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Abstract
Arsenic (As) is a carcinogen and it is ubiquitous in the environment. Its accumulation in plants can enter the food chain, thereby causing adverse impacts on human health. Based on studies using Xenopus oocytes, engineered microbes, and model plants, aquaporins play key roles in arsenite (AsIII) passage across the cell membrane. Herein, we summarized the roles of aquaporins in AsIII uptake, transport, and accumulation. The coupling action between polar-localized aquaporins and positive transporters probably explains the efficient As transport mediated by bi-directional channels. The expression of aquaporins is regulated at both transcriptional and post-transcriptional levels via microRNAs. However, in response to As, the proteins can be modified through phosphorylation and be degraded via the ubiquitin 26S proteasome system. Further, a proposed model comprising reactive oxygen species, Ca, Ca-dependent kinases, and transcriptional factors is constructed to reveal the signaling pathways and aquaporins’ responses to As in model plants. We also provided strategies to identify and investigate putative aquaporins in plants. Identification and modification of aquaporins’ residues critical for their substrate selectivity, and optimization of their expression pattern by employing appropriate promoters can be employed to reduce As accumulation in crops. Based on the characteristics of their functions and expression patterns, it is promising to employ aquaporins for genetic-engineering of crops to reduce As content and increase food safety.