Abstract
Uptake of water and nutrients by roots affects the ontogenesis of the whole plant. Nanoparticles, e.g. gold nanoparticles, have a broad range of applications in many fields which leads to the transfer of these materials into the environment. Thus, the understanding of their impact on the growth and development of the root system is an emerging issue. During our studies on the effect of positively charged gold nanoparticles on the barley roots, a hairless phenotype was found. We investigated whether this phenotype correlates with changes in symplasmic communication, which is an important factor that regulates, among others, differentiation of the rhizodermis into hair and non-hair cells. The results showed no restriction in symplasmic communication in the treated roots, in contrast to the control roots, in which the trichoblasts and atrichoblasts were symplasmically isolated during their differentiation. Moreover, differences concerning the root morphology, histology, ultrastructure and the cell wall composition were detected between the control and the treated roots. These findings suggest that the harmful effect of nanoparticles on plant growth may, among others, consist in disrupting the symplasmic communication/isolation, which leads to the development of a hairless root phenotype, thus limiting the functioning of the roots.
Highlights
The effect of nanoparticles (NPs) on plant growth is well documented[1,2,3], we are still far from full understanding of mutual interactions between NPs and the developmental processes, in particular, the mechanisms that lead to reduction in plant growth under their influence
The root epidermis is composed of cells that produce root hairs and non-hair cells[9,10]
An inhibition of root hair development was observed in Arabidopsis seedlings that were grown in the presence of different NPs18 as well as in the roots of rice that had been treated with the AgNPs19
Summary
The effect of nanoparticles (NPs) on plant growth is well documented[1,2,3], we are still far from full understanding of mutual interactions between NPs and the developmental processes, in particular, the mechanisms that lead to reduction in plant growth under their influence. One developmental strategy that is favoured by plants is to increase the root-soil contact via the development of root hairs that enhance water and nutrient uptake[8]. Nanotechnology has incredible potential in the agricultural sector, it may have unknown risk due to their environmental and health impact that can prevail over their potential benefits[15] The evaluation of these risks is associated with the new field of knowledge, “nanotoxicology,” which confirms the need to analyse the influence of nanomaterials on living organisms[16]. Despite the increasing number of reports about the NPs-plant interactions, our knowledge about the influence of NPs on the development and growth of root hairs is still insufficient and no general conclusion can be drawn
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