Molecular evidence for the adaptive evolution of Geobacter sulfurreducens to perform dissimilatory iron reduction in natural environments
The electrically conductive pili (e‐pili) of Geobacter species enable extracellular electron
transfer to insoluble metallic minerals, electrodes and other microbial species, which confers …
transfer to insoluble metallic minerals, electrodes and other microbial species, which confers …
Molecular evidence for the adaptive evolution of Geobacter sulfurreducens to perform dissimilatory iron reduction in natural environments.
X Liu, Y Ye, K Xiao, C Rensing, S Zhou - Molecular Microbiology, 2019 - europepmc.org
The electrically conductive pili (e-pili) of Geobacter species enable extracellular electron
transfer to insoluble metallic minerals, electrodes and other microbial species, which confers …
transfer to insoluble metallic minerals, electrodes and other microbial species, which confers …
Molecular evidence for the adaptive evolution of Geobacter sulfurreducens to perform dissimilatory iron reduction in natural environments
X Liu, Y Ye, K Xiao, C Rensing… - Molecular …, 2020 - pubmed.ncbi.nlm.nih.gov
The electrically conductive pili (e-pili) of Geobacter species enable extracellular electron
transfer to insoluble metallic minerals, electrodes and other microbial species, which confers …
transfer to insoluble metallic minerals, electrodes and other microbial species, which confers …
Molecular evidence for the adaptive evolution of Geobacter sulfurreducens to perform dissimilatory iron reduction in natural environments.
X Liu, Y Ye, K Xiao, C Rensing… - Molecular …, 2020 - search.ebscohost.com
The electrically conductive pili (e‐pili) of Geobacter species enable extracellular electron
transfer to insoluble metallic minerals, electrodes and other microbial species, which confers …
transfer to insoluble metallic minerals, electrodes and other microbial species, which confers …