Release of Citric Acid into the Medium by Aluminum-Tolerant Carrot Cells

One physiological characteristic of an Al-tolerant cell line(TA-1) selected from a cultured carrot cell line (SO-1) wasthe release of more citric acid into the medium than the parentalSO-1 line. Aluminum chloride was added to the media at a concentration,at which SO-1 as well as TA-1 could grow normally without inhibition.The amounts of citric acid and the soluble Al present in themedium were determined during the growth period. Much citricacid was released from TA-1 cells into the medium in the firsthalf of the culture period. At the time of maximum growth, theamount of citric acid in the medium of TA-1 cells was twiceas much as in the medium of SO-1 cells. The precipitates ofAl compound(s), which were formed in the medium by the additionof AlCl₃ as the Al source, became soluble as culture proceeded,depending on the amount of citric acid present in the medium. (Received September 3, 1983; Accepted May 9, 1984)     

Effect of various metal ions on growth of two wheat lines known to differ in aluminium tolerance

The effects of aluminium (Al), manganese (Mn), zinc (Zn), copper (Cu), boron (B), iron (Fe), gallium (Ga), scandium (Sc) and lanthanum (La) on growth of an Al-tolerant and an Al-sensitive line of wheat (Triticum aestivum L.) were measured in solution culture. The concentrations of nutrients in the basal nutrient solution were (M) 500 Ca, 100 Mg, 300 K, 600 N (150 NH₄, 450 NO₃), 600 SO₄, 2.5 P, 3 B, 2.5 Fe, 0.5 Zn, 0.5 Mn, 0.1 Cu at a pH of 4.7. The major solution nutrient concentrations were maintained at the nominal concentration with monitoring, frequent additions and weekly renewal. Differentiation in yield between the Al-tolerant and Al-sensitive line only occurred in the presence of Al indicating that, in the long term, none of the other metals tested could be used as an analog for Al. The visual symptoms in the roots of Cu toxicity (in both lines) and Al toxicity (in the sensitive line) were similar. The solution concentration (M) at which yield of the roots of the tolerant line was reduced by 50% was, in order of increasing tolerance, Cu 0.5, Sc 1.1, La 7.1, Ga 8.6, Al 15, Zn 19, Fe 84, B 490 and Mn 600.     

Selection of Copper and Zinc Resistant Nicotiana plumbaginifolia Cell Suspension Cultures

Copper and zinc resistant cells of Nicotiana plumbaginifoliawere selected using unmutagenized cell suspensions in mediumcontaining normally lethal concentrations of CuSO₄ or ZnSO₄.Both resistances were retained for thirty cell doublings withoutselection pressure. The Cu resistant cells were 10-times andthe Zn resistant cells were 6-times as resistant as the wildtype cells. The Zn resistant cells were also somewhat resistantto AlCl₃ in comparison with the wild type cells, while the Curesistant cells were also somewhat resistant to ZnSO₄ and AlCl₃.The uptake of Cu by the Cu resistant cells and Zn by the Znresistant cells was higher than that of the wild type cells. (Received April 21, 1986; Accepted June 30, 1986)     

Aluminum induces changes in oxidative burst scavenging enzymes in Coffea arabica L. suspension cells with differential Al tolerance

The accumulation of reactive oxygen species (ROS) and concomitant oxidative stress have been considered deleterious consequences of aluminum toxicity. However, several lines of evidence suggest that ROS can function as important signaling molecules in the plant defense system for protection from abiotic stress and the acquisition of tolerance. The role of ROS-scavenging enzymes was assayed in two different coffee cell suspension lines. We treated L2 (Al-sensitive) and LAMt (Al-tolerant) Coffea arabica suspension cells with 100 μM AlCl₃ and observed significant differences in catalase activity between the two cell lines. However, we did not observe any differences in superoxide dismutase or glutathione reductase activity in either cell line following Al treatment. ROS production was diminished in the LAMt cell line. Taken together, these results indicate that aluminum treatment may impair the oxidative stress response in L2 cells but not in LAMt cells. We suggest a possible role for Al-induced oxidative bursts in the signaling pathways that lead to Al resistance and protection from Al toxicity.     

