Low-molecular-weight organic acids inhibit the methane-dependent arsenate reduction process in paddy soils.

Anaerobic methane oxidation (AOM) can drive soil arsenate reduction, a process known as methane-dependent arsenate reduction (M-AsR), which is a critical driver of arsenic (As) release in soil. Low molecular weight organic acids (LMWOAs), an important component of rice root exudates, have an unclear influence and mechanism on the M-AsR process. To narrow this knowledge gap, three typical LMWOAs—citric acid, oxalic acid, and acetic acid—were selected and added to As-contaminated paddy soils, followed by the injection of ¹³CH 4 and incubation under anaerobic conditions. The results showed that LMWOAs inhibited the M-AsR process and reduced the As(III) concentration in soil porewater by 35.1–65.7 % after 14 days of incubation. Among the LMWOAs, acetic acid exhibited the strongest inhibition, followed by oxalic and citric acid. Moreover, LMWOAs significantly altered the concentrations of ferrous iron and dissolved organic carbon in the soil porewater, consequently impacting the release of As in the soil. The results of qPCR and sequencing analysis indicated that LMWOAs inhibited the M-AsR process by simultaneously suppressing microbes associated with ANME-2d and arrA. Our findings provide a theoretical basis for modulating the M-AsR process and enhance our understanding of the biogeochemical cycling of As in paddy soils under rhizosphere conditions. [Display omitted] • LMWOAs addition inhibited anaerobic methane oxidation. • LMWOAs addition inhibited the dissimilatory iron reduction. • LMWOAs addition reduced As(III) concentration and As mobility in methane-rich paddy soil. • LMWOAs simultaneously suppressed microbes associated with ANME-2d and arrA. • LMWOAs inhibited the methane-dependent arsenate reduction process in paddy soil. [ABSTRACT FROM AUTHOR]