Microaerobic Lifestyle at Nanomolar O Concentrations Mediated by Low-Affinity Terminal Oxidases in Abundant Soil Bacteria.

High-affinity terminal oxidases (TOs) are believed to permit microbial respiration at low oxygen (O) levels. Genes encoding such oxidases are widespread, and their existence in microbial genomes is taken as an indicator for microaerobic respiration. We combined respiratory kinetics determined via highly sensitive optical trace O sensors, genomics, and transcriptomics to test the hypothesis that high-affinity TOs are a prerequisite to respire micro- and nanooxic concentrations of O in environmentally relevant model soil organisms: acidobacteria. Members of the harbor branched respiratory chains terminating in low-affinity (-type cytochrome oxidases) as well as high-affinity (-type cytochrome oxidases and/or -type quinol oxidases) TOs, potentially enabling them to cope with varying O concentrations. The measured apparent () values for O of selected strains ranged from 37 to 288 nmol O liter, comparable to values previously assigned to low-affinity TOs. Surprisingly, we could not detect the expression of the conventional high-affinity TO ( type) at micro- and nanomolar O concentrations but detected the expression of low-affinity TOs. To the best of our knowledge, this is the first observation of microaerobic respiration imparted by low-affinity TOs at O concentrations as low as 1 nM. This challenges the standing hypothesis that a microaerobic lifestyle is exclusively imparted by the presence of high-affinity TOs. As low-affinity TOs are more efficient at generating ATP than high-affinity TOs, their utilization could provide a great benefit, even at low-nanomolar O levels. Our findings highlight energy conservation strategies that could promote the success of in soil but might also be important for as-yet-unrevealed microorganisms. Low-oxygen habitats are widely distributed on Earth, ranging from the human intestine to soils. Microorganisms are assumed to have the capacity to respire low O concentrations via high-affinity terminal oxidases. By utilizing strains of a ubiquitous and abundant group of soil bacteria, the , and combining respiration kinetics, genomics, and transcriptomics, we provide evidence that these microorganisms use the energetically more efficient low-affinity terminal oxidases to respire low-nanomolar O concentrations. This questions the standing hypothesis that the ability to respire traces of O stems solely from the activity of high-affinity terminal oxidases. We propose that this energetically efficient strategy extends into other, so-far-unrevealed microbial clades. Our findings also demonstrate that physiological predictions regarding the utilization of different O concentrations based solely on the presence or absence of terminal oxidases in bacterial genomes can be misleading.