Aluminum Ions Induce Oat Protoplasts to Produce an Extracellular (1-->3)beta-d-Glucan

Aluminum chloride induced mesophyll protoplasts of oat (Avena sativa) to produce an extracellular polysaccharide (EPS). EPS induced by AlCl₃ appeared identical to that produced in response to the phytotoxin victorin (JD Walton, ED Earle [1985] Planta 165: 407-415). Al ions at 1 millimolar were toxic to protoplasts, but maximum EPS production occurred at a sublethal concentration of 200 micromolar, assayed at pH 6.0. As measured by incorporation of [¹⁴C]glucose, AlCl₃ stimulated EPS production 10- to 15- fold. Pretreatment of protoplasts with cycloheximide prevented EPS production but not cell death in response to AlCl₃, indicating that protein synthesis was necessary for EPS production but not for the phytotoxicity of Al ions. The trivalent salts of Y, Yb, Gd, and In also induced EPS production but those of Sc, Fe, Ga, Cr, and La did not. Mesophyll protoplasts from an acid-soil tolerant oat cultivar, Coker 83-23, produced less EPS in response to AlCl₃ than the acid-soil sensitive cultivar Fla 501. EPS was also produced by wheat (Triticum aestivum) and barley (Hordeum vulgare) protoplasts in response to AlCl₃. An Al-tolerant cultivar of wheat, Atlas, produced less EPS than an Al-sensitive cultivar, Scout, but an Al-tolerant cultivar of barley, Dayton, produced more than the Al-sensitive cultivar Kearney. Therefore, production of EPS by protoplasts in response to Al ions did not appear to be related to Al ion tolerance at the level of whole plants. EPS fluoresced in the presence of Calcofluor and Sirofluor and was degraded by purified laminarinase [(1→3)β-d-glucanase] but not pectinase (polygalacturonase). EPS was composed solely of glucose in 1→3 linkages; hence it is a (1→3)β-d-glucan (callose).     

Quantitative Estimation of Aluminium Toxicity in Cultured Tobacco Cells: Correlation between Aluminium Uptake and Growth Inhibition

The relationship between aluminium (Al) uptake and growth inhibitionwas studied in tobacco cells (Nicotiana tabacum L. cv. Samsun;nonchlorophyllic cell line) in suspension culture. Cells atthe logarithmic phase of growth were treated with 100 µMA1C1³ in modified Murashige-Skoog medium prepared without P_iand EDTA (pH 4.0) for up to 21 h. After treatment, the inhibitionof cell growth by Al was estimated from the growth of the Al-treatedcells relative to that of the control cells during post-treatmentculture. Neither Al uptake nor the inhibition of the growthoccurred with less than a 10-h exposure but then both parametersincreased rapidly, reaching maximum values after an 18-h exposure.When cells were treated with AlCl₃ at various concentrationsfor 18 h, the extent of growth inhibition was found to be afunction of the Al content of the cells. The dose-response curve(Al uptake versus growth inhibition) resembled the curve expectedfor "single-hit" kinetics. Extrapolation from the curve suggestedthat the uptake of 1 x 10¹¹ Al atoms per cell is the minimumdose that inhibits cell growth. Cells of stationary phase wereresistant to Al and did not take up Al, an indication that theuptake of Al depends on the active growth of cells. Resultsof several types of experiment (hematoxylin staining, washingwith chelators, digestion of cell walls) indicated that Al wasincorporated inside the cells. Together, therefore, our resultssuggest that the amount of Al absorbed by the cells is a determiningfactor in the inhibition of growth by Al. ¹Present address: Department of Biology, Faculty of Science,Hirosaki University Hirosaki, Aomori, 036 Japan     

