We examined the potential for CH₄ oxidation to be coupled with oxygen derived from the dissimilatory reduction of perchlorate, chlorate, or via chlorite (ClO−2) dismutation. Although dissimilatory reduction of ClO⁻₄ and ClO⁻₃ could be inferred from the accumulation of chloride ions either in spent media or in soil slurries prepared from exposed freshwater lake sediment, neither of these oxyanions evoked methane oxidation when added to either anaerobic mixed cultures or soil enriched in methanotrophs. In contrast, ClO−2 amendment elicited such activity. Methane (0.2 kPa) was completely removed within several days from the headspace of cell suspensions ofDechloromonas agitata CKB incubated with either Methylococcus capsulatus Bath orMethylomicrobium album BG8 in the presence of 5 mM ClO−₂. We also observed complete removal of 0.2 kPa CH₄ in bottles containing soil enriched in methanotrophs when co-incubated with D. agitata CKB and 10 mM ClO−2. However, to be effective these experiments required physical separation of soil from D. agitata CKB to allow for the partitioning of O₂ liberated from chlorite dismutation into the shared headspace. Although a link between ClO−2 and CH₄ consumption was established in soils and cultures, no upstream connection with either ClO⁻₄ or ClO⁻₃ was discerned. This result suggests that the release of O₂ during enzymatic perchlorate reduction was negligible, and that the oxygen produced was unavailable to the aerobic methanotrophs.  link to publication