Interactions among Ca2+, Na+ and K+ in salinity toxicity: quantitative resolution of multiple toxic and ameliorative effects

Root elongation by wheat seedlings (Triticum aestivum L. cv. Scout 66) was not inhibited by NaCl or KCl up to 130 mM in culture solutions or by high Na⁺ (2 mg g^-1 FW) or K⁺ (4 mg g^-1 FW) in the root tissue, provided that [Ca²⁺]>2 mM in the rooting medium. At [NaCl], [KCl], or [mannitol] >250 mOs, root elongation was progressively inhibited, irrespective of high [Ca²⁺]. In contrast, shoot elongation was sensitive to any diminution of water potential, and Ca²⁺ alleviated the toxicity only weakly. At solute concentrations <250 mOs, the following interactions were observed. Ca²⁺ alleviated Na⁺ and K⁺ toxicity to roots by at least three separate mechanisms. K⁺ was more toxic to roots than Na⁺, but Na⁺ was more toxic to shoots. Low levels of K⁺ relieved Na⁺ toxicity, but low levels of Na⁺ enhanced K⁺ toxicity. Tissue concentrations of Na⁺ were reduced by Ca²⁺ and K⁺ in the rooting medium, and tissue concentrations of K⁺ were enhanced by Ca²⁺ and Na⁺. Several hypotheses relating to salinity toxicity can be evaluated, at least for wheat seedlings. The osmoticant hypotheses (salinity intoxication occurs because of diminished water potential) is true for shoots at all salinity levels, but is true for roots only at high salinity. The Ca²⁺-displacement hypothesis (Na⁺ is toxic because it displaced Ca²⁺ from the cell surface) is correct, but often of minor importance. The K⁺-depletion hypothesis (Na⁺ is toxic because it causes a loss of K⁺ from plant tissues) is false. The Cl^--toxicity hypothesis (the apparent toxicity of Na⁺ is induced by associated Cl^-) is false. The results indicate that, apart from osmotic effects, high levels of Na⁺ in the rooting medium and in the tissues are not toxic unless Ca²⁺ is also deficient, a condition probably leading to inadequate compartmentation and excessive cytoplasmic accumulation. This study related growth to ion activities at plasma-membrane surfaces. These activities were computed by a Gouy-Chapman-Stern model then incorporated into non-linear growth models for growth versus toxicants and ameliorants.Key words: Calcium, potassium, salinity, sodium, toxicity      

Re-evaluating the effects of organic ligands on copper toxicity to barley root elongation in culture solution

Abstract

In the presence of weak ligands, both free ion activity and organic complexes of Cu should b considered when predicting Cu toxicity in aquatic and soil-plant systems. However, there is littl information about the quantitative contribution of Cu that is organically complexed to Cu toxicity. In thi study, a bioassay using barley root elongation in culture solution was used to investigate the effects o organic ligands with different conditional stability constants on Cu toxicity and the quantitativ contribution of the organically complexed Cu to the Cu toxicity. The results indicated that a significan decrease (p<0.05) in Cu toxicity, assessed by barley root elongation, was observed in response to th addition of organic ligands. The decrease differed, to some extent, with different organic ligands o disodium ethylenediaminetetraacetic acid (EDTA), nitrilotriacetic acid (NTA), oxalate and malate at low and constant free Cu²⁺ activity. Addition of EDTA or NTA resulted in strong reduction of Cu toxicity while modest reduction of Cu toxicity was observed for the addition of malate as the relatively wea ligand. Furthermore, the results of the present study revealed that the CuNTA^? and CuEDTA^2? complexes were not toxic, while the Cu–malate complexes were mildly toxic to barley root elongation More importantly, it was found that the toxicity of Cu–malate complexes were nearly 0.5-fold less than that of free Cu²⁺ ions.     

