Abstract
Pollution by heavy metals (HM) represents a serious threat for both the environment and human health. Due to their elemental character, HM cannot be chemically degraded, and their detoxification in the environment mostly resides either in stabilization in situ or in their removal from the matrix, e.g., soil. For this purpose, phytoremediation, i.e., the application of plants for the restoration of a polluted environment, has been proposed as a promising green alternative to traditional physical and chemical methods. Among the phytoremediation techniques, phytoextraction refers to the removal of HM from the matrix through their uptake by a plant. It possesses considerable advantages over traditional techniques, especially due to its cost effectiveness, potential treatment of multiple HM simultaneously, no need for the excavation of contaminated soil, good acceptance by the public, the possibility of follow-up processing of the biomass produced, etc. In this review, we focused on three basic HM phytoextraction strategies that differ in the type of plant species being employed: natural hyperaccumulators, fast-growing plant species with high-biomass production and, potentially, plants genetically engineered toward a phenotype that favors efficient HM uptake and boosted HM tolerance. Considerable knowledge on the applicability of plants for HM phytoextraction has been gathered to date from both lab-scale studies performed under controlled model conditions and field trials using real environmental conditions. Based on this knowledge, many specific applications of plants for the remediation of HM-polluted soils have been proposed. Such studies often also include suggestions for the further processing of HM-contaminated biomass, therefore providing an added economical value. Based on the examples presented here, we recommend that intensive research be performed on the selection of appropriate plant taxa for various sets of conditions, environmental risk assessment, the fate of HM-enriched biomass, economical aspects of the process, etc.
Keywords: heavy metals, phytoremediation, phytoextraction, hyperaccumulators, genetically modified plants, heavy metal protein transporters, heavy metal binding proteins, green biotechnology
Introduction
With the industrialization and urbanization of developing countries and the increasing demands of mankind, the consumption of heavy metal elements (HM, see Glossary) has been growing enormously. As a result, pollution by HM and metalloids (see Glossary) has become an increasingly serious issue, which has raised public awareness. Unlike organic pollutants, which can be entirely, or partly degraded by the action of various (micro)organisms or detoxified by the action of plants, HM are non-degradable and can only be transformed into forms with altered toxicity and/or mobility/bioavailability (e.g., bacterial reduction of Hg2+ to elementary Hg0 that is less toxic and can evaporate, or the reduction of arsenate to less toxic arsenite oxyanions; Silver and Phung, 2005; Silver and Phung le, 2005). The persistence of HM in environmental matrices, especially soils, sediments and water bodies, is a result of the elemental character of HM (Chapman et al., 1996). Pollution by HM therefore represents a long-term threat for the environment and human health, not only in industrial and post-industrial areas.
Glossary.
Heavy Metal There is not yet a consensus definition of the term “heavy metal” (HM). Nevertheless, the most recent criterion suggested defines HMs as naturally occurring metals having atomic number >20 and elemental density >5 g.cm−3 (Ali and Khan, 2018). In biological sciences, this term instead describes a series of metallic elements and metalloids with a potential toxic effect on living organisms even at very low concentrations. From this toxicological/ecotoxicological standpoint, chemical properties and behavior in living systems are a more important criterion. Therefore, in addition to transition metal elements such as Cd, Pb, Hg, Zn, Cu, Co, Ni, Al, Cr, Fe, the metalloids As, Se or Sb can also be regarded as “heavy metals.”
Phytoremediation The use of plants for the restoration of a polluted environment. Generally, there are two principal strategies for decreasing HM toxicity in soils: site stabilization (including phytostabilization techniques) and “clean-up” techniques (including phytoextraction and phytovolatilization techniques).
Phytostabilization The use of plants for the reduction of HM toxicity in soil through reducing their mobility/bioavailability.
Phytoextraction The use of plants for HM removal from the contaminated matrix (soil and water) through their uptake into the harvestable parts of the plant.
Hyperaccumulation The ability of a plant to accumulate HMs in its above-ground parts without phytotoxic symptoms at concentrations up to 100–1,000-fold higher than in non-hyperaccumulating species (Baker, 1981). Such an ability resides in (i) enhancement of the uptake of HMs from the rhizosphere across the root cell plasma membrane, (ii) reduction of the sequestration of HMs in root-cell vacuoles, (iii) enhancement of the loading of HMs into the xylem for transport to shoots, and (iv) stimulation of HM influx across the leaf cell plasma membrane and sequestration in the leaf (mesophyll cells) vacuoles (Milner and Kochian, 2008).
Phytomining The use of plants for the in situ removal of HMs from sub-economic ore bodies, metalliferous soils or from contaminated mine sites with the additional aim of recovering an economic amount of metals from the plants [according to Sheoran et al. (2009)].
“Gene-Stacking” Strategy (also “Gene-Pyramiding” Strategy) The expression or manipulation of multiple (trans)genes in a single plant line [for review see Halpin (2005)]. This process provides the potential to accumulate multiple traits, typically multiple resistance to different types of stress or pathogen. As discussed in the text, this can also provide a tool for obtaining a plant variety suitable for efficient HM phytoextraction.
Short-Rotation Forestry/Plantation System The concept of culturing woody plants (especially fast-growing trees such as willow, poplar, pine, aspen, birch, beech, eucalyptus, etc.) or annually-harvested energy crops for energy production.
Trangenosis A gene-technology breeding method of introducing a transgene, which is according to Jacobsen and Schouten (2009) a (synthetic) gene with some or all regulatory sequences and coding sequences from donors other than crossable plants, including microorganisms and animals. Transgenes comprise a new gene pool for plant breeding.
Cisgenesis A gene technology breeding method of introducing a cisgene, which is according to Jacobsen and Schouten (2009) an already existing natural gene from the plant taxon itself or from crossable species, including its native promoter and terminator. The gene belongs to the traditional breeder gene pool and is the already existing result of natural evolution.
Intragenesis A gene technology breeding method of introducing an intragene, which is according to Jacobsen and Schouten (2009) a gene comprising of natural functional elements, such as the coding part, promoter and terminator originating from different genes from the plant taxon itself or from crossable species. All natural gene elements belong to the traditional breeder gene pool.
Conventional physical and chemical methods of HM removal from a polluted environment are usually not usable at large scales, and are often costly and not well accepted by the public [for a recent review see Khalid et al. (2017)]. In contrast, bioremediation i.e., the use of living organisms or their parts for remediation, is a group of methods that are highly applicable in large contaminated areas, especially in cases where the removal of HM contamination is not urgent. The use of plants for the decontamination of a polluted environment has been termed phytoremediation and was described in the mid-90s (Sandermann, 1994; Cunningham et al., 1995; Schnoor et al., 1995; Cunningham and Ow, 1996). Ever since, a vast number of studies have focused on the employment of various plant species for the removal or stabilization of both organic and inorganic pollutants (for reviews see Salt et al., 1998; Macek et al., 2000; Mackova et al., 2006a,b; Marmiroli et al., 2006; Cristaldi et al., 2017; Wang et al., 2017).
