迁徙型鸫鸟与定居型鸫鸟线粒体性能的比较。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Emma M Rhodes, Kang Nian Yap, Geoffrey E Hill, Wendy R Hood
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引用次数: 0

摘要

鸟类的迁徙策略多种多样。与典型的日常活动相比,持续的拍打飞行需要产生更高水平的能量,因此候鸟在生理上有多种适应措施,以支持迁徙的能量需求。然而,尽管线粒体是为飞行提供动力的 ATP 的来源,但线粒体的呼吸性能在迁徙过程中几乎没有得到研究。我们假设,与不迁徙的物种相比,迁徙物种在迁徙过程中的线粒体呼吸性能更高。为了验证这一假设,我们比较了两种共栖鸟类--迁徙性灰猫鸟(Dumetella carolinensis)和非迁徙性北方知更鸟(Mimus polyglottos)--线粒体呼吸功能的相关变量。我们在阿拉巴马州海湾沿岸的同一地点捕获了这些鸟,我们假定灰猫鸟是迁徙鸟,而北方知更鸟则常年生活在那里。我们发现柠檬酸合成酶活性呈上升趋势,这表明灰猫鸟的胸肌线粒体体积较大,但我们没有观察到迁徙物种与非迁徙物种个体在线粒体呼吸或复合酶活性方面的其他差异。然而,当我们使用成熟的迁徙生理指标对研究中的猫蝠鸟进行评估时,发现猫蝠鸟分为两组:一组的生理指标表明猫蝠鸟具有迁徙的生理特征,另一组则表明猫蝠鸟不具有迁徙的生理特征。因此,我们的比较包括了似乎不处于迁徙状态的猫蝠鸟。当我们比较这三类鸟的线粒体性能时,我们发现迁徙猫鸟的线粒体呼吸能力与北方知更鸟的线粒体呼吸能力非常相似,而被判定为非迁徙的猫鸟的线粒体呼吸能力最低。对这些观察结果的一种解释是,这些物种的日常飞行行为截然不同。虽然我们采样的知更鸟既不繁殖也不迁徙,但它们是高度活跃的鸟类,生活在空旷的地方,每天都在进行拍打飞行。相比之下,灰猫鸟生活在灌木丛中,不迁徙时很少飞行。这种基本能量需求的差异很可能会影响我们对迁徙适应性的研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Comparison of the mitochondrial performance between migratory and sedentary mimid thrushes.

Birds exhibit a variety of migration strategies. Because sustained flapping flight requires the production of elevated levels of energy compared to typical daily activities, migratory birds are well-documented to have several physiological adaptations to support the energy demands of migration. However, even though mitochondria are the source of ATP that powers flight, the respiratory performance of the mitochondria is almost unstudied in the context of migration. We hypothesized that migratory species would have higher mitochondrial respiratory performance during migration compared to species that do not migrate. To test this hypothesis, we compared variables related to mitochondrial respiratory function between two confamilial bird species-the migratory Gray Catbird (Dumetella carolinensis) and the non-migratory Northern Mockingbird (Mimus polyglottos). Birds were captured at the same location along the Alabama Gulf Coast, where we assumed that Gray Catbirds were migrants and where resident Northern Mockingbirds live year-round. We found a trend in citrate synthase activity, which suggests that Gray Catbirds have a greater mitochondrial volume in their pectoralis muscle, but we observed no other differences in mitochondrial respiration or complex enzymatic activities between individuals from the migrant versus the non-migrant species. However, when we assessed the catbirds included in our study using well-established indicators of migratory physiology, birds fell into two groups: a group with physiological parameters indicating a physiology of birds engaged in migration and a group with the physiology of birds not migrating. Thus, our comparison included catbirds that appeared to be outside of migratory condition. When we compared the mitochondrial performance of these three groups, we found that the mitochondrial respiratory capacity of migrating catbirds was very similar to that of Northern Mockingbirds, while the catbirds judged to be not migrating were lowest. One explanation for these observations is these species display very different daily flight behaviors. While the mockingbirds we sampled were not breeding nor migrating, they are highly active birds, living in the open and engaging in flapping flights throughout each day. In contrast, Gray Catbirds live in shrubs and fly infrequently when not migrating. Such differences in baseline energy needs likely confounded our attempt to study adaptations to migration.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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