Calcium Dependence of Eugenol Tolerance and Toxicity in Saccharomyces cerevisiae

Eugenol is a plant-derived phenolic compound which has recognised therapeutical potential as an antifungal agent. However little is known of either its fungicidal activity or the mechanisms employed by fungi to tolerate eugenol toxicity. A better exploitation of eugenol as a therapeutic agent will therefore depend on addressing this knowledge gap. Eugenol initiates increases in cytosolic Ca²⁺ in Saccharomyces cerevisiae which is partly dependent on the plasma membrane calcium channel, Cch1p. However, it is unclear whether a toxic cytosolic Ca²⁺elevation mediates the fungicidal activity of eugenol. In the present study, no significant difference in yeast survival was observed following transient eugenol treatment in the presence or absence of extracellular Ca²⁺. Furthermore, using yeast expressing apoaequorin to report cytosolic Ca²⁺ and a range of eugenol derivatives, antifungal activity did not appear to be coupled to Ca²⁺ influx or cytosolic Ca²⁺ elevation. Taken together, these results suggest that eugenol toxicity is not dependent on a toxic influx of Ca²⁺. In contrast, careful control of extracellular Ca²⁺ (using EGTA or BAPTA) revealed that tolerance of yeast to eugenol depended on Ca²⁺ influx via Cch1p. These findings expose significant differences between the antifungal activity of eugenol and that of azoles, amiodarone and carvacrol. This study highlights the potential to use eugenol in combination with other antifungal agents that exhibit differing modes of action as antifungal agents to combat drug resistant infections.     

Linking waterlogging tolerance with Mn2+ toxicity: a case study for barley

Vast agricultural areas are affected by flooding, causing up to 80% yield reduction and resulting in multibillion dollar losses. Up to now, the focus of plant breeders was predominantly on detrimental effects of anoxia, while other (potentially equally important) traits were essentially neglected; one of these is soil elemental toxicity. Excess water triggers a progressive decrease in soil redox potential, thus increasing the concentration of Mn²⁺ that can be toxic to plants if above a specific threshold. This work aimed to quantify the relative contribution of Mn²⁺ toxicity to waterlogging stress tolerance, using barley as a case study. Twenty barley (Hordeum vulgare) genotypes contrasting in waterlogging stress tolerance were studied for their ability to cope with toxic (1 mm ) amounts of Mn²⁺ in the root rhizosphere. Under Mn²⁺ toxicity, chlorophyll content of most waterlogging‐tolerant genotypes (TX9425, Yerong, CPI‐71284‐48 and CM72) remained above 60% of the control value, whereas sensitive genotypes (Franklin and Naso Nijo) had 35% less chlorophyll than 35% of controls. Manganese concentration in leaves was not related to visual Mn²⁺ toxicity symptoms, suggesting that various Mn²⁺ tolerance mechanisms might operate in different tolerant genotypes, i.e. avoidance versus tissue tolerance. The overall significant (r = 0.60) correlation between tolerance to Mn²⁺ toxicity and waterlogging in barley suggests that plant breeding for tolerance to waterlogging traits may be advanced by targeting mechanisms conferring tolerance to Mn²⁺ toxicity, at least in this species.     

Influence of silicon on cobalt, zinc, and magnesium in baker's yeast, Saccharomyces cerevisiae

Silicon (Si, as silicate) is involved in numerous important structure and function roles in a wide range of organisms, including man. Silicate availability influences metal concentrations within various cell and tissue types, but, as yet, clear mechanisms for such an influence have been discovered only within the diatoms and sponges. In this study, the influence of silicate on the intracellular accumulation of metals was investigated in baker's yeast (Saccharomyces cerevisiae). It was found that at concentrations up to 10 mM, silicate did not influence the growth rate of S. cerevisiae within a standard complete medium. However, an 11% growth inhibition was observed when silicate was present at 100 mM. Intracellular metal concentrations were investigated in yeast cultures grown without added silicate (−Si) or with the addition of 10 mM silicate (+Si). Decreased amounts of Co (52%), Mn (35%), and Fe (20%) were found within +Si-grown yeast cultures as compared to −Si-grown ones, whereas increased amounts of Mo (56%) and Mg (38%) were found. The amounts of Zn and K were apparently unaffected by the presence of silicon. +Si enhanced the yeast growth rate for low-Zn²⁺ medium, but it decreased the growth rate under conditions of a low Mg²⁺ medium and did not alter the growth rates in high Zn²⁺ and Co²⁺ media. +Si doubled the uptake rate of Co²⁺ but did not influence that of Zn²⁺. We propose that a possible explanation for these results is that polysilicate formation at the cell wall changes the cell wall binding capacity for metal ions. The toxicity of silicate was compared to germanium (Ge, as GeO₂), a member of the same group of elements as Si (group 14). Hence, Si and Ge are chemically similar, but silicate starts to polymerize to oligomers above 5 mM, whereas Ge salts remain as monomers at such concentrations. Ge proved to be far more toxic to yeast than Si and no influence of Si on Ge toxicity was found. We propose that these results relate to differences in cellular uptake.     

