Associative learning in insects: evolutionary models, mushroom bodies, and a neuroscientific conundrum

Pub Date : 2011-01-01 DOI:10.3819/CCBR.2011.60004

K. Hollis, L. Guillette

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引用次数: 25

Abstract

Environmental predictability has for many years been posited to be a key variable in whether learning is expected to evolve in particular species, a claim revisited in two recent papers. However, amongst many researchers, especially neuroscientists, consensus is building for a very different view, namely that learning ability may be an emergent property of nervous systems and, thus, all animals with nervous systems should be able to learn. Here we explore these differing views, sample research on associative learning in insects, and review our own work demonstrating learning in larval antlions (Neuroptera: Myrmeleontidae), a highly unlikely insect candidate. We conclude by asserting that the capacity for associative learning is the default condition favored by neuroscientists: Whenever selection pressures favor evolution of nervous systems, the capacity for associative learning follows ipso facto. Nonetheless, to reconcile these disparate views, we suggest that (a) models for the evolution of learning may instead be models for conditions overriding behavioral plasticity; and, (b) costs of learning in insects may be, in fact, costs associated with more complex cognitive skills, skills that are just beginning to be discovered, rather than simple associative learning.

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昆虫的联想学习:进化模型、蘑菇体和一个神经科学难题

多年来，环境的可预测性一直被认为是影响特定物种学习能力是否进化的关键变量，最近的两篇论文重新审视了这一观点。然而，在许多研究人员，特别是神经科学家之间，共识正在建立一个非常不同的观点，即学习能力可能是神经系统的一种紧急属性，因此，所有有神经系统的动物都应该能够学习。在这里，我们探讨了这些不同的观点，对昆虫的联想学习进行了抽样研究，并回顾了我们自己的工作，证明了幼虫蚁(神经翅目:蚁科)的学习能力，这是一种极不可能的昆虫候选人。我们的结论是，联想学习的能力是神经科学家青睐的默认条件:每当选择压力有利于神经系统的进化时，联想学习的能力就会理所当然地随之而来。尽管如此，为了调和这些不同的观点，我们建议(a)学习进化的模型可能是凌驾于行为可塑性之上的条件的模型;(b)昆虫学习的成本实际上可能是与更复杂的认知技能相关的成本，这些技能才刚刚开始被发现，而不是简单的联想学习。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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