Aluminium induces changes in organic acids metabolism in Coffea arabica suspension cells with differential Al-tolerance

The primary Al-tolerance mechanism in plants involves exudation and/or accumulation of specific organic acid species, which form non-phytotoxic complexes with Al³⁺ under physiological conditions. An evaluation was done of the role of organic acids in the tolerance mechanism of a cell suspension line of coffee Coffea arabica that exhibits Al-tolerance (LAMt) but for which the metabolic tolerance mechanism remains unknown. Significant differences existed in malate dehydrogenase and citrate synthase activities (key enzymes in organic acids metabolism) between protein extracts (day 7 of culture cycle) of the L2 (Al-sensitive) and LAMt (Al-tolerant) cells when cell suspensions were treated with 100 μM AlCl₃. HPLC analysis showed that the suspension cells of both lines exudate malate when incubated in a minimal solution but that exudation was not enhanced by treatment with AlCl₃ (100 μM). This is the first study demonstrating that plant Al-tolerance may be associated with down-regulation of malate dehydrogenase and citrate synthase activities.     

A physiological characterization of Mn-tolerant tobacco plants selected by in vitro culture

In previous research, an in vitro stepwise procedure permitted us to obtain Nicotiana tabacum regenerated plant lines able to grow in the presence of Mn at 2 and 5 mM (Mn-tolerant plants). These plants showed several morpho-physiological and cytological differences in comparison to the Mn-sensitive regenerated plants. In particular, the number of xylem cells and the degree of lignification appeared to be influenced differently by these Mn concentrations. In the present work these Mn-tolerant and Mn-sensitive N. tabacum plants, maintained in the presence of Mn 2 and 5 mM, have been characterized with regards to the uptake of Mn and Fe, the activity of extracellular peroxidases in the stems, and the activity of superoxide dismutase, ascorbate peroxidase, and glutathione reductase in the leaves. The leaf response to an increasing Mn concentration in the medium, corresponded a parallel decrease of Fe content. Plants tolerant of 5 mM Mn showed almost a doubling Mn content over that of the 5 mM Mn-sensitive plants. In the stem, 2 and 5 mM Mn inhibited the extracellular free peroxidases (guaiacol peroxidases) either in the Mn-tolerant plants or in the Mn-sensitive plants. In the Mn-sensitive plants treated with 2 mM Mn the activity of the peroxidases of the ionically and covalently bound wall peroxidases was also depressed. In 5 mM Mn-tolerant plants, an enhanced activity of the covalently bound wall peroxidases was observed. The effect of Mn on the covalently bound wall syringaldazine peroxidases was identical to that observed in the guaiacol peroxidases; the activity was significantly higher in the Mn-tolerant plants grown in the presence of 5 mM Mn. In the leaf, the increase of Mn content inhibited the activity of guaiacol peroxidase, ascorbate peroxidase and superoxide dismutase in the Mn-tolerant as well as in the Mn-sensitive plants. However, the effect was greater in the Mn-sensitive plants. Only glutathione reductase did not show significant variation except for the 2 mM Mn-sensitive plants, where an increased activity was detected.     

Aluminum effects on calcium fluxes at the root apex of aluminum-tolerant and aluminum-sensitive wheat cultivars

