When bacteria regulate the jellyfish reproduction

Researchers at Kiel University demonstrate the key role of the microbiome in the life cycle of the moon jellyfish
Jellyfish are among the oldest animals on Earth, found in all the world’s oceans and serve as a valuable model systems for biological research. Microbiologists at Kiel University have now shown that the asexual reproduction of the moon jellyfish (Aurelia aurita) is largely regulated by bacterial metabolites. Beta-carotene, produced by microbes within the jellyfish’s natural microbiome, plays a key role in this process. Without these microorganisms, the so-called strobilation process – the transformation of the polyp into young jellyfish – comes to a halt. This leads to developmental defects and severely reduced reproduction success. The researchers recently published their findings in the journal iScience, highlighting at the molecular level how closely the moon jellyfish’s life cycle is linked to its natural microbial community.

The microbiome: A key player in the jellyfish life cycle
The microbiome, the community of bacteria that live in and on a multicellular organism, plays a critical role in the fitness and health of many marine animals. The moon jellyfish hosts a particularly adaptable microbiome that can adjust to different environmental conditions and influences transitions between different life stages. The complex life cycle begins with tiny larvae that settle on solid surfaces and develop into sessile polyps. Through a process called strobilation, these polyps release free-swimming juvenile jellyfish, known as ephyra, which later develop into the adult medusae. The researchers demonstrated that this asexual reproductive process is significantly influenced by the associated microbiome.

“Our results show that not only environmental factors such as temperature or salinity influence jellyfish reproduction, but that the natural microbiome of the host is essential. The microbial influence is particularly critical before strobilation begins,” says first author Dr. Nadin Jensen, who conducted her doctoral research on the topic in the working group of Professor Ruth Schmitz-Streit at the Institute of General Microbiology at Kiel University (IfAM).

Beta-carotene as a melecular key to metamorphosis
Strobilation, the transformation from a polyp into a free-swimming jellyfish, is a multi-step process: First, bacteria within the polyp produce beta-carotene. This provitamin is then taking up by the jelly and metabolized into bioactive molecules – most notably retinoic acid (9-cis-retinoic acid). It acts as a biological signal that activates key genes needed for strobilation, thereby triggering the onset of metamorphosis. “In the absence of the natural microbiome, polyps show clear development abnormalities. They segment incompletely and release very few ephyra,” explains Professor Ruth Schmitz-Streit, head of the Molecular Biology of Microorganisms working group at Kiel University.

In laboratory experiments, sterile polyps that lacked the natural microbiome showed significant defects such as shortened bodies, deformed segmentation, missing tentacles and low ephyra production. However, when the researchers added beta-carotene or 9-cis-retinoic acid to the surrounding water, the polyps’ defects could be partly or fully restored. Conversely, when they used specific inhibitors to block the retinoic acid signaling pathway, strobilation was disrupted — even in healthy polyps with an intact microbiome. The researchers also confirmed that the genes responsible for beta-carotene production are active and were found exclusively in the bacteria, not in the jellyfish itself. This shows that the jellyfish is dependent on its microbiome for these crucial signals.

“Our experiments confirm that the retinoic acid pathway is vital for the strobilation of the jellyfish. Without it, the polyp remains stuck in an early developmental stage”, says Dr. Jensen. “However, we are still at the beginning of our research – we haven’t yet determined the exact concentration of beta-carotene involved and we have so far focused on just four key genes.”

New insights into the adaptability of marine organisms
The new study illustrates how closely the development of a marine organism is linked to its microbial partners. In the absence of its natural microbiome, the moon jellyfish cannot fully carry out essential life processes such as strobilation. The new findings not only help to a better understand jellyfish development, but also provide insights into the broder adaptability of marine life. They may even help explain large-scale phenomena such as jellyfish blooms. “Jellyfish are an important part of marine ecosystems and have a remarkable ability to adapt to changing environmental conditions. A better understanding of how they reproduce could help us understand their distribution in the oceans and perhaps also to counteract it in the future,” summarizes microbiologist Schmitz-Streit.

The research was condected within the framework of the Collaborative Research Center (CRC) 1182 “Origin and Function of Metaorganisms”, funded by the German Research Foundation (DFG).

Original publication:
Nadin Jensen, Nancy Weiland-Bräuer, Cynthia Maria Chibani, Ruth Anne Schmitz, Microbiota-derived β carotene is required for strobilation of Aurelia aurita by impacting host retinoic acid signaling, iScience, Volume 28, Issue 2, 2025, 111729, ISSN 2589-0042
doi.org/10.1016/j.isci.2024.111729

Scientific Contact:
Prof. Dr. Ruth Schmitz-Streit
Institute for General Microbiology (IfAM)
Kiel University
rschmitz@ifam.uni-kiel.de
0431 / 880-4334

More information:
Working Goup Molecular Biology of Microorganisms, Kiel University:
www.mikrobio.uni-kiel.de/de/ag-schmitz-streit

Research project B2 (PI Schmitz-Streit) Microbiota-host interactions at the base of the metazoan tree, CRC 1182:
www.metaorganism-research.com/project-groups/b2/