Generally, the most yet-employed strategies on how to remediate an HM-polluted environment are based either on their stabilization in situ, i.e., reducing HM acute toxicity through decreasing their mobility and bioavailability (so-called “site stabilization” techniques), or are based on HM removal (the group of “clean-up” techniques). When using plants, the first group is referred to by the term phytostabilization (see Glossary). Among the clean-up techniques, phytoextraction employs plants for the extraction of HM from soils and their accumulation in harvestable parts, which are subsequently removed and further processed (Baker et al., 1994; Salt et al., 1995, 1998; Chaney et al., 1997). Phytovolatilization, another subgroup of clean-up techniques, represents the conversion of HM/metalloids such as Hg, As, and Se into a volatile form via biological conversion within plants, and their release into the atmosphere (Rugh et al., 1996; Raskin et al., 1997; He et al., 2001; Che et al., 2003; Tangahu et al., 2011). Despite decreasing the pollution locally, this group of techniques contributes to the pool of mobile forms transportable over long distances, and is somewhat controversial (Prasad and Freitas, 2003).
Over the last three decades, great progress has been made in researching the applicability of phytoremediation techniques, including the use both of natural varieties and genetically modified (GM) plants. Therefore, in this review, we discuss the use of plants for the phytoextraction of HM and metalloids from soils. Particular attention is paid to the prospective employment of genetic modifications leading to plant varieties with a phenotype favoring HM phytoextraction from polluted sites.
Hyperaccumulators
Baker (1981) defined two main strategies adopted by plants naturally growing on metalliferous sites based on the strategy of survival. Excluders, representing the majority of plant species capable of surviving in soils containing elevated levels of toxic trace elements, have adopted the survival strategy of maximal exclusion of HM ions from the plant. If an HM ion is taken up by an excluder plant, the toxic effect is restricted to the roots, where it is detoxified, while the aerial parts remain more or less unaffected. In contrast, hyperaccumulators are plants which, when exposed to elevated concentrations of HM, are able to accumulate them in their above-ground parts without phytotoxicity symptoms (Baker, 1981; Rascio and Navari-Izzo, 2011; van der Ent et al., 2013). The term hyperaccumulator was first applied when describing the New Caledonian Ni-accumulating tree Sebartia acuminata (Sapotaceae); the nickel content in the latex was determined to be 26% percent of dry weight (Jaffré et al., 1976). According to Baker and Brooks (1989), the content limits of some metal elements in dry biomass for plants to be termed hyperaccumulators are 100 mg.kg−1 for Cd and Se, 1,000 mg.kg−1 for Co, Cu, Ni and Pb, and 10,000 mg.kg−1 for Zn and Mn. These values are up to 100–1,000-fold higher than for non-hyperaccumulating species under the same conditions (Reeves, 2006; Rascio and Navari-Izzo, 2011). The number of identified hyperaccumulators has been constantly rising, with over 450 HM-hyperaccumulating species known as of 2015, found in 45 angiosperm families (Rascio and Navari-Izzo, 2011; Bhargava et al., 2012; Krzciuk and Gałuszka, 2015). About 25% of hyperaccumulators identified so far recruit from the family Brassicaceae; other families rich in hyperaccumulators include Asteraceae, Euphorbiaceae, Rubiaceae, Fabaceae, Scrophulariacea, Myrtaceae, Proteaceae, Caryophylaceae, Tiliaceae, etc. (Reeves, 2006; Rascio and Navari-Izzo, 2011). Some plant genera appear to include a significant proportion of hyperaccumulator species; e.g., in studies comprehensively surveying the genus Alyssum, 48 out of 170 species tested were found to hyperaccumulate Ni (Brooks and Radford, 1978; Brooks et al., 1979). Interestingly, hyperaccumulation ability was found to vary within a species; metal specificity and accumulation can vary among different populations (Reeves et al., 2001; Assuncao et al., 2008).
As stated by Milner and Kochian (2008), who surveyed the Zn, Cd and Ni model hyperaccumulator alpine pennycress (Noccaea caerulescens, formerly Thlaspi caerulescens), several crucial physiological steps of HM detoxification are different in hyperaccumulators compared to non-hyperaccumulators. These are (i) boosted HM ions uptake from the rhizosphere across the root cell plasma membrane, (ii) reduced HM ions sequestration in root vacuoles, (iii) intensified HM ions loading into the xylem for transport to shoots, and (iv) stimulated HM ions influx across the leaf cell plasma membrane and (v) sequestration in the leaf vacuole. Nevertheless, a considerable contribution of cell wall components, especially low-methylesterified pectins, in the sequestration of HM ions within a plant body was also proposed (for reviews, see Krzesłowska, 2011; Le Gall et al., 2015). Leitenmaier and Küpper (2013) concluded that the key factor for hyperaccumulation is the plant's enhanced active metal transport rather than strengthened metal complexation by various intracellular ligands (such as glutathione, phytochelatins, or metallothioneins). Similarly, cross-species transcriptomic and genome-wide analyses of the extremophilic Zn- and Cd-hyperaccumulator Arabidopsis halleri revealed an enrichment in HM-transporting P-ATPAse HMA4 gene copies and corresponding transcripts as well as other transition metal homeostasis and biotic stress function genes compared to the non-accumulating sister species Arabidopsis lyrata and closely related reference model species Arabidopsis thaliana (Hanikenne et al., 2008; Suryawanshi et al., 2016). More detailed information on the various tolerance strategies of plants under HM stress and on hyperaccumulators, their taxonomic and geographical distribution, metal specificity as well as molecular mechanisms behind hyperaccumulation have been provided by Reeves (2006); Verbruggen et al. (2009); Rascio and Navari-Izzo (2011); Leitenmaier and Küpper (2013); van der Ent et al. (2013); Krzciuk and Gałuszka (2015), and Singh et al. (2016).
Phytoextraction–a tool for the remediation of HM-polluted sites?
In order to be suitable for phytoextraction purposes, plant species should meet the following criteria: (i) metallotolerance toward elements present in toxic levels, (ii) high biomass production and (iii) effective accumulation of HM in easy-to-harvest parts (Vangronsveld et al., 2009). The overall concept of the restoration of polluted areas using phytoextraction consists of the cultivation of appropriate plant species in situ, harvesting the HM-containing biomass and treating it to decrease its volume and weight (by composting, compacting, drying, thermal decomposition). The resultant HM-enriched mass containing high levels of metal contaminants is subsequently disposed of as a hazardous waste or, if economically advantageous, can be utilized for the re-extraction of trace elements (McGrath et al., 2002; Sheoran et al., 2009). In general, three basic strategies can be considered for HM phytoextraction, differing in the type of plant species used: (i) natural hyperaccumulators, (ii) fast-growing plant species with high-biomass production, and (iii) genetically engineered plants, all of which are discussed below. Advantages and drawbacks of these strategies are summarized in Table 1.
