Abstract
Synthetic biology is transforming how we understand and teach microbial energy metabolism. In a recent study (F. Li, B. Zhang, X. Long, H. Yu, et al., Nat Commun 16:2882, 2025, https://doi.org/10.1038/s41467-025-57497-z), the authors demonstrated a synthetic gene circuit that enables Shewanella oneidensis to produce and release phenazine-1-carboxylic acid, a redox-active metabolite that enhances extracellular electron transfer and electricity generation. This perspective highlights the significance of their work, focusing on how controlling the production of redox mediators provides new insights into microbial electron flow and bioelectronic design. Beyond its technological implications, this system also serves as a valuable educational case study for teaching principles of redox balance, gene regulation, and metabolic engineering. Viewing this advancement in the context of biology education underscores the potential of synthetic circuits to deepen our understanding of microbial metabolism and to promote interdisciplinary learning in microbiology, biotechnology, and engineering.