Effects of ethylene, kinetin, and calcium on growth and wall composition of pea epicotyls

Ethylene supplied with indoleacetic acid at 0.1 and 1 mum inhibited elongation and enhanced swelling in epicotyls of decapitated and derooted pea seedlings (Pisum sativum L., var. Alaska). These growth responses were correlated with the development of cell walls rich in weak acid-extractable materials and pectic uronic acids. Ethylene had no effect on the formation of hemicellulose, or hemicellulosic uronic acid. Ethylene stimulated the formation of residual materials at 0.1 mum indoleacetic acid but had little effect at 1 mum. With indoleacetic acid at 10 mum, ethylene modified neither the growth or wall composition appreciably. Growth and wall composition in intact seedlings were modified in similar fashion by ethylene. In intact seedlings ethylene promoted the development of walls high in weak acid-extractable materials and pectic uronic acid. These effects were less impressive in the first 24 hours than in the second 24 hours when the control plants suffered a net loss of these constituents. Ethylene considerably inhibited the formation of hemicellulose and residual wall materials in the apical sections but promoted it in the basal sections of the intact seedlings.Measurements of ethylene production by decapitated and derooted pea seedlings suggest that Ca(2+) and kinetin do not promote swelling through an effect on the formation of ethylene.We propose that cells of ethylene-treated pea epicotyls lack polarity because their walls are abnormally rich in pectic substances.     

Effects of calcium and kinetin on growth and cell wall composition of pea epicotyls

Kinetin and CaCl₂, in the presence of indoleacetic acid, promoted lateral expansion of epicotyls of decapitated and derooted Alaska pea seedlings (Pisum sativum L.) and inhibited their elongation. This growth response was correlated with the development of cell walls unusually rich in pectic uronic acids. Epicotyls in calcium-auxin solutions continued to enlarge and to add new wall material long after tissues in auxin only had stopped. Longitudinal enlargement, associated with the development of walls poor in pectic uronic acids, was favored by KCl, MgCl₂, and ethylenediaminetetraacetate. The last of these agents promoted the loss of ⁴⁵Ca from the epicotyls. Seedings grown in vermiculite moistened with CaCl₂, KCl, or MgCl₂ solutions did not differ in appearance or in the composition of their walls. They responded similarly to experimental treatment except that the decapitated epicotyls of the MgCl₂-grown plants suffered an absolute loss of pectic uronate when incubated in that salt.     

On the Nature and Origin of the Calcium Asymmetry Arising during Gravitropic Response in Etiolated Pea Epicotyls

Seven day old etiolated pea epicotyls were loaded symmetrically with ³H-indole 3-acetic acid (IAA) or ⁴⁵Ca²⁺, then subjected to 1.5 hours of 1g gravistimulation. Epidermal peels taken from top and bottom surfaces after 90 minutes showed an increase in IAA on the lower side and of Ca²⁺ on the upper side. Inhibitors of IAA movement (TIBA, 9-hydroxyfluorene carboxylic acid) block the development of both IAA and Ca²⁺ asymmetries, but substances known to interfere with normal Ca²⁺ transport (nitrendipine, nisoldipine, Bay K 8644, A 23187) do not significantly alter either IAA or Ca²⁺ asymmetries. These substances, however, are active in modifying both Ca²⁺ uptake and efflux through oat and pea leaf protoplast membranes. We conclude that the ⁴⁵Ca²⁺ fed to pea epicotyls occurs largely in the cell wall, and that auxin movement is primary and Ca²⁺ movement secondary in gravitropism. We hypothesize that apoplastic Ca²⁺ changes during graviresponse because it is displaced by H⁺ secreted through auxin-induced proton release. This proposed mechanism is supported by localized pH experiments, in which filter paper soaked in various buffers was applied to one side of a carborundum-abraded epicotyls. Buffer at pH 3 increases calcium loss from the side to which it is applied, whereas pH 7 buffer decreases it. Moreover, 10 micromolar IAA and 1 micromolar fusicoccin, which promote H⁺ efflux, increase Ca²⁺ release from pea epicotyl segments, whereas cycloheximide, which inhibits H⁺ efflux, has the reverse effect. We suggest that Ca²⁺ does not redistribute actively during gravitropism: the asymmetry arises because of its release from the wall adjacent to the region of high IAA concentration, proton secretion, and growth. Thus, the asymmetric distribution of Ca²⁺ appears to be a consequence of growth stimulation, not a critical step in the early phase of the graviresponse.     