Induction of peroxisome proliferation and increase of catalase activity in yeast,Candida albicans,by cadmium

The effects of cadmium on the growth rate, catalase activity, and peroxisome proliferation in yeast,Candida albicans, were evaluated. The yeast growth was markedly inhibited by 1 mM cadmium at the initial hours. The toxic effect of cadmium on the cell growth persisted. The catalase activity of the cells treated with 1 mM Cd²⁺ first decreased, and then rose at 24 h to about 2.6 times that of the controls. The average number of peroxisomes per cell in the yeast treated with 1 mM Cd²⁺ was about sixfold higher than the control groups. The proliferation of peroxisomes and the increase of catalase activity following cadmium toxicity gives credence to the hypothesis that cadmium toxicity is related to its potential to induce oxidative stress in cells.     

Identification and characterization of zinc-starvation-induced ZIP transporters from barley roots

Zinc (Zn) is an essential element for plants but limited information is currently available on the molecular basis for Zn²⁺ transport in crop species. To expand the knowledge on Zn²⁺ transport in barley (Hordeum vulgare L.), a cDNA library prepared from barley roots was expressed in the yeast (Saccharomyces cerevisiae) mutant strain Δzrt1/Δzrt2, defective in Zn²⁺ uptake. This strategy resulted in isolation and identification of three new Zn²⁺ transporters from barley. All of the predicted proteins have a high similarity to the ZIP protein family, and are designated HvZIP3, HvZIP5 and HvZIP8, respectively. Complementation studies in Δzrt1/Δzrt2 showed restored growth of the yeast cells transformed with the different HvZIPs, although with different efficiency. Transformation into Fe²⁺ and Mn²⁺ uptake defective yeast mutants showed that the HvZIPs were unable to restore the growth on Fe²⁺ and Mn²⁺ limited media, respectively, indicating a specific role in Zn²⁺ transport. In intact barley roots, HvZIP8 was constitutively expressed whereas HvZIP3 and HvZIP5 were mainly expressed in ?Zn plants. These results suggest that HvZIP3, HvZIP5 and HvZIP8 are Zn²⁺ transporters involved in Zn²⁺ homeostasis in barley roots. The new transporters may facilitate breeding of barley genotypes with improved Zn efficiency and Zn content.     

Phytotoxicity of pathogenic fungi and their mycotoxins to cereal seedling viability

Aspergillus flavus, Alternaria alternata and Fusarium oxysporum were the pathogenic fungi most reduced cereal (barley, sorghum and wheat) seedlings. The pathogens have the ability to produce aflatoxin B₁ and G₁, diacetoxyscirpenol, kojic acid and tenuazonic acid that reduced seedling viability. The inhibition dose for 50% reduction (LD₅₀) was recorded by aflatoxins at 0.83 mg L^-1 for barley, 1.74 mg L^-1 for wheat and 2.75 mg L^-1 for sorghum. Diacetoxyscirpenol produced its inhibition at 1.26 mg L^-1 for barley, 3.98 mg L^-1 for wheat and 10 mg L^-1 for sorghum. Kojic acid induced 50% inhibition at 63 mg L^-1 for barley, 105 mg L^-1 for wheat and 251 mg L^-1 for sorghum. However, tenuazonic acid was less toxic where the toxicity ranged between 79–550 mg L^-1. The germination inhibition was more pronounced in barley followed by wheat and was negligible in sorghum for all tested mycotoxins. This inhibition was attributed to the reduction in the seedling amylase activity, where amylase was also reduced in the same trend: barley > wheat > sorghum. Grain treated with carboxin-captan and thiophanatemethyl-thiram at 1 g kg^-1 grain increased the seedlings vigour of wheat in sterilized soil by 45 and 22%, barley by 24 and 33% and sorghum by 15 and 30%, respectively. These fungicides also had a positive effect on cereal when the soil was inoculated with A. flavus, A. alternata and F. oxysporum, but the improvement was still below normal. This revised version was published online in June 2006 with corrections to the Cover Date.     

