The interplay of NAD and hypoxic stress and its relevance for ageing

老化 相关性(法律) NAD+激酶 神经科学 心理学 化学 医学 生物化学 政治学 内科学 法学
作者
Johannes Burtscher,Vanna Denti,Johanna M. Gostner,Alexander Weiß,Barbara Strasser,Katharina Hüfner,Martin Burtscher,Giuseppe Paglia,Martin Kopp,Tobias Dünnwald
出处
期刊:Ageing Research Reviews [Elsevier BV]
卷期号:104: 102646-102646 被引量:8
标识
DOI:10.1016/j.arr.2024.102646
摘要

Nicotinamide adenine dinucleotide (NAD) is an essential regulator of cellular metabolism and redox processes. NAD levels and the dynamics of NAD metabolism change with increasing age but can be modulated via the diet or medication. Because NAD metabolism is complex and its regulation still insufficiently understood, achieving specific outcomes without perturbing delicate balances through targeted pharmacological interventions remains challenging. NAD metabolism is also highly sensitive to environmental conditions and can be influenced behaviorally, e.g., by exercise. Changes in oxygen availability directly and indirectly affect NAD levels and may result from exposure to ambient hypoxia, increased oxygen demand during exercise, ageing or disease. Cellular responses to hypoxic stress involve rapid alterations in NAD metabolism and depend on many factors, including age, glucose status, the dose of the hypoxic stress and occurrence of reoxygenation phases, and exhibit complex time-courses. Here we summarize the known determinants of NAD-regulation by hypoxia and evaluate the role of NAD in hypoxic stress. We define the specific NAD responses to hypoxia and identify a great potential of the modulation of NAD metabolism regarding hypoxic injuries. In conclusion, NAD metabolism and cellular hypoxia responses are strongly intertwined and together mediate protective processes against hypoxic insults. Their interactions likely contribute to age-related changes and vulnerabilities. Targeting NAD homeostasis presents a promising avenue to prevent/treat hypoxic insults and - conversely - controlled hypoxia is a potential tool to regulate NAD homeostasis.
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