Acidification of the Medium Associated with Normal and Fusicoccin-Induced Seed Germination

Fusicoccin, a toxin stimulating cell enlargement and inducing proton extrusion in various plant tissues, has been shown to replace kinetin, gibberellic acid and red light in breaking seed dormancy. It also removes the inhibitory effect of abscisic acid. The present data also show that the stimulating effect of fucicoccin on embryo growth of decoated radish (Raphanus sativus L.) and maize (Zea mays) seeds and on the development of maize embryos is accompanied by an early, significant acidification of the medium. Acidification of the medium is also observed when fusicoccin reverses the abscisic acid-induced inhibition of germination. These results support the hypothesis that the mode of action of fusicoccin in promoting germination involves, as in stimulation of cell enlargement, the activation at the cell membrane level of proton extrusion processes. The physiological significance of fusicoccin-induced release of protons at the onset of germination is discussed in comparison with the results concerning the mechanism of action of fusicoccin on cell enlargement in other plant materials.     

Effects of ophiobolin B on cell enlargement and H+/K+ exchange in maize coleoptile tissues

Ophiobolin B (OPH B), a sesterpene metabolite of Helminthosporium oryzae, inhibits proton extrusion from maize coleoptiles. Moreover OPH B counteracts the biological activity of fusicoccin (FC), another terpenoid toxin produced by Fusicoccum amygdali having a similar basic chemical structure: OPH B inhibits FC-promoted proton extrusion, potassium uptake and cell enlargement.The findings suggest that the effect of OPH B in stimulating electrolites, glucose and aminoacid leakage, reported in a previous paper, can be explained by the capacity of the toxin to inhibit proton extrusion.Abbreviations FC fusicoccin - OPH B ophiobolin B     

The effects of podolactone-type inhibitors on fusicoccin-induced growth and proton efflux

Podolactones A and E and lycoritidinol inhibit growth induced by fusicoccin in dwarf pea ( Pisum sativum L.) hooks and tips; however the inhibition is reduced at the highest fusicoccin concentrations. In short term experiments (3 h) on pea stem tissues, growth and proton efflux induced by fusicoccin are only partially inhibited by podolactone A and lycoricidinol. Auxin-induced growth and proton efflux are completely suppressed by 10 μM lycoricidinol. The inhibitors do not affect ATP levels.     

Comparative analysis of the effects of fusicoccin (FC) and of its derivative dideacetylfusicoccin (DAF) on maize leaves and roots

In maize ( Zea mays L. cv. DEKALB XL 640) leaf discs or root segments fusicoccin (FC) is by about 5-10 times more active than its derivative dideacetylfusicoccin (DAF) in stimulating proton extrusion and the hyperpolarization of the transmembrane electrical potential (PD). Also the uptake by leaf discs in liquid medium and the affinity for a receptor present in cell free membrane preparations are by 3–5 times greater for FC than for DAF, while a much greater difference (by about two orders) in activity between the two substances is observed for their effects on leaf transpiration.
FC reaches in the leaf tissue a concentration much higher than that of DAF. This is interpreted as due to the higher activity of FC in inducing stomata opening, thus accelerating the transpiratory water flow. The long distance translocation of both FC and DAF mainly depends on mass flow. Thus the initial stimulus on transpiration would induces an increase in concentration of the active substance in the reactive tissue, in a kind of autocatalytic cycle, resulting in the amplification of the difference in activity at cell level between the two toxins.
The data on the promotion of H⁺ extrusion and the hyperpolarization of PD confirm the correlation and thus the possible cause-effect relationship between FC (or its less active derivative DAF) binding to a receptor at the membrane, and the functions studied. The relationships between the "pathological" (transpiration and wilting) and the "physiological" (electrogenic proton secretion) effects of FC and DAF are also in agreement with the view that all of the known effects of FC and of its active derivatives can be explained as consequences of the activation of electrogenic proton extrusion.     

Effects of Ni2+ on proton extrusion, dark CO2 fixation and malate synthesis in maize roots

The presence of Ni²⁺ in the incubation medium of maize root segments ( Zen mays L. cv. Dekalb XL 640) induces an early and significant enhancement of the rate of proton extrusion both in the absence and presence of fusicoccin; with time, an inhibition of proton extrusion and a leakage of K⁺ appear. The inhibition of proton extrusion is accompanied by a decrease in the dark CO₂ fixation and by a decrease in the level of malate in the cells. Ni²⁺ inhibits in vitro phosphoenolpyruvale carboxylase activity of maize roots. The data indicate a correlation between the operativity of the proton pump and that of the malate-pH stat mechanism for the homeostasis of cytoplasmic pH.     