Salinity-induced calcium deficiencies in wheat and barley

Salinity-calcium interactions, which have been shown to be important in plants grown in dryland saline soils of the Canadian prairies, were studied in two species differing in salt tolerance. In solution culture, wheat showed a greater reduction in growth and a higher incidence of foliar Ca deficiency symptoms than barley when grown under MgSO₄ or Na₂SO₄ plus MgSO₄ salt stress. Amendment of the saline solution with Ca to increase the Ca/(Na+Mg) ratio ameliorated the effects of salt, but more so in wheat than in barley. At least part of the difference in salt tolerance between the two species must therefore relate to species differences in the interaction of salinity and Ca nutrition. The greater response of wheat to Ca was not due to a lower Ca status in leaf tissue; on the contrary, although Ca amendments improved tissue Ca/(Na+Mg) ratios in both species, salinized wheat had equivalent or higher Ca content, and higher Ca/(Na+Mg) ratios than did barley. The higher Ca requirement of wheat is apparently specific to a saline situation; at low salinity, wheat growth was not reduced as extensively as that of barley as Ca/(Na+Mg) ratio was decreased. High night-time humidity dramatically improved wheat growth under saline conditions, but increasing the Ca concentration of the saline solution had no effect on growth in the high humidity treatment. Membrane leakage from leaf tissue of wheat grown under saline conditions was increased compared to tissue from non-saline plants. Plants grown in Ca-amended saline solutions showed no increase in membrane leakage. These results confirm the importance of Ca interaction with salinity stress, and indicate differences in species response.     

Endoplasmic reticulum is a major target of cadmium toxicity in yeast

Cadmium (Cd²⁺) is a very toxic metal that causes DNA damage, oxidative stress and apoptosis. Despite many studies, the cellular and molecular mechanisms underlying its high toxicity are not clearly understood. We show here that very low doses of Cd²⁺ cause ER stress in Saccharomyces cerevisiae as evidenced by the induction of the unfolded protein response (UPR) and the splicing of HAC1 mRNA. Furthermore, mutant strains (Δire1 and Δhac1) unable to induce the UPR are hypersensitive to Cd²⁺, but not to arsenite and mercury. The full functionality of the pathways involved in ER stress response is required for Cd²⁺ tolerance. The data also suggest that Cd²⁺‐induced ER stress and Cd²⁺ toxicity are a direct consequence of Cd²⁺ accumulation in the ER. Cd²⁺ does not inhibit disulfide bond formation but perturbs calcium metabolism. In particular, Cd²⁺ activates the calcium channel Cch1/Mid1, which also contributes to Cd²⁺ entry into the cell. The results reinforce the interest of using yeast as a cellular model to study toxicity mechanisms in eukaryotic cells.     

The barley MATE gene,HvAACT1, increases citrate efflux and Al3+ tolerance when expressed in wheat and barley

Background and Aims

Aluminium is toxic in acid soils because the soluble Al³⁺ inhibits root growth. A mechanism of Al³⁺ tolerance discovered in many plant species involves the release of organic anions from root apices. The Al³⁺-activated release of citrate from the root apices of Al³⁺-tolerant genotypes of barley is controlled by a MATE gene named HvAACT1 that encodes a citrate transport protein located on the plasma membrane. The aim of this study was to investigate whether expressing HvAACT1 with a constitutive promoter in barley and wheat can increase citrate efflux and Al³⁺ tolerance of these important cereal species.

