Birds and longevity: Does flight driven aerobicity provide an oxidative sink?
- 作者:Anthony J.R. Hickeya ; b ; c ; a.hickey@auckland.ac.nz ; Mia Jü ; lliga ; b ; Jacqueline Aitkena ; b ; Kerry Loomesa ; b ; Mark E. Hauberd ; Anthony R.J. Phillipsa ; b ; c
- 关键词:CR ; caloric restriction ; DCA ; dichloroacetic acid ; ETF ; electron transfer flavoprotein ; ETS ; electron transport system ; FOXO1 ; Forkhead box protein O1 ; H2O2 ; hydrogen peroxide ; Gp ; DHglycerol 3-phosphate dehydrogenase ; IGF-1R ; insulin-like-growth factor r
- 刊名:Ageing Research Reviews
- 出版年:2012
- 期刊代码:272_15681637
- 类别:med
- 出版时间:April, 2012
- 卷:11
- 期:2
- 页码:242-253
- 文件大小:1029 K
摘要
Birds generally age slower and live longer than similar sized mammals. For birds this occurs despite elevated blood glucose levels that for mammals would in part define them as diabetic. However these data were acquired in respiration states that have little resemblance to conditions in healthy tissues and mitochondrial RS production is probably minimal in healthy animals. Indeed mitochondria probably act as net consumers rather than producers of RS. Here we propose that (1) if mitochondria are antioxidant systems, the greater mitochondrial mass in athletic species, such as birds, is advantageous as it should provide a substantial sink for RS. (2) The intense drive for aerobic performance and decreased body density to facilitate flight may explain the relative insensitivity of birds to insulin, as well as depressed insulin levels and apparent sensitization to glucagon. Glucagon also associates with the sirtuin protein family, most of which are associated with caloric restriction regulated pathways, mitochondrial biogenesis and life span extension. (3) We note that telomeres, which appear to be unusually long in birds, bind Sirtuins 2 and 4 and therefore may stabilize and protect nuclear DNA. Ultimately these flight driven responses may suppress somatic growth and protect DNA from oxidative damage that would otherwise lead to ageing and non-viral cancers.