Abstract
The ability to execute different responses in an expedient temporal order is central for efficient goal-directed actions and often referred to as multi-component behaviour. However, the underlying neural mechanisms on a cellular level remain unclear. Here we establish a link between neural activity at the cellular level within functional neuroanatomical structures to this form of goal-directed behaviour by analyzing immediate early gene (IEG) expression in an animal model, the pigeon (Columba livia). We focus on the group of zif268 IEGs and ZENK in particular. We show that when birds have to cascade separate task goals, ZENK expression is increased in the avian equivalent of the mammalian prefrontal cortex, i.e. the nidopallium caudolaterale (NCL) as well as in the homologous striatum. The results provide the first link between cellular IEG expression and behavioural outcome in multitasking situations. Moreover, the data suggest that the function of the fronto-striatal circuitry is comparable across species indicating that there is limited flexibility in the implementation of complex cognition such as multi-component behaviour within functional neuroanatomical structures.
Highlights
The ability to execute different responses in an expedient temporal order is central for efficient goaldirected actions and often referred to as multi-component behaviour
Given the involvement of the fronto-striatal network in humans[1,3,4,6,7,8,9,12,13], it would be expected that the avian equivalents of the prefrontal cortex (PFC) and the striatum are involved in multi-component behaviour in pigeons
In the current study we examine ZENK expression in pigeons (Columba livia) after performing a STOP-CHANGE paradigm
Summary
The ability to execute different responses in an expedient temporal order is central for efficient goaldirected actions and often referred to as multi-component behaviour. We establish a link between neural activity at the cellular level within functional neuroanatomical structures to this form of goal-directed behaviour by analyzing immediate early gene (IEG) expression in an animal model, the pigeon (Columba livia). Based on the analogy of the NCL and the PFC and the homology of the avian and mammalian striatum, we hypothesize that both structures are involved in multi-component behaviour in pigeons. To examine this hypothesis, this study measured brain activity of the above-mentioned brain areas by quantifying immediate early gene (IEG) expression after pigeons engaged in multi-component behaviour. We hypothesize that this efficacy parameter of multi-component is directly correlated with the brain activity in the above-mentioned structures
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