The role of Ca²⁺ transport in the mechanism of Al toxicity was investigated, using a Ca²⁺-selective microelectrode system to study Al effects on root apical Ca²⁺ fluxes in two wheat (Triticum aestivum L.) cultivars: Al-tolerant Atlas 66 and Al-sensitive Scout 66. Intact 3-day-old low-salt-grown (100 micromolar CaCl₂, pH 4.5) wheat seedlings were used, and it was found that both cultivars maintained similar rates of net Ca²⁺ uptake in the absence of Al. Addition of Al concentrations that were toxic to Scout (5-20 micromolar AlCl₃) immediately and dramatically inhibited Ca²⁺ uptake in Scout, whereas Ca²⁺ transport in Atlas was relatively unaffected. The Al-induced inhibition of Ca²⁺ uptake in Scout 66 was rapidly reversed following removal of Al from the solution bathing the roots. Similar studies with morphologically intact root cell wall preparations indicated that the Al effects did not involve Al-Ca interactions in the cell wall. These results suggest that Al inhibits Ca²⁺ influx across the root plasmalemma, possibly via blockage of calcium channels. The differential effect of Al on Ca²⁺ transport in Al-sensitive Scout and Al-tolerant Atlas suggests that Al blockage of Ca²⁺ channels could play a role in the cellular mechanism of Al toxicity in higher plants.     

Al Binding in the Epidermis Cell Wall Inhibits Cell Elongation of Okra Hypocotyl

Al inhibits root elongation at micromolar concentrations, butthe mechanisms leading to this process are unknown. In thesestudies, Al-induced inhibition of cell elongation was examinedusing hypocotyl of okra (Abelmoschus esculentus Moench cv. ClemsonSpineless) as an experimental model. One-h exposure to Al (0.5mM A1Cl₃) in the presence of 10 µM auxin in 0.5 mM CaCl₂,pH 4.0 significantly inhibited auxin-induced cell elongationof okra hypocotyl segments. Elongation was further suppressedwith increasing Al concentrations up to 1 mM. Treatment of thehypocotyl with 1 mM citrate for 10 minutes after 2-h exposureto Al resulted in significant recovery of elongation. The amountof Al in the cell wall relative to the total in the tissue was96.0, 96.2, and 85.4%, respectively, following 1-, 2-, and 3-hexposure to the Al solution. The total and cell wall Al contentwas decreased by half after the citrate desorption treatment.Further-more, 95% of Al was found in the epidermis, and 95%of the Al in the epidermis was associated with the cell wall.Experiments using split hypocotyl segments showed that Al exposureincreased the outward bending of hypocotyl segments, suggestingthat the epidermis elongation was specifically inhibited byAl. Al inhibited the autolysis of epidermis by about 20%, buthad little effect on the autolysis of core tissue. Taken together,these results suggest that Al binding in the epidermal cellwall inhibits critical components in cell wall loosening mechanism,resulting in inhibition of cell elongation.     

A split-root experiment shows that translocated phosphorus does not alleviate aluminium toxicity within plant tissue

Background and aims

My previous experimental findings suggested that phosphorus (P) enhances aluminium (Al) tolerance in both Al-tolerant and Al-sensitive wheat seedlings. However, the role of P in the amelioration of Al toxicity within plant tissue is still unclear. Therefore, a soil culture horizontal split-root system was used to quantify whether or not translocated P alleviates Al toxicity within the plant tissue.

Methods

Different level of Al and P were added in two compartments in various combinations for separate root halves. Constrasting Al-tolerant (ET8) and Al-sensitive (ES8) wheat genotypes were used as a testing plant.

Results

The limitation of root growth was independent to Al-toxicity in one root half. However, root proliferation occurred as a compensatory growth on the other root half that has no Al-toxicity. Where half of the roots were given 60 mg P/kg, plant did not translocated P in the other part of the root system that grown in Al toxic soil. When 40 mg P/kg were mixed with 60 mg AlCl₃/kg within one root half combinations, root dry weight of both ET8 and ES8 increased markedly in that root half. In contrast, root dry weight of both ET8 and ES8 decreased noticeably only 60 mg AlCl₃/kg treated root half. The shoot P and Al uptake in both ET8 and ES8 was lower in combined 40 mg P/kg and 60 mg AlCl₃/kg addition as compared to other combination with same P and Al level.

Conclusions

Result from this study confirm that addition of P to Al toxic acid soil played dual role like amelioration of Al-toxicity in soil and utilize P as nutrition for plant growth and development. Findings also attributed that added P was reduced by precipitation with added Al. However, evidence found that translocated P was not able to alleviate Al toxicity within plant tissue of both ES8 and ET8.     

