Cyanamide mode of action during inhibition of onion (Allium cepa L.) root growth involves disturbances in cell division and cytoskeleton formation

Cyanamide is an allelochemical produced by hairy vetch (Vicia villosa Roth.). Its phyotoxic effect on plant growth was examined on roots of onion (Allium cepa L.) bulbs. Water solution of cyanamide (2-10 mM) restricted growth of onion roots in a dose-dependent manner. Treatment of onion roots with cyanamide resulted in a decrease in root growth rate accompanied by a decrease in accumulation of fresh and dry weight. The inhibitory effect of cyanamide was reversed by its removal from the environment, but full recovery was observed only for tissue treated with this chemical at low concentration (2-6 mM). Cytological observations of root tip cells suggest that disturbances in cell division may explain the strong cyanamide allelopathic activity. Moreover, in cyanamide-treated onion the following changes were detected: reduction of mitotic cells, inhibition of proliferation of meristematic cells and cell cycle, and modifications of cytoskeleton arrangement.     

Involvement of phosphoinositides,calmodulin and glyoxalase-I in cell proliferation in callus cultures of Amaranthus paniculatus

The effect of lithium and trifluoperazine (TFP) was studied on cell proliferation in callus cultures of Amaranthus paniculatus. TFP (20 μM) and lithium (40 mM) inhibited the callus growth by 50% and 80%, respectively. The inhibition by lithium was reversed by the addition of myoinositol (2.5 mM). Equimolar concentration of NaCl, as that of LiCl, had no significant effect on callus growth. The activity of calmodulin was inhibited by TFP as tested both by in vivo and in vitro experiments. The level of phosphatidylinositol (PI) in calli grown on lithium was lower than the calli grown on the medium containing inositol alone. The activity of the enzyme glyoxalase-I was inhibited by lithium and TFP. The inhibition of the enzyme activity by lithium was reversed by the addition of inositol. Possible involvement of phosphoinositide cycle, calcium and calmodulin in cell proliferation in in vitro cultures is suggested.     

Lithium-induced accumulation of inositol 1-phosphate during cholecystokinin octapeptide- and acetylcholine-stimulated phosphatidylinositol breakdown in dispersed mouse pancreas acinar cells

Dispersed mouse pancreas acinar cells were prepared in which phosphatidylinositol had been labeled with myo[2-3H]inositol. During incubation with 0.3 microM cholecystokinin octapeptide (CCK-8) for 15 min, there was a loss of [3H]phosphatidylinositol radioactivity (23%) and a 3-fold gain in trichloroacetic acid-soluble radioactivity. Replacement of NaCl by up to 58 mM LiCl did not significantly affect the amount of CCK-8-stimulated [3H]phosphatidylinositol breakdown or the gain in acid-soluble radioactivity. However, in normal medium, the product of phosphatidylinositol breakdown was almost all inositol, whereas in Li+-containing medium, the product was almost all inositol 1-phosphate. Similar results were obtained with acetylcholine which, in the presence of Li+, gave a dose-responsive increase in inositol 1-phosphate over the concentration range of 0.1 to 10 microM. No increased accumulation of [3H]inositol diphosphate or [3H]inositol triphosphate was detected in stimulated cells. Time courses in the presence of Li+ indicated that the formation of inositol 1-phosphate preceded the formation of inositol. Addition of up to 50 mM myoinositol to the incubation medium showed no diluting effect on the amount of [3H]inositol 1-phosphate found. The accumulation of inositol 1-phosphate is presumably due to the known ability of Li+ to inhibit myoinositol 1-phosphatase. The results provide clear evidence that stimulated phosphatidylinositol breakdown involves a phospholipase C type of phosphodiesterase activity. 1.25 mM Li+ gave half-maximal inositol 1-phosphate accumulation. This is close to the range of plasma Li+ levels which is used therapeutically in psychiatric disorders. In unstimulated cells, [3H]inositol 1-phosphate accumulation in the presence of Li+ corresponded to a breakdown rate for [3H]phosphatidylinositol of 2 to 3%/h.     

Characterization of the forward and reverse reactions catalyzed by CDP-diacylglycerol:inositol transferase in rabbit lung tissue.

