Generation of Vascular Endothelial Cells and Hematopoietic Cells by Blastocyst Complementation

Hamanaka, Sanae; Umino, Ayumi; Sato, Hideyuki; Hayama, Toyoaki; Yanagida, Akira; Mizuno, Naoto; Kobayashi, Toshihiro; Kasai, Masahiro; Suchy, Fabian P.; Yamazaki, Satoshi; Hara, Masaki; Yamaguchi, Tomoyuki; Nakauchi, Hiromitsu

doi:10.1016/j.stemcr.2018.08.015

Cited by 62 publications

(57 citation statements)

References 22 publications

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“…Vasculogenesis can be disrupted by the deficiency of the Flk-1 gene in rodents (Shalaby et al, 1995). Thus, establishing a vasculogenesis-disabled trait in the host animal and restoring the trait by exogenous cells may be a strategy to overcome composite vasculogenesis of the host-and donor-derived cells (Hamanaka et al, 2018). In this study, we, therefore, examined whether deficiency of the FLK1 ortholog or kinase insert domain receptor (KDR) in pigs can cause the vasculogenesis-disabled phenotype as seen in rodents (Sakurai et al, 2005;Shalaby et al, 1995) and whether the trait can be restored by blastocyst complementation.…”

Section: Apancreatic Phenotype Generated By Pdx1-ko and Restoration Omentioning

confidence: 99%

“…Fetuses with restored vasculogenesis generated by complementation of the PDX1/KDR-KO embryos were chimeric with a systemically higher contribution of exogenous cells. KDR expression is pivotal for the development of multiple tissues that are distributed throughout the whole body, including vascular endothelia, smooth muscles, and hematopoietic cells (Hamanaka et al, 2018;Sakurai et al, 2005;Shalaby et al, 1995). Therefore, dense distribution of exogenous cells throughout the body tissue of the chimeric fetuses may be hardly avoidable when the empty niche of KDR deficiency is to be compensated.…”

Section: Ahepatogenic Phenotype Generated By Hematopoietically Expresmentioning

confidence: 99%

“…This approach is endorsed by the notion that in vitro generation of human organs with complex function and structure is extremely difficult (Rashid et al, 2014), and organ development from PSCs in the natural physiological environment of a xenogeneic fetus would be better supported. Recent studies have been demonstrated compelling evidence for blastocyst complementation in rodents by generating organs, such as kidney, brain, vessels, and blood (Goto et al, 2019;Hamanaka et al, 2018;Kobayashi et al, 2010;Matsunari et al, 2013;Nagashima and Matsunari, 2016;Rashid et al, 2014;Usui et al, 2012;Wu et al, 2016;Yamaguchi et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…In recent years, gene knockout (KO) by genome editing has significantly advanced its feasibility and practical applicability in mammals (Gupta and Musunuru, 2014;Tan et al, 2012). Thus, knocking out the master regulator gene of a specific organ has become a straightforward method for generating the dysorganogenetic phenotype (Goto et al, 2019;Hamanaka et al, 2018;Kobayashi et al, 2010;Usui et al, 2012;Vilarino et al, 2017). Direct genome editing for zygotes, however, has been reported to result in mosaic mutations (Vilarino et al, 2017), which hinder obtaining conclusive evidence for blastocyst complementation.…”

Section: Introductionmentioning

confidence: 99%

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Compensation of Disabled Organogeneses in Genetically Modified Pig Fetuses by Blastocyst Complementation

et al. 2020

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We have previously established a concept of developing exogenic pancreas in a genetically modified pig fetus with an apancreatic trait, thereby proposing the possibility of in vivo generation of functional human organs in xenogenic large animals. In this study, we aimed to demonstrate a further proof-of-concept of the compensation for disabled organogeneses in pig, including pancreatogenesis, nephrogenesis, hepatogenesis, and vasculogenesis. These dysorganogenetic phenotypes could be efficiently induced via genome editing of the cloned pigs. Induced dysorganogenetic traits could also be compensated by allogenic blastocyst complementation, thereby proving the extended concept of organ regeneration from exogenous pluripotent cells in empty niches during various organogeneses. These results suggest that the feasibility of blastocyst complementation using genome-edited cloned embryos permits experimentation toward the in vivo organ generation in pigs from xenogenic pluripotent cells.