Effects of aluminum on superoxide dismutase and peroxidase activities,and lipid peroxidation in the roots and calluses of soybeans differing in aluminum tolerance

The seedlings of two soybean genotypes, Al-tolerant PI 416937 (PI) and Al-sensitive Young, were cultured in the solution containing 0, 25 or 50 μM Al (AlCl₃·6H₂O) for 24, 36 or 48 h in the hydroponics, and the calluses induced from two genotypes were cultured in medium containing 0, 10, 50 or 100 μM Al for 5, 10 or 15 days, respectively. The effects of Al on growth of seedling roots and calluses, antioxidant enzyme activities of superoxide dismutase (SOD) and peroxidase (POD) and lipid peroxidation were investigated. Under Al stress, PI was more tolerant to Al toxicity than Young at both intact plant and tissue levels and lower concentrations of Al significantly stimulated the root and callus growth of PI. Al application enhanced the activities of SOD and POD and lipid peroxidation in both roots and calluses of two genotypes. Although the differences of SOD activities between two genotypes in response to Al toxicity depended on Al concentration and durations of treatment, SOD activities in the roots of PI were higher than those in the roots of corresponding Young in the presence of Al for 36 or 48 h. Meanwhile, the POD activities in PI roots increased as the Al levels and durations of treatment increased, significantly higher than those in the corresponding Young roots. Moreover, Al-treated PI had significantly lower lipid peroxidation than Young at both root and callus levels. These results suggest that the enhanced antioxidant-related enzyme activities and reduced lipid peroxidation in PI might be one of Al-tolerant mechanisms.     

Isolation of aluminum-tolerant cell lines of tobacco in a simple calcium medium and their responses to aluminum

Aluminum (Al)-tolerant cell lines (ALT301 and ALT401) of tobacco were isolated in a simple calcium (Ca) solution from ethyl methane sulfonate (EMS)-treated suspension cultured tobacco cells ( Nicotiana tabacum L. cv. Samsun, a cell line SL) at the logarithmic phase of growth. A highly tolerant cell line ALT301 exhibited the accumulation of Al and the deposition of callose to the same extent as the parental SL cells during the exposure to Al. However, the Al-treated ALT301 cells grew much better than the Al-treated SL cells after transfer to Al-free growth medium. Compared to SL cells, ALT301 cells were more tolerant to toxicity of copper and iron, but not to that of lanthanum. These results suggest that ALT301 cells have an internal tolerance mechanism, which makes cells grow normally in spite of Al accumulation and Al-induced lesion represented by the deposition of callose. This tolerance mechanism seems also to be effective against copper and iron toxicity. A slightly tolerant cell line ALT401 also accumulated Al to the same degree as SL cells, but deposited significantly less callose than did SL cells (43% of SL). The growth of ALT401 cells after Al treatment was only slightly better than that of SL cells. Thus, it seems that ALT401 cells have a mechanism to protect cells only from the Al-induced deposition of callose, which is not enough to overcome the Al-induced inhibition of growth. The different phenotypes exhibited by these Al-tolerant cell lines suggest that the deposition of callose is not directly related to the inhibition of growth in Al-treated cells.     

Organic acid exudation as an aluminum-tolerance mechanism in maize (Zea mays L.)