Boron and calcium, essential inorganic constituents of pectic polysaccharides in higher plant cell walls

Among 16 essential elements of higher plants, Ca²⁺ and B have been termed as apoplastic elements. This is mainly because of their localization in cell walls, however, it has turned to be highly likely that these two elements significantly contribute to maintain the integrity of cell walls through binding to pectic polysaccharides. Boron in cell walls exclusively forms a complex with rhamnogalacturonan II (RG-II), and the B-RG-II complex is ubiquitous in higher plants. Analysis of the structure of the B-RG-II complex revealed that the complex contains two molecules boric acid, two molecules Ca²⁺ and two chains of monomeric RG-II. This result indicates that pectic chains are cross-linked covalently with boric acid at their RG-II regions. The complex was reconstitutedin vitro only by mixing monomeric RG-II and boric acid, however, the complex decomposed spontaneously unless Ca²⁺ was supplemented. Furthermore, the native complex decomposed when it was incubated withtrans-1,2-diaminocyclohexane-N, N, N′, N′-tetraacetic acid (CDTA) which chelates Ca²⁺. When radish root cell walls were washed with a buffered 1.5% (w/v) sodium dodesyl sulfate (SDS) solution (pH 6.5), 96%, 13% and 6% of Ca²⁺, B and pectic polysaccharides of the cell walls, respectively, were released and the cell wall swelled twice. Subsequent extraction with 50 mM CDTA (pH 6.5) of the SDS-washed cell walls further released 4%, 80% and 61% of Ca²⁺, B and pectic polysaccharides, respectively. Pectinase hydrolysis of the SDS-treated cell walls yielded a B-RG-II complex and almost all the remaining Ca²⁺ was recovered in the complex. This result suggests that cell-wall bound Ca²⁺ is divided into at least two fractions, one anchors the CDTA-soluble pectic polysaccharides into cell walls together with B, and the other may control the properties of the pectic gel. These studies demonstrate that B functions to retain CDTA-soluble pectic polysaccharides in cell walls through its binding to the RG-II regions in collaboration with Ca²⁺.     

Stimulation of ethylene production in the mung bean hypocotyls by cupric ion, calcium ion, and kinetin

The synergistic stimulation of ethylene production by kinetin and Ca²⁺ in hypocotyl segments of mung bean (Phaseolus aureus Roxb.) seedling was further studied. The requirement for Ca²⁺ in this system was specific. Except for Sr²⁺, which mimicked the effect of Ca²⁺, none of the following divalent cations, including Ba²⁺, Mg⁶⁺, Cu²⁺, Hg²⁺, Co²⁺, Ni²⁺, Sn²⁺, and Zn²⁺, showed synergism with kinetin on ethylene production. Fe²⁺, however, showed a slight synergism with kinetin. Some of them (Hg²⁺, Co²⁺, and Ni²⁺) had a strong inhibitory effect, while others (Zn²⁺, Mg²⁺, Sn²⁺, and Ba²⁺) had a slight or no inhibitory effect on ethylene production in the absence or presence of kinetin.     

Interaction of kinetin and calcium in relation to their effect on stimulation of ethylene production

Application of kinetin and Ca²⁺ caused a striking synergistic increase in ethylene production by mung bean (Phaseolus aureus Roxb) hypocotyl segments. The effect of kinetin on Ca²⁺ uptake and of Ca²⁺ on the uptake and metabolism of kinetin in relation to their effect on ethylene production was studied. Tracer experiments showed that kinetin greatly increased the uptake of ⁴⁵Ca²⁺ after 6 hours of incubation. Reciprocally, Ca²⁺ stimulated the uptake of kinetin-8-¹⁴C and remarkably enhanced the metabolism of kinetin-8-¹⁴C into several polar metabolites. Consequently, the quantity of free kinetin-8-¹⁴C remaining in Ca²⁺-treated segments was much less than in control segments. A possible mechanism accounting for the synergism between kinetin and calcium on ethylene production is discussed.     

