posted on 2020-06-03, 18:36authored byVasily Kantsler, Elena Ontañón-McDonald, Cansu Kuey, Manjari J. Ghanshyam, Maria Chiara Roffin, Munehiro Asally
Creating adaptive,
sustainable, and dynamic biomaterials is a forthcoming
mission of synthetic biology. Engineering spatially organized bacterial
communities has a potential to develop such bio-metamaterials. However,
generating living patterns with precision, robustness, and a low technical
barrier remains as a challenge. Here we present an easily implementable
technique for patterning live bacterial populations using a controlled
meniscus-driven fluidics system, named as MeniFluidics. We demonstrate
multiscale patterning of biofilm colonies and swarms with submillimeter
resolution. Utilizing the faster bacterial spreading in liquid channels,
MeniFluidics allows controlled bacterial colonies both in space and
time to organize fluorescently labeled Bacillus subtilis strains into a converged pattern and to form dynamic vortex patterns
in confined bacterial swarms. The robustness, accuracy, and low technical
barrier of MeniFluidics offer a tool for advancing and inventing new
living materials that can be combined with genetically engineered
systems, and adding to fundamental research into ecological, evolutional,
and physical interactions between microbes.