Department of Biology, Advanced Facility for Avian Research, University of Western Ontario, London, Ontario, Canada, N6A 5B7
Department of Biology, Advanced Facility for Avian Research, University of Western Ontario, London, Ontario, Canada, N6A 5B7.
J Exp Biol. 2019 Mar 1;222(Pt 5):jeb187708. doi: 10.1242/jeb.187708.
Migration poses many physiological challenges for birds, including sustaining high intensity aerobic exercise for hours or days. A consequence of endurance flight is the production of reactive oxygen species (ROS). ROS production may be influenced by dietary polyunsaturated fatty acids (PUFA), which, although prone to oxidative damage, may limit mitochondrial ROS production and increase antioxidant capacity. We examined how flight muscles manage oxidative stress during flight, and whether dietary long-chain PUFA influence ROS management or damage. Yellow-rumped warblers were fed diets low in PUFA, or high in long-chain n-3 or n-6 PUFA. Flight muscle was sampled from birds in each diet treatment at rest or immediately after flying for up to a maximum of 360 min in a wind tunnel. Flight increased flight muscle superoxide dismutase activity but had no effect on catalase activity. The ratio of glutathione to glutathione disulphide decreased during flight. Oxidative protein damage, indicated by protein carbonyls, increased with flight duration (Pearson =0.4). Further examination of just individuals that flew for 360 min (=15) indicates that oxidative damage was related more to total energy expenditure (Pearson =0.86) than to flight duration itself. This suggests that high quality individuals with higher flight efficiency have not only lower energy costs but also potentially less oxidative damage to repair after arrival at the destination. No significant effects of dietary long-chain PUFA were observed on antioxidants or damage. Overall, flight results in oxidative stress and the degree of damage is likely driven more by energy costs than fatty acid nutrition.
迁徙给鸟类带来了许多生理挑战,包括数小时或数天维持高强度的有氧运动。耐力飞行的一个后果是产生活性氧(ROS)。膳食多不饱和脂肪酸(PUFA)可能会影响 ROS 的产生,尽管它们容易受到氧化损伤,但可以限制线粒体 ROS 的产生并增加抗氧化能力。我们研究了飞行肌肉在飞行过程中如何应对氧化应激,以及膳食长链 PUFA 是否会影响 ROS 的管理或损伤。黄腹山雀喂食低 PUFA、高长链 n-3 或 n-6 PUFA 的饮食。在风洞中飞行最长 360 分钟后,从每种饮食处理的鸟类的飞行肌肉中取样。飞行增加了飞行肌肉中超氧化物歧化酶的活性,但对过氧化氢酶的活性没有影响。飞行期间,谷胱甘肽与谷胱甘肽二硫化物的比值下降。氧化蛋白损伤,用蛋白质羰基表示,随着飞行时间的延长而增加(皮尔逊=0.4)。进一步只检查飞行 360 分钟的个体(=15)表明,氧化损伤与总能量消耗(皮尔逊=0.86)的关系比与飞行时间本身的关系更密切。这表明,具有更高飞行效率的高质量个体不仅具有更低的能量成本,而且在到达目的地后可能需要修复的氧化损伤也更少。膳食长链 PUFA 对抗氧化剂或损伤没有显著影响。总的来说,飞行会导致氧化应激,而损伤的程度可能更多地由能量成本驱动,而不是脂肪酸营养。