On the role of calcium in indole-3-acetic acid movement and graviresponse in etiolated pea epicotyls

To determine whether Ca²⁺ plays a special role in the early graviresponse of shoots, as has been reported for roots, we treated etiolated pea epicotyls with substances known to antagonize Ca²⁺ (La³⁺), to remove Ca²⁺ from the wall (spermidine, EGTA), to inhibit calmodulin mediated reactions (chlorpromazine), or to inhibit IAA transport (TIBA). We studied the effect of these substances on IAA and Ca²⁺ uptake into 7 mm long subapical 3rd internode etiolated pea epicotyl sections and pea leaf protoplasts, on pea epicotyl growth, and graviresponse and on lateral IAA redistribution during gravistimulation.Our results support the view that adequate Ca²⁺ in the apoplast is required for normal IAA uptake, transport and graviresponse. Experiments with protoplasts indicate that Ca²⁺ may be controlling a labile membrane porter, possibly located on the external surface of cell membrane, while inhibitor experiments suggest that calmodulin is also implicated in both the movement of IAA and graviresponse. Since a major transfer of Ca²⁺ through free space during graviresponse has not yet been demonstrated, and since inhibition of calcium channels does not affect IAA redistribution (Migliaccio and Galston, 1987, Plant Physiology 85:542), we conclude that no clear evidence links prior Ca²⁺ movement with IAA redistribution during graviresponse in stems.Abbreviations IAA indole-3-acetic acid - CPZ chlorpromazine - EGTA ethylene glycol bis-(aminoethyl ether) N, N, N¹, N¹-tetracetic acid - G C gravicurvature The research was supported by NASA grant NSG-7290 to AWG.     

Polyamines and pectins. II. Modulation of pectic-signal transduction

A previous study had shown that polyamines adsorb selectively on plant cell walls according to the valence of the polyamine (Messiaen et al. 1997, Plant Physiol. 113: 387–395). In this study, the adsorption of polyamines onto isolated carrot cell walls and onto pure polygalacturonic acid was investigated in the presence of competing mono- and divalent cations (Na⁺ and Ca²⁺). Putrescine (Put²⁺) was unable to remove all the calcium (Ca²⁺) from cell walls or from polygalacturonic acid. Spermidine (Spd³⁺) and spermine (Spm⁴⁺) adsorbed on all galacturonates and were able to remove Ca²⁺ completely from both the walls and the pure polygalacturonates. Therefore, Spd³⁺ and Spm⁴⁺, unlike Put²⁺, prevented polygalacturonic acid from adopting the Ca²⁺-induced supramolecular conformation recognized by the 2F4 anti-pectin monoclonal antibody. We show that the signal transduction cascade otherwise initiated in plant cells by Ca²⁺-bound α-1,4-oligogalacturonides was indeed blocked by both Spd³⁺ and Spm⁴⁺, but not by Put²⁺. The mobilization of cytosolic free Ca²⁺ and the cytosolic acidification usually observed after treatment with pectic fragments did not occur and the subsequent activation of phenylalanine ammonia-lyase was suppressed. It is hypothesized that the disruption by Spd³⁺ and Spm⁴⁺ of the Ca²⁺-induced supramolecular conformation of pectic fragments was the cause of the inhibition of the pectic signal. We conclude that polyamines can act on plant cell physiology by modulating the transduction of the pectic signal. Received: 14 March 1998 / Accepted: 28 October 1998     

Inhibition of ethylene production by cobaltous ion

The effect of Co²⁺ on ethylene production by mung bean (Phaseolus aureus Roxb.) and by apple tissues was studied. Co²⁺, depending on concentrations applied, effectively inhibited ethylene production by both tissues. It also strongly inhibited the ethylene production induced by IAA, kinetin, IAA plus kinetin, Ca²⁺, kinetin plus Ca²⁺, or Cu²⁺ treatments in mung bean hypocotyl segments. While Co²⁺ greatly inhibited ethylene production, it had little effect on the respiration of apple tissue, indicating that Co²⁺ does not exert its inhibitory effect as a general metabolic inhibitor. Ni²⁺, which belongs to the same group as Co²⁺ in the periodic table, also markedly curtailed both the basal and the induced ethylene production by apple and mung bean hypocotyl tissues.     

