Lead Induced Toxicity, Detoxification and Bioremediation 191
11.2.2 Lead Uptake and Toxicity in Plant System
Pb is available in different exchangeable and non-exchangeable forms in soil. Among these, Pb (II) is
the only form that can be absorbed by plants. Higher concentrations of Pb in soil may lead to its entry
inside the plant system. Soil pH is also one of the essential factors which affect the bioavailability
of Pb to plants. Pb is adsorbed by plant roots at low pH, as high pH favors the formation of stable
and insoluble covalent Pb compounds such as acetates, carbonates and hydroxides (Shahid et al.
2017). The most common mechanism by which Pb enters the plant body is through roots. However,
Pb is translocated through the apoplast pathway and Ca channels on the plasma membrane to above
ground parts of the plant. Nevertheless, the level of Pb that reaches the shoot region is very low as
most of it is sequestered through chelation with the mucilage and galacturonic acids of the cell walls
of roots. Even lower concentrations of Pb that enter the plant system causes significant disturbances
in plant fundamental processes.
Pb being a toxic heavy metal, has no biological function in plant primary as well secondary
processes. Excessive amounts of Pb in growing environments may negatively influence plant
activities from seed germination to crop yield. Pb contamination disrupts seed germination by
inhibiting activities of various enzymes such as amylases, proteases thereby leading to retarded
seedling development. Decreased root, shoot length, leaf area and impaired photosynthesis are other
symptoms reflected in plants grown in Pb prone areas.
Pb pollution inhibited root growth, root hair differentiation, water and essential divalent cations
absorption such as Mg, Ca, Mn, Fe, etc., by roots, which resulted in damage to normal machinery
of plants (Rucińska-Sobkowiak 2016). Pb may also directly interact with many functional groups
such as -OH, -COOH, -SH, CO, CHO, etc., thereby, leading to conformational changes in primary
biomolecules, i.e., lipids, proteins, carbohydrates and nucleic acids. In addition to this, the production
of Reactive Oxygen Species (ROS) under Pb stress has also been reported in many research studies.
These ROS may oxidize vital plant metabolites and hence, hamper the overall efficiency of various
metabolic processes such as photosynthesis, respiration, transpiration, etc. (Ghori et al. 2019,
Hasanuzzaman et al. 2020).
Pb is also shown to inhibit the action of enzymes involved in the production of chlorophyll
synthesis and upregulates the activity of chlorophyllase, chlorophyll degrading enzyme which results
in decreased chlorophyll content in plants (Yang et al. 2020). In certain cases, the replacement of
the central Mg atom of chlorophyll by Pb has also been found. Other processes which are disturbed
include hill reaction, Calvin cycle and grana stacking in the chloroplast. All these factors lead to
impaired photosynthesis, one of the most indispensable processes influencing crop productivity
(Santos et al. 2015). The toxic effects of Pb on plant health have been summarized in Figure 11.1.
A large amount of nuclear damage resulting from Pb toxicity has also been reported in different
plants, including polyploidy, replication errors leading to single stranded DNA formation, incomplete
cell cycle and chromosome stickiness (Pizzaia et al. 2019). In addition to these, modifications in
the level of water potential, membrane integrity and hormonal signaling may also occur due to Pb
induced induced plant damage. All these alterations assertively result in dwindled crop productivity
and hence create a serious threat to the world’s health and economy.
11.3 Lead Tolerance and Detoxification Mechanism Inside Plant System
Pb enters the environment as a result of a number of anthropogenic activities. Plants being sessile
organisms, cannot change their habitat in response to such conditions. Therefore, they adapt to such
an environment by stimulating intracellular mechanisms that ensure the normal survival of plants.
These mechanisms may include Pb accumulation in plant parts without any visible symptoms,
sequestration of Pb into vacuoles, exudation from roots into soils in the insoluble precipitated form
that cannot be reabsorbed. All such mechanisms are referred to as tolerance and detoxification
mechanisms (Figure 11.2). Usually, entry of Pb stimulate either or all the following detoxification
processes: