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Correlation found between evolution of higher brain center, behavior in hymenopteran insects

Did diversification of nerve cells in insect brain give rise to behavioral evolution?

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Graduate School of Science / Faculty of Science
2018/04/27

© 2018 Satoyo Oya, Hiroki Kohno, Yooichi Kainoh, Masato Ono, and Takeo Kubo.Evolutionary history tree of five insect species analyzed in this study, top, photos of the species, middle, and illustrations of Kenyon cell subtypes that compose mushroom bodies.

Increase in number of Kenyon cell subtypes associated with behavioral evolution in hymenopteran insects
Evolutionary history tree of five insect species analyzed in this study, top, photos of the species, middle, and illustrations of Kenyon cell subtypes that compose mushroom bodies.
© 2018 Satoyo Oya, Hiroki Kohno, Yooichi Kainoh, Masato Ono, and Takeo Kubo.

Researchers at the University of Tokyo and their collaborators have demonstrated that the number of subtypes of neurons called Kenyon cells that constitute the higher center of the insect brain, known as mushroom bodies, has increased according to the behavioral evolution in the hymenopteran order of insects, which includes bees, wasps, ants, and sawflies.

The order Hymenoptera comprises many insect species exhibiting various behavioral traits. The most primitive of these insects, such as the sawflies belonging to the suborder Symphyta, are solitary and feed on plants. The more evolutionarily advanced parasitic wasps are also solitary, whereas the highest lineages belonging to the Aculeata group, including hornets, scoliid wasps, ants, and honeybees, which exhibit nesting behavior, are both solitary and social. The evolution of the higher brain center that underlies the behavioral evolution of such hymenopteran insects is largely unknown to scientists.

In insect brains, the mushroom bodies are a higher-order center for sensory integration and memory. In the present study, graduate students Satoyo Oya and Hiroki Kohno and Professor Takeo Kubo of the Graduate School of Science at the University of Tokyo demonstrated that the number of Class I Kenyon cell subtypes that make up the mushroom bodies increases from one to two to three, in correlation with the behavioral evolution from phytophagous (plant-eating) to parasitic to nidificating (nest-building) in hymenopteran insects. This finding suggests for the first time that an increase in the number of Kenyon cell subtypes underlies the behavioral evolution in hymenopteran insects; it further provides insights into the mechanisms of behavioral evolution of animals in general. The acquisition of nesting behavior, in particular, is of great interest as it has been observed in various higher animal species, and it could be a prerequisite for the subsequent evolution of social behavior. Further elucidation of the function of each Kenyon cell subtype promises to help unveil the mystery of the behavioral evolution of hymenopteran insects.

"I am glad to be able to demonstrate the parallel course of the behavioral evolution of Hymenoptera and the cells of their higher brain," says Oya. Kubo comments that "The functional evolution of the brain that underlies the behavioral evolution in hymenopteran insects has long been a big mystery. We hope that this finding could be a clue to further help elucidate this mystery."

The current findings are the result of a research collaboration with Professor Yooichi Kainoh at the University of Tsukuba and Professor Masato Ono at Tamagawa University.

Press release (Japanese)

Paper

Satoyo Oya, Hiroki Kohno, Yooichi Kainoh, Masato Ono, and Takeo Kubo, "Increased complexity of mushroom body Kenyon cell subtypes in the brain is associated with behavioral evolution in hymenopteran insects", Scientific Reports Online Edition: 2017/10/23 (Japan time), doi: 10.1038/s41598-017-14174-6.
Article link (Publication)

Links

Graduate School of Science

Department of Biological Sciences, Graduate School of Science

Laboratory of Physiological Chemistry, Department of Biological Sciences, Graduate School of Science

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