Reactive oxygen species enhance differentiation of human embryonic stem cells into mesendodermal lineage

Ji, Ae Ri; Ku, Seung Yup; Cho, Myung Soo; Kim, Yoon Young; Kim, Yong Jin; Oh, Sun Kyung; Kim, Seok Hyun; Moon, Shin Yong; Choi, Young Min

doi:10.3858/emm.2010.42.3.018

Cited by 147 publications

(103 citation statements)

References 22 publications

(41 reference statements)

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“…Hence, the observed higher resistance of undifferentiated hESC to oxidative stress and genotoxic stress compared to somatic cell types, as reported by our previous studies [5,6], could be due to lower innate basal intracellular levels of ROS within hESCs compared to somatic cell types. Our findings are consistent with previous studies which showed that ROS play crucial roles as secondary messengers during stem cell differentiation into various somatic lineages [10,11], so that an increase in ROS levels in differentiated stem cell progenies is therefore expected. Hirano and Tamae [12] and Kuboyama et al [13], also reported that undifferentiated embryonic stem cells were more resistant to DNA damage induced by the ROS -8-oxoguanine (which is known to generate GC-to-TA point mutations in genomic DNA), as compared to their differentiated progenies.…”

Section: Discussionsupporting

confidence: 93%

Differential resistance of human embryonic stem cells and somatic cell types to hydrogen peroxide-induced genotoxicity may be dependent on innate basal intracellular ROS levels

Vinoth

Manikandan

Sethu

et al. 2015

Folia Histochem Cytobiol.

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Previously, we demonstrated that undifferentiated human embryonic stem cells (hESC) displayed higher resistance to oxidative and genotoxic stress compared to somatic cells, but did not further probe the underlying mechanisms. Using H 2 O 2 -induced genotoxicity as a model, this study investigated whether higher resistance of hESC to oxidative and genotoxic stress could be due to lower innate basal intracellular levels of reactive oxygen species (ROS), as compared to their differentiated fibroblastic progenies (H1F) and two other somatic cell types -human embryonic palatal mesenchymal (HEPM) cells and peripheral blood lymphocytes (PBL). Comet assay demonstrated that undifferentiated hESC consistently sustained lower levels of DNA damage upon acute exposure to H 2 O 2 for 30 min, compared to somatic cells. DCFDA and HE staining with flow cytometry showed 170 Kumar Jayaseelan Vinoth et al.

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Section: Discussionsupporting

confidence: 93%

Differential resistance of human embryonic stem cells and somatic cell types to hydrogen peroxide-induced genotoxicity may be dependent on innate basal intracellular ROS levels

Vinoth

Manikandan

Sethu

et al. 2015

Folia Histochem Cytobiol.

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“…A low-level ROS pulse is required specifically for cardio and vascular differentiation from mES cells [5]. ROS also enhances spontaneous differentiation of human ES cells into mesendodermal cell lineage [47].…”

Section: Discussionmentioning

confidence: 99%

SIRT1 Deficiency Downregulates PTEN/JNK/FOXO1 Pathway to Block Reactive Oxygen Species-Induced Apoptosis in Mouse Embryonic Stem Cells

Chae

Broxmeyer

2011

Stem Cells and Development

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Silent mating type information regulation 2 homolog 1 (SIRT1) plays a critical role in reactive oxygen speciestriggered apoptosis in mouse embryonic stem (mES) cells. Here, we investigated a possible role for the PTEN=Akt=JNK pathway in the SIRT1-mediated apoptosis pathway in mES cells. Akt was activated by removal of anti-oxidant 2-mercaptoethanol in SIRT1À=À mES cells. Since PTEN is a negative regulator of Akt and its activity can be modulated by acetylation, we investigated if SIRT1 deacetylated PTEN to downregulate Akt to trigger apoptosis in anti-oxidant-free culture conditions. PTEN was hyperacetylated and excluded from the nucleus in SIRT1À=À mES cells, consistent with enhanced Akt activity. SIRT1 deficiency enhanced the acetylation=phos-phorylation level of FOXO1 and subsequently inhibited the nuclear localization of FOXO1. Cellular acetylation levels were enhanced by DNA-damaging agent, not by removal of anti-oxidant. c-Jun NH2-terminal kinase ( JNK) was activated by removal of anti-oxidant in SIRT1-dependent manner. Although p53 acetylation was stronger in SIRT1 À=À mES cells, DNA-damaging stress activated phosphorylation and enhanced cellular levels of p53 irrespective of SIRT1, whereas removal of anti-oxidant slightly activated p53 only with SIRT1. Expression levels of Bim and Puma were increased in anti-oxidant-free culture conditions in an SIRT1-dependent manner and treatment with JNK inhibitor blocked induction of Bim expression. DNA-damaging agent activated caspase3 regardless of SIRT1. Our data support an important role for SIRT1 in preparing the PTEN=JNK=FOXO1 pathway to respond to cellular reactive oxygen species.

