AI Article Synopsis
- Two plant species, Pterocarpus indicus (C3) and Sansevieria trifasciata (CAM), showed the highest efficiency in absorbing trimethylamine (TMA), achieving up to 90% uptake in 8 hours without hindering photosystem II (PSII) functions.
- S. trifasciata utilized stomata and leaf wax for TMA uptake, while P. indicus mainly relied on leaf wax and stems, indicating different mechanisms for TMA removal between the two plant types.
- The study revealed that fatty acids were key components in both plants' wax, aiding in TMA absorption, and that CAM plants could convert TMA into dimethylamine and methylamine through
Article Abstract
From screening 23 plant species, it was found that Pterocarpus indicus (C3) and Sansevieria trifasciata (crassulacean acid metabolism (CAM)) were the most effective in polar gaseous trimethylamine (TMA) uptake, reaching up to 90% uptake of initial TMA (100 ppm) within 8 h, and could remove TMA at cycles 1-4 without affecting photosystem II (PSII) photochemistry. Up to 55 and 45% of TMA was taken up by S. trifasciata stomata and leaf epicuticular wax, respectively. During cycles 1-4, interestingly, S. trifasciata changed its stomata apertures, which was directly induced by gaseous TMA and light treatments. In contrast, for P. indicus the leaf epicuticular wax and stem were the major pathways of TMA removal, followed by stomata; these pathways accounted for 46, 46, and 8%, respectively, of TMA removal percentages. Fatty acids, particularly tetradecanoic (C14) acid and octadecanoic (C18) acid, were found to be the main cuticular wax components in both plants, and were associated with TMA removal ability. Moreover, the plants could degrade TMA via multiple metabolic pathways associated with carbon/nitrogen interactions. In CAM plants, one of the crucial pathways enabled 78% of TMA to be transformed directly to dimethylamine (DMA) and methylamine (MA), which differed from C3 plant pathways. Various metabolites were also produced for further detoxification and mineralization so that TMA was completely degraded by plants.
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