Methods HvAACT1

was over-expressed in wheat (Triticum aestivum) and barley (Hordeum vulgare) using the maize ubiquitin promoter. Root apices of transgenic and control lines were analysed for HvAACT1 expression and organic acid efflux. The Al³⁺ tolerance of transgenic and control lines was assessed in both hydroponic solution and acid soil.

Key Results and Conclusions

Increased HvAACT1 expression in both cereal species was associated with increased citrate efflux from root apices and enhanced Al³⁺ tolerance, thus demonstrating that biotechnology can complement traditional breeding practices to increase the Al³⁺ tolerance of important crop plants.     

Effects of waterlogging and drought on winter wheat and winter barley grown on a clay and a sandy loam soil

Summary The effects of winter waterlogging and a subsequent drought on the growth of winter barley and winter wheat have been examined. We used lysimeters containing soil monoliths with facilities to control the water table and a mobile shelter to control rainfall. Winter wheat was grown on a clay and on a sandy loam, but winter barley only on the clay soil. Lysimeters were either freely-drained during the winter or waterlogged with the water table 10 cm below the soil surface from 2 December until 31 March (that could occur by rainfall with a return period of 2 to 3 years). The lysimeters then were either irrigated so that the soil moisture deficit did not exceed 84 mm, or subjected to drought by limiting rainfall (equivalent to a 1 in 10 dry year in the driest area of England) so that the deficits reached maximum values of 150 mm in the clay and 159 mm in the sandy loam by harvest.Winter waterlogging restricted tillering and restricted the number of ears for all crops; grain yield of the winter barley was decreased by 219 g/m² (30%), and that of winter wheat by 170 g/m² (24%) and 153 g/m² (21% on the clay and sandy loam respectively.The drought treatment reduced the straw weight of winter barley by 75 g/m² (12%) but did not significantly depress the grain yield. For winter wheat on the clay, where the soil was freely-drained during the winter, drought depressed total shoot weight by 344 g/m² (17%) and grain weight by 137 g/m² (17%), but after winter waterlogging, drought did not further depress total or grain weight. In contrast, the winter wheat on the sandy loam was not significantly affected by drought.From these results, which are discussed in relation to other experiments in the United Kingdom, it seems that winter waterlogging is likely to cause more variation in the yield of winter barley and winter wheat than drought.     

Assessing the phytotoxicity of mononuclear hydroxy-aluminum

Abstract Al³⁺ is an important rhizotoxic ion in acid soils around the world. Al³⁺ is in equilibrium with mononuclear hydroxy-Al species, such as AlOH²⁺ and AL(OH)₂⁺, but the toxicity of these species has not been determined. Polynuclear Al may also coexist with Al³⁺, and one of these species, AlO₄Al₁₂(OH)₂₄(H₂O)₁₂⁷⁴, is very toxic. In order to determine the toxicity of mononuclear hydroxy-Al we have reanalysed the results of previously published, solution-culture experiments and have performed new experiments. Several problems are inherent in these studies. At pH values less than 5.0, the activities of the mononuclear hydroxy-Al species are low relative to Al³⁺, but attempts to change the ratio by raising the pH generally initiate the formation of polynuclear Al. (We discovered that mononuclear solutions are stable for many days when {Al³⁺}/{H⁺}³≤ 10^8.8, where braces denote activities.) We avoided, or accounted for, polynuclear Al in our studies. In addition, we used up-to-date equilibrium constants to compute Al species, very simple culture media (generally containing CaCl₂, AlCl₃ and HCl as the only inputs), short-term (2d) growth, and an Al-sensitive wheat variety (Triticum aestivum L. cv. Tyler) that permitted low Al levels and, consequently, higher pH values without Al polymerization. Experiments were designed in which the solutions were constant in {Al³⁺} and variable in mononuclear hydroxy-Al or were orthonal (factorial) in {Al³⁺} and {AlOH²⁺}. Linear and nonlinear, simple and multiple, regression analyses of these and previous experiments failed to reveal any toxicity for mononuclear hydroxy-Al to Tyler wheat.     

