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RESEARCH PRODUCT
Black Queen Evolution and Trophic Interactions Determine Plasmid Survival after the Disruption of the Conjugation Network
Cairns JohannesKoskinen KatariinaPenttinen ReettaPatinen TommiHartikainen AnnaJokela RoosaRuusulehto LiisaViitamäki SirjaMattila SariHiltunen TeppoJalasvuori Mattisubject
trophic levelsantibiotic resistanceevoluutiospreadEcological and Evolutionary Sciencedependent phagesEditor's PickMicrobiologyQR1-502saalistusbakteeritstrainsplasmiditprotozoacoevolutionpredationhorisontaalinen geeninsiirtobacteria1183 Plant biology microbiology virologyBlack Queen evolutionResearch Articleantibioottiresistenssiconjugationdescription
Bacterial antibiotic resistance is often a part of mobile genetic elements that move from one bacterium to another. By interfering with the horizontal movement and the maintenance of these elements, it is possible to remove the resistance from the population. Here, we show that a so-called plasmid-dependent bacteriophage causes the initially resistant bacterial population to become susceptible to antibiotics. However, this effect is efficiently countered when the system also contains a predator that feeds on bacteria. Moreover, when the environment contains antibiotics, the survival of resistance is dependent on the resistance mechanism. When bacteria can help their contemporaries to degrade antibiotics, resistance is maintained by only a fraction of the community. On the other hand, when bacteria cannot help others, then all bacteria remain resistant. The concentration of the antibiotic played a less notable role than the antibiotic used. This report shows that the survival of antibiotic resistance in bacterial communities represents a complex process where many factors present in real-life systems define whether or not resistance is actually lost.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2018-10-01 |