Table 1.
Natural hyperaccumulators | High-biomass producing non-hyperaccumulators | Genetically engineered plant | |
---|---|---|---|
Advantages | High bioaccumulation rates Often autochtonic species–prevents the introduction of non-native and potentially invasive species | High biomass production rate, possibility of production of biomass with added value Low growth requirements Possible use in short-rotation plantation Number of species convenient for diverse range of climatic conditions, water regime, soil type, character of contamination Often autochthonic species–prevents the introduction of non-native and potentially invasive species Usually low metal/toxicant specificity–applicability for mixed contamination (both multiple HM and mixture of HM and organic xenobiotics) |
Possibility of directed engineering of metallophenotype toward high bioconcentration factor Number of (trans)genes available for modification, possibility of organ/tissue-specific transgene expression enabling modulation of resultant phenotype Possible stacking of multiple phenotypical traits Possibility of selection of host plant species (depending on the intended fate or use of resulting HM-enriched biomass) |
Disadvantages | High metal specificity (often only single heavy metal element hyperaccumulated) Often slowly growing, low-biomass producing species, with specific ecology and requirements in terms of climate, soil characteristics, water regime, etc. |
Low bioaccumulation rates–lengthy phytoextraction process | Often high metal specificity depending on (trans)gene/genetic modification Lack of information from field trials performed on large areas in terms of overall applicability (economical aspects, efficiency of the process, management of HM-enriched biomass produced) GMO-linked environmental risks and related strict GMO regulation policy, thorough ecological risk assessment needed |
Several criteria should be taken into account when evaluating the suitability of a plant species for HM phytoextraction, in particular the quantitative ability of each plant species to accumulate HM in harvestable parts, and the overall production of biomass which can be expressed by the biomass yield per crop and number of crops per year. McGrath and Zhao (2003) determined that for economically feasible phytoextraction, the use of a plant with a metal bioconcentration factor, defined as the ratio of HM concentration in the plant to the soil, higher than 20 and biomass yield of 10 t·ha−1 is required, or with a bioconcentration factor of 10 and biomass production of 20 t·ha−1 (Peuke and Rennenberg, 2005). Other criteria to be considered are the depth of the contaminated layer (if the contamination is deeper than 20–30 cm, deep-rooting woody species should be utilized), the intended fate of HM-enriched biomass (e.g., re-extraction of metal elements; biofuel, energy and fiber production), climatic and soil conditions, etc. (Brooks et al., 1998; Mench et al., 2009; Sheoran et al., 2009).
The toxic element and its bioavailable concentration in the polluted matrix (soil) also needs to be considered, as well as the ability of a plant to maintain photosynthetic activity and biomass production even under HM-induced stress. If a toxicant content is too high, it can exceed the plant's tolerance level, especially for non-hyperaccumulator species, resulting in toxic symptoms and reduced photosynthetic capability and, consequently, lower biomass yield and reduced phytoextraction performance of a plant. Therefore, a systematic experimental assessment of HM-induced alterations in biomass production, plant anatomy, morphology, photosynthetic, and transpiration rate, photosynthetic pigments content, GSH-content, activity of reactive oxygen species (ROS)-defense enzymes, etc. should be preferably performed during the evaluation of a plant's suitability for HM phytoextraction, as was done with poplar (Populus sp.) (Ivanova et al., 2011; Chandra and Kang, 2016), eucalyptus (Eucalyptus camaldulenses) (Gomes et al., 2012), flax (Linnum ussitatissimum) and China aster (Callistephus chinensis) (Kavuličová et al., 2012), cardoon (Cynara cardunculus) (Arena et al., 2017; Sorrentino et al., 2018), rapeseed (Brassica napus) (Benáková et al., 2017), etc.
Phytoextraction employing high-biomass non-accumulators
The employment of fast-growing deep-rooting woody species such as willow (Salix spp.) and Populus spp. is a reasonable choice for phytoextraction (Unterbrunner et al., 2007). These taxa are able to produce a high amount of biomass in a relatively short time, have a high rate of water uptake and transpiration, have a deep root system, can be effectively and rapidly reproduced through re-sprouting, and their aboveground parts are easy to harvest. Importantly, Unterbrunner et al. (2007) discovered that Zn and Cd are preferentially accumulated in the leaves and not in the wood of these taxa; HM can be therefore continuously removed from the site by harvesting leaf biomass. Additionally, covering the remediated area with hardy vegetation prevents the erosion and transfer of contaminated material to the surrounding environment (i.e., plants act as phytostabilizers). Another major advantage of using non-edible woody species for HM clean-up is the biomass produced during the phytoextraction process which can provide an added economic value if used, for instance, in energy production (short-rotation forestry system concept; Einspahr, 1976a,b; Nixon et al., 2001; Volk et al., 2004; Hinchee et al., 2009; Kidd et al., 2015). For instance, experiments with cotton (Gossypium sp.) plants grown in a former industrial area in Bulgaria near Plovdiv contaminated with HMs demonstrated that after treating the produced cotton fiber with boiling water, the Cd, Zn, Cu, and Pb content was diminished to levels comparable to the plant material grown in non-contaminated sites. These findings make cotton another crop suitable for sustainable long-term use in contaminated areas (Yankov et al., 2000). Vangronsveld et al. (2009) demonstrated the potential of biomass for biofuel and biogas production despite the fact that the phytoextraction efficiency in their field trial, in which they employed Z. mays, tobacco (Nicotiana tabacum), B. napus and sunflower (Helianthus annuus), was not very encouraging (the estimated time required for clean-up of agricultural land moderately contaminated with Cd and Zn ranged from 29 years for tobacco to 234 years for rapeseed). An interesting approach to the subsequent utilization of HM-contaminated biomass produced during a phytoextraction process was applied in the studies of Zheljazkov and Nielsen (1996a,b). Medicinal plants such as peppermint (Mentha piperita) and lavender (Lavandula angustifolia) were proven to accumulate moderate levels of HM in the harvested biomass, and at the same time the aromatic oil produced from this contaminated biomass was contaminant free.
