Reverse ecology approach reveals hidden complexity in gut microbiome
· News-MedicalMicrobiome studies usually classify bacteria into whole species or genetically similar groups. Whilst these categories are practical, they do not necessarily reflect the populations that have adapted to different conditions within the human body. As a result, it often remains unclear which bacteria are associated with diseases, which are merely incidental – and which may offer protection. This raises a key question: can more precise biological units be identified that have emerged through adaptation and occupy different ecological niches in the gut?
About the study
The research team analyzed thousands of bacterial isolates from the human gut, as well as extensive metagenomic data – that is, the complete genetic information of microbial communities in the sample – from people in different countries and across various age and health groups. Using a newly developed bioinformatic method within the framework of 'reverse ecology' – an approach that infers ecological adaptations from genomic data – the researchers searched for genetic traces of successful adaptation.
More than one species
Particularly interesting were indications of so-called 'genome-wide selective sweeps' – processes in which an individual acquires a beneficial mutation and thereby displaces other, closely related individuals. On the one hand, this leads to a loss of diversity; on the other, it gives rise to populations of individuals that are very homogeneous in terms of both kinship and function, and which therefore stand out clearly from one another in the dataset. The analysis showed that many known gut bacterial species branch into several such lineages. These populations appear to differ in the conditions under which they thrive particularly well. "If you don't just count species but take evolutionary adaptation into account, you can identify the biologically relevant units in the microbiome much more accurately," says lead author Xiaoqian Annie Yu, Centre for Microbiology and Environmental Systems Science (CeMESS), University of Vienna. "Even within the same bacterial species, some populations occur more frequently than others in certain diseases. When all are considered together, this often remains hidden."
Global spread within a few decades
The researchers also found evidence that highly competitive populations can spread rapidly across continents – in some cases within a few decades. Until now, such a pattern has been observed primarily in pathogens.
Martin F. Polz, University of ViennaOur findings show that gut bacteria are also more dynamic than previously thought. Well-adapted strains can spread internationally and occupy new ecological niches."
This suggests that it is not only diet, medication or lifestyle that shape the microbiome, but that transmission processes between people could also play an important role.
New perspectives for medicine and diagnostics
The study opens up new possibilities for microbiome research. Instead of linking entire bacterial species to diseases, it may in future be possible to specifically target those populations that are actually significant. This could improve the search for biomarkers and, in the long term, enable more precise therapies – for example, by specifically promoting beneficial bacterial strains or suppressing problematic ones. As a next step, the team intends to investigate which genes distinguish the identified populations from one another and what biological functions are associated with them.
Summary
- Many species of gut bacteria consist of several evolutionarily distinct populations.
- Some of these populations are associated with ageing, colorectal cancer, inflammatory bowel disease and type 2 diabetes.
- Successful lineages can spread worldwide within a few decades.
- This approach could enable more precise diagnostics and more targeted microbiome therapies.
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