Bioadsorption of cadmium ion by cell surface-engineered yeasts displaying metallothionein and hexa-His

The Cd²⁺-chelating abilities of yeast metallothionein (YMT) and hexa-His displayed on the yeast-cell surface were compared. Display of YMT and hexa-His by -agglutinin-based cell-surface engineering was confirmed by immunofluorescent labeling. Surface-engineered yeast cells with YMT and hexa-His fused in tandem showed superior cell-surface adsorption and recovery of Cd²⁺ under EDTA treatment on the cell surface than hexa-His-displaying cells. YMT was demonstrated to be more effective than hexa-His for the adsorption of Cd²⁺. Yeast cells displaying YMT and/or hexa-His exhibited a higher potential for the adsorption of Cd²⁺ than Escherichia coli cells displaying these molecules. In order to investigate the effect of the displayed YMT and hexa-His on sensitivity to toxic Cd²⁺, growth in Cd²⁺-containing liquid medium was monitored. Unlike hexa-His-displaying cells, cells displaying YMT and hexa-His fused in tandem induced resistance to Cd²⁺ through active and enhanced adsorption of toxic Cd²⁺. These results indicate that YMT-displaying yeast cells are a unique bioadsorbent with a functional chelating ability superior to that of E. coli.     

Studies on copper toxicity in nickel-resistant strains ofNeurospora crassa

Copper toxicity has been studied in three nickel-resistant strains ofNeurospora crassa (Ni^R1, Ni^R2, and Ni^R3). Ni^R1 and Ni^R2, but not Ni^R3, were two-to threefold more sensitive than the parent wild strain (N. crassa EM 5297a) to Cu²⁺ on a normal N medium. On a nitrate N medium, Cu²⁺ was 16-fold more toxic to Ni^R3 because of reduced synthesis of nitrite reductase; Ni^R1 and Ni^R2 were only fivefold more sensitive to Cu²⁺, and nitrite reductase synthesis was unaffected. Mn²⁺ reversed Cu²⁺ toxicity on normal N medium only, in all strains. Fe³⁺ counteracted Cu²⁺ toxicity on nitrate N medium also. It was shown that Cu²⁺ affected Fe³⁺ utilization for nitrite reductase synthesis in Ni^R3 only and that in these Ni²⁺-resistant strains, Fe³⁺ antagonized effects of Cu²⁺, but not of other toxic metal ions.     

Interactive effects of Al, h, and other cations on root elongation considered in terms of cell-surface electrical potential

The rhizotoxicities of Al³⁺ and of La³⁺ to wheat (Triticum aestivum L.) were similarly ameliorated by cations in the following order of effectiveness: H⁺ ≈ C³⁺ > C²⁺ > C¹⁺. Among tested cations of a given charge, ameliorative effectiveness was similar except that Ca²⁺ was slightly more effective than other divalent cations and H⁺ was much more effective than other monovalent cations. H⁺ rhizotoxicity was also ameliorated by cations in the order C³⁺ > C²⁺ > C¹⁺. These results suggest a role for cell-surface electrical potential in the rhizotoxicity of Al³⁺, La³⁺, H⁺, and other toxic cations: negatively charged cell surfaces of the root accumulate the toxic cations, and amelioration is effected by treatments that reduce the negativity of the cell-surface electrical potential by charge screening or cation binding. Membrane-surface activities of free Al³⁺ or La³⁺ computed according to a Gouy-Chapman-Stern model correlated well with growth inhibition, which correlated only poorly with Al³⁺ or La³⁺ activities in the external medium. The similar responses of Al-intoxicated and La-intoxicated roots to ameliorative treatments provide evidence that Al³⁺, rather than AlOH²⁺ or Al(OH)₂⁺, is the principal toxic species of mononuclear Al. Comparisons of the responses of Al-sensitive and Al-tolerant wheats to Al³⁺ and to La³⁺ did not support the hypothesis that varietal sensitivity to Al³⁺ is based upon differences in cell-surface electrical potential.     