CDPdiacylglycerol:inositol transferase activity in rabbit lung tissue has been characterized and the optimum conditions for assaying this enzyme in vitro were determined. Rabbit lung tissue CDPdiacylglycerol:inositol transferase activity was found primarily in the microsomal fraction. The pH optimum of the enzyme activity was between 8.8 and 9.4, and the reaction was dependent on either Mn2+ or Mg2+. Detergents and Ca2+ inhibited the activity of the enzyme. The apparent Km values of the enzyme for CDPdioleoylglycerol and myoinositol were 0.18 mM and 0.10 mM, respectively. The reversibility of the reaction catalyzed by CDPdiacylglycerol:inositol transferase in microsomes prepared from rabbit lung tissue was demonstrated by the synthesis of [3H]CMPdiacylglycerol when [3H]CMP and phosphatidylinositol were present in the incubation mixture. The reverse reaction was characterized and its importance in the regulation of the acidic phospholipid composition of surfactant during lung development is discussed. The pH optimum for the reverse reaction was 6.2, and the reverse reaction was also dependent on Mn2+ or Mg2+. The apparent Km value of CDPdiacylglycerol:inositol transferase for CMP was found to be 2.8 mM.     

Short term cultivation of isolated barley roots and their mitotic activity

Roots were excised from barley embryos cultivated in the complete liquid nutrient solution and cultivated in the same nutrient solution separately. The excised roots continued their growth but a progressive decrease in the growth rate was observed. There was a considerable short-term drop of the mitotic activity immediately after excision, which was followed by a compensatory increase and then equilibrium was reached 12 h after excision. During the next at least three days, the mitotic index of isolated barley roots varied between 5–6.5%, which is slightly lower than the mitotic index of the root meristems of isolated barley embryos under identical conditions. The mitotic cycle index of isolated barley roots and the size of the root meristem later decreased gradually.     

Effects of high osmotic potential of a medium on mitotic cycle in roots ofVicia faba L

The present paper deals with the effects of osmotic potential of a medium on cell reproduction and elongation of the roots ofVicia faba L. andVicia sativa L. As the osmoticum polyethylene glycol (PEG 4000) in various concentrations ranging from 5 % to 25 % (i.e. fromca.-0.11 up to -1.27 MPa) has been used. The results show that at higher concentrations than 7.5 %, the growth of roots is slowed down and at the concentration of 25 % PEG this decrease in growth rate is as much as 6 fold compared with the control. The mitotic cycle is prolonged, however, only 1.86 times. Thus, the inhibition of root growth is caused mainly by the inhibition of cell elongation. Concerning the effect of high osmotic potential on mitotic cycle it was found that the roots after immersion into 25% PEG are able to overcome this osmotic stress and after 6 h to renew the mitotic activity. The S phase of the cycle is the most sensitive to this factor and even after mitotic activity was renewed it showed a slower rate in comparison with the control.     

Phospholipase C activity from Catharanthus roseus transformed roots: aluminum effect

The effect of aluminum on the activity of PLC was examined in transformed roots from Catharanthus roseus (L) G. Don. When added in vitro to the reaction mixture, Al inhibited the enzymatic activity in a concentration and time-dependent fashion. This effect is very similar for both activities (soluble and membrane-associated). When roots were treated in vivo with Al 0.1 mM for short periods (0-4 h), PLC activity was also inhibited. Aluminum (1 mM) diminished root growth in approximately 50% when added on the first day of the culture cycle conditions in which PLC activity is also affected. Other enzymatic activities (NAD+-GDH, NADH-GDH, NADH-GOGAT and HMGR) were not affected when roots were treated with Al (0.1 mM) for short periods of time (1 h). Results obtained in this work suggest that the Al can affect PLC activity as a specific target. Enzymes: Phospholipase C (EC 3.1.4.10).     

