Ex vivo identification of transcriptional regulation landscape and potential therapeutic targets against oxidative stress using Alzheimer's disease patient‐derived dermal fibroblast: findings from BICWALZS cohort.

Background: Reactive oxygen species (ROS) is considered as a central pathophysiology for neurodegeneration in Alzheimer's disease (AD). Many studies using in vitro cell line or in vivo mouse model have shown the possible association between ROS defense mechanisms and cellular damage. However, that connection was not elucidated well in AD patient‐derived cell or brain organoids. In this study, we aimed to identify transcriptional regulation landscape and potential therapeutic targets against oxidative stress using AD dementia patient‐derived dermal fibroblast Methods: For the purposes of ex vivo research, we performed skin biopsy and stabilized dermal fibroblasts in vitro. Total of 20 AD dementia patients and 22 cognitively normal older adults were assessed. All of AD dementia patients were amyloid positive on PET imaging, APOE e4 carrier, and cognition was imparied. On the contrary, all of cognitively normal older adults were amyloid negative on PET imaging, and APOE e4 non‐carrier. We applied H2O2 (600 uM) to dermal fibroblast for 24 hours as an oxidant agent to promote oxidative stress. After that, to identify transcriptional regulation landscape against oxidative stress, RNA sequencing was performed. Results: Total of 406 transcripts (up = 61, down = 345) were commonly differentially expressed in both of AD dementia and cognitively normal older adults derived dermal fibroblast by ROS‐H2O2. These transcripts were enriched in GO categories related to cell division, cell cycle, and DNA repair. Interestingly, 133 transcripts (up = 41, down = 92) were only differentially expressed in AD dementia dermal fibroblast by ROS‐H2O2. These transcripts were enriched in GO categories related to DNA duplex unwinding, cell division, and DNA replication. Total of 147 transcripts (up = 67, down = 80) were only differentially expressed in cognitively normal older adults dermal fibroblast by ROS‐H2O2. These transcripts were enriched in GO categories related to negative regulation of cell proliferation, notch signaling pathway, and NMDA glutamate receptor signaling pathway. Conclusion: We identified transcriptional regulation landscape by ROS‐H2O2 in AD dementia and cognitively normal older adults dermal fibroblast. Further bioinformatic analysis with computational tools and validation experiments will be performed to find potential therapeutic targets against oxidative stress. [ABSTRACT FROM AUTHOR]