Influence of Temperature on Proton Secretion and Hexacyanoferrate (III) Reduction of Zea mays L. Roots

Responses of potassium hexacyanoferrate (III) [HCF(III)] reduction and net proton secretion by Zea mays L. cv Goldprinz roots to changes in ambient temperature were investigated. Arrhenius plots of proton secretion and redox activity showed a constant slope between 5 and 20[deg]C, indicating that reaction kinetics do not change. Proton secretion without HCF(III) was strongly temperature dependent. This dependence was not altered when H+ efflux was stimulated by fusicoccin or by increased K+ concentration. The temperature coefficient for HCF(III) reduction was low, indicating that the velocity of this reaction was limited by apoplastic diffusion of the ferric complex. In the presence of HCF(III) but not hexacyanoferrate (II), temperature dependence of proton efflux markedly declined, indicating fundamental changes in the process(es) contributing to net proton secretion. It is concluded that HCF(III) establishes a proton extrusion path that is directly linked with the reduction reaction.     

Proton extrusion in seed coats of Phaseolus vulgaris L.

Abstract. The present investigations were designed to identify proton pumps in seed coats of Phaseolus vulgaris L. Vacated seed-coat halves were exposed to bathing solutions with indicators for proton pump action and the pH changes in the media were measured. Fusicoccin increased the rate of proton extrusion from the seed coats. Orthovanadate and abscisic acid retarded the proton extrusion evoked by fusicoccin. Abolition of the proton extrusion by parachloromercuriphenylsulphonic acid was partially reversed by diethioerythritol. The extrusion was stimulated by high osmolarities (100 mol m⁻³ sorbitol), potassium ions (100 mol m⁻³ KCI) and light. Old seed coats reacted more rapidly to fusicoccin treatments than young ones. Proton pumping in seed coats and cotyledons showed differential responses to fusicoccin, K⁺ and sucrose. In contrast to seed coats, medium acidification by cotyledons was prohibited by addition of sucrose. The significance of proton pumps for photosynthate transfer in vivo is discussed.     

Influence of phytohormones and other effectors on proton extrusion by isolated protoplasts from rape leaves

The roles of phytohormones and fusicoccin in H⁺ extrusion by isolated protoplasts from rape leaves ( Brassica napus L. cv. Belinda) were investigated and compared to results obtained with leaf segments of the same plants. Net H⁺ release by protoplasts, which was at least partly due to ATPase activity, was enhanced by 10 μ M indole-3-acetic acid and reduced by 20 μ M abscisic acid, whereas fusicoccin (10 μ M ), brassinosteroid (3 μ M ), kinetin (20 μ M ) and gibberellic acid (10 μ M ) had no effect. Hormone effects and H⁺ release were not detectable with leaf segments from the same plants. However, using field-grown plants, indole-3-acetic acid and especially fusicoccin stimulated the acidification of the external medium by leaf segments. Hormonecontrolled H⁺ release by leaf cells is interpreted as the first step in acid-triggered and turgor-regulated cell growth.     

Inhibition by fusicoccin of germination of pea seeds

Fusicoccin inhibits the germination of pea (Pisum sativum L. cv Progress 9) seeds by decreasing the growth of the embryonal axis and by stimulating the fresh weight increase of the cotyledons. The growth of isolated embryonal axes in the presence of sucrose and KCl is stimulated by fusicoccin. The effect of fusicoccin on the seeds is not counteracted by sucrose and KCl. Fusicoccin promotes preferentially in the cotyledons a hyperpolarization of the transmembrane electric potential and an increase in the uptake capacity, suggesting the reinforcement of the sink strength of the cotyledons in comparison with the one of the embryonal axis and therefore the inhibition of translocation from the cotyledons of some substance necessary for the growth of the embryonal axis.     

