SubsidieMeestersNeural basis of zebrafish collective decision-making
This project aims to investigate the behavioral algorithms and neural mechanisms of collective decision-making in juvenile zebrafish using virtual reality and advanced neuroscientific techniques.
Projectdetails
Introduction
It is challenging for isolated animals to reliably extract and integrate behaviorally relevant information from the natural environment. Due to the limited sensory capacity of individuals, many animal species therefore share and evaluate cues collectively, allowing them to solve complex decision-making tasks as a group. The behavioral algorithms and neural mechanisms that give rise to these cognitive abilities remain poorly understood.
Research Context
In many fish species, these behaviors are largely vision-based, providing the opportunity to decipher the underlying general computational principles under well-controlled experimental conditions in the lab. At the same time, it is becoming possible to employ powerful neuroscientific techniques, enabling new detailed analyses of the neural circuitry that orchestrates behavior.
Proposed Model System
I propose to establish the juvenile zebrafish as a model system that is optimally suited for the study of collective decision-making. At this intermediate developmental stage, zebrafish offer an excellent compromise between cognitive ability and experimental accessibility.
Key Features of Juvenile Zebrafish
- They can temporally and spatially integrate information.
- They start to socially interact.
- One can characterize and manipulate brain activity in intact behaving animals.
Experimental Approach
Using closed-loop virtual reality experiments, I will initially dissect the algorithmic rules by which juvenile zebrafish make decisions when swimming in heterogeneously biased groups.
Brain Activity Characterization
I will then characterize brain activity related to this behavior, in freely swimming fish, and in restrained preparations.
Causal Link Investigation
Finally, to causally link neural circuit function and group decision-making performance, I will carry out targeted laser ablation and optogenetic activation experiments.
Conclusion
Thus, my proposed research in juvenile zebrafish will, for the first time, provide key insights into the behavioral algorithms and neural mechanisms of how individual animals and animal collectives acquire sensory information and make complex decisions.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.498.787 |
| Totale projectbegroting | € 1.498.787 |
Tijdlijn
| Startdatum | 1-8-2023 |
| Einddatum | 31-7-2028 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- UNIVERSITAT KONSTANZpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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This project aims to uncover how brainstem circuits and spinal feedback generate flexible locomotion in zebrafish using advanced all-optical techniques and single-cell analysis.
Neuronal implementation of cognitive maps for navigation
This project aims to elucidate the mechanisms of cognitive maps in zebrafish by integrating brain imaging, electron microscopy, and transcriptomics to understand neuronal connectivity and behavior.
Collective Regulation of Cell Decisions
This project aims to explore how collective tissue properties influence cell decisions in zebrafish by manipulating cell parameters to engineer tissue characteristics and uncover developmental mechanisms.
Understanding diversity in decision strategy: from neural circuits to behavior
This project aims to uncover the neural mechanisms behind the brain's flexibility in decision-making strategies during foraging, using advanced computational and electrophysiological methods in mice.
Simple minds – competition of parallel neural filters in behaviour selection of Drosophila
This project investigates how Drosophila integrates sensory and internal states through neural filters to influence behavior related to hunger and sleep, aiming to uncover the physiological basis of these processes.