Several different clones of willows have been found to accumulate substantial amounts of Cd and Zn (Greger and Landberg, 1999). A field experiment performed with a Cd-accumulating clone of Salix viminalis cultivated in sludge-amended soil demonstrated that the total amount of extracted Cd (expressed as weight of Cd removed per ha and y) was ca 5 × and 6 × higher than the hyperaccumulating species Alyssum murale and N. caerulescens, respectively (Greger and Landberg, 1999). A large-scale field experiment performed on a site moderately contaminated with Cd and Zn in Lommel (Belgium) employed different clones of Populus sp. and Salix sp. for the phytoextraction of Cd. According to the most optimistic estimation based on the output data, from 12.5 up to 25 years would be needed for the restoration of a site with a Cd content of 1 mg·kg−1 soil (experiments reviewed in Vangronsveld et al., 2009). The influence of clone choice and the necessity of foliage harvesting were also highlighted in the two above-mentioned studies, as well as in the study of Vyslouzilova et al. (2006). Another field trial employing a short-rotation coppice of willow grown in metal-contaminated agricultural soil demonstrated the ability of a Salix coppice to remove 72 g Cd and 2 kg Zn ha−1 year−1, values much higher than maize (Zea mays) or B. napus grown in the same soil (Van Slycken et al., 2013b).
Z. mays has been also widely surveyed for its potential employment in the management of HM-contaminated soil due to its rapid growth, high biomass production and general Cd-tolerance. In a field-scale trial conducted on an area of Cd-contaminated farmland in China, Z. mays was shown to accumulate up to 3 mg.kg−1 of dry biomass while maintaining grain Cd concentrations under the Chinese government's limit for coarse cereals (Xu et al., 2013). Van Slycken et al. (2013a) adopted Z. mays for the management of Cd, Zn, Pb and As-contaminated agricultural land. In their study, Z. mays was shown to remove on average 19 g Cd ha−1·year−1 and 4.3 kg Zn ha−1·year−1 with the biomass produced being comparable with Z. mays grown in non-contaminated soil in the same region. Moreover, the Cd content in the harvested biomass did not exceed European threshold values for animal feed. The use of biomass for biogas production was also demonstrated, with the production values being unaffected by the HM content. The issue of employing Z. mays for the phytoextraction of HM-contaminated soils was comprehensibly reviewed by Rizwan et al. (2017). The employment of other high-biomass-producing non-hyperaccumulating plants for trace element extraction have been also reported, both from small- and large-scale field experiments (for a comprehensive review see Vangronsveld et al., 2009).
A more advanced approach of employing plants for the clean-up of soil, proposed by Macci et al. (2013), is to take advantage of the synergic action of trees, shrubs and grasses. In their recent study, Macci et al. (2016) investigated the real-scale clean-up of a former industrial area polluted with a mixed contamination of HMs, hydrocarbons and polychlorinated biphenyls. Three different woody plants were employed, namely Populus sp., empress tree (Paulownia tomentosa), and the perennial shrub Scotch broom (Cytisus scoparius), in combination with naturally growing vegetation and the addition of organic matter (horse manure). Within 2 years, vegetation with any of the three species resulted in the reduction of both organic and HM contamination (average reduction of about 35, 40, and 70% in the soil content of HMs, hydrocarbons and PCBs, respectively); moreover, soil functionality was also recovered during the remediation.
Phytoextraction employing hyperaccumulators
In a vast number of published manuscripts, hyperaccumulators have been shown to possess an exceptional ability to take up HMs from soil and store them in aerial plant organs, a trait that is seemingly promising for employment in phytoextraction. For instance, the study of Robinson et al. (1998) summarized that phytoextraction using N. carulescens would be entirely feasible for low Cd soil levels; since plants reached values of bioaccumulation coefficients of about 60 and 10 for 1 mg·kg−1 and 50 mg·kg−1 Cd in soil, respectively, only a single harvest would be needed to halve a soil Cd content of 10 mg·kg−1. Unlike Cd, the remediation of Zn was not found to be feasible within an economic time frame (i.e., < 10 years) because of the low Zn bioaccumulation coefficients (bellow 1) achieved at higher soil Zn levels. Similar conclusions were made by Nishiyama et al. (2005), whose study performed with N. caerulescens grown at a Cd soil concentration of 5 mg·kg−1 indicated that only about 2 – 6 harvests (depending on the soil type, Fluvisol or Andosol) could decrease the Cd concentration to 50%. Moreover, field trials conducted on urban HM-contaminated soil by Jacobs et al. (2017) using N. caerulescens, showed that Cd and Zn removal from soil was in a range that is already practically applicable for phytoextraction (Cd and Zn uptake values of 200 g.ha−1 and 47 kg.ha−1, respectively).
Other hyperaccumulating taxa have been proposed to be employable for HM removal from soils (Sarma, 2011). For instance, B. juncea was reported to effectively remove Cd, Cr, Cu, Ni, Pb, and Zn from a hydroponic medium (Dushenkov et al., 1995), hydrophyte water hyacinth (Eichhornia crassipes) was able to efficiently accumulate Cd, Cr, Cu, and Se, especially in roots. Similarly, the perennial shrub Sesbania drummondii, a Pb hyperaccumulator, exhibited an ability to uptake Pb (shoot concentrations of >4% Pb in hydroponic culture) while maintaining a high biomass yield (Sahi et al., 2002).
An example of an extension of hyperaccumulator-based HM phytoextraction providing an added economical value is phytomining (see Glossary). The field study by Robinson et al. (1997) was performed on ultramafic soils in Italy with the autochthonic Ni hyperaccumulator Alyssum bertolonii. The authors showed that this perennial might be used for the economically feasible phytomining of Ni, providing up to 72 kg Ni.ha−1 without the need to resow for a further crop. Similarly, field trials with A. murale recovered up to 112 kg Ni.ha−1 in a single crop (Robinson et al., 1997; Bani et al., 2015a,b).
Green biotechnology application–GM plants with enhanced HM tolerance and phytoextraction efficiency
As was shown above, the use of plants might represent an economically- and ecologically-friendly alternative to conventional techniques for the decontamination/stabilization of HM-polluted sites. However, some features limit their successful use, including (i) low biomass production of many natural hyperaccumulators and (ii) low phytoextraction efficiency of plant species that, on the other hand, fulfill the required technological parameters such as high growth rate and biomass production. Therefore, the use of such a convenient plant species, but purposely genetically engineered to the “hyperaccumulator-like” phenotype (e.g., with increased HM accumulation in aboveground parts and HM tolerance), seems to be a sustainable way to utilize plants for the decontamination of polluted matrices. A general strategy for the production of such bioengineered plants has been reviewed elsewhere, for instance by Bhargava et al. (2012).
If the resultant genetically engineered plant is intended for the decontamination of HM-polluted matrices, the aim of the transgenosis is to modify the distribution of accumulated HM throughout the plant body. HM should be preferentially translocated into above-ground parts that can be easily harvested, and the plant's growth rate should not be reduced as the result of HM accumulation. Hence, sustaining root-to-shoot translocation (HM loading into xylem vessels) and subsequent vacuolization and/or sequestration in the cells of the plant aerial parts account for the most frequently employed strategies to create hyperaccumulator-like plant varieties (for more detailed reviews on the topic, see e.g., Bhargava et al., 2012; Mosa et al., 2016).