Pectic polysaccharide breakdown of cell walls in cucumber roots grown with calcium starvation

Pectic polysaccharides from the roots of cucumber (Cucumis sativus L.) grown in liquid culture medium with or without calcium (1 mm CaCl₂) were studied after extraction successively by hot water and Na hexametaphosphate solution. The Ca²⁺ starvation-treatment caused a striking reduction in content of extracted pectic polysaccharide; from an equivalent weight of cell walls, only 33.1% of the control level was extracted from root cell walls of plants cultured under Ca²⁺ deficiency. The extracted pectic polysaccharides were fractionated into neutral and acidic polymers by a DEAE-Sephadex column. The acidic polymers, which represented more than 76% of the yield, appeared to be a major fraction of extracted pectic polysaccharides. The changes of molecular size and glycosyl residue composition of this fraction were compared for the control and Ca²⁺-deprived samples. The results indicate that Ca²⁺ deficiency caused structural changes which could involve both branching pattern and extent of contiguous galacturonosyl units in the water-solubilized pectic polysaccharides. Ca²⁺ starvation also led to a notable decrease in molecular size of the hexametaphosphate-solubilized polysaccharides and, to a lesser extent, of the water-solubilized fraction as well. In addition, polygalacturonase activity in tissue homogenates increased remarkably with the Ca²⁺ deficiency, whereas β-galactosidase activity did not undergo a change. Thus, it appears that one major effect of Ca²⁺ deprivation was to stimulate polygalacturonase activity, an effect which could be involved in the control of the breakdown of pectic polysaccharides in the cell walls.     

Composition of cell walls from cotyledons of Pisum sativum,Vicia faba and Glycine max

Cell walls from cotyledons of smooth field pea, broad bean and soya bean contain ca 55% pectic polysaccharides associated with 9% cellulose. Arabinose is the major pectic sugar of pea and broad bean walls whereas soya bean pectic polymers are constituted of galactose and arabinose in the ratio (2:1). Galacturonic acid represents ca 20% of the walls. In addition, pea and broad bean cell walls contain, respectively, 12% and 6% of non-starchy and non-cellulosic glucans bearing 4,6-linked and 3-linked glycosyl units. EDTA-soluble acidic pectic substances are distinct rhamnogalacturonans bearing decreasing proportions of interrupting rhamnose from highly interrupted moieties to nearly homogenous homogalacturonans. Pea and broad bean rhamnogalacturonans are associated with arabinose-containing polymers of average DP ca 30–35 whereas soya bean ones have side chains of arabinose and galactose of DP ca 40.     

EFFECT OF GIBBERELLIC ACID ON ELONGATION AND NUCLEIC ACID SYNTHESIS IN ETIOLATED ALASKA PEA EPICOTYL

The following results were obtained using etiolated Alaska pea epicotyls. Gibberellic acid (GA) had the remarkable effect on the elongation in part I (elongating region) of epicotyls, whereas it had little effect on that in part II (mature region) of epicotyls. In cortex of part I and II of epicotyls, the cell number in longitudinal direction was hardly affected by GA. On the increase in width of epicotyls, GA was hardly effective in any parts of epicotyls. In both part I and II GA enhanced the incorporation of ³²P into all nucleic acid fractions prepared by methylated albumin kieselguhr (MAK) columns, i.e. sRNA, DNA and rRNA + mRNA. In part I the net increase in DNA and RNA content during the incubation period was slightly promoted by GA, whereas in part II the net decrease in both nucleic acids content was slightly promoted by GA. The relationship between GA-induced growth and nucleic acid synthesis is discussed.     

Relations Between Indoleacetic Acid, Calcium Ions and Ethylene in the Regulation of Growth and Cell Wall Composition in Picea abies

Effects of indoleacetic acid, calcium ions and ethylene on thegrowth of and deposition of different cell wall fractions inthe hypocotyl of Norway spruce (Picea abies (L.) Karst.) seedlingswere investigated. Indoleacetic acid progressively stimulated cellulose depositionas the amount of added Ca²⁺ increased. In contrast, indoleaceticacid promoted lignification and the deposition of non-cellulosicpolysaccharides only in the absence of added Ca²⁺ . When Ca²⁺was added, the indoleacetic acid effect disappeared. Similarly,indoleacetic acid promoted non-cellulosic polysaccharide depositiononly in the absence of ethylene. At increasing ethylene levelsthe effect of indoleacetic acid on non-cellulosic polysaccharidedeposition disappeared and indoleacetic acid instead promotedcellulose deposition. The response to indoleacetic acid depended on the Ca²⁺ concentrationand on the rate of ethylene production. The relationship betweenindoleacetic acid and Ca²⁺ seemed complex, but clearly indoleaceticacid could partially overcome a Ca²⁺ deficiency. The resultssuggest that ethylene may be a factor of particular importancefor the type of polysaccharide deposition during cell wall formation. Key words: Calcium, cell wall, conifers, ethylene, indoleacetic acid     