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“…Further the growth of hESCs in ROS-inducing conditions (BSO treatment, which inhibits intracellular glutathione and enriches ROS levels) has been shown to induce an up-regulation in mesodermal and endodermal differentiation and this occurred through MAPK signalling (Ji et al, 2010). These studies are the first to demonstrate ROS-mediated differentiation in hESCs.…”

Section: Mapk Pathway-mediated Hesc Differentiationmentioning

confidence: 79%

“…This study found a link between the eicosanoid signalling pathway and pluripotency and several oxidized metabolites and the promotion of neuronal and cardiac differentiation. A previously mentioned study found that an increase in ROS, which would lead to an increase in oxidized metabolites, led to cardiac differentiation (Serena et al, 2009) and mesodermal/ endodermal differentiation (Ji et al, 2010). Oxygen tension may also affect differentiation (Chen et al, 2010b;Lim et al, 2011) as, similar to hESC culture, differentiation protocols do no tend to use physiological levels of oxygen, as is shown in the production of retinal progenitor cells (Bae et al, 2011), mesoderm and cardiac cells (Niebruegge et al, 2009), chondrocytes (Koay andAthanasiou, 2008) and functional endothelium (Prado-Lopez et al, 2010) from hESCs.…”

Section: Metabolomicsmentioning

confidence: 93%

Potential for pharmacological manipulation of human embryonic stem cells

Atkinson

Lako

Armstrong

2013

British J Pharmacology

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The therapeutic potential of human embryonic stem cells (hESCs) and induced pluripotent stem cells (iPSCs) is vast, allowing disease modelling, drug discovery and testing and perhaps most importantly regenerative therapies. However, problems abound; techniques for cultivating self‐renewing hESCs tend to give a heterogeneous population of self‐renewing and partially differentiated cells and general include animal‐derived products that can be cost‐prohibitive for large‐scale production, and effective lineage‐specific differentiation protocols also still remain relatively undefined and are inefficient at producing large amounts of cells for therapeutic use. Furthermore, the mechanisms and signalling pathways that mediate pluripotency and differentiation are still to be fully appreciated. However, over the recent years, the development/discovery of a range of effective small molecule inhibitors/activators has had a huge impact in hESC biology. Large‐scale screening techniques, coupled with greater knowledge of the pathways involved, have generated pharmacological agents that can boost hESC pluripotency/self‐renewal and survival and has greatly increased the efficiency of various differentiation protocols, while also aiding the delineation of several important signalling pathways. Within this review, we hope to describe the current uses of small molecule inhibitors/activators in hESC biology and their potential uses in the future.LINKED ARTICLES This article is part of a themed section on Regenerative Medicine and Pharmacology: A Look to the Future. To view the other articles in this section visit http://dx.doi.org/10.1111/bph.2013.169.issue‐2

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Reactive oxygen species enhance differentiation of human embryonic stem cells into mesendodermal lineage

Cited by 147 publications

References 22 publications

Differential resistance of human embryonic stem cells and somatic cell types to hydrogen peroxide-induced genotoxicity may be dependent on innate basal intracellular ROS levels

Differential resistance of human embryonic stem cells and somatic cell types to hydrogen peroxide-induced genotoxicity may be dependent on innate basal intracellular ROS levels

SIRT1 Deficiency Downregulates PTEN/JNK/FOXO1 Pathway to Block Reactive Oxygen Species-Induced Apoptosis in Mouse Embryonic Stem Cells

Potential for pharmacological manipulation of human embryonic stem cells

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