ROS induced cellular toxicity and tissue damage

ROS诱导的细胞毒性和组织损伤

• 批准号: 7012539
• 负责人: ATANU DUTTAROY
• 金额: $ 20.38万
• 依托单位: HOWARD UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-03-01 至 2010-02-28
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7012539
• 关键词: DNA damage; Drosophilidae; age difference; aging; apoptosis; clinical research; enzyme activity; enzyme linked immunosorbent assay; free radical oxygen; longevity; mitochondria; oxidative stress; oxidized lipid; superoxide dismutase; terminal nick end labeling

DESCRIPTION (provided by applicant): Reactive oxygen species (ROS) is seemingly the major determinant of life-span. To understand the aging potential of specific cell types or tissue we need to understand the effect of intracellular ROS toxicity on specific tissue in vivo. The creation of an intrinsic oxidative stress environment in specific tissue without affecting others was not easy until the advent of molecular-genetic tools. It is now possible to ask this question in vivo in model systems like Drosophila. The enzyme manganese superoxide dismutase, which catalyzes the detoxification of superoxide radicals in the mitochondrial matrix, plays a central role in cellular aging, as evident from the fact that loss of MnSOD function severely reduces organismic life span, while its over-expression could extend it. Hypothesis: The specific hypothesis to be tested is that depletion of MnSOD activity from a specific tissue will trigger cellular damage through an intracellular rise in ROS concentration; however, the amount of damage to individual tissues will vary, as will their biological efficacies, which will be reflected at the organismal level. We will examine our hypothesis in four different tissues in Drosophila including fat body, muscle, brain and retinal cells of the eye, all of which are essential for the viability of the organism with the exception of retinal cells. By using a state-of-the-art technique, MnSOD function will be depleted in vivo from each of these tissues. We will address several important biological questions involving tissue specific ROS generation, tissue specific oxidative damage to DNA and protein, tissue specific apoptotic cell death potential. Depletion of MnSOD function from each of these tissues will provide important insight regarding the contribution of ROS towards cellular aging.

描述（由申请人提供）：活性氧（ROS）似乎是寿命的主要决定因素。为了了解特定细胞类型或组织的衰老潜力，我们需要了解细胞内 ROS 毒性对体内特定组织的影响。在分子遗传学工具出现之前，在特定组织中创建内在的氧化应激环境而不影响其他组织并不容易。现在可以在果蝇等模型系统中在体内提出这个问题。锰超氧化物歧化酶催化线粒体基质中超氧自由基的解毒，在细胞衰老中发挥着核心作用，这一点可以从以下事实中看出：MnSOD功能的丧失会严重缩短生物体的寿命，而其过度表达可以延长生物体的寿命。 。假设：要测试的具体假设是，特定组织中 MnSOD 活性的消耗将通过细胞内 ROS 浓度升高而引发细胞损伤；然而，对个体组织的损害程度会有所不同，其生物功效也会有所不同，这将反映在有机体水平上。我们将在果蝇的四种不同组织中检验我们的假设，包括脂肪体、肌肉、大脑和眼睛的视网膜细胞，除视网膜细胞外，所有这些组织对于生物体的生存都至关重要。通过使用最先进的技术，这些组织中的 MnSOD 功能将在体内被耗尽。我们将解决几个重要的生物学问题，涉及组织特异性 ROS 生成、组织特异性 DNA 和蛋白质氧化损伤、组织特异性凋亡细胞死亡潜力。这些组织中 MnSOD 功能的耗尽将为了解 ROS 对细胞衰老的贡献提供重要的见解。