The degree of fidelity between microbes and their hosts varies considerably among different animal groups but also along the host's developmental stages and depends on the stability of their microbial communities. Cheutin et al. showcase experimentally the stability of whole body bacterial microbiome in a dermapteran insect species, the European earwig Forficula auricularia. The carefully designed experiments, which include a large number of investigated families and the related methodologies along with the data analysis, revealed that the bacterial communities of this insect are highly dynamic during the early developmental stages, but these changes are rather specific to each developmental stage and rather irrelevant to moulting. Some of these changes were reflected in the dominant predicted metabolic pathways. Another important finding of this study was that maternal care of the eggs has a detectable impact on the future shaping of the adult insect bacterial microbiome.

The findings of this paper clearly answer its working hypotheses, but they also generate a set of specific novel hypotheses for future studies. These hypotheses are of interest to the general field of animal-microbe interactions and, more specifically, to the driving forces of transmissability of microbes from one generation to the next one. This study also depicts some of the most likely important metabolic pathways in this insect-microbe relationship that could be the focus of future studies with more specific methodologies.

References

Cheutin M-C, Boucicot M, Meunier J. (2024). Microbiome turnover during offspring development varies with maternal care, but not moult, in a hemimetabolous insect. bioRxiv, ver.3, peer-reviewed and recommended by Peer Community In Microbiology. https://www.biorxiv.org/content/10.1101/2024.03.26.586808v3

The issue of whether there is a clear and detectable relationship -either deterministic or stochastic- of fish gut microbiota with evolutionary processes is far from being resolved. Studies on fish microbiota are more perplexed as this animal group includes species both from wild and farmed populations (for food production, ornamental fish and animal models), with variable life cycles and ecophysiologies, and all these features expand the type of interactions to be studied. Based on this biological features variability, multiple methodological limitations, especially for the species with wild populations, are perhaps among of the central reasons for this knowledge gap. Therefore, experimental approaches, which can eliminate some of this variability, seem to be the best approach.

The preprint by Evangelista et al. (2023) entitled "Within-species variation in the gut microbiome of medaka (Oryzias latipes) is driven by the interaction of light intensity and genetic background" is an example of such a targeted study with a freshwater fish species. Due to the paper's finely detailed experimental design, the interdisciplinary skills of the participating co-authors and exhaustive data analysis, this paper manages to draw solid and reproducible results and conclusions. This renders it not only an insightful contribution towards the more general host-microbe interactions in an evolutionary framework, but also a perfect example on how current and future relevant research should be conducted. I feel confident that this paper will assist other scientits of the field to move forward with their current working hypotheses but also to generate novel ones.

Reference :

Evangelista C, Kamenova S, Diaz Pauli B, Sandkjenn J, Vollestad A, Edeline E, Trosvik P, de Muinck E (2023) Within-species variation in the gut microbiome of medaka (Oryzias latipes) is driven by the interaction of light intensity and genetic background. bioRxiv, 2023.02.17.528956, ver. 2 peer-reviewed and recommended by Peer Community in Microbiology. https://doi.org/10.1101/2023.02.17.528956