Neuroevolution: Same Neurons Coordinate Different Behaviors
Nudibranche or sea slug.
Scientists at Georgia State University have rewired the neural circuit of one species and given it the connections of another species to test a hypothesis about the evolution of neural circuits and behavior.
Neurons are connected to each other to form networks that underlie behaviors. Drs. Akira Sakurai and Paul Katz of Georgia State’s Neuroscience Institute study the brains of sea slugs, more specifically nudibranchs, which have large neurons that form simple circuits and produce simple behaviors. In this study, they examined how the brains of these sea creatures produce swimming behaviors. They found that even though the brains of two species – the giant nudibranch and the hooded nudibranch – had the same neurons, and even though the behaviors were the same, the wiring was different.
The researchers blocked some of the connections in the giant nudibranch using curare, a paralyzing poison used on blow darts by indigenous South Americans. This prevented the brain of the giant nudibranch from producing the pattern of impulses that would normally cause the animal to swim. Then, they inserted electrodes into the neurons to create artificial connections between the brain cells that were based on connections from the hooded nudibranch. The brain was able to produce rhythmic, alternating activity that would underlie the swimming behavior, showing these two species produce their swimming behavior using very different brain mechanisms.
“Behaviors that are homologous and similar in form would naturally be assumed to be produced by similar neural mechanisms,” said Katz, co-author of the study and a Regent’s Professor in the Neuroscience Institute at Georgia State. “This and previous studies show that connectivity of the neural circuits of two different species of sea slugs differ substantially from each other despite the presence of homologous neurons and behaviors. Thus, the evolution of microcircuitry could play a role in the evolution of behavior.”
The study’s results are significant for several reasons. First, they show that over the course of evolution, behaviors might be conserved, but the underlying neural basis for the behaviors could shift.
In addition, other work by these researchers and Katz’s lab has underscored the conclusion that neurons are conserved, but differ in function across species. This has implications for extrapolating results across species in general and means caution must be taken in assuming that neural mechanisms are conserved even though brain regions and behaviors are present.
Sakurai, Akira, and Paul S. Katz. "Artificial Synaptic Rewiring Demonstrates That Distinct Neural Circuit Configurations Underlie Homologous Behaviors". Current Biology (2017)
This article has been republished from materials provided by Georgia State University. Note: material may have been edited for length and content. For further information, please contact the cited source.
Neural Computer Hears Like HumansNews
Modelling the human senses is an incredibly complex task. Our brains arrange cells into complex hierarchies that process information from our surroundings. Now, a group at MIT have created a model of the human auditory cortex that can hear sounds and music in the same way that humans do.READ MORE
New Microscope Captures Detailed 3-D Movies of Cells Deep Within Living SystemsNews
Merging lattice light sheet microscopy with adaptive optics reveals the most detailed picture yet of subcellular dynamics in multicellular organisms.READ MORE
Stable Beta-Amyloid Dimers Identified in Alzheimer’s BrainsNews
A recent study exploited state-of-the-art mass spectrometry to provide the first direct evidence of beta-amyloid dimers in patients with Alzheimer’s disease and points to the potential of these molecules as biomarkers. Beta-amyloid dimers may be the smallest pathological species that trigger Alzheimer’s disease.