Abstract
Concentrations of heavy metals in soil seldom reach a level sufficient to cause osmotic disturbances in plants. It is likely that water entry to the roots is indirectly governed by other factors which are themselves affected by metals. Decreased elongation of the primary root, impaired secondary growth, increased root dieback, or reduced root hair caused by toxic ions all exert a deleterious effect on the root-absorbing area and water uptake. Moreover, metals are able to decelerate short-distance water transfer both in symplast and apoplast, which in turn reduce the movement of water into the vascular system and affect water supply to the shoot. Long-distance transport is limited also due to decreased hydraulic conductivity in the root, stem and leaf midrib caused by a reduction in the size of vessels and tracheids, and partial blockage of xylem elements by cellular debris or gums. Heavy metals influence water delivery to the shoot due to inhibition of transpiration as they decrease the size of the leaves and the thickness of the lamina, reduce intercellular spaces, affect the density of stomata and decrease their aperture. Stomata closure is induced by direct interaction of toxic metals with guard cells and/or as a consequence of the early effects of metal toxicity on roots and stems. In metal-stressed plants, root-derived ABA or ABA-induced signals might play a role in stomatal movement. Disturbances in water relations trigger differential regulation of aquaporin gene expression, which may contribute to further reductions in water loss.
Highlights
Heavy metals as a general collective term refers to metals and metalloids with an atomic number above 20 and a relatively high density greater than 4 g/cm3, or 5 times or more, greater than water (Barceloand Poschenrieder 1990; Nagajyoti et al 2010)
Increased Abscisic acid (ABA) concentrations in leaves of P. vulgaris exposed to Zn and Ni (Rauser and Dumbroff 1981) as well as in leaves of O. sativa treated with Cu (Chen et al 2001) concomitant with increased stomatal resistance (Rauser and Dumbroff 1981) seems to confirm the hypothesis that hydroactive mechanism might be responsible for metal-induced stomata closure
According to Kholodova et al (2011), these results indicate that heavy metals induce critical rearrangements in the water relations of M. crystallinum plants based on the rapid suppression of the transpiration flow and strong inhibition of root sap exudation
Summary
Heavy metals as a general collective term refers to metals and metalloids with an atomic number above 20 and a relatively high density greater than 4 g/cm3, or 5 times or more, greater than water (Barceloand Poschenrieder 1990; Nagajyoti et al 2010). The presence of callose deposits observed in the cell walls of Pb-treated L. luteus roots may lead to the assumption that intercellular water transport through the plasmodesmata is limited, which in turn would favor water accumulation in the vacuoles (Rucinska-Sobkowiak et al 2013).
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