In addition to HM removal from polluted matrices, enhanced HM uptake and translocation into aboveground parts via genetic modifications has been also proposed to increase the concentration of trace elements (such as Fe, Zn, Cu, Se) in biomass for nutritional purposes when grown in non-contaminated sites (biofortification). For instance, transgenic wheat (Triticum aestivum) expresing gene OsNAS2 encoding for nicotianamine synthase 2 from rice (Oryza sativa) was shown to attain dietary significant levels of Zn and Fe in grains (Singh et al., 2017). Similarly, authors Wu et al. (2018) used combination of three genes AtNAS1 encoding for nicotianamine synthase 1 from A. thaliana, AtFRD3 (transporter loading xylem with citrate-iron complex) and PvFER (ferritin from bean Phaseolus vulgaris) resulting in increased Zn and Fe content in grains of resultant multi-transgenic lines of O. sativa. A trial with O. sativa expressing a cisgene (see Glossary) OsNAS2 and a transgene SferrH-1 encoding for ferritin from soybean (Glycine max) proved biofortification of grains with Fe and Zn even under field conditions without any concomitant contamination with other harmful HM (Trijatmiko et al., 2016). The topic of biofortification via genetic modification was reviewed in Palmgren et al. (2008) and Borrill et al. (2014).
HM protein transporters
As mentioned previously, enhanced HM translocation across biological membranes most likely denotes a fundamental physiological process determining the hyperaccumulation ability of a plant. HM transport in plants includes transport through both the cytoplasmic membrane (apoplasm/symplasm interphase, e.g., uploading/unloading xylem vessels) and tonoplast and, possibly, borders of other intracellular compartments (Leitenmaier and Küpper, 2013). Alteration of these processes via genetic modification therefore appears to be an option to develop a plant variety suitable for HM phytoextraction and such genetic modifications have been frequently employed. Yeast cadmium factor protein YCF (a vacuolar glutathione S-conjugate pump and a member of the ATP-binding cassette transporter family associated with multi-drug resistance) is an example of a HM protein transporter used for transgenosis (Li et al., 1996). For instance, in the study of Bhuiyan et al. (2011b) the YCF1 gene was introduced into B. juncea and the resultant transformants exhibited enhanced tolerance to Cd and Pb and also an increased accumulation of these HMs in shoots (about 1.5- to 2-fold compared to the wild type). The same gene was employed by Shim et al. (2013) for hybrid Populus sp. transgenosis. Upon Cd exposure, the resultant plants exhibited enhanced growth, reduced Cd toxicity symptoms, and increased Cd content in the aerial tissue compared to non-transgenic plants. Furthermore, the plants accumulated more Cd, Zn, and Pb in roots because they were able to establish an extensive root system in HM-contaminated mine tailing soil. Similarly, B. juncea plants expressing AtATM3, another mitochondrial membrane ABC transporter involved in the biogenesis of Fe-S clusters and iron homeostasis in thale cress (Arabidopsis thaliana), exhibited increased Cd and Pb tolerance and shoot accumulation (about 1.5- to 2.5-fold higher compared to the wild type). These changes in metallophenotype were attributed to increased expression levels of intrinsic glutathione synthetase II and phytochelatin synthase 1 induced by AtATM3 overexpression (Bhuiyan et al., 2011a).
Bacterial HM-protein transporters is another vast pool of molecules potentially employable for transgenosis in order to increase phytoextraction efficiency. Wu et al. (2011) reported ectopic expression of mutated variant of CAX1 gene from A. thaliana encoding for Ca2+/H+ antiporter in petunia (Petunia × hybrida). CAX1-bearing plants exhibited up to 2.5-fold greater Cd tolerance and accumulation compared to the control. Furthermore, an exemplary study demonstrated that the introduction of a bacterial HM transporter PbtA into a yeast resulted in an increased accumulation of Pb, Zn, and Cd, and this transporter is further suggested to be employed for plant transgenosis aiming at increased phytoextraction efficiency and higher resistance of the plant (Suman et al., 2014). More examples of HM transporters employed in plant transgenosis are listed the Table 2.
Table 2.
Gene or coding sequence (protein product) | Source | Recipient | Tested metal | Effect | References |
---|---|---|---|---|---|
TRANSGENES OF BACTERIAL ORIGIN | |||||
merA (modified) mercury(II) reductase | Tn21 transposon | Nicotiana tabacum | Hg | Enhanced mercury volatilization | He et al., 2001 |
merA (modified) mercury(II) reductase | Tn21 transposon | Populus deltoides | Hg | Enhanced mercury volatilization and tolerance | Che et al., 2003 |
merA (modified) mercury(II) reductase | Tn21 transposon | Arabidopsis thaliana | Hg (Au) | Increased Hg tolerance volatilization, increased Au tolerance | Rugh et al., 1996 |
merB (organomercurial lyase) | Escherichia coli | A. thaliana | Organomer curials | Increased tolerance to organomercurials | Bizily et al., 1999 |
merC (HM transporter), constitutive promoter | Acidithioba-cillus ferrooxidans | N. tabacum, A. thaliana | Hg | Hg hypersensitivity, enhanced Hg uptake | Sasaki et al., 2006 |
merC (HM transporter), specific membrane targeting | Tn21 transposon | A. thaliana | Cd | Increased Cd accumulation and tolerance | Kiyono et al., 2012 |
merP (Hg2+-binding protein) | Bacillus megaterium | A. thaliana | Hg, Cd, Pb | Enhanced Hg, Cd and Pb tolerance and accumulation | Hsieh et al., 2009 |
gsh1 (γ-glutamylcysteine synthetase) | E. coli | Brassica juncea | Cd | Enhanced Cd tolerance and shoot accumulation | Zhu et al., 1999 |
gsh2 (glutathione synthetase) | E. coli | B. juncea | Cd | Enhanced Cd tolerance and shoot accumulation | Liang Zhu et al., 1999 |
gsh1 (γ-glutamylcysteine synthetase) | E. coli | Populus canescens | Zn | Elevated HM uptake, elevated glutathione levels | Bittsánszky et al., 2005 |
hybrid Populus tremula × Populus alba) | Cd | Enhanced Cd accumulation in young leaves | Koprivova et al., 2002 | ||
gsh1 (γ-glutamylcysteine synthetase) and gsh2 (glutathion synthetase) | E. coli | A. thaliana, co-expression | Hg, As | Enhanced Hg and As tolerance, enhanced Hg accumulation in aboveground tissues | Li et al., 2006b |
GCS and GS (γ-glutamylcysteine synthetase and glutathione synthetase) | Streptococcus thermophilus | Beta vulgaris | Cd, Zn, Cu | Enhanced Cd, Zn and Cu tolerance and accumulation; increased multiple HM tolerance and accumulation without selectivity among Cd, Zn and Cu | Liu et al., 2015 |
zntA (Pb2+/Zn2+/Cd2+-transporting P-ATPase) | E. coli | A. thaliana | Pb, Cd | Enhanced Pb and Cd tolerance, diminished Cd and Pb shoot accumulation | Lee et al., 2003 |