Induction of elongation in maize coleoptiles by hexachloroiridate and its interrelation with auxin and fusicoccin action

The demonstration of an auxin-stimulated NADH-oxidase in the plasma membrane (Brightman et al. 1988. Plant Physiol. 86: 1264–1269) has led to the suggestion that the plasma membrane redox system is involved in the mechanism of auxin action. To evaluate the relevance of this concept in vivo, the influence of micromolar concentrations of hexachloroiridate (IV), an impermeable electron acceptor for the plant plasma membrane redox system, on elongation growth of excised, abraded maize coleoptile ( Zea mays L. cv. Golden Bantam) segments was studied. It was found that the substance induced a rapid growth response if the experiment was carried out in an unbuffered solution. This effect was entirely prevented by a 2 m M phosphate buffer. Nevertheless, the acid-growth-theory does not seem sufficient to explain this effect, since proton extrusion is induced without a lag, whereas increased growth rates commence after a lag phase of 40 min.
If growth is stimulated by a pretreatment with fusicoccin or auxin, hexachloroiridate IV transiently inhibits growth. The kinetics of the response are then determined by the concentrations of hexachloroiridate and auxin or fusicoccin. These results are compatible with the view that the plasma membrane redox system is somehow involved in the control of elongation growth.     

Effect of Indoleacetic Acid- and Fusicoccin-Stimulated Proton Extrusion on Internal pH of Pea Internode Cells

Using ³¹P nuclear magnetic resonance spectroscopy, we followed cytoplasmic and vacuolar pH in pea (Pisum sativum cv Alaska) internode segments during treatment with indoleacetic acid (IAA) or fusicoccin (FC) in continuously perfused, oxygenated buffer. Although IAA and FC induced normal H⁺ extrusion, elongation, and glucan synthase activity responses during the measurements, neither the cytoplasmic nor the vacuolar pH showed significant change at any time between 5 minutes and 1 to 3 hours of treatment. Changes in cytoplasmic pH as small as about 0.04 pH unit were detected after treatment with 1-naphthyl acetate. Therefore, cytoplasmic pH changes do not appear to mediate IAA or FC stimulation of H⁺ extrusion or other metabolic responses to these effectors.     

Effects of canavanine on IAA- and fusicoccin-stimulated cell enlargement, proton extrusion and potassium uptake in maize coleoptiles

In maize coleoptiles (Zea mays F₁ XL 640A, cv. Dekalb) canavanine and cycloheximide strongly and simultaneously inhibit cell elongation, H⁺ extrusion and K⁺ uptake, induced by IAA. They inhibit also, although to a much lesser degree, the same phenomena induced by fusicoccin. Cycloheximide severely depresses the incorporation of leucine into proteins, while canavanine leaves leucine incorporation almost unchanged. The data confirm that elongation, H⁺ extrusion and K⁺ uptake can be regarded as correlated processes; they also support the view that normal protein synthesis is essential for IAA-induced growth, while this requirement is only partial in growth stimulated by fusicoccin.     

Modulation of plasma membrane H+-ATPase activity differentially activates wound and pathogen defense responses in tomato plants.

Systemin is an important mediator of wound-induced defense gene activation in tomato plants, and it elicits a rapid alkalinization of the growth medium of cultured Lycopersicon peruvianum cells. A possible mechanistic link between proton fluxes across the plasma membrane and the induction of defense genes was investigated by modulating plasma membrane H+-ATPase activity. Inhibitors of H+-ATPase (erythrosin B, diethyl stilbestrol, and vanadate) were found to alkalinize the growth medium of L. peruvianum cell cultures and to induce wound response genes in whole tomato plants. Conversely, an activator of the H+-ATPase (fusicoccin) acidified the growth medium of L. peruvianum cell cultures and suppressed systemin-induced medium alkalinization. Likewise, in fusicoccin-treated tomato plants, the wound- and systemin-triggered accumulation of wound-responsive mRNAs was found to be suppressed. However, fusicoccin treatment of tomato plants led to the accumulation of salicylic acid and the expression of pathogenesis-related genes. Apparently, the wound and pathogen defense signaling pathways are differentially regulated by changes in the proton electrochemical gradient across the plasma membrane. In addition, alkalinization of the L. peruvianum cell culture medium was found to depend on the influx of Ca2+ and the activity of a protein kinase. Reversible protein phosphorylation was also shown to be involved in the induction of wound response genes. The plasma membrane H+-ATPase as a possible target of a Ca2+-activated protein kinase and its role in defense signaling are discussed.     