Stimulation of Root Elongation and Curvature by Calcium

Ca²⁺ has been proposed to mediate inhibition of root elongation. However, exogenous Ca²⁺ at 10 or 20 millimolar, applied directly to the root cap, significantly stimulated root elongation in pea (Pisum sativum L.) and corn (Zea mays L.) seedlings. Furthermore, Ca²⁺ at 1 to 20 millimolar, applied unilaterally to the caps of Alaska pea roots, caused root curvature away from the Ca²⁺ source, which was caused by an acceleration of elongation growth on the convex side (Ca²⁺ side) of the roots. Roots of an agravitropic pea mutant, ageotropum, responded to a greater extent. Roots of Merit and Silver Queen corn also responded to Ca²⁺ in similar ways but required a higher Ca²⁺ concentration than that of pea roots. Roots of all other cultivars tested (additional four cultivars of pea and one of corn) curved away from the unilateral Ca²⁺ source as well. The Ca²⁺-stimulated curvature was substantially enhanced by light. A Ca²⁺ ionophore, A23187, at 20 micromolar or abscisic acid at 0.1 to 100 micromolar partially substituted for the light effect and enhanced the Ca²⁺-stimulated curvature in the dark. Unilateral application of Ca²⁺ to the elongation zone of intact roots or to the cut end of detipped roots caused either no curvature or very slight curvature toward the Ca²⁺. Thus, Ca²⁺ action on root elongation differs depending on its site of application. The stimulatory action of Ca²⁺ may involve an elevation of cytoplasmic Ca²⁺ in root cap cells and may participate in root tropisms.     

Borate-Rhamnogalacturonan II Bonding Reinforced by Ca2+ Retains Pectic Polysaccharides in Higher-Plant Cell Walls

The extent of in vitro formation of the borate-dimeric-rhamnogalacturonan II (RG-II) complex was stimulated by Ca²⁺. The complex formed in the presence of Ca²⁺ was more stable than that without Ca²⁺. A naturally occurring boron (B)-RG-II complex isolated from radish (Raphanus sativus L. cv Aokubi-daikon) root contained equimolar amounts of Ca²⁺ and B. Removal of the Ca²⁺ by trans-1,2-diaminocyclohexane-N,N,N′,N′-tetraacetic acid induced cleavage of the complex into monomeric RG-II. These data suggest that Ca²⁺ is a normal component of the B-RG-II complex. Washing the crude cell walls of radish roots with a 1.5% (w/v) sodium dodecyl sulfate solution, pH 6.5, released 98% of the tissue Ca²⁺ but only 13% of the B and 22% of the pectic polysaccharides. The remaining Ca²⁺ was associated with RG-II. Extraction of the sodium dodecyl sulfate-washed cell walls with 50 mm trans-1,2-diaminocyclohexane-N,N,N′,N′-tetraacetic acid, pH 6.5, removed the remaining Ca²⁺_, 78% of B, and 49% of pectic polysaccharides. These results suggest that not only Ca²⁺ but also borate and Ca²⁺ cross-linking in the RG-II region retain so-called chelator-soluble pectic polysaccharides in cell walls.Boron (B) is an essential element for higher plant growth, although its primary function is not known (Loomis and Durst, 1992). Determining the sites of B in cells is required to identify its function. In cultured tobacco cells more than 80% of cellular B is in the cell wall (Matoh et al., 1993), whereas the membrane fraction (Kobayashi et al., 1997) and protoplasts (Matoh et al., 1992) do not contain a significant amount of B. In radish (Raphanus sativus L. cv Aokubi-daikon) root cell walls, B cross-links two RG-II regions of pectic polysaccharides through a borate-diol ester (Kobayashi et al., 1995, 1996). The association of B with RG-II has been confirmed in sugar beet (Ishii and Matsunaga, 1996), bamboo (Kaneko et al., 1997), sycamore and pea (O''Neill et al., 1996), and red wine (Pellerin et al., 1996). In cultured tobacco cells the B associated with RG-II accounts for about 80% of the cell wall B (Kobayashi et al., 1997) and RG-II may be the exclusive carrier of B in higher plant cell walls (Matoh et al., 1996). Germanic acid, which partly substitutes for B in the growth of the B-deprived plants (Skok, 1957), also cross-links two RG-II chains (Kobayashi et al., 1997). These results suggest that the physiological role of B is to cross-link cell wall pectic polysaccharides in the RG-II region and thereby form a pectic network.It is believed that in the cell wall pectic polysaccharides are cross-linked with Ca²⁺, which binds to carboxyl groups of the polygalacturonic acid regions (Jarvis, 1984). Thus, the ability of B and Ca²⁺ to cross-link cell wall pectic polysaccharides needs to be evaluated. In this report we describe the B-RG-II complex of radish root and the role of B-RG-II and Ca²⁺ in the formation of a pectic network.     

