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Main Authors: Zhu, Jialiang, Zhong, Xinxing, He, Huanjing, Cao, Jingxiao, Zhou, Zhengyang, Dong, Jiebin, Li, Honggang, Zhang, Anqi, Lyu, Yulin, Li, Cheng, Guan, Jingyang, Deng, Hongkui
Format: Artículo científico
Language:en
Published: Cell stem cell 2024
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/39442525/
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author Zhu, Jialiang
Zhong, Xinxing
He, Huanjing
Cao, Jingxiao
Zhou, Zhengyang
Dong, Jiebin
Li, Honggang
Zhang, Anqi
Lyu, Yulin
Li, Cheng
Guan, Jingyang
Deng, Hongkui
author_facet Zhu, Jialiang
Zhong, Xinxing
He, Huanjing
Cao, Jingxiao
Zhou, Zhengyang
Dong, Jiebin
Li, Honggang
Zhang, Anqi
Lyu, Yulin
Li, Cheng
Guan, Jingyang
Deng, Hongkui
Zhu, Jialiang
Zhong, Xinxing
He, Huanjing
Cao, Jingxiao
Zhou, Zhengyang
Dong, Jiebin
Li, Honggang
Zhang, Anqi
Lyu, Yulin
Li, Cheng
Guan, Jingyang
Deng, Hongkui
collection PubMed - marine biology
contents Generation of human expandable limb-bud-like progenitors via chemically induced dedifferentiation. Zhu, Jialiang Zhong, Xinxing He, Huanjing Cao, Jingxiao Zhou, Zhengyang Dong, Jiebin Li, Honggang Zhang, Anqi Lyu, Yulin Li, Cheng Guan, Jingyang Deng, Hongkui Humans Cell Dedifferentiation Limb Buds Cell Differentiation Stem Cells Cells, Cultured Cell Proliferation In certain highly regenerative animals, cellular dedifferentiation occurs after injury, allowing specialized cells to become progenitor cells for regeneration. However, this capacity is restricted in human cells due to reduced plasticity. Here, we introduce a chemical-induced dedifferentiation approach that reverts the differentiated cells to a progenitor-like state, conferring the features of human limb bud cells from human adult somatic cells. These chemically induced human limb-bud-like progenitors (hCiLBP cells) show a high degree of transcriptomic similarity to human embryonic limb bud progenitors. Importantly, we established culture conditions that allow hCiLBP cells to undergo extensive expansion while maintaining population homogeneity and long-term self-renewal capacity. Moreover, hCiLBP cells exhibit increased osteochondrogenic differentiation ability, providing an innovative platform for generation of skeletal lineage cell types. These results highlight a potential therapeutic approach for repairing damaged human tissues through reversal of developmental pathways from mature cells to expandable progenitor cells.
format Artículo científico
id pubmed_39442525
institution PubMed
language en
publishDate 2024
publisher Cell stem cell
record_format pubmed
spellingShingle Generation of human expandable limb-bud-like progenitors via chemically induced dedifferentiation.
Zhu, Jialiang
Zhong, Xinxing
He, Huanjing
Cao, Jingxiao
Zhou, Zhengyang
Dong, Jiebin
Li, Honggang
Zhang, Anqi
Lyu, Yulin
Li, Cheng
Guan, Jingyang
Deng, Hongkui
Humans
Cell Dedifferentiation
Limb Buds
Cell Differentiation
Stem Cells
Cells, Cultured
Cell Proliferation
Generation of human expandable limb-bud-like progenitors via chemically induced dedifferentiation. Zhu, Jialiang Zhong, Xinxing He, Huanjing Cao, Jingxiao Zhou, Zhengyang Dong, Jiebin Li, Honggang Zhang, Anqi Lyu, Yulin Li, Cheng Guan, Jingyang Deng, Hongkui Humans Cell Dedifferentiation Limb Buds Cell Differentiation Stem Cells Cells, Cultured Cell Proliferation In certain highly regenerative animals, cellular dedifferentiation occurs after injury, allowing specialized cells to become progenitor cells for regeneration. However, this capacity is restricted in human cells due to reduced plasticity. Here, we introduce a chemical-induced dedifferentiation approach that reverts the differentiated cells to a progenitor-like state, conferring the features of human limb bud cells from human adult somatic cells. These chemically induced human limb-bud-like progenitors (hCiLBP cells) show a high degree of transcriptomic similarity to human embryonic limb bud progenitors. Importantly, we established culture conditions that allow hCiLBP cells to undergo extensive expansion while maintaining population homogeneity and long-term self-renewal capacity. Moreover, hCiLBP cells exhibit increased osteochondrogenic differentiation ability, providing an innovative platform for generation of skeletal lineage cell types. These results highlight a potential therapeutic approach for repairing damaged human tissues through reversal of developmental pathways from mature cells to expandable progenitor cells.
title Generation of human expandable limb-bud-like progenitors via chemically induced dedifferentiation.
topic Humans
Cell Dedifferentiation
Limb Buds
Cell Differentiation
Stem Cells
Cells, Cultured
Cell Proliferation
url https://pubmed.ncbi.nlm.nih.gov/39442525/