Abstract
Industrial accidents, such as the Fukushima and Chernobyl disasters, release harmful chemicals into the environment, covering large geographical areas. Natural flora may serve as biological sensors for detecting metal contamination, such as cesium. Spectral detection of plant stresses typically employs a few select wavelengths and often cannot distinguish between different stress phenotypes. In this study, we apply hyperspectral reflectance imaging in the visible and near-infrared along with multivariate curve resolution (MCR) analysis to identify unique spectral signatures of three stresses in Arabidopsis thaliana: salt, copper, and cesium. While all stress conditions result in common stress physiology, hyperspectral reflectance imaging and MCR analysis produced unique spectral signatures that enabled classification of each stress. As the level of potassium was previously shown to affect cesium stress in plants, the response of A. thaliana to cesium stress under variable levels of potassium was also investigated. Increased levels of potassium reduced the spectral response of A. thaliana to cesium and prevented changes to chloroplast cellular organization. While metal stress mechanisms may vary under different environmental conditions, this study demonstrates that hyperspectral reflectance imaging with MCR analysis can distinguish metal stress phenotypes, providing the potential to detect metal contamination across large geographical areas.
Highlights
Anthropogenic activities or accidents associated with industrial processes may result in the release of toxic metals into the environment
The objective of this study was to determine whether spectral reflectance signatures of plants may provide unique indicators to distinguish between different types of metal stresses
While cesium stress was previously shown to lead to reduced chlorophyll-a and -b content in A. thaliana, under conditions of depleted potassium (Le Lay et al, 2006), reduced chlorophyll content has been detected under other stress conditions (Jansen et al, 2009; MartínezPeñalver et al, 2012)
Summary
Anthropogenic activities or accidents associated with industrial processes may result in the release of toxic metals into the environment. Through groundwater contamination, poses a significant risk to human health. Metals in the environment may impact plant, animal, and microbial life, resulting in damage to the ecosystem. Nuclear reactor accidents like the Chernobyl and Fukushima disasters released an estimated 149.8 petabecquerel (PBq) of radioactive cesium (Cs-134 and Cs-137) or approximately 47 kilograms (Imanaka et al, 2015). Due to the high water solubility of cesium, Cs-134 and Cs-137 spread rapidly in the environment and are taken up by local flora and fauna A rapid and non-invasive method for measuring environmental contamination by Cs and other toxic metals would reduce the risk of human exposure and facilitate cleanup efforts
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