Gibberellin structure and function: biological activity and competitive inhibition of gibberellin 2- and 3-oxidases

Some gibberellin (GA) analogues, especially with C-16,17 modifications of GA(5), can inhibit growth of plants apparently by acting as competitors with the endogenous substrate of GA biosynthetic enzymes. Here, we directly confirm the competitive action of GA derivatives but also show that some analogues may retain significant bioactivity. A recombinant 3-oxidase from pea, which converts GA(20) to bioactive GA(1), was inhibited by GA(5), and 16,17-dihydro-GA(5) derivatives, especially if the C-17 alkyl chain length was increased by up to three carbons or if the C-13 hydroxyl was acetylated. Genetic confirmation that GA(5) analogues target 3-oxidases in vivo was provided by comparing the growth response of a WT (LE) pea with a 3-oxidase mutant (le-1). Two pea 2-oxidases that inactivate bioactive GAs, were inhibited by GA(1) and GA(3) but were generally insensitive to GA(5) analogues. alpha-Amylase production by barley half-seeds in response to GA analogues provided a method to study their action when effects on GA biosynthesis were excluded. This bioactivity assay showed that 16,17-dihydro GA(5) analogues have some inherent activity but mostly less than for GA(5) (5-50-fold), which in turn was 100-fold less active than GA(1) and GA(3). However, although C-17 alkyl derivatives with one or two added carbons showed little bioactivity and were purely 3-oxidase inhibitors, adding a third carbon (the 17-n-propyl-16,17-dihydro GA(5) analogue) restored bioactivity to that of GA(5). Furthermore, this analogue has lost its capacity to inhibit stem elongation of Lolium temulentum (Mander et al., Phytochemistry 49:1509-1515, 1998a), although it strongly inhibits the 3-oxidase. Thus, the effectiveness of a GA derivative as a growth retardant will reflect the balance between its bioactivity and its capacity to inhibit the terminal enzyme of GA biosynthesis. The weaker growth inhibition in dicots including pea (approximately 10%) than in monocots such as L. temulentum (>35%) is suggestive of taxonomic differences in the bioactivity of GAs and/or their effects on GA biosynthesis.     

Effects of 2-iodobenzanilide on potassium uptake, H+ extrusion and K+-stimulated ATPase of corn roots

The carboxanilide systemic fungicide 2-iodobenzanilide (2-IB) after 2 h pretreatment at 0.25 m M inhibited K⁺ and SO₄^2- uptake by excised corn roots ( Zea mays L., cv. Dekalb 342) up to ca 70 and 40%, respectively. Proton extrusion from corn roots was also reduced by ca 50% after 1 h contact, and the microsomal K⁺-stimulated ATPase activity from corn roots and pea stems ( Pisum sativum L., cv. Alaska) inhibited by 50 and 72%, respectively. In contrast, the Mg²⁺-ATPase activities of microsomes and mitochondria at pH 6.0 and 8.7, respectively, were unaffected. After 2 h of preincubation with 0.25 m M 2-IB, O₂ consumption by corn roots and pea stems was inhibited by 12 and 18%, respectively. ATP content of corn roots was not altered by 2-IB treatment. Therefore, energy availability "in vivo" was unaffected and the primary effect on corn roots is suggested to be at the plasmalemma ATPase which forms the proton gradient.
With isolated pea stem mitochondria, 0.25 m M 2-IB inhibited O₂ consumption by ca 60% when NADH or malate plus pyruvate were added as substrates; when succinate was used O₂ consumption was unaffected. The mode of action on isolated mitochondria was different from that shown for carboxin and also formerly attributed to the whole class of carboxanilide fungicides.     

Proton excretion and cell expansion in bean leaves

Light-induced expansion of Phaseolus vulgaris L. leaf cells is accompanied by increased cell-wall plasticity. The possibility that leaf-cell walls are loosened by excreted protons has been investigated. First, light causes acidification, detected at the leaf surface, within 5–15 min. Growth starts 10–20 min after exposure to light. Second, exogenous acid induces loosening of isolated leaf cell walls. Third, infiltration of the tissue with a neutral buffer inhibits light-induced growth. Fourth, fusicoccin stimulates growth of as well as H⁺ excretion by bean leaf cells, without light. These findings show that the acid-growth theory is applicable to light-induced growth of leaf cells, and indicate that light-induced proton excretion initiates cell enlargement in leaves.Abbreviations FC fusicoccin - RL red light - WEx wall extensibility - WL white light     