Manganese toxicity towards Saccharomyces cerevisiae : Dependence on intracellular and extracellular magnesium concentrations

Inhibition of the growth of Saccharomyces cerevisiae was evident at concentrations of 0.5 mM Mn²⁺ or higher, but a tolerance to lower Mn²⁺ concentrations was observed. The inhibitory effects of 2.0 mM Mn²⁺ were eliminated by supplementing the medium with excess Mg²⁺ (10 mM), whereas addition of excess Ca²⁺ and K⁺ had negligible effect on Mn²⁺ toxicity. Growth inhibition by Mn²⁺, in the absence of a Mg²⁺ supplement, was attributed to Mn²⁺ accumulation to toxic intracellular levels. Mn levels in S. cerevisiae grown in Mg²⁺-supplemented medium were severalfold lower than those of cells growing in unsupplemented medium. Mn²⁺ toxicity was also influenced by intracellular Mg, as Mn²⁺ toxicity was found to be more closely correlated with the cellular Mg:Mn ratio than with cellular Mn levels alone. Cells with low intracellular levels of Mg were more susceptible to Mn²⁺ toxicity than cells with high cellular Mg, even when sequestered Mn²⁺ levels were similar. A critical Mg:Mn ratio of 2.0 was identified below which Mn²⁺ toxicity became acute. The results demonstrate the importance of intracellular and extracellular competitive interactions in determining the toxicity of Mn²⁺. Received: 18 June 1997 / Received last revision: 10 January 1998 / Accepted: 24 January 1998     

Differential superoxide dismutase expression in ryegrass cultivars in response to short term aluminium stress

Background and aims

Saline soils limit plant production worldwide through osmotic stress, specific-ion toxicities, and nutritional imbalances.

Methods

The ability of Ca²⁺ and K⁺ to alleviate toxicities of Na⁺ and Mg²⁺ was examined using 89 treatments in short-term (48 h) solution culture studies for cowpea (Vigna unguiculata (L.) Walp.) roots. Root elongation was related to ionic activities at the outer surface of the root plasma membrane.

Results

The addition of K⁺ was found to alleviate the toxic effects of Na⁺, and supplemental Ca²⁺ improved growth further in these partially-alleviated solutions where K⁺ was present. Therefore, Na⁺ appears to interfere with K⁺ metabolism, and Ca²⁺ reduces this interference. Interestingly, the ability of Ca²⁺ to improve K-alleviation of Na⁺ toxicity is non-specific, with Mg²⁺ having a similar effect. In contrast, the addition of Ca²⁺ to Na-toxic solutions in the absence of K⁺ did not improve growth, suggesting that Ca²⁺ does not directly reduce Na⁺ toxicity in these short-term studies (for example, by reducing Na⁺ uptake) when supplied at non-deficient levels. Finally, K⁺ did not alleviate Mg²⁺ toxicity, suggesting that Mg²⁺ is toxic by a different mechanism to Na⁺.

Conclusions

Examination of how the toxic effects of salinity are alleviated provides clues as to the underlying mechanisms by which growth is reduced.     

Development of a Multi-Species Biotic Ligand Model Predicting the Toxicity of Trivalent Chromium to Barley Root Elongation in Solution Culture

Little knowledge is available about the influence of cation competition and metal speciation on trivalent chromium (Cr(III)) toxicity. In the present study, the effects of pH and selected cations on the toxicity of trivalent chromium (Cr(III)) to barley (Hordeum vulgare) root elongation were investigated to develop an appropriate biotic ligand model (BLM). Results showed that the toxicity of Cr(III) decreased with increasing activity of Ca²⁺ and Mg²⁺ but not with K⁺ and Na⁺. The effect of pH on Cr(III) toxicity to barley root elongation could be explained by H⁺ competition with Cr³⁺ bound to a biotic ligand (BL) as well as by the concomitant toxicity of CrOH²⁺ in solution culture. Stability constants were obtained for the binding of Cr³⁺, CrOH²⁺, Ca²⁺, Mg²⁺ and H⁺ with binding ligand: log K_CrBL 7.34, log K_CrOHBL 5.35, log K_CaBL 2.64, log K_MgBL 2.98, and log K_HBL 4.74. On the basis of those estimated parameters, a BLM was successfully developed to predict Cr(III) toxicity to barley root elongation as a function of solution characteristics.