Abstract
BackgroundThe heavy metal cadmium (Cd) accumulates in the environment due to anthropogenic influences. It is unessential and harmful to all life forms. The plant cell wall forms a physical barrier against environmental stress and changes in the cell wall structure have been observed upon Cd exposure. In the current study, changes in the cell wall composition and structure of Medicago sativa stems were investigated after long-term exposure to Cd. Liquid chromatography coupled to mass spectrometry (LC-MS) for quantitative protein analysis was complemented with targeted gene expression analysis and combined with analyses of the cell wall composition.ResultsSeveral proteins determining for the cell wall structure changed in abundance. Structural changes mainly appeared in the composition of pectic polysaccharides and data indicate an increased presence of xylogalacturonan in response to Cd. Although a higher abundance and enzymatic activity of pectin methylesterase was detected, the total pectin methylation was not affected.ConclusionsAn increased abundance of xylogalacturonan might hinder Cd binding in the cell wall due to the methylation of its galacturonic acid backbone. Probably, the exclusion of Cd from the cell wall and apoplast limits the entry of the heavy metal into the symplast and is an important factor during tolerance acquisition.
Highlights
The heavy metal cadmium (Cd) accumulates in the environment due to anthropogenic influences
This study focuses on the cell wall monosaccharide composition and lignin content in M. sativa stems, when plants were exposed to a realistic Cd concentration in the soil for an entire season
Proteins involved in photosynthesis are found throughout the three cell wall protein fractions
Summary
The heavy metal cadmium (Cd) accumulates in the environment due to anthropogenic influences. The plant cell wall forms a physical barrier against environmental stress and changes in the cell wall structure have been observed upon Cd exposure. The plant cell wall is a dynamic structure, which continuously undergoes changes to adapt to the plant’s development as well as environmental conditions and serves as a physical barrier against environmental threats such as Cd. Its structural components provide mechanical support and rigidity, which is maintained by the activity of embedded cell wall proteins conferring optimal characteristics to the cell wall [2, 3]. Cellulose is the main structural component and composed of β-1,4-linked glucose, forming crystalline microfibrils. Those microfibrils are embedded in a complex, heterogeneous polysaccharide matrix.
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