Effect of lithium ions on the growth of wheat roots and the role of phosphoinositide cycle in growth regulation]

The influence of lithium ions (LiCl in concentrations of 0.5, 1.0, and 5.0 mM) on the growth processes of roots of 2-5-day old wheat seedlings was studied. It was shown that the inhibition of the root growth increased with the increase of LiCl concentration and seedling age. The membrane potential of root cells was lower and the loss of K+ by cells was greater when roots were treated with 5 mM LiCl, compared with the control. The growth inhibition by lithium was decreased by univalent ions, partially by potassium at the beginning of growth and completely by sodium throughout the experimental period. The divalent ions calcium and barium decreased the Li(+)-induced inhibition of root growth by reducing the rate of lithium uptake by cells. Myoinositol, controlled by Li-sensitive inositolmonophosphatase, reversed the Li-induced root growth inhibition in 2-day old seedlings, but did not prevent the inhibition during subsequent elongation. It can be concluded that lithium effects on wheat root growth are mediated by a partial blockage of signal transduction for proliferation (via the phosphoinositide cycle), because of calcium deficiency and caused by modification of ion transporting systems of the plasmalemma, and by disturbance of ion gradients, primarily H+ and K+.     

The response of apical meristems of primary roots of Vicia faba L. to colchicine treatments

The effects of 0.5% and 0.025% solutions of colchicine on the passage of cells through the mitotic cycle in apical meristems of primary roots of Vicia faba have been examined. Both treatments affected cell progression through the mitotic cycle in the same way: S and G1 were shorter, and G2 and mitosis longer, than the corresponding control values. The duration of the various phases of the mitotic cycle were similar to those reported previously for apical meristems of lateral roots though cycle time itself was longer. Recovery of root proliferating tissues from colchicine-induced inhibition of growth is correlated with the presence of quiescent cells. Meristems which have no quiescent cells do not recover from eolchicine treatment, while meristems which contain many quiescent cells recover faster than those which contain few. The growth fraction and the proportion of proliferating cells with a short cycle time are linearly related to the duration of the S period in root meristems.     

Dependence of Root Cell Growth and Division on Root Diameter

Primary roots of 98 species from different families of monocotyledonous and dicotyledonous plants and adventitious roots obtained from bulbs and rhizomes of 24 monocot species were studied. Root growth rate, root diameter, length of the meristem and elongation zones, number of meristematic cells in a file of cortical cells, and length of fully elongated cells were evaluated in each species after the onset of steady growth. The mitotic cycle duration and relative cell elongation rate were calculated. In all species, the meristem length was approximately equal to two root diameters. When comparing different species, the rate of root growth increased with a larger root diameter. This was due to an increase in the number of meristematic cells in a row and, to a lesser degree, to a greater length of fully elongated cells. The duration of the mitotic cycle and the relative cell elongation rate did not correlate with the root diameter. It is suggested that the meristem size depends on the level of nutrient inflow from upper tissues, and is thereby controlled during further growth.     

Response to copper excess in Arabidopsis thaliana: Impact on the root system architecture,hormone distribution,lignin accumulation and mineral profile

Growth, in particular reorganization of the root system architecture, mineral homeostasis and root hormone distribution were studied in Arabidopsis thaliana upon copper excess. Five-week-old Arabidopsis plants growing in hydroponics were exposed to different Cu²⁺ concentrations (up to 5 μM). Root biomass was more severely inhibited than shoot biomass and Cu was mainly retained in roots. Cu²⁺ excess also induced important changes in the ionome. In roots, Mg, Ca, Fe and Zn concentrations increased, whereas K and S decreased. Shoot K, Ca, P, and Mn concentrations decreased upon Cu²⁺ exposure. Further, experiments with seedlings vertically grown on agar were carried out to investigate the root architecture changes. Increasing Cu²⁺ concentrations (up to 50 μM) reduced the primary root growth and increased the density of short lateral roots. Experiment of split-root system emphasized a local toxicity of Cu²⁺ on the root system. Observations of GUS reporter lines suggested changes in auxin and cytokinin accumulations and in mitotic activity within the primary and secondary root tips treated with Cu²⁺. At toxic Cu²⁺ concentrations (50 μM), these responses were accompanied by higher root apical meristem death. Contrary to previous reports, growth on high Cu²⁺ did not induce an ethylene production. Finally lignin deposition was detected in Cu²⁺-treated roots, probably impacting on the translocation of nutrients. The effects on mineral profile, hormonal status, mitotic activity, cell viability and lignin deposition changes on the Cu²⁺-induced reorganization of the root system architecture are discussed.     

