Engineered Bacterial Swarm Patterns As Spatial Records of Environmental Inputs

Overview

Journal Nat Chem Biol

Specialties Biochemistry
Biology
Chemistry

Date 2023 May 4

PMID 37142806

Authors

Anjali Doshi

Marian Shaw

Ruxandra Tonea

Soonhee Moon

Rosalia Minyety

Anish Doshi

Andrew Laine

Jia Guo

Tal Danino

Affiliations

Soon will be listed here.

Abstract

A diverse array of bacteria species naturally self-organize into durable macroscale patterns on solid surfaces via swarming motility-a highly coordinated and rapid movement of bacteria powered by flagella. Engineering swarming is an untapped opportunity to increase the scale and robustness of coordinated synthetic microbial systems. Here we engineer Proteus mirabilis, which natively forms centimeter-scale bullseye swarm patterns, to 'write' external inputs into visible spatial records. Specifically, we engineer tunable expression of swarming-related genes that modify pattern features, and we develop quantitative approaches to decoding. Next, we develop a dual-input system that modulates two swarming-related genes simultaneously, and we separately show that growing colonies can record dynamic environmental changes. We decode the resulting multicondition patterns with deep classification and segmentation models. Finally, we engineer a strain that records the presence of aqueous copper. This work creates an approach for building macroscale bacterial recorders, expanding the framework for engineering emergent microbial behaviors.

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