Explore the vast range of titles available.

Methane (CH 4 ), the most abundant hydrocarbon in the atmosphere, originates largely from biogenic sources 1 linked to an increasing number of organisms occurring in oxic and anoxic environments. Traditionally, biogenic CH 4 has been regarded as the final product of anoxic decomposition of organic matter by methanogenic archaea. However, plants 2 , 3 , fungi 4 , algae 5 and cyanobacteria 6 can produce CH 4 in the presence of oxygen. Although methanogens are known to produce CH 4 enzymatically during anaerobic energy metabolism 7 , the requirements and pathways for CH 4 production by non-methanogenic cells are poorly understood. Here, we demonstrate that CH 4 formation by Bacillus subtilis and Escherichia coli is triggered by free iron and reactive oxygen species (ROS), which are generated by metabolic activity and enhanced by oxidative stress. ROS-induced methyl radicals, which are derived from organic compounds containing sulfur- or nitrogen-bonded methyl groups, are key intermediates that ultimately lead to CH 4 production. We further show CH 4 production by many other model organisms from the Bacteria, Archaea and Eukarya domains, including in several human cell lines. All these organisms respond to inducers of oxidative stress by enhanced CH 4 formation. Our results imply that all living cells probably possess a common mechanism of CH 4 formation that is based on interactions among ROS, iron and methyl donors, opening new perspectives for understanding biochemical CH 4 formation and cycling. Methane formation by a ROS-mediated process is linked to metabolic activity and is identified as a conserved feature across living systems.

Bacterial populations frequently encounter potentially lethal environmental stress factors. Growing Bacillus subtilis populations are comprised of a mixture of “motile” and “sessile” cells but how this affects population-level fitness under stress is poorly understood. Here, we show that, unlike sessile cells, motile cells are readily killed by monovalent cations under conditions of nutrient deprivation – owing to elevated expression of the lytABC operon, which codes for a cell-wall lytic complex. Forced induction of the operon in sessile cells also causes lysis. We demonstrate that population composition is regulated by the quorum sensing regulator ComA, which can favor either the motile or the sessile state. Specifically social interactions by ComX-pheromone signaling enhance population-level fitness under stress. Our study highlights the importance of characterizing population composition and cellular properties for studies of bacterial physiology and functional genomics. Our findings open new perspectives for understanding the functions of autolysins and collective behaviors that are coordinated by chemical and electrical signals, with implications for multicellular development and biotechnology.