1-aminocyclo-propane-1-carboxylic acid (ACC) deaminase | Enterobacter cloacae | Lycopersicon aesculentum | Cd, Co, Cu, Ni, Pb, Zn | Enhanced tolerance to and altered accumulation of Cd, Co, Cu, Ni, Pb and Zn | Grichko et al., 2000 |
ACC deaminase, iaa (tryptophan monooxygenase) | Pseudomonas putida (ACC deaminase), Agrobacte-rium tumefaciens (iaa) | N. tabacum, Petunia × hybrida co-expression | Cu, Co | Increased Cu and Co tolerance and accumulation, growth in a complex contaminated soil | Zhang et al., 2008 |
arsC (arsenate reductase) | E. coli | N. tabacum, A. thaliana | Cd | Enhanced Cd tolerance and shoot accumulation | Dhankher et al., 2003 |
TRANSGENES OF FUNGAL ORIGIN | |||||
CUP1 (metallothionein) | Saccharomyces cerevisiae | N. tabacum | Cd | Increased Cd tolerance, increased Cd levels in roots whereas decreased in shoots | Krystofova et al., 2012 |
Saccharomyces cerevisiae | N. tabacum | Cu | Enhanced Cu accumulation, no Cd-associated phenotypical changes | Thomas et al., 2003 | |
YCF1 (ATP-binding cassette transporter) | S. cerevisiae | B. juncea | Cd, Pb | Enhanced Cd and Pb tolerance and shoot accumulation | Bhuiyan et al., 2011b |
tzn1 (high specificity zn transporter) | Neurospora crassa | N. tabacum | Zn | Enhanced Zn accumulation | Dixit et al., 2010 |
TRANSGENES OF PLANT ORIGIN | |||||
MuSI (multiple stress response gene I) | Ipomoea batatas | N. tabacum | Cd | Enhanced Cd tolerance, diminished Cd accumulation and root-to-shoot translocation | Kim et al., 2011 |
PCS1 (phytochelatin synthase) | Thlaspi arvense | Nicotiana glauca | Cd, Zn, Pb, Cu | Enhanced HM accumulation, high biomass production in real mining soil experiment | Martínez et al., 2006 |
Ceratophyllum demersum | N. tabacum | Cd, As | Enhanced Cd and As root accumulation | Shukla et al., 2012 | |
Nelumbo nucifera | A. thaliana | Cd | Enhanced Cd accumulation | Liu et al., 2012 | |
Cynodon dactylon | N. tabacum | Cd | Increase Cd tolerance and accumulation | Li et al., 2006a | |
PCS1 (phytochelatin synthase) and GSH1 | Allium sativum (PCS1), S. cerevisiae (GSH1) | A. thaliana, co-expression | Cd, As | Enhanced Cd and As tolerance and shoot accumulation | Guo et al., 2008 |
GS cysteine synthase | Spinacia oleracea | N. tabacum | Cd, Se, Ni | Increased Cd, Se and Ni tolerance, enhanced Cd shoot accumulation | Kawashima et al., 2004 |
GCS (γ-glutamylcysteine synthetase) | Phragmites australis | Agrostis stolonifera | Cd | Increased Cd tolerance and accumulation | Zhao et al., 2010 |
CBP4 (calmodulin-binding channel-like protein) | N. tabacum | N. tabacum overexpression | Ni, Pb | Increased Ni tolerance Pb and hypersensitivity, reduced Ni and enhanced Pb accumulation | Arazi et al., 1999 |
MRP7 (ATP-binding cassette transporter) | A. thaliana | N. tabacum | Cd | Increased Cd tolerance, decreased Cd root-to-shoot translocation, enhanced Cd accumulation in leaf vacuoles | Wojas et al., 2009 |
ATM3 (ATP-binding cassette transporter) | A. thaliana | B. juncea | Cd, Pb | Increased Cd and Pb tolerance and accumulation | Bhuiyan et al., 2011a |
CAX1 (mutated variant) (cation/H+ antiporter) | A. thaliana | Petunia × hybrida | Cd | Increased Cd tolerance and accumulation, | Wu et al., 2011 |
MT2b (metallothionein) and HMA4 (P1B-ATPase) | A. thaliana | N. tabacum, co-expression | Cd, Zn | Enhanced Cd tolerance, enhanced Cd and Zn root-to-shoot transport, synergy between the two transgenes | Grispen et al., 2011 |
MT2b (metallothionein) | A. sativum | A. thaliana | Cd | Enhanced Cd tolerance and accumulation | Zhang et al., 2006 |
CET3, CET4 (cation-efflux transporters) | B. juncea | N. tabacum, co-expression | Cd | Enhanced Cd tolerance, altered Cd accumulation | Lang et al., 2011 |
ACBP1 (acylCoA-binding protein) | A. thaliana | A. thaliana overexpression | Pb | Enhanced Pb tolerance and shoot accumulation | Xiao et al., 2008 |
TRANSGENES OF OTHER ORIGIN | |||||
MTII (clas II metallothionein) | Homo sapiens sapiens | N. tabacum | Cd | Decreased Cd levels in leaves whereas increased in roots and stems | de Borne et al., 1998 |
Pseudophytochelatin Met(GluCys)6Gly | Synthetic | N. tabacum | Cd | Enhanced Cd tolerance and shoot accumulation | Postrigan et al., 2012 |
Protein/peptidic HM chelators and low-molecular binding agents
Another strategy adopted to artificially enhance the HM accumulation capacity and tolerance of plants is through increased levels of HM binding agents in planta. Generally, it is hypothesized that the cell capacity to accumulate HM should be enhanced via the increased intracellular production of HM-ions binding sites, along with increasing metalloresistance through avoiding the appearance of “free” metal ions in the plant. Several examples of specific genetic determinants introduced into various plant species with the aim of increasing intracellular metal-chelating compounds can be found in Table 2. A frequently investigated approach is exemplified by the overproduction of peptidic chelators such as glutathione (GSH) and phytochelatins (PC) through the overexpression of the enzymes of their biosynthetic pathways. An example of an effort to increase intracellular GSH content is the overexpression of genes encoding for γ-glutamylcysteine synthetase (γ-ECS) and cysteine synthetase (GS), of both bacterial and eukaryotic origin (Liang Zhu et al., 1999; Koprivova et al., 2002; Bittsánszky et al., 2005; Li et al., 2006b; Zhao et al., 2010). These enzymes catalyze two ATP-dependent reactions: the formation of γ-glutamylcysteine (γ-ES) from glutamate and cysteine and the addition of glycine at the C-terminal end of γ-ES, respectively, yielding GSH (Meister, 1988). For instance, in the pioneering work of Noctor et al. (1996), transgenic Populus sp. bearing γ-ECS (gsh1) from E. coli were generated. Foliar γ-ES and glutathione content increased 10- and 3-fold, respectively, without affecting either the general physiological parameters of the transgenic plants or the reduction state of the glutathione pool and the foliar cysteine content. Several other studies were published employing genes for either γ-ECS or GS, or both simultaneously, for the alteration of the metallophenotype of plant species such as B. juncea (Liang Zhu et al., 1999; Zhu et al., 1999), Populus sp. (Koprivova et al., 2002; Bittsánszky et al., 2005), A. thaliana (Li et al., 2006b), creeping bentgrass (Agrostis palustris) (Zhao et al., 2010), etc. The resultant (double-)transgenic plants generally exhibited an increased rate of tolerance and accumulation of HMs such as Cd (Liang Zhu et al., 1999; Zhu et al., 1999; Koprivova et al., 2002; Zhao et al., 2010), Zn (Bittsánszky et al., 2005), or Hg (Li et al., 2006b).
A similar approach to increase the pool of HM-binding thiol compounds is the introduction of phytochelatin synthase (PCS), an enzyme catalyzing the formation of PC from the precursor γ-ES (Ha et al., 1999; Clemens and Persoh, 2009). PCS-encoding genes predominantly of plant origin were used for the transgenosis, leading to enhanced HM accumulation and tolerance (Table 2; Li et al., 2006a; Martínez et al., 2006; Guo et al., 2008; Liu et al., 2012; Shukla et al., 2012).
Unlike GSH and PCs, metallothioneins (MT) are gene-encoded metal binding proteins with multiple functions in planta, including metal homeostasis (for a comprehensive review, see Leszczyszyn et al., 2013). These small proteins have been found to exert HM binding capacity in vivo including Zn, Cd and Cu, when heterologously and ectopically expressed (Kille et al., 1991; Tommey et al., 1991; Evans et al., 1992; Abdullah et al., 2002). In addition to the inspection of their physiological function, a possible use of MT for enhancing metalloresistance and/or the accumulation capacity of GM plants was proposed by several authors (Thomas et al., 2003; Zhang et al., 2006; Krystofova et al., 2012). Nevertheless, the effect of such ectopic and heterologous expression on the metallophenotype is rather difficult to predict; accumulation and tolerance patterns differ among metal elements and across studies (for instance Krystofova et al., 2012 vs. Thomas et al., 2003, Table 2). Since in the majority of studies MT imparted an increased metallotolerance to the resultant transgenic plants together with an enhanced retention of the studied HM in roots, MT are more likely to be employed in protecting plants against HM stress in contaminated locations rather than for metallocrop preparation (Krystofova et al., 2012).
A study by Pianelli et al. (2005) investigated another metal ligand molecule, nicotianamine, an ubiquitous non-proteinogenic amino acid biosynthesized from methionine, involved in plant Fe homeostasis and able to bind various other metals as well (Rudolph et al., 1985). A. thaliana plants overexpressing nicotianamine synthase cDNA (NAS1) from the N. caerulescens exhibited an up to 100-fold higher accumulation of nicotianamine in their tissue and higher Ni tolerance and accumulation than the control. The authors proposed this gene to be introduced into suitable high-biomass plant species in combination with a HM-complex root-to-shoot translocator (e.g., yellow stripe 1, YSL1; Curie et al., 2001) in order to enhance the root-to-shoot ratio of accumulated metal and therefore “move” the metal to harvestable parts.
“gene stacking” strategy
The term “gene stacking” (or “gene pyramiding”) refers to the simultaneous expression or manipulation of multiple transgenes in a single GM plant or hybrid variety (Halpin, 2005). The accumulation of traits leading to an increased HM uptake and storage in harvestable parts and/or increased metalloresistance represents an advanced approach to modifying the plant metallophenotype for use in HM phytoextraction. In the study by Li et al. (2006b), A. thaliana hybrid plants of two single-transgenic lines bearing γ-ECS and GS were prepared, and their metallophenotype was compared to the parental one. Enhanced PC levels in roots as well as increased Hg tolerance and accumulation was observed for the ECS/GS co-expressing lines achieving a Hg bioconcentration factor as high as 600. Similar findings by Guo et al. (2008) showed that dual-transgenic A. thaliana plants overexpressing both PCS and γ-ECS (derived from garlic and yeasts, respectively) led to elevated PC levels and exhibited significantly higher Cd/As tolerance and accumulation than single transgenic and non-transgenic controls (about 2.5 times and 10 times higher for the two elements, respectively).
Synergy in the function of two genes expressed simultaneously was also shown in the work of Grispen et al. (2011). A. thaliana genes AtMT2b and AtHMA4 encoding for a IIb-class metallothionein and a stellar Zn2+- and Cd2+-transporting ATPase, respectively, were introduced into N. tabacum plants, and the double transformants exhibited enhanced Cd tolerance (ca 2-fold), enhanced Cd/Zn root-to-shoot transport, but unaltered Zn tolerance and overall Cd/Zn uptake, compared with both non-transgenic and single-transgenic controls. Hence, the authors highlighted the synergy between two genes introduced into plants. Since the observed metallophenotype was altered only moderately, they suggested (especially for the HMA4 gene) the use of the A. thaliana native promoter of the HMA4 gene instead of the constitutive cauliflower mosaic virus promoter and, possibly, the introduction of multiple transgene copies. Both proposed modifications should imitate the intrinsic tissue/organ localization and regulation of those found in the natural hyperaccumulator rockcress Arabidopsis halleri (Hanikenne et al., 2008).
Phytoextraction of HM using GM plants in the field?
Several articles comprehensively reviewing the issue of the potential employment of GM plants in HM phytoremediation have been released over the last decade (Cherian and Oliveira, 2005; Macek et al., 2008, 2009, 2013; Kotrba et al., 2009; Sarma, 2011; Bhargava et al., 2012; Ibañez et al., 2016). A number of various transgenes of both bacterial and eukaryotic origin have been employed (examples are listed in Table 2), predominantly in lab-scale studies on model plant species such as N. tabacum, A. thaliana, or tomato (Lycopersicon esculentum). In the majority of published studies, HM removal and tolerance experiments were only performed under model controlled conditions, typically in “ideal” agar-based or hydroponic cultures with only one metal element being examined in a single experiment; only a few studies were performed on a mixture of different metal elements, investigating interactions between the metals (e.g., Liu et al., 2015). Moreover, only several studies have moved from model conditions to pot-scale experiments, some of which were performed in real HM-contaminated soil (Bennett et al., 2003; Heaton et al., 2003; Pavlikova et al., 2004; Martínez et al., 2006; Rodriguez et al., 2008; Pilon-Smits and Leduc, 2009; Shim et al., 2013). Nevertheless, the “giant leap for mankind,” i.e., remediation experiments performed under field conditions, was shown to be indispensable for the reliable assessment of the applicability of GM plants for phytoremediation. The effect of examined genetic determinants on the phenotype can be severely influenced by real conditions in situ, including the co-occurrence of other organic and inorganic contaminants as many different contaminating metal elements tend to occur simultaneously (Banerjee et al., 1999), the bioavailability of micro- and macronutrients, soil type, content of organic matter, climatic conditions, interactions with other (micro)organisms, etc.