NaCl induced changes in ionically bound peroxidase activity in roots of rice seedlings

The changes in ionically bound peroxidase activity in roots of NaCl-stressed rice seedlings and their correlation with root growth were investigated. Increasing concentrations of NaCl from 50 to 150 mM progressively decreases root growth. The reduction of root growth by NaCl is closely correlated with the increase in ionically bound peroxidase activity. Since proline and ammonium accumulations are associated with root growth inhibition caused by NaCl, we determined the effects of proline or NH4Cl on root growth and ionically bound peroxidase activity in roots. External application of proline or NH4Cl markedly inhibited root growth and increased ionically bound peroxidase activity in roots of rice seedlings in the absence of NaCl. An increase in ionically bound peroxidase activity in roots preceded inhibition of root growth caused by NaCl, NH4Cl or proline. Mannitol inhibited root growth, but decreased rather than increased ionically bound peroxidase activity at the concentration iso-osmotic with NaCl. The inhibition of root growth and the increase in ionically bound peroxidase activity in roots by NaClis reversible and is associated with ionic rather than osmotic component. This revised version was published online in June 2006 with corrections to the Cover Date.     

Direct Evaluation of the Ca2+-Displacement Hypothesis for Al Toxicity

One explanation for Al toxicity in plants suggests that Al displaces Ca2+ from critical sites in the apoplasm. We evaluated the Ca2+-displacement hypothesis directly using near-isogenic lines of wheat (Triticum aestivum L.) that differ in Al tolerance at a single locus. We measured both the growth and total accumulation (apoplasmic plus symplasmic) of 45Ca and Al into roots that had been exposed to Al alone or to Al with other cations. Root growth in the Al-sensitive line was found to be severely inhibited by low activities of Al, even though Ca2+ accumulation was relatively unaffected. In solutions containing the same activity of the Al3+ and Ca2+ ions as above, but also including either 3.0 mM Mg2+, 3.0 mM Sr2+, or 30 mM Na+, growth improved, whereas 45Ca2+ accumulation was significantly decreased. Since most of the 45Ca2+ accumulated by roots during short-term treatments will reside in the apoplasm, these results indicate that displacement of Ca2+ from the apoplasm by Al cannot account for the Al-induced inhibition of root growth and, therefore, do not support the Ca2+-displacement hypothesis for Al toxicity. We also show that total accumulation of Al by root apices is greater in the Al-sensitive genotype than the Al-tolerant genotype and suggest that cation amelioration of Al toxicity is caused by the reduction in Al accumulation.     

Shoot-to-Root Signal Transmission Regulates Root Fe(III) Reductase Activity in the dgl Mutant of Pea

To understand the root, shoot, and Fe-nutritional factors that regulate root Fe-acquisition processes in dicotyledonous plants, Fe(III) reduction and net proton efflux were quantified in root systems of an Fe-hyperaccumulating mutant (dgl) and a parental (cv Dippes Gelbe Viktoria [DGV]) genotype of pea (Pisum sativum). Plants were grown with (+Fe treated) or without (-Fe treated) added Fe(III)-N,N'-ethylenebis[2-(2-hydroxyphenyl)-glycine] (2 [mu]M); root Fe(III) reduction was measured in solutions containing growth nutrients, 0.1 mM Fe(III)-ethylenediaminetetraacetic acid, and 0.1 mM Na2-bathophenanthrolinedisulfonic acid. Daily measurements of Fe(III) reduction (d 10-20) revealed initially low rates in +Fe-treated and -Fe-treated dgl, followed by a nearly 5-fold stimulation in rates by d 15 for both growth types. In DGV, root Fe(III) reductase activity increased only minimally by d 20 in +Fe-treated plants and about 3-fold in -Fe-treated plants, beginning on d 15. Net proton efflux was enhanced in roots of -Fe-treated DGV and both dgl growth types, relative to +Fe-treated DGV. In dgl, the enhanced proton efflux occurred prior to the increase in root Fe(III) reductase activity. Reductase studies using plants with reciprocal shoot:root grafts demonstrated that shoot expression of the dgl gene leads to the generation of a transmissible signal that enhances Fe(III) reductase activity in roots. The dgl gene product may alter or interfere with a normal component of a signal transduction mechanism regulating Fe homeostasis in plants.     

