Germination and pH of intracellular compartments in seeds of Phacelia tanacetifolia

³¹ P nuclear magnetic resonance spectroscope (NMR) was used to study the response of Phacelia tanacetifolia seeds to dark and light conditions during the first 72 h of incubation. Changes in the chemical shifts (δ) of the pH-dependent ³¹P-NMR signals from the vacuolar and the cytoplasmic orthophosphate pools were correlated with the different incubation conditions. In the dark (favorable to germination), the cytoplasmic pH remained nearly constant over the whole period considered, while the vacuolar pH shitted to more acidic values after the 24th h of incubation. In the light (inhibiting germination), the values of cytoplasmic pH tended to become more acidic than in the dark after the 24th h of incubation, while the vacuolar pH remained practically constant. When seed germination was inhibited in the dark by butyric acid (BA). a permeant weak acid, the values of cytoplasmic and vacuolar pH were similar to those of the ungerminated seeds incubated in the light. When, vice versa, seed germination was promoted in the light by fusicoccin (FC), the values of cytoplasmic and vacuolar pH were similar to those of the dark-germinated seeds. A progressive augmentation of P, metabolism occurred both in the dark and in the light up to the 24th h of incubation. Subsequently, light blocked any further evolution of this parameter. Treatment with butyric acid in the dark again mimicked the effect of light, while FC reversed the negative effect of light. The data show that in Phacelia tanacetifolia seeds germination is linked to a more alkaline cytoplasmic pH. The finding that the light-dependent metabolic inhibition occurs after an early activation of metabolism, i.e. after the first 24 h. suggests that the effects of light on the cytoplasmic and vacuolar pH depend on the early metabolic processes involved in the control of the homeostasis of cell pH and/or on the inhibition of the reactivation of the transport mechanisms.     

Calcium-calmodulin in germination of Phacelia tanacetifolia seeds: effects of light, temperature, fusicoccin and calcium-calmodulin antagonists

Germination in the dark and at 16°C of photoblastic and thermosensitive seeds of Phacelia tanacetifolia was inhibited when incubated with EGTA and the Ca²⁺-ionophore A 23187; A 23187 in the presence of Ca²⁺ still inhibited germination, but to a lesser extent. Treatments with EGTA or Ca²⁺ at different concentrations in the presence or in the absence of A 23187 did not remove light inhibition. The calmodulin (CaM) inhibitor, calmidazolium, strongly inhibited germination. The specificity of these inhibitors and their effects on seed germination are discussed.
CaM from Phacelia tanacetifolia seeds has been purified and its characteristics (molecular weight, heat and acid stability, kinetics of phosphodiesterase [EC 3.1.4.17] activation) were very similar to those of other plant sources. More than 90% of total CaM was present in the soluble fraction (ca 41 μg g^-1 fresh weight in ungerminated seeds). The CaM level greatly increased in the early phases of seed germination; this increase did not take place when germination was inhibited by light or high temperature. When fusicoccin, a toxin which promotes germination by activating membrane functions, relieved light or high temperature inhibition, CaM increased up to the control value in the dark at 16°C. The parallel increase in CaM and seed germination suggest that CaM plays an important role in the process. Fusicoccin in the dark at 16°C stimulated CaM and fresh weight increase, but not the metabolic reactivation measured as increase in DNA and total RNA levels; at 30°C fusicoccin stimulated the increase in fresh weight and in CaM level, but the increases in DNA and total RNA were very low. These results suggest that the activation of membrane functions with cell enlargement induced by fusicoccin is related to CaM increase.     

Effect of sink size on photosynthesis and carbohydrate content of leaves of three spring wheat varieties

Effects of CO₂ on stomatal movements of Commelina communis L. were studied with plants, epidermal strips and guard cell protoplasts. With plants, the stomatal response induced by a blue light pulse was studied for different ambient CO₂ concentration ranging from CO₂-deprived air to 100 Pa in darkness or under red light. It was observed that the blue light response could be obtained not only under a red light background but also in darkness and CO₂-free air, the two responses being quite similar.
With epidermal strips, the effect of CO₂ on ferricyanide reductase activity at the guard cell plasmalemma was studied by transmission electron microscopy. In the presence of ferric ions, reduced ferricyanide gives an electron dense precipitate of Prussian Blue. In darkness and air, no precipitate was observed. In darkness and CO₂-free air as well as under light and normal air, a precipitate was found along the plasmalemma of the guard cells, indicating a ferricyanide reductase activity. With guard cell protoplasts suspended in a medium either in equilibrium with air or in a CO₂-free medium the H⁺ extrusion induced by a blue light pulse added to a red light background was measured. A low CO₂ content was obtained by adding photosynthetic algae to the suspension of guard cell protoplasts. In a CO₂-free medium the rate of H⁺ extrusion was enhanced.
The results are discussed on the basis of a possible competition for reducing power between CO₂ fixation and a putative blue light dependent redox chain located on the plasma membrane.     