Among the few published studies that meet the requirement of in situ testing, Bañuelos et al. (2005) showed that GM plants can perform efficiently under field conditions. In their work, three different transgenic lines of B. juncea plants were planted in a field plot with a layer of Se, B and salt contaminated sediment covered with a layer of non-contaminated nutrient-rich soil and cultivated under continuous irrigation for 45 days. Even after this relatively short time period, plants bearing genes encoding for adenosine triphosphate sulfurylase (APS), γ-ECS and GS were able to accumulate 4.3-, 2.8-, and 2.3-fold more Se, respectively, in their shoots than the control, with the first value theoretically corresponding to 4.4% of the total extractable Se present in the contaminated drainage sediment. The aerial biomass produced was significantly lower than with control plants cultivated in the pristine soil (about 80% for GS plants), but still about 50% higher than for the wild-type strain kept in the polluted soil. Even though the duration of this field trial was short, the results indicated the potential of such GM plants for Se-phytoremediation.
The aforementioned work of Shim et al. (2013) was another study performed under real field conditions. It assessed the phytoextraction potential of transgenic Populus sp. plants hybrids of P. alba × P. tremula var. glandulosa BH1 (non-flowering mutant clone) harboring the yeast HM transporter gene Ycf1. During the field experiment, pre-cultivated cuttings of Ycf1-plants were kept in pots containing diluted Zn mine tailing soil under the open sky for a period of over 6 months. During this period, Ycf1-plants accumulated approximately 4–6 times more Cd in their shoots than non-GM control plants, while maintaining the same biomass production. The root system of GM plants was even more developed. Although these findings looked promising in terms of the use of the Ycf1-plants for the removal of Cd, Zn, As, and Pb from soils, the authors did not support this idea. The bioconcentration factor of the Ycf 1-plants of Populus sp. under field conditions was calculated to be only 0.3 for Cd, 0.9 for Zn, 0.2 for As, and 1.9 for Pb, values in strong contrast with those found for the hydroponic culture also surveyed in the study. The minimal bioconcentration factor value essential for effective short-term remediation (i.e., in time-span of ca 10 crops) using these specific Ycf1-bearing plants was estimated to be around 14. Nevertheless, the authors proposed the possible application of those GM plants for long-term phytoextraction with concurrent phytostabilization of polluted sites. The entire study was an example of a possible discrepancy between results obtained under hydroponic and real soil conditions, which needs to be considered before making conclusions about the potential applicability of any “GM plants with enhanced phytoextraction efficiency.” On the other hand, the field trial carried out by Bañuelos et al. (2005) with GM B. juncea described above basically confirmed the data obtained in their previous studies performed under model conditions (Liang Zhu et al., 1999; Pilon-Smits et al., 1999; Zhu et al., 1999).
Conclusions and future perspectives
The first vector and bacterial strain system that enabled the introduction of genetic modifications into plants emerged in 1985 (Deblaere et al., 1985). Over the next three decades, the process of transgenosis has become routinely used for the generation of GM plants with many different goals. The methods of genetic engineering have provided us with a powerful tool for producing a vast number of model GM plants, thereby enormously contributing to our understanding of HM homeostasis and detoxification, ROS-defense systems, etc.
The possibility of employing GM plants for the clean-up of HM-contaminated matrices has been intensively researched, a number of plant taxa bearing transgenes of various origins and presumptive functions have been surveyed. As summarized herein, many studies proved that the resultant transgenic plants manifested metallophenotypes making such an approach promising for use in phytoextraction. Nevertheless, the actual use of GM plants for soil clean-up has been relatively limited. Only several published GM varieties fulfill the requirements for phytoextraction efficiency that would allow the clean-up process to be feasible in terms of time and costs.
However, GM varieties have been so far almost solely prepared for research purposes that examine the usability of a genetic determinant, incorporating no more than pot-scale or controlled field experiments. As a result, their direct introduction into the environment is rather controversial, since they do not meet the requirements for modern GM organisms, i.e., the absence of a selection marker gene and vector backbone, the site-specific character of genetic modification, the use of genes from an evolutionary close gene pool (see Glossary for cisgenesis or intragenesis), etc. Further improvements are required in the genesis of new GM varieties, which would allow both the development of plants with superior metallophenotypes, and their commercialization even in countries where GM organisms are poorly accepted (Kamthan et al., 2016). Recent advances in the genome editing system CRISPR/Cas9 have enabled highly site-specific modifications of many plant genomes, and has therefore become a powerful tool for the development of selectable-marker-free transgenic hyperaccumulators potentially more suitable for real conditions (for recent reviews, see Bortesi and Fischer, 2015; Liu et al., 2017).
At the same time, a more thorough assessment of the risks related to the introduction of GM plants into the environment is indispensable prior to their use in the field (Hilbeck et al., 2011; Sanvido et al., 2012). With GM plants intended for phytoextraction, such risks include gene-flow from transgenics which could quantitatively reduce the genetic diversity of both wild and domesticated relatives, the horizontal transfer of transgenes into non-relative organisms including prokaryotes e.g., through cross-pollination, Agrobacterium-mediated transformation with naked DNA, etc. (EFSA Panel On Geneticlay Modified Organisms (GMO), 2010; Tsatsakis et al., 2017). We also propose another environmental risk to be considered prior to field applications of both natural and transgenic hyperaccumulators–the toxicity of HM-enriched biomass and subsequent impact on wildlife in situ, including herbivores, natural enemies, pollinators, decomposers, microbial symbionts, and overall biodiversity.
Finally, as shown above in this article, recent field studies have demonstrated that some hyperaccumulators meet the requirements for utilization in a real phytoextraction process, especially for their enormous HM bioaccumulation rates being far higher than those of high-biomass non-hyperaccumulators including those from genus Salix, Populus, etc. With more effort put into more modern GM techniques, the performance of many plant taxa can be further improved and efficiently used for large-scale phytoextraction purposes in real locations.
Author contributions
All authors listed have made a substantial, direct and intellectual contribution to the work, and approved it for publication.
Conflict of interest statement
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Footnotes
Funding. Funding from the Czech Science Foundation via grant 15-22276S is gratefully acknowledged.
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