Self-organized hemanoids derived from human iPSCs create a niche that produces definitive extraembryonic hematopoiesis.
Avdili, A.; Auer, M.; Brislinger, D.; Kolb, D.; Moser, G.; Reinisch, A.; Hoefler, G.; Bernecker, C.; Fuchs, J.; Feichtinger, J.; Schlenke, P.; Dorn, I.
Show abstract
Manufacturing red blood cells (RBCs) from human induced pluripotent stem cells (iPSCs) can improve our understanding of embryonic erythropoiesis, foster innovative treatments for RBC-related diseases, and ultimately address clinical blood supply shortages. However, existing systems face low efficiency, enucleation failure, and uncertainty about the develop-mental wave of cultured RBCs. We successfully used self-organized hemanoids to improve iPSC-derived RBC generation. Based on the hypothesis that cellular interactions and 3D organization promote hematopoietic cell fate, we aimed to thoroughly characterize hemanoids. We visualized the spatiotemporal emergence of hematopoiesis by generating a CD43-GFP reporter iPSC line. Imaging and spatial transcriptomics analysis provided de-tailed insight into the hemanoid architecture, identifying stromal cells and hepatoblasts as potential erythropoiesis-supportive elements. The developmental stage mirrors extraembryonic hematopoiesis. Given the difficulties of accessing these early stages in vivo, our system offers a platform not only for further clinical translation but also for exploring hu-man embryonic blood wave dynamics.
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