Effect of light intensity on proton extrusion by roots of intact maize plants

Shading of maize plants ( Zea mays L. cv. Blizzard) reduced net H⁺ extrusion by roots and increased K⁺ release, whereas there was no significant effect on anion efflux in deionized water. With lower light intensity the concentrations of carbohydrates in the roots decreased, but ATP levels and energy charge remained unchanged. Also, shading raised the tissue pH of roots and made the cytoplasmic pH of root cells drop. There was a significant influence of light intensity on H⁺ uptake by roots from an acidified test solution and CCCP (carbonylcyanide-3-chlorophenylhydrazone)-in-duced H⁺ uptake was modified by shading.
It is concluded that low light intensity does not limit active H⁺ release by plasmalemma ATPase activity in the root cells, but that a reduced carbohydrate supply brings about a change in biochemical reactions which alter the membrane permeability for protons. An increased passive reflux of H⁺ into the cells rather than a reduced H⁺ ATPase activity explains the decrease of net H⁺ release by roots of intact maize plants under low light intensity.     

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.     

Stimulation of proton extrusion by K+ and divalent cations (Ni2+, Co2+ Zn2+) in maize root segments

Entry of the divalent cations Ni²⁺, Co²⁺ and Zn²⁺ into cells of maize ( Zea mays L. cv. Dekalb XL 85) root tissue is accompanied by an acidification of the incubation medium, a decrease in both the pH of the cell sap and the level of malate in the cells, and by an inhibition of dark fixation of CO₂. K⁺, on the contrary, induces only a very low acidification of the incubation medium, does not change either the pH of the cell sap or the malate level in the cells, and induces an increase in CO₂ dark fixation. Different mechanisms are postulated for the stimulation of proton extrusion by divalent cations and K⁺.     

Response to osmotic medium and fusicoccin by seeds of radish (Raphanus sativus) in the early phase of germination

The effect of increasing osmotic values of the medium (mannitol) on the growth and the response mechanisms of seeds of radish ( Raphanus sativus L., cv. Ton do Rosso Quarantino) during the early phase of germination was investigated in the presence or absence of fusicoccin (FC). Decreasing the water potential in the medium inhibited the growth and the evolution of protein synthesis and enhanced H⁺ extrusion, net uptake of K⁺ and malic acid synthesis. FC, which stimulates these latter functions, counteracted the inhibitory effect of the decreasing water potential of the medium on growth and protein synthesis. Neither in the absence nor in the presence of FC did decreasing water potential of the medium enhance the synthesis of soluble sugars and amino acids to support the osmotic pressure of the seeds. The osmotic and water potentials of the seeds increased during germination. FC made the increase more rapid, while mannitol kept both potentials low. The pressure potentials of the seeds also decreased with time, and both FC and mannitol enhanced this change. If the seeds were without turgor, the development of protein synthesis was blocked. The seeds counteract the effect of decreasing water potentials in the medium by: a) enhancing H⁺ extrusion (and, as a consequence, wall loosening and transport mechanisms) and the synthesis of malic acid as apparent in the presence of FC; b) regulating the osmotic potentials of the cells (with a lower dilution of the osmotic compounds present in the seeds due to the diminished uptake of water); c) controlling the growth through the effects of a) and b) on the pressure potentials (internal hydrostatic pressure) of the seeds and on protein synthesis.     

Effect of thiourea on the ionic content and dark fixation of CO2 in embryonic axes of Cicer arietinum seeds

During the first 12 h of germination of Cicer arietinum L. (cv. Castellans) seeds, K⁺ is first lost into the surrounding medium and is later reabsorbed. Thiourea accelerates this reabsorption. Since there is an increase in the mobilization of K⁺ in response to thiourea, a greater accumulation of malate due to the carboxylation of phosphoenolpyruvic acid takes place as compared with that occurring in water. The subapical zone of the radicle accumulates the greatest amounts of water, K⁺ and malate. The variation in the "in vitro" activity of phosphoenolpyruvate carboxylase does not explain the difference in malate in response to the different treatments, consequently there must be chemical changes in the cytoplasm which favour this carboxylation "in vivo". These results show that thiourea accelerates the mobilization of K⁺ and stimulates the dark fixation of CO₂ in embryonic axes of Cicer arietinum.     

Probable Role of Allylisothiