Your search keyword '"Moon Bo-Hyun"' showing total 2 results

1. Low dose radiation upregulates Ras/p38 and NADPH oxidase in mouse colon two months after exposure.

Author

Kumar S, Suman S, Moon BH, Fornace AJ Jr, and Datta K

Subjects

Animals, Humans, Mice, Adaptor Proteins, Signal Transducing metabolism, Colon metabolism, Gamma Rays, Reactive Oxygen Species metabolism, Signal Transduction, p38 Mitogen-Activated Protein Kinases, ras Proteins, NADPH Oxidases genetics, NADPH Oxidases metabolism, Oxidative Stress radiation effects

Abstract

Background: Exposure to ionizing is known to cause persistent cellular oxidative stress and NADPH oxidase (Nox) is a major source of cellular oxidant production. Chronic oxidative stress is associated with a myriad of human diseases including gastrointestinal cancer. However, the roles of NADPH oxidase in relation of long-term oxidative stress in colonic epithelial cells after radiation exposure are yet to be clearly established., Methods and Results: Mice were exposed either to sham or to 0.5 Gy γ radiation, and NADPH oxidase, oxidative stress, and related signaling pathways were assessed in colon samples 60 days after exposure. Radiation exposure led to increased expression of colon-specific NADPH oxidase isoform, Nox1, as well as upregulation of its modifiers such as Noxa1 and Noxo1 at the mRNA and protein level. Co-immunoprecipitation experiments showed enhanced binding of Rac1, an activator of NADPH oxidase, to Nox1. Increased 4-hydroxynonenal, 8-oxo-dG, and γH2AX along with higher protein carbonylation levels suggest increased oxidative stress after radiation exposure. Immunoblot analysis demonstrates upregulation of Ras/p38 pathway, and Gata6 and Hif1α after irradiation. Increased staining of β-catenin, cyclinD1, and Ki67 after radiation was also observed., Conclusions: In summary, data show that exposure to a low dose of radiation was associated with upregulation of NADPH oxidase and its modifiers along with increased Ras/p38/Gata6 signaling in colon. When considered along with oxidative damage and proliferative markers, our observations suggest that the NADPH oxidase pathway could be playing a critical role in propagating long-term oxidative stress after radiation with implications for colon carcinogenesis., (© 2022. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2023

2. Effects of High-Linear-Energy-Transfer Heavy Ion Radiation on Intestinal Stem Cells: Implications for Gut Health and Tumorigenesis.

Author

Kumar, Santosh, Suman, Shubhankar, Angdisen, Jerry, Moon, Bo-Hyun, Kallakury, Bhaskar V. S., Datta, Kamal, and Fornace Jr., Albert J.

Subjects

EPITHELIAL cells, MITOGEN-activated protein kinases, NF-kappa B, RESEARCH funding, INTESTINAL mucosa, SILICONES, RADIATION, CELLULAR aging, OXIDATIVE stress, CELLULAR signal transduction, MICE, GENE expression, INTESTINAL absorption, INTESTINAL tumors, ENERGY transfer, DNA damage, ANIMAL experimentation, STEM cells, T-cell exhaustion, HEMOSTASIS, PHYSIOLOGICAL effects of radiation

Abstract

Simple Summary: Heavy ion radiation, found in outer space and used in some cancer treatments, can damage vital cells in the intestines. Studies using mice show that this type of radiation causes long-lasting stress, accelerated aging, and harmful changes in these cells, which can perturb gut function and increase the risk of developing cancer. Specialized mouse models were employed to monitor how these intestinal stem cells are affected over time after exposure to this radiation. We found that particle radiation caused more stress-induced damage and tumor incidence compared to photon radiation. Intestinal stem cells showed signs of aging and inflammation, which persisted for up to a year. This ongoing stress and damage also disrupt the gut barrier's function and ability to absorb nutrients properly. The findings suggest that astronauts exposed to this radiation during deep space missions might face increased risks of gut dysfunction as well as increased cancer risk. Heavy ion radiation, prevalent in outer space and relevant for radiotherapy, is densely ionizing and poses a risk to intestinal stem cells (ISCs), which are vital for maintaining intestinal homeostasis. Earlier studies have shown that heavy-ion radiation can cause chronic oxidative stress, persistent DNA damage, cellular senescence, and the development of a senescence-associated secretory phenotype (SASP) in mouse intestinal mucosa. However, the specific impact on different cell types, particularly Lgr5+ intestinal stem cells (ISCs), which are crucial for maintaining cellular homeostasis, GI function, and tumor initiation under genomic stress, remains understudied. Using an ISCs-relevant mouse model (Lgr5+ mice) and its GI tumor surrogate (Lgr5+Apc1638N/+ mice), we investigated ISCs-specific molecular alterations after high-LET radiation exposure. Tissue sections were assessed for senescence and SASP signaling at 2, 5 and 12 months post-exposure. Lgr5+ cells exhibited significantly greater oxidative stress following 28Si irradiation compared to γ-ray or controls. Both Lgr5+ cells and Paneth cells showed signs of senescence and developed a senescence-associated secretory phenotype (SASP) after 28Si exposure. Moreover, gene expression of pro-inflammatory and pro-growth SASP factors remained persistently elevated for up to a year post-28Si irradiation. Additionally, p38 MAPK and NF-κB signaling pathways, which are critical for stress responses and inflammation, were also upregulated after 28Si radiation. Transcripts involved in nutrient absorption and barrier function were also altered following irradiation. In Lgr5+Apc1638N/+ mice, tumor incidence was significantly higher in those exposed to 28Si radiation compared to the spontaneous tumorigenesis observed in control mice. Our results indicate that high-LET 28Si exposure induces persistent DNA damage, oxidative stress, senescence, and SASP in Lgr5+ ISCs, potentially predisposing astronauts to altered nutrient absorption, barrier function, and GI carcinogenesis during and after a long-duration outer space mission. [ABSTRACT FROM AUTHOR]

Published

2024