In this study, the role of root organic acid synthesis and exudation in the mechanism of aluminum tolerance was examined in Al-tolerant (South American 3) and Al-sensitive (Tuxpeño and South American 5) maize genotypes. In a growth solution containing 6 M Al³⁺, Tuxpeño and South American 5 were found to be two- and threefold more sensitive to Al than South American 3. Root organic acid content and organic acid exudation from the entire root system into the bulk solution were investigated via high-performance liquid chromatographic analysis while exudates collected separately from the root apex or a mature root region (using a dividedroot-chamber technique) were analyzed with a more-sensitive ion chromatography system. In both the Al-tolerant and Al-sensitive lines, Al treatment significantly increased the total root content of organic acids, which was likely the result of Al stress and not the cause of the observed differential Al tolerance. In the absence of Al, small amounts of citrate were exuded into the solution bathing the roots. Aluminum exposure triggered a stimulation of citrate release in the Al-tolerant but not in the Al-sensitive genotypes; this response was localized to the root apex of the Al-tolerant genotype. Additionally, Al exposure triggered the release of phosphate from the root apex of the Al-tolerant genotype. The same solution Al³⁺ activity that elicited the maximum difference in Al sensitivity between Al-tolerant and Al-sensitive genotypes also triggered maximal citrate release from the root apex of the Al-tolerant line. The significance of citrate as a potential detoxifier for aluminum is discussed. It is concluded that organic acid release by the root apex could be an important aspect of Al tolerance in maize.Abbreviations SA3 South American 3, an Al-tolerant maize cultivar - SA5 South American 5, an Al-sensitive maize cultivar The authors would like to express their appreciation to Drs. John Thompson, Ross Welch and Mr. Stephen Schaefer for their training and guidance in the use of the chromatography systems. This work was supported by a Swiss National Science Foundation Fellowship to Didier Pellet, and U.S. Department of Agriculture/National Research Initiative Competitive Grant 93-37100-8874 to Leon Kochian. We would also like to thank Drs. S. Pandey and E. Ceballos from the CIMMYT Regional office at CIAT Cali, Colombia for providing seed for the maize varieties and inbred line.     

Differential tolerance to Mn toxicity in perennial ryegrass genotypes: involvement of antioxidative enzymes and root exudation of carboxylates

Mechanisms underlying differential tolerance to Manganese (Mn) toxicity in perennial ryegrass (Lolium perenne L.) cultivars are poorly understood. We evaluated activity of antioxidative enzymes and root exudation of carboxylates in four ryegrass cultivars subjected to increasing Mn supply under nutrient solution conditions. A growth reduction caused by Mn toxicity was smaller in Jumbo and Kingston than Nui and Aries cultivars. Shoot Mn accumulation varied in the order Nui > Aries > Kingston > Jumbo. Ascorbate peroxidase and guaiacol peroxidase activities increased with Mn excess. Mn-tolerant Jumbo and Kingston had high activity of these enzymes and relatively low lipid peroxidation. Kingston was most tolerant to high tissue Mn concentrations and had the highest superoxide dismutase activity. Increased activity of antioxidative enzymes in Mn-tolerant cultivars could protect their tissues against oxidative stress triggered by Mn excess. Mn toxicity induced root exudation of carboxylates; oxalate and citrate may decrease Mn availability in the rhizosphere, thus enhancing Mn tolerance in ryegrass.     

Aluminum tolerance in maize is correlated with increased levels of mineral nutrients, carbohydrates and proline, and decreased levels of lipid peroxidation and Al accumulation

We investigated the uptake of aluminum (Al) and transport to shoots in two inbred maize lines (Zea mays L., VA-22 and A(4/67)) differing in Al tolerance. Seedlings were grown for 7 days in hydroponic culture with nutrient solution that contained 0, 240, 360, and 480muM Al at pH 4.2. After 7 days of exposure to Al, roots of sensitive maize line (A(4/67)) plants accumulated 2-2.5 times more Al than roots of tolerant line (VA-22) plants. Inductively coupled plasma atomic emission spectrometry (ICP-AES) showed that the tolerant line retained higher concentrations of Ca(2+), Mg(2+), and K(+) compared with the sensitive line. In response to Al treatment, proline (Pro) concentration increased three-fold in roots of tolerant plants, while a slight increase was observed in roots of sensitive-line plants. A substantial carbon surplus (two-fold increase) was observed in roots of the Al-tolerant maize line. Carbohydrate concentration remained almost unchanged in roots of Al-sensitive line plants. Al treatment triggered the enhancement of lipid peroxidation in the sensitive line, while no change in lipid peroxidation level was observed in the tolerant maize line. These data provide further support to the hypothesis that a mechanism exists that excludes Al from the roots of the tolerant maize line, as well as an internal mechanism of tolerance that minimizes accumulation of lipid peroxides through a higher Pro and carbohydrate content related to osmoregulation and membrane stabilization.     

