适应性行为的进化调整需要增强神经丘感觉系统。
Evolutionary tuning of an adaptive behavior requires enhancement of the neuromast sensory system.
作者信息
Yoshizawa Masato, Jeffery William R
机构信息
Department of Biology; University of Maryland; College Park, MD USA.
出版信息
Commun Integr Biol. 2011 Jan;4(1):89-91. doi: 10.4161/cib.4.1.14118.
Abstract
Cave animals are faced with the challenge of carrying out fundamental life processes in a completely dark environment. Evolution of behavioral changes could be one of the key steps that adapt these animals to the absence of light. Astyanax mexicanus is a teleost with sighted surface dwelling (surface fish) and blind cave dwelling (cavefish) forms. Cavefish, a descendant of surface fish ancestors, have evolved a suite of constructive traits including an increase in the number and diameter of superficial neuromasts (SN). Prior to our study, no clear relationships had been established between constructive traits and the evolution of behavior. The current results link SN enhancement to vibration attraction behavior (VAB), a behavioral shift that is beneficial for feeding in a dark environment. We discuss a possible scenario in which the evolution of VAB may be a key factor in the establishment and survival of cavefish ancestors in the dark cave environment.
摘要
洞穴动物面临着在完全黑暗的环境中进行基本生命过程的挑战。行为变化的进化可能是使这些动物适应无光环境的关键步骤之一。墨西哥丽脂鲤是一种硬骨鱼,有视力的表层栖息(表层鱼)和盲眼洞穴栖息(洞穴鱼)两种形态。洞穴鱼是表层鱼祖先的后代,已经进化出一系列结构性特征,包括体表神经丘(SN)数量和直径的增加。在我们的研究之前,结构性特征与行为进化之间尚未建立明确的关系。目前的结果将SN增强与振动吸引行为(VAB)联系起来,VAB是一种行为转变,有利于在黑暗环境中觅食。我们讨论了一种可能的情况,即VAB的进化可能是洞穴鱼祖先在黑暗洞穴环境中生存和繁衍的关键因素。
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