Abstract
Barley is one of the cereals that are most sensitive to aluminum (Al). Al in acid soils limits barley growth and development and, as a result, its productivity. The inhibition of root growth is a widely accepted indicator of Al stress. Al toxicity is affected by many factors including the culture medium, pH, Al concentration and the duration of the treatment. However, Al can act differently in different species and still Al toxicity in barley deserves study. Since the mechanism of Al toxicity is discussed we cytogenetically describe the effects of different doses of bioavailable Al on the barley nuclear genome—mitotic activity, cell cycle profile and DNA integrity. At the same time, we tested an established deep-water culture (DWC) hydroponics system and analyzed the effects of Al on the root system parameters using WinRHIZO software. We demonstrated the cytotoxic and genotoxic effect of Al in barley root cells. We showed that Al treatment significantly reduced the mitotic activity of the root tip cells and it also induced micronuclei and damaged nuclei. The DNA-damaging effect of Al was observed using the TUNEL test. We define the inhibitory influence of Al on DNA replication in barley. Analysis with the labelling and detection of 5-ethynyl-2‘-deoxyuridin (EdU) showed that the treatment with Al significantly decreased the frequency of S phase cells. We also demonstrated that Al exposure led to changes in the cell cycle profile of barley root tips. The delay of cell divisions observed as increased frequency of cells in G2/M phase after Al treatment was reported using flow cytometry.
Highlights
Aluminum toxicity is considered to be the primary abiotic factor that limits crop production in regions with acid soils [1]
Using an established deep-water culture (DWC) hydroponics system, we showed that Al treatment resulted in a significant decrease in the mitotic activity of the root tip cells and an increased frequency of cells with micronuclei and damaged nuclei
The plant material used in the study was the spring barley (Hordeum vulgare L.) cultivar ‘Sebastian’
Summary
Aluminum toxicity is considered to be the primary abiotic factor that limits crop production in regions with acid soils [1]. Aluminum is the most abundant metal and the third most abundant element in the earth’s crust and makes up 8% of its mass. In neutral pH, aluminum is bound in various minerals and among them bauxite is the most frequently occurring [2,3]. In soils with a pH level below 5.0, aluminum solubilizes and becomes available for plants as phytotoxic Al3+ ions [4].
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