Abstract
Discussions of the function of early nervous systems usually focus on a causal flow from sensors to effectors, by which an animal coordinates its actions with exogenous changes in its environment. We propose, instead, that much early sensing was reafferent; it was responsive to the consequences of the animal's own actions. We distinguish two general categories of reafference—translocational and deformational—and use these to survey the distribution of several often-neglected forms of sensing, including gravity sensing, flow sensing and proprioception. We discuss sensing of these kinds in sponges, ctenophores, placozoans, cnidarians and bilaterians. Reafference is ubiquitous, as ongoing action, especially whole-body motility, will almost inevitably influence the senses. Corollary discharge—a pathway or circuit by which an animal tracks its own actions and their reafferent consequences—is not a necessary feature of reafferent sensing but a later-evolving mechanism. We also argue for the importance of reafferent sensing to the evolution of the body-self, a form of organization that enables an animal to sense and act as a single unit.This article is part of the theme issue ‘Basal cognition: multicellularity, neurons and the cognitive lens’.
Highlights
Work on early nervous system evolution is generally shaped by the assumption that the main function of a nervous system is to control behaviour [1,2]
We argue for the importance of reafferent sensing to the evolution of the body-self, a form of organization that enables an animal to sense and act as a single unit
A tradition of work on more neurally complex animals, including arthropods and vertebrates, has argued for a different view of these relationships between sensing and action, one that makes central the concept of reafference: the effects of action on what is sensed [6]. Extending and redirecting these ideas, we develop the concept of reafference through the general principle that self-initiated action evokes sensory change, and apply these ideas to early nervous system evolution
Summary
Work on early nervous system evolution is generally shaped by the assumption that the main function of a nervous system is to control behaviour [1,2]. A tradition of work on more neurally complex animals, including arthropods and vertebrates, has argued for a different view of these relationships between sensing and action, one that makes central the concept of reafference: the effects of action on what is sensed [6] (see box 1 for a glossary of terms). Extending and redirecting these ideas, we develop the concept of reafference through the general principle that self-initiated action evokes sensory change, and apply these ideas to early nervous system evolution. These considerations shed new light on the origin of a ‘self’ in animal evolution, which we formalize in the concept of the body-self
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