The Inhibition of Growth by Gravitropic Stimulation in Darkness in Agravitropic Primary Roots of Zea and the Role of Calcium

The primary roots of the "Golden Cross Bantam 70" cultivar ofZea mays are agravitropic in darkness and their orthogravitropismis light-dependent. Analysis of the agravitropic roots providesimportant information about the mechanism of orthogravitropism.However, the underlying mechanism of the agravitropic responsein darkness is unknown. We found that the growth of intact primaryroots was inhibited by gravitropic stimulation (i.e., changingthe orientation of the roots from vertical to horizontal) indarkness, but that of detipped roots was not. The role of calciumin this gravistimulation-dependent inhibition of growth wasinvestigated using apical 5-mm segments of the primary roots.The gravistimulation-dependent inhibition of growth was preventedby applying 10 mM MES-KOH buffer at pH 6.0 to the root cap.By contrast, the application of 0.1–1 mM buffer at pH6.0 and 10 mM buffer at pH 4.5–5.0 allowed the gravistimulation-dependentinhibition of growth. Furthermore, when the buffer of 10 mM(pH 6.0) contained 1–5 mM CaCl₂, the gravistimulation-dependentinhibition of growth was apparent. By contrast, when weak (1mM) buffer at pH 6.0 or 10 mM buffer at pH 4.5 contained 5 mMEGTA, no gravistimulation-dependent inhibition of growth wasobserved. Thus, the gravistimulation-dependent inhibition ofgrowth in darkness seemed to be mediated by an increase in thelevel of free Ca²⁺ in the root tip. These results suggest thatfree Ca²⁺ in the apoplast of the root tip plays an importantrole in the agravitropic response in darkness as well as inorthogravitropism under light of the roots of this cultivarof Zea mays. (Received March 21, 1994; Accepted July 25, 1994)     

SPATIAL AND TEMPORAL DEVELOPMENT OF IRON(III) REDUCTASE ACTIVITY IN ROOT SYSTEMS OF PISUM SATIVUM (FABACEAE) CHALLENGED WITH IRON-DEFICIENCY STRESS

The development of plasma membrane-associated iron(III) reductase activity was characterized in root systems of Pisum sativum during the first 2 wk of growth, as plants were challenged with iron-deficiency stress. Plants of a parental genotype (cv. Sparkle) and a functional iron-deficiency mutant genotype (E107) were grown hydroponically with or without supplemental iron. Iron(III) reductase activity was visualized by placing the roots in an agarose matrix containing 0.2 idm Fe(III)-ethylenediaminetetraacetic acid and 0.3 mM Na₂-bathophenanthrolinedisulfonic acid (BPDS). Red staining patterns, resulting from the formation of Fe(II)-BPDS, were used to identify iron(III)-reducing regions. Iron(III) reduction was extensive on roots of E107 as early as d 7, but not until d 11 for -Fe-treated Sparkle. Roots of +Fe-treated Sparkle showed limited regions of reductase activity throughout the period of study. For secondary lateral roots, iron(III) reduction was found for all growth types except + Fe-treated Sparkle. Treating Sparkle plants alternately to a cycle of iron deficiency, iron sufficiency, and iron deficiency revealed that reductase activity at a given root zone could be alternatively present, absent, and again present. Our results suggest that for Pisum roots grown under the present conditions, iron-deficiency stress induces the activation of iron(III) reductase capacity within 2 d.     

Cell cycle modulation in the response of the primary root of Arabidopsis to salt stress

