How the Chagas pathogen changes the intestinal microbiota of predatory bugs
There is no vaccine against the pathogen and treating the disease in the advanced stage is difficult. That is why the focus in Latin America is rather on controlling the bug that transmits Chagas trypanosomes: the predatory blood-sucking bug of the insect subfamily Triatominae. It ingests the trypanosomes during the sting, which then colonize its intestine. Through its faeces that it mostly deposited next to the bite, the bug excretes the pathogen, which is often rubbed into the wound when scratching the extremely itchy bite.
Although the number of new infections has dropped in various regions where insecticides are sprayed on a wide scale, problems are emerging: over the last decade, resistance to common insecticides by several species of predatory bugs has been increasingly observed. These insecticides also have a negative impact on the environment and the local population.
Researchers worldwide are making intense efforts to find alternative methods to help control Trypanosoma cruzi. One possibility might be to modify bacteria in the predatory bug’s intestine in such a way that they eliminate the Chagas trypanosomes or inhibit their development.
In collaboration with scientists at the Instituto René Rachou in Belo Horizonte, Brazil, parasitologists and infection biologists Fanny Eberhard and Professor Sven Klimpel from Goethe University, the Senckenberg — Leibniz Institution for Biodiversity and Earth System Research (SGN) and the LOEWE Centre for Translational Biodiversity Genomics have now investigated how Chagas trypanosomes change the bacterial community in the predatory bug’s intestine. To do so, they used genome analysis, which allowed them to compare the composition of the bacterial community in the bug’s intestine, the microbiome, before and after infection with the pathogen (metagenomic shotgun sequencing).
The result: after the infection, the range of bacterial strains in the bug’s intestine significantly decreased. Certain strains, including the potentially pathogenic bacterium Enterococcus faecalis, profited from the parasites’ presence. Moreover, the researchers succeeded in identifying four bacterial species that probably take on functions important for the bug, such as the synthesis of B vitamins.
Fanny Eberhard explains: “Vitamin B is one of the nutrients that blood-sucking insects do not obtain through their blood meals. Bacteria that produce vitamin B are therefore very important for the bug, are found in practically all individuals and stay in the predatory bug’s intestine even across generations. Hence, such bacteria are potentially suitable recipients for genes that produce defensive substances against Chagas trypanosomes.”
Professor Sven Klimpel elaborates: “Ultimately, our goal is for the predatory bug to defend itself against Chagas trypanosomes and, in this way, to prevent infection in humans. However, before we can produce bacteria with such properties and then release predatory bugs containing them, we need to understand better how the ecology of the bug’s intestine is structured and how the extensive interactions between host, pathogen and microbiome function. Our work is delivering an essential contribution to this.”