木豆叶总黄酮测定方法的比较研究

采用比色法测定木豆叶中的总黄酮含量。对三氯化铝比色法、硼酸—柠檬酸比色法和硝酸铝比色法3种测定方法进行比较,确定了硝酸铝比色法为木豆叶总黄酮的最佳测定方法,该方法稳定性、精密度和重现性好,其RSD分别为2.1%、0.9%和2.3%,应用该方法测定木豆叶总黄酮含量为15.65 mg·g^-1 DW。本方法适用于木豆叶或其制剂中总黄酮的质量分析检验,为木豆叶中黄酮的研究开发提供了质控依据。     

Zonal responses of sensitive vs. tolerant wheat roots during Al exposure and recovery

Aluminium (Al) irreversibly inhibits root growth in sensitive, but not in some tolerant genotypes. To better understand tolerance mechanisms, seedlings from tolerant ('Barbela 7/72' line) and sensitive ('Anahuac') Triticum aestivum L. genotypes were exposed to AlCl(3) 185 μM for: (a) 24 h followed by 48 h without Al (recovery); (b) 72 h of continuous exposure. Three root zones were analyzed (meristematic (MZ), elongation (EZ) and hairy (HZ)) for callose deposition, reserves (starch and lipids) accumulation, endodermis differentiation and tissue architecture. Putative Al-induced genotoxic or cytostatic/mytogenic effects were assessed by flow cytometry in root apices. Tolerant plants accumulated less Al, presented less root damage and a less generalized callose distribution than sensitive ones. Starch and lipid reserves remained constant in tolerant roots but drastically decreased in sensitive ones. Al induced different profiles of endodermis differentiation: differentiation was promoted in EZ and HZ, respectively, in sensitive and tolerant genotypes. No ploidy changes or clastogenicity were observed. However, differences in cell cycle blockage profiles were detected, being less severe in tolerant roots. After Al removal, only the 'Barbela 7/72' line reversed Al-induced effects to values closer to the control, mostly with respect to callose deposition and cell cycle progression. We demonstrate for the first time that: (a) cell cycle progression is differently regulated by Al-tolerant and Al-sensitive genotypes; (b) Al induces callose deposition >3 cm above root apex (in HZ); (c) callose deposition is a transient Al-induced effect in tolerant plants; and (d) in HZ, endodermis differentiation is also stimulated only in tolerant plants, probably functioning in tolerant genotypes as a protective mechanism in addition to callose.     

Characteristics of carrot plant regenerated from two cell line selected as either ionic-Al tolerant cell or Al-phosphate utilizing cells

Plantlets of carrot (Daucus carota L.) were regenerated from two types of cell lines. One type was selected as ionic-Al tolerant (IAT) cells, while the second type featured Al-phosphate utilizing cells (IPG). Their tolerance characteristics were investigated. The plantlets from IAT were directly regenerated, whereas those from IPG were regenerated after somatic hybridization with wild-type cells previously inactivated with iodacetamide, because the IPG cells had completely lost the ability to regenerate naturally.The sexual progeny of IAT showed Al-tolerant properties, established by testing their root elongation in the presence of 500 µM Al ions. Most of the calli obtained from the somatic hybrids grew more rapidly than the wild-type cells when Al-phosphate was used as a sole source of phosphorus. Thus, we obtained two types of carrot plantlets, regenerated from IAT and IPG. Both possessed the tolerant characteristics as observed with the stress-selected cells.