Abstract
We are curious by nature, particularly when young. Evolution has endowed our brain with an inbuilt obligation to educate itself. In this perspectives article, we posit that self-tuition is an evolved principle of vertebrate brain design that is reflected in its basic architecture and critical for its normal development. Self-tuition involves coordination between functionally distinct components of the brain, with one set of areas motivating exploration that leads to the experiences that train another set. We review key hypothalamic and telencephalic structures involved in this interplay, including their anatomical connections and placement within the segmental architecture of conserved forebrain circuits. We discuss the nature of educative behaviours motivated by the hypothalamus, innate stimulus biases, the relationship to survival in early life, and mechanisms by which telencephalic areas gradually accumulate knowledge. We argue that this aspect of brain function is of paramount importance for systems neuroscience, as it confers neural specialization and allows animals to attain far more sophisticated behaviours than would be possible through genetic mechanisms alone. Self-tuition is of particular importance in humans and other primates, whose large brains and complex social cognition rely critically on experience-based learning during a protracted childhood period.This article is part of the theme issue ‘Systems neuroscience through the lens of evolutionary theory’.
Highlights
A critical early mission of the brain is to direct its own education [1]
We focus on the hypothalamus and its generation of motivated behaviours during early royalsocietypublishing.org/journal/rstb Phil
In addition to its direct control of motor circuits through descending projections [24], the hypothalamus has the ability to intervene directly in the expression of behaviour initiated by the telencephalon
Summary
A critical early mission of the brain is to direct its own education [1]. Genetic programmes are limited in their capacity to confer sophisticated behaviours. The brain has evolved systems that develop specialization through experience. Some learned specializations are shared broadly, whereas others are linked to a given ecology or sensory modality In this perspectives article, we posit that the vertebrate forebrain has evolved to support an interplay between brain areas that drives its own education based on a curiosity-driven exploration of the environment. We posit that the vertebrate forebrain has evolved to support an interplay between brain areas that drives its own education based on a curiosity-driven exploration of the environment We refer to this process as self-tuition. We provide examples of how early life behaviours can serve the dual role of immediate survival and longer-term training of the brain. While we posit that this aspect of brain operation is a conserved feature of the vertebrate brain, we focus on mammals, and primates, whose long childhood affords them an extended developmental window for this process to unfold
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