不同盐处理对玉米幼苗根系质子分泌及细胞膜透性的影响

以玉米品种郑单958为实验材料,分别用100 mmol/L NaCl、100 mmol/L KCl和50 mmol/L Na2CO3处理其幼苗3 d,研究不同盐类对玉米根系质子分泌和细胞膜透性的影响.结果表明:不同盐处理都显著抑制玉米幼苗根系的生长,抑制程度依次为Na2CO3>KCl>NaCl;不同盐处理均使玉米幼苗根系Na 含量显著增加,NaCl和Na2CO3处理显著降低根系K 含量而导致其Na /K 升高,但KCl处理却显著提高根系K 含量使其Na /K 降低;不同盐处理均能显著增加细胞膜透性而降低根系质子分泌能力,影响程度依次为Na2CO3>KCl>NaCl.研究发现,相同阳离子浓度条件下,KCl处理对玉米根系质子分泌的抑制作用强于NaCl,碱性盐的抑制作用大于中性盐;盐胁迫可能通过改变玉米幼苗根系质膜的稳定性来影响质子分泌,从而抑制根系生长.     

The role of cell wall synthesis in sustained auxin-induced growth

The dependence of auxin-induced growth on continued cell wall synthesis was investigated in stem segments of etiolated pea ( Pisum sativum L. cv. Alaska) seedlings using the cell wall synthesis inhibitors monensin and 2,6-dichlorobenzonitrile (DCB). Monensin (5 μ M ) potently inhibited indole-3-acetic acid (IAA)-induced growth, particularly during the second hour of treatment, whereas growth in fusicoccin (FC) was inhibited much less effectively. Incorporation of [¹⁴C]-glucose into both matrix and cellulose fractions of the wall showed a sharp increase beginning after about 60 min, this rise being promoted by both IAA and FC. Monensin inhibited this rise in incorporation of label and completely removed the promotion of this by IAA, although some promotion by FC remained. Monensin inhibited incorporation into cellulose in a manner similar to that into matrix, but the use of the apparently specific cellulose synthesis inhibitor DCB showed that cellulose synthesis could be strongly inhibited without effect on growth, at least in the short term. The results support the view that sustained auxin-induced growth depends upon the incorporation of new matrix cell wall components into the wall.     

Effect of fusicoccin and gibberellic acid on primary dormant Avena fatua caryopses

Fusicoccin induced germination in dormant and partially afterripened dormant caryopses of Avena fatua L. The rate of caryopsis germination was slower and final percentage germination lower in the highly dormant inbred line M73 at a given concentration of fusicoccin than in the dormant caryopses of line AN265. Gibberellic acid was more effective than fusicoccin in breaking dormancy in both lines. Promotion of germination of dormant caryopses by fusicoccin was inhibited by a 6-day pretreatment with (2-chloroethyl)trimethylammonium chloride.
The basal rate of proton efflux from embryos isolated from dormant and fully afterripened line AN265 caryopses was similar. Addition of fusicoccin increased the rate of proton efflux from the isolated embryos of dormant and afterripened caryopses by nearly 400%. Gibberellic acid had no effect on the rate of proton extrusion. The uptake of ⁸⁶Rb⁺ in dormant and afterripened A. fatua embryos was similar after a 2 h uptake period. The addition of fusicoccin to the medium doubled the uptake of ⁸⁶Rb⁴ by dormant and afterripened embryos. Gibberelleic acid had no effect on the uptake of ⁸⁶Rb⁺ by isolated embryos from either dormant or afterripened caryopses. The experimental results indicate that gibberellic acid is more versatile in its action than fusicoccin, and gibberellic acid may facilitate dormant A. fatua caryopsis germination by stimulating mechanisms other than the direct H⁺ efflux and K⁺ uptake at the membrane level.     

Mechanism of the growth-promoting action of fusicoccin

Summary Analogies and differences between the growth-promoting action of fusicoccin (FC), the toxic agent produced by Fusicoccum amygdali, and of indole-3-acetic acid (IAA) in etiolated pea internode segments were further investigated. It was confirmed that the effect of FC, at optimal concentration, on growth by cell enlargement is markedly higher (ca. 70%) than that of IAA. The lack of an inhibitory effect of FC at high concentrations corresponds to a lack of capacity of the toxin to induce ethylene synthesis. When FC and IAA are present together at suboptimal concentrations, the effects of the two substances are clearly additive. Growth stimulation by a mixture of FC and IAA at optimal concentrations is equal to that by FC alone. NaF, 2,4-DNP, actinomycin D, and cycloheximide strongly depress FC-induced stimulation of cell enlargement. These data are in agreement with the hypothesis that FC promotes growth through some effect on cell-wall extensibility probably identical to the one mediating auxin-induced growth, while the primary site of action of FC is different from that of the natural and synthetic auxins.