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在黑暗环境中,幼虫猎物捕获(LPC)的进化改造。

Evolutionary modifications of larval prey capture (LPC) in a dark environment.

机构信息

School of Science, Marist College, Poughkeepsie, NY 12601, USA. E-mail:

Depto. de Física, Universidad Autónoma Metropolitana - Iztapalapa, Ciudad de México C.P. 09310, México.

出版信息

Zool Res. 2023 Jul 18;44(4):750-760. doi: 10.24272/j.issn.2095-8137.2022.466.

DOI:10.24272/j.issn.2095-8137.2022.466
PMID:37464932
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10415770/
Abstract

Feeding strategies of an organism depend on the multimodal sensory processing that most efficiently integrates available visual, chemosensory, and/or mechanoreceptive cues as part of their environmental adaptation. The blind cavefish morph of has developed sensory-dependent behaviors to find food more efficiently than their eyed, surface-morph counterparts while in darkness. In the absence of light, adult cavefish have evolved enhanced behaviors, such as vibration attraction behavior (VAB), and changes in feeding angle. Here, we identified evolved differences in cavefish larval prey capture (LPC) behavior. In the dark, LPC is more efficient in cavefish than in surface fish. Furthermore, different cave populations express laterality in their LPC and strike towards prey preferentially located on their left or right sides. This suggests the occurrence, to some extent, of divergent LPC evolution among cave populations. While LPC can be triggered exclusively by a vibration stimulus in both surface and cavefish, we provide evidence that LPC is, at least partially, a multimodal sensory process different from adult VAB. We also found that a lack of food may exacerbate the laterality of LPC. Thus, we proposed a mathematical model for explaining laterality based on a balance between: (1) enlarged range of foraging field (behavioral or perceptive) due to asymmetry, (2) food abundance, and (3) disadvantages caused by laterality (unequal lateral hydrodynamic resistance when swimming, allocation of resources for the brain and receptors, and predator escape).

摘要

生物体的摄食策略取决于多模态的感觉处理,该处理最有效地整合了可用的视觉、化学感觉和/或机械感觉线索,作为其环境适应的一部分。 已发育出的感觉依赖行为,使盲眼洞穴鱼在黑暗中比有眼的地表鱼更有效地寻找食物。 在没有光的情况下,成年洞穴鱼已经进化出了增强的行为,例如振动吸引行为(VAB)和摄食角度的变化。 在这里,我们确定了洞穴鱼幼虫捕食(LPC)行为的进化差异。 在黑暗中,洞穴鱼的 LPC 比地表鱼更有效。 此外,不同的洞穴种群在 LPC 中表现出偏侧性,并优先向位于左侧或右侧的猎物发起攻击。 这表明,在某种程度上,洞穴种群之间的 LPC 进化存在分歧。 虽然在地表鱼和洞穴鱼中,仅通过振动刺激就可以触发 LPC,但我们提供的证据表明,LPC 至少部分是一种不同于成年 VAB 的多模态感觉过程。 我们还发现,缺乏食物可能会加剧 LPC 的偏侧性。 因此,我们提出了一个数学模型来解释偏侧性,该模型基于以下三个因素之间的平衡:(1)由于不对称性而扩大的觅食范围(行为或感知),(2)食物丰度,以及(3)偏侧性带来的劣势(游泳时不对称的横向水动力阻力、大脑和受体资源的分配,以及逃避捕食者)。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9227/10415770/4d291a3e2924/zr-44-4-750-8.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9227/10415770/4d291a3e2924/zr-44-4-750-8.jpg
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Lessons from behavioral lateralization in olfaction.嗅觉行为侧化的启示。
Brain Struct Funct. 2022 Mar;227(2):685-696. doi: 10.1007/s00429-021-02390-w. Epub 2021 Oct 1.
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Eye morphogenesis in the blind Mexican cavefish.盲眼墨西哥洞穴鱼的眼睛形态发生。
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Cavefish as biological models in the laboratory and in the wild.洞穴鱼作为实验室和野外的生物学模型。
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