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01.04.2026 17:48

Millions-of-years-old insect symbioses are surprisingly fragile

Angela Overmeyer Presse- und Öffentlichkeitsarbeit
Max-Planck-Institut für chemische Ökologie

An introduced bacterium displaces the sawtoothed grain beetle's symbiotic partner, leading to the complete collapse of a previously stable symbiosis within a few generations.

Many insects have lived in close symbiosis with bacteria for millions of years, during which time the bacteria have provided them with vital nutrients, making the mutualistic relationship so close that neither partner can survive without the other. However, the mechanisms and reasons behind the occasional exchange of symbionts during evolution have remained unclear until now. In a new study, researchers from the Max Planck Institute for Chemical Ecology in Jena and the University of Utah showed that the bacterium Sodalis praecaptivus can destroy the symbiosis between the sawtoothed grain beetle (Oryzaephilus surinamensis) and its symbiont (Shikimatogenerans silvanidophilus) within a few generations. Female beetles injected with Sodalis could pass the bacterium on to their offspring via the eggs. However, beetles infected with Sodalis exhibited reduced fitness. The beetles developed a strong immune response to Sodalis; in contrast, the original symbiont was unable to respond to the intruder due to its high degree of specialization in nutrient supply and was ultimately eliminated. This study demonstrates that even an ancient symbiosis is fragile. A new bacterial partner can quickly establish itself. This is a crucial step in understanding symbiosis dynamics in evolution.

A model for the dynamics of symbiosis: Sodalis as a driver of symbiont replacement

The mutual dependence between insects and their bacterial symbionts is the result of millions of years of coevolution. Many insects live in close mutualistic relationships with symbiotic bacteria that provide them with essential nutrients. This partnership has developed and proven itself over millions of years. However, seemingly stable symbioses are not unchangeable. In some insect species, the loss of original symbionts or their replacement by new bacteria has been observed, even when the original partners had formed a close symbiosis over long periods of time. The mechanisms and reasons behind this exchange are largely unexplored, primarily due to the lack of experimentally accessible systems.

"The lack of an easily manageable symbiosis was the driving force behind our study," explains Ronja Krüsemer, the first author from the Department of Insect Symbiosis at the Max Planck Institute for Chemical Ecology. "Our goal was to establish a controllable model system that would allow us to directly observe and study symbiont exchange."

Sodalis praecaptivus as an intruder: displacement of the original symbiont in the sawtoothed grain beetle

In collaboration with Colin Dale from the University of Utah, who had already established an artificial symbiosis between grain weevils and the bacterium Sodalis praecaptivus, Martin Kaltenpoth's team at the Max Planck Institute for Chemical Ecology took a targeted approach. They injected the bacterium into female grain beetles (Oryzaephilus surinamensis) to test its influence on natural symbiosis.

The novel bacterium proved to be highly adaptable. It colonized nearly all of the beetles' tissues and organs and, surprisingly, was successfully transmitted from mother to offspring via eggs. The researchers were able to raise several beetle generations, which led to a surprising discovery. In the third generation, the original symbiont, Shikimatogenerans silvanidophilus had disappeared.

However, infection with Sodalis affected more than just the original symbiont. The beetles exhibited lighter cuticles, reduced life expectancy, and lower reproduction rates. At the same time, their immune systems were activated, as evidenced by increased expression of immune genes. Sodalis invaded the bacteriomes, the specialized organs that harbor the original symbiont, and altered the conditions there to the disadvantage of the old symbiont.

Genome erosion plays a decisive role here. Shikimatogenerans, which has coexisted with its host for millions of years and is exclusively found in beetles, has lost many genes due to a lack of selection pressure. This makes the symbiont more susceptible to changes in the host environment. Following the introduction of Sodalis, Shikimatogenerans was unable to adapt to the new conditions, displayed morphological abnormalities and was ultimately displaced.
"We didn't expect the original symbiont to be completely lost this fast," says Ronja Krüsemer. "This observation came as a big surprise, but it is also the key to investigating the onset of symbiont exchange."

A pioneering model system for the future of symbiosis research

The Oryzaephilus surinamensis-Sodalis praecaptivus system is proving to be a promising model for investigating the mechanisms behind symbiont exchange, symbiosis establishment, and the evolution of mutualisms. Future studies will examine how genetic mutations influence the fitness of hosts and symbionts, and will include large-scale fitness experiments with infected beetles and their offspring.

"With our system, we can directly observe the dynamics behind symbiont exchange," says study leader Martin Kaltenpoth. "Our study shows that new bacteria can displace the original symbionts, and this process can happen faster than previously thought. Furthermore, the loss of the original symbiont can occur in the context of an incipient symbiont exchange."

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Wissenschaftliche Ansprechpartner:

Ronja Krüsemer, Department of Insect Symbiosis, Max Planck Institute for Chemical Ecology, Hans-Knöll-Straße 8, 07745 Jena, Germany, Tel. +49 3641 57-1562, E-Mail rkruesemer@ice.mpg.de
Prof. Dr. Martin Kaltenpoth, Department of Insect Symbiosis, Max Planck Institute for Chemical Ecology, Hans-Knöll-Straße 8, 07745 Jena, Germany, Tel. +49 3641 57-1500 , E-Mail kaltenpoth@ice.mpg.de

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Originalpublikation:

Krüsemer, R., Carvalho, A.S.P., Keller, J. et al. Experimental Sodalis infection eliminates ancient insect symbiont. Nat Commun 17, 3153 (2026). https://doi.org/10.1038/s41467-026-71143-2

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Weitere Informationen:

https://www.ice.mpg.de/94941/insect-symbiosis Department of Insect Symbiosis,

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infected bacteriome
Quelle: Ronja Krüsemer
Copyright: Max Planck Institute for Chemical Ecology

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Ronja Krüsemer and Martin Kaltenpoth.
Quelle: Benjamin Weiss
Copyright: Max Planck Institute for Chemical Ecology

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