posted on 2021-12-28, 13:40authored bySeokju Seo, Saoirse Disney-McKeethen, Ramya Ganiga Prabhakar, Xinhao Song, Heer H. Mehta, Yousif Shamoo
In vitro experimental evolution of pathogens to
antibiotics is commonly used for the identification of clinical biomarkers
associated with antibiotic resistance. Microdroplet emulsions allow
exquisite control of spatial structure, species complexity, and selection
microenvironments for such studies. We investigated the use of monodisperse
microdroplets in experimental evolution. Using Escherichia
coli adaptation to doxycycline, we examined how changes
in environmental conditions such as droplet size, starting lambda
value, selection strength, and incubation method affected evolutionary
outcomes. We also examined the extent to which emulsions could reveal
potentially new evolutionary trajectories and dynamics associated
with antimicrobial resistance. Interestingly, we identified both expected
and unexpected evolutionary trajectories including large-scale chromosomal
rearrangements and amplification that were not observed in suspension
culture methods. As microdroplet emulsions are well-suited for automation
and provide exceptional control of conditions, they can provide a
high-throughput approach for biomarker identification as well as preclinical
evaluation of lead compounds.