Long-distance electron transfer in a filamentous Gram-positive bacterium

Long-distance extracellular electron transfer has been observed in Gram-negative bacteria and plays roles in both natural and engineering processes. The electron transfer can be mediated by conductive protein appendages (in short unicellular bacteria such as Geobacter species) or by conductive cell envelopes (in filamentous multicellular cable bacteria). Here we show that Lysinibacillus varians GY32, a filamentous unicellular Gram-positive bacterium, is capable of bidirectional extracellular electron transfer. In microbial fuel cells, L. varians can form centimetre-range conductive cellular networks and, when grown on graphite electrodes, the cells can reach a remarkable length of 1.08mm. Atomic force microscopy and microelectrode analyses suggest that the conductivity is linked to pili-like protein appendages. Our results show that long-distance electron transfer is not limited to Gram-negative bacteria. Long-distance extracellular electron transfer has been observed in Gram-negative bacteria. Here, Yang et al. show that a filamentous, unicellular Gram-positive bacterium is capable of bidirectional extracellular electron transfer, and forms centimetre-range conductive networks consisting of 1mm-long cells and conductive appendages.

Automated summary

Long-distance extracellular electron transfer has been observed in Gram-negative bacteria and now also in a filamentous, unicellular Gram-positive bacterium. The filamentous bacterium Lysinibacillus varians GY32 is capable of bidirectional extracellular electron transfer, forming centimetre-range conductive cellular networks with 1mm-long cells and conductive appendages. Our results demonstrate that Gram-positive bacteria can also participate in long-distance electron transfer processes.