Salt stress inhibits plant growth and development. We investigated the importance of cell cycle regulation in mediating the primary root growth response of Arabidopsis to salt stress. When seedlings were transferred to media with increasing concentrations of NaCl, root growth rate was progressively reduced. At day 3 after transfer of seedlings to growth medium containing 0.5% NaCl the primary roots grew at a constant rate well below that prior to the transfer, whereas those transferred to control medium kept accelerating. Kinematic analysis revealed that the growth reduction of the stressed roots was due to a decrease in cell production and a smaller mature cell length. Surprisingly, average cell cycle duration was not affected. Hence, the reduced cell production was due to a smaller number of dividing cells, i.e. a meristem size reduction. To analyze the mechanism of meristem size adaptation prior to day 3, we investigated the short-term cell cycle events following transfer to saline medium. Directly after transfer cyclin-dependent kinase (CDK) activity and CYCB1;2 promoter activity were transiently reduced. Because protein levels of both CDKA;1 and CDKB1;1 were not affected, the temporary inhibition of mitotic activity that allows adaptation to the stress condition is most likely mediated by posttranslational control of CDK activity. Thus, the adaptation to salt stress involves two phases: first, a rapid transient inhibition of the cell cycle that results in fewer cells remaining in the meristem. When the meristem reaches the appropriate size for the given conditions, cell cycle duration returns to its default.     

Increased erythritol production in Torula sp. with inositol and phytic acid

Of the vitamins tested, inositol was the most effective for erythritol production. To increase erythritol production by Torula sp., inositol and a related compound, phytic acid (myoinositol hexaphosphate), were added to the culture media. Erythritol production in the presence of phytic acid was greater than that in the presence of inositol, due to the synergistic effects of phosphate and inositol. Supplementation with phosphate and inositol increased cell growth, erythritol production, and the activity of erythrose reductase in cells. Inositol was a more effective stimulator of cell growth and erythritol production than was phosphate.     

The Growth of the Nucleus in Dividing and Non-dividing Cells of the Pea Root

The growth of the nucleus and the cell in the pea root was followedthrough the mitotic cycle and subsequently in post-mitotic developmentby comparing cells and nuclei from the meristem, at differentstages of interphase, and cells and nuclei from two regionsof the enlarging zone of the root. Measurements of cell andnuclear volumes were made in sections of fixed roots. Measurementsof nuclear volume, DNA content, and dry mass were made on isolatednuclei. Growth in the mitotic cycle was characterized by a doublingof DNA and nuclear dry mass and a five-fold increase of nuclearvolume. Since cell volume doubled, a differential hydrationof cytoplasm and nucleus is inferred. Post-mitotic growth wascharacterized by a four-fold or greater increase in cell volume,with vacuolation and a continued increase of cytoplasmic constituents,but a cessation of nuclear growth except by uptake of water;the only increase in nuclear dry matter appeared to be in cellsbecoming endopolyploid. The concentration of dry matter in thenucleus fell as the nuclei enlarged in the mitotic cycle andin post-mitotic growth. The relationships between the measuredparameters are examined to see whether they might be indicativeof causal relationships.     

Effect of calcium chloride on heavy metal induced alteration in growth and nitrate assimilation of Sesamum indicum seedlings

In the early growth phase of Sesamum indicum cv. PB-1, the decrease in fresh and dry mass was higher with 1.0 mM Cd²⁺ than with the same level of Pb²⁺ and Cu²⁺. Recovery from the metal stress was considerable in the root fresh weight and almost completely in the root dry weight when 10.0 mM (1.9 EC), calcium chloride was supplied to the growing seedlings along with the metal salts in various combinations. Accumulation of Pb²⁺, Cd²⁺ and Cu²⁺ was differential to the metals and the plant parts when supplied without or with 10.0 mM calcium chloride. The order of endogenous metal accumulation was Cu²⁺Cd²⁺Pb²⁺ and roots accumulated more metal than the leaves in the absence, as well as in the presence, of calcium chloride. Calcium chloride could recover loss of in vivo NRA in roots caused by either of the metal combinations, whereas the salt could recover the loss in leaf NRA caused only by Pb²⁺Cd²⁺ (1.0 mM each). Response of root and leaf NRA was on the other hand, different when the enzyme was assayed directly using an in vitro assay method, and the salt accelerated the loss in enzyme activity drastically. The organic-N content of root and leaf was, however, increased significantly (p < 0.001) with calcium chloride alone and with the metals supplied in various combinations. Our data indicate that instead of a high endogenous accumulation of Cu²⁺, Cd²⁺ and Pb²⁺ in roots and leaves the metal toxicity is recovered to a great extent in the presence of 10.0 mM calcium chloride in the root environment regarding growth and nitrate reduction of the roots and leaves of young sesame seedlings.