Hunger is a driving force for all living beings, even the simplest of creatures. The University of Kiel zoologist Christoph Giez and his team decided to study brainless jellyfish relatives called hydra to understand how these creatures manage feelings of hunger and fullness without a conventional brain. What they discovered was a surprising level of complexity in hydra nervous systems, challenging traditional notions of how creatures without brains regulate behaviors related to food intake.
Contrary to expectations, the researchers found that hydra have more sophisticated networks of neurons than previously believed. Despite lacking a traditional brain, hydra possess a nervous system with distinct networks. One network serves a role similar to our central nervous system, while the other functions like our peripheral nervous system. This discovery suggests that even creatures with simple nervous systems can sense complex internal states such as hunger and regulate behaviors accordingly.
Through a series of experiments, the researchers observed that hydra can detect changes in their internal metabolic state and adjust their behaviors accordingly. After feeding, the animals exhibited reduced attraction to light stimuli and suppressed natural movement patterns, indicating a sense of fullness. The researchers even found that by removing a specific network of neurons responsible for the feeling of fullness, the hydra lost their light orientation abilities and displayed increased interest in food, highlighting the intricate role of different neuron populations in regulating behaviors related to hunger and satiety.
The findings from studying hydra nervous systems offer insights into the early evolution of animal nervous systems. Despite lacking direct physical connections between the two networks, hydra’s ability to control appetite through separate but communicating systems suggests an early emergence of complex neural functions in animal evolution. The researchers speculate that chemical communication between the networks plays a crucial role in coordinating responses to hunger and fullness.
The study of hydra nervous systems challenges existing beliefs about the relationship between brain complexity and the ability to regulate behaviors related to feeding. The intricate networks of neurons in hydra demonstrate that even creatures without conventional brains can possess sophisticated nervous systems capable of sensing internal states and modulating behaviors accordingly. This research not only expands our understanding of neural evolution but also highlights the fascinating capabilities of seemingly simple organisms in managing essential biological functions like hunger and satiety.