New Synthetic Biology Tools to Track Microbial Dynamics in the Earth System

Abstract:

Microbes drive processes in the Earth system far exceeding their physical scale, mediating significant fluxes in the global C and N cycles. The tools of synthetic biology have the potential to significantly improve our understanding of microbes’ role in the Earth system; however, these tools have not yet seen wide laboratory use because synthetically “programmed” microbes typically report by fluorescing (expressing green fluorescent protein), making them challenging to deploy into many Earth materials, the majority of which are not transparent and are heterogeneous (soils, sediments, and biomass). We are developing a new suite of biosensors that report instead by releasing gases.

We will provide an overview of the use of gas-reporting biosensors in biogeochemistry and will report the development of the systematics of these sensors. These sensors will make tractable the testing of gene expression hypotheses derived from metagenomics data. Examples of processes that could be tracked non-invasively with gas sensors include coordination of biofilm formation, nitrification, rhizobial infection of plant roots, and at least some forms of methanogenesis, all of which are managed by an easily-engineered cell-cell communication system. Another relatively simple process to track with gas sensors is horizontal gene transfer.

Successful development of gas biosensors for Earth science applications will require addressing issues including: engineering the intensity and selectivity of microbial gas production to maximize the signal to noise using the tools of synthetic biology; normalizing the gas reporter signal to cell population size, since the number of cells and gene expression both contribute to gas production; managing gas diffusion effects on signal shape; and developing multiple gases that can be used in parallel to report on multiple biological processes in parallel. We will report on progress addressing each of these issues.