Abstract
Aerobic methane-oxidizing bacteria, known as methanotrophs, serve important roles in biogeochemical cycling. Methanotrophs occupy a specific environmental niche within methane-oxygen counter gradients found in soils and sediments, which influences their behavior on an individual and community level. However, conventional methods to study the physiology of these greenhouse gas-mitigating microorganisms often use homogeneous planktonic cultures, which do not accurately represent the spatial and chemical gradients found in the environment. This hinders scientists' understanding of how these bacteria behave in situ. Here, a simple, inexpensive model ecosystem called the gradient syringe is described, which uses semi-solid agarose to recreate the steep methane-oxygen counter gradients characteristic of methanotrophs' natural habitats. The gradient syringe allows for the cultivation of methanotrophic strains and the enrichment of mixed methane-oxidizing consortia from environmental samples, revealing phenotypes only visible in this spatially resolved context. This protocol also reports various biochemical assays that have been modified to be compatible with the semi-solid agarose matrix, which may be valuable to researchers culturing microorganisms within other agarose-based systems.
| Original language | English |
|---|---|
| Article number | e67191 |
| Journal | Journal of Visualized Experiments |
| Volume | 2024 |
| Issue number | 211 |
| DOIs | |
| State | Published - Sep 2024 |
| Externally published | Yes |
Funding
This work was supported by startup funding from the University of Utah Department of Chemistry and NSF CAREER Award #2339190. We thank members of the Puri Lab for helpful discussions. We thank Rachel Hurrell (University of Utah) for initial guidance with the flow cytometry experiment.