99021 | Selleckchem | S2924 | GSK-3α/β inhibitor |
Cholesterol Lipid Concentrate | Gibco | 12531018 | 250× |
Citrate Antigen Retrieval Solution | Servicebio | G1202-250ML | 20×, pH 6.0 |
CS10 | STEMCELL Technologies | 1001061 | Cell Freezing Medium |
DAPI | Roche | 10236276001 | Nuclear counterstain |
Dimethyl sulfoxide(DMSO) | Sigma | D2650 | |
DMEM/F12 | Gibco | 11330032 | Medium |
DMEM/F12-GlutaMAX | Gibco | 10565018 | Medium |
Donkey anti-Mouse Alexa Fluor Plus 488 | Invitrogen | A32766 | Secondary Antibody |
Donkey anti-Rabbit Alexa Fluor 568 | Invitrogen | A10042 | Secondary Antibody |
Ethylene Diamine Tetraacetic Acid (EDTA) | Biosharp | BL518A | 0.5 M, pH 8.0, cell dissociation |
Extracellular matrix (ECM) | Corning | 354277 | Coating plates |
F12-Glutamax | Gibco | 31765035 | Medium |
Fetal Bovine Serum | Gibco | A5669701 | |
Flow-like tissue cell quantitative analyzer | TissueGnostics | TissueFAXS Plus | Scan sections |
IMDM-GlutaMAX | Gibco | 31980030 | Medium |
IWR1-endo | Selleckchem | S7086 | Wnt-inhibitor |
KnockOut Serum Replacement | Gibco | 10828028 | |
LDN-193189 2HCl | Selleckchem | S7507 | BMP-inhibitor |
Low-adhesion 24-well Plates | Corning | 3473 | |
Low-adhesion 6-well Plates | Corning | 3471 | |
Maintenance medium (MM) | STEMCELL Technologies | 85850 | Medium |
N2 supplement | Gibco | 17502048 | |
Normal Donkey Serum | Solarbio | SL050 | Blocking buffer |
Paraplast | Leica | 39601006 | Tissue embedding |
PBS pH 7.4 basic (1x) | Gibco | C10010500BT | Without Ca+,Mg+ |
Reconbinant human bone morphogenetic protein-4(rhBMP4) | R&D | 314-BP | Key protein factor |
Retinoic acid | Sigma | R2625 | Powder, keep out of light |
SB431542 | Selleckchem | S1067 | ALK5-inhibitor |
SU5402 | Selleckchem | S7667 | Tyrosine kinase inhibitor |
Super PAP Pen | ZSGB-BIO | ZLI-9305 | |
Taurine | Sigma | T0625-10G | |
Thioglycerol | Sigma | M1753 | |
Triton X-100 | Sigma | X100 | Permeabilization |
WA09 embryonic stem cell line | WiCell Research Institute | Cell line | |
Xylene | SINOPHARM | 10023418 | Dewaxing |
Y-27632 2HCL | Selleckchem | S1049 | ROCK-inhibitor |