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Section: Apancreatic Phenotype Generated By Pdx1-ko and Restoration Omentioning

confidence: 99%

Section: Ahepatogenic Phenotype Generated By Hematopoietically Expresmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Compensation of Disabled Organogeneses in Genetically Modified Pig Fetuses by Blastocyst Complementation

et al. 2020

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“…The renal lineage cells were derived from the injected PSCs, whereas nonrenal lineages such as blood vessels and stromal cells in kidneys were chimeric for both blastocyst cells and PSCs. Recently, mouse PSC-derived vascular endothelial cells were regenerated into Flk-1 knockout mice, lacking a key gene for vascular endothelial development [38]. By simultaneously disrupting Flk-1 and genes required for genesis of the target organ, rejection-free organs could be generated from patient-specific iPSCs.…”

Section: Blastocyst Complementationmentioning

confidence: 99%

A Novel Strategy for Xeno-Regenerative Therapy

Fujimoto¹,

Yokoo²,

Kobayashi³

2020

Xenotransplantation - Comprehensive Study

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The shortage of organs for transplantation is of critical importance worldwide. Xenotransplantation or xeno-embryonic organ transplantation can stably supply organs and is considered to be an established alternative treatment. Regenerative medicine is another option, and recent advances in stem cell research have enabled the reproduction of miniature organs, called organoids, derived in vitro from human induced pluripotent stem cells. However, the in vitro production of large and complex organs that can efficiently function in vivo is not yet accomplished. We proposed a novel strategy for xenotransplantation in which a chimeric kidney is constructed by injecting human nephron progenitor cells into a porcine embryonic kidney, thereby eliminating pig nephron progenitor cells and allowing transplantation into a human and long-term survival. In this chapter, we discussed advantages and pitfalls of xenotransplantation and xeno-embryonic kidney transplantation. Recent attempts of human organoids and blastocyst complementation were reviewed. Finally, we proposed our novel xeno-regenerative therapeutic strategy.

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Blastocyst complementation reveals that NKX2‐1 establishes the proximal‐peripheral boundary of the airway epithelium

Ustiyan

Wen

et al. 2021

Developmental Dynamics

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Background: Distinct boundaries between the proximal conducting airways and more peripheral-bronchial regions of the lung are established early in foregut embryogenesis, demarcated in part by the distribution of SOX family and NKX2-1 transcription factors along the cephalo-caudal axis of the lung. We used blastocyst complementation to identify the role of NKX2-1 in the formation of the proximal-peripheral boundary of the airways in mouse chimeric embryos.Results: While Nkx2-1 −/− mouse embryos form primordial tracheal cysts, peripheral pulmonary structures are entirely lacking in Nkx2-1 −/− mice.Complementation of Nkx2-1 −/− embryos with NKX2-1-sufficient embryonic stem cells (ESCs) enabled the formation of all tissue components of the peripheral lung but did not enhance ESC colonization of the most proximal regions of the airways. In chimeric mice, a precise boundary was formed between NKX2-1-deficient basal cells co-expressing SOX2 and SOX9 in large airways and ESC-derived NKX2-1 + SOX9 + epithelial cells of smaller airways. NKX2-1-sufficient ESCs were able to selectively complement peripheral, rather than most proximal regions of the airways. ESC complementation did not prevent ectopic expression of SOX9 but restored β-catenin signaling in Nkx2-1 −/− basal cells of large airways.Conclusions: NKX2-1 and β-catenin function in an epithelial cellautonomous manner to establish the proximal-peripheral boundary along developing airways.

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Generation of Vascular Endothelial Cells and Hematopoietic Cells by Blastocyst Complementation

Cited by 62 publications

References 22 publications

Compensation of Disabled Organogeneses in Genetically Modified Pig Fetuses by Blastocyst Complementation

Compensation of Disabled Organogeneses in Genetically Modified Pig Fetuses by Blastocyst Complementation

A Novel Strategy for Xeno-Regenerative Therapy

Blastocyst complementation reveals that NKX2‐1 establishes the proximal‐peripheral boundary of the airway epithelium

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