Influence of calcium and magnesium on ethylene production by apple tissue slices

The decline in ethylene production in apple (Pyrus malus L. cv. Golden Delicious) tissue slices during 24 hours incubation in 600 millimolar sorbitol and 10 millimolar 2-(N-morpholino)ethanesulfonic acid buffer (pH 6.0) is recognized as a senescent phenomenon. The inclusion of very high concentrations (100 millimolar) of Ca²⁺, Mg²⁺, or Ca²⁺ plus Mg²⁺ severely inhibited ethylene production during the first 6 hours of incubation. However, after 6 hours and up to 24 hours the ethylene-forming system was stablized. These high concentrations of Ca²⁺, Mg²⁺, or Ca²⁺ plus Mg²⁺ virtually eliminated lipid peroxidation and protein leakage from these slices. Also conversion of 1-aminocyclopropane-1-carboxylic-1-acid to ethylene and the influence of indoleacetic acid on ethylene production was stabilized after 24 hours of incubation by these high concentrations of Ca²⁺, Mg²⁺, and Ca²⁺ plus Mg²⁺. Addition of divalent ionophores severely inhibited ethylene production, but this inhibition was prevented by Ca²⁺ in concentrations greater than the ionophore. These data suggest that the loss of ethylene production by aging tissue slices results from degradation of membranes. They support previous work that indicates that the ethylene-forming system, perhaps the segment of the pathway from 1-aminocyclo-propane-1-carboxylic-1-acid to ethylene, resides in the plasma membrane.     

Polar Calcium Flux in Sunflower Hypocotyl Segments : II. The Effect of Segment Orientation, Growth, and Respiration

Calcium flux in sunflower (Helianthus annuus L. cv Russian mammoth) hypocotyl was measured with a Ca²⁺ electrode as the increase or decrease in Ca²⁺ in an aqueous solution (10 micromolar CaCl₂) in contact with either the basal or apical end of 20 millimeter segments. Ca²⁺ efflux was significantly higher at the apical end compared with the basal end; this apparent polarity was maintained even when the segments were inverted. No significant difference was observed in the cation exchange capacity of apical and basal cell walls that could explain the difference in Ca²⁺ efflux at opposite ends of the hypocotyl segment. The presence of exogenous indoleacetic acid (IAA) in the segment medium resulted in the promotion of both Ca²⁺ efflux and segment elongation. However, osmotic inhibition of the IAA-induced elongation did not result in inhibiting the IAA-induced Ca²⁺ efflux. Ca²⁺ efflux was inhibited by cyanide. Lowering the temperature from 25°C also caused the gradual reduction of Ca²⁺ efflux; at 5°C the hypocotyl segments showed a net absorption of Ca²⁺ from the segment medium. These findings support the suggestion that: (a) the observed Ca²⁺ efflux in hypocotyl segments is probably the manifestation of the system which maintains the transmembrane Ca²⁺ gradient at the cellular level. (b) The acropetal polarity of Ca²⁺ efflux may be the result of the involvement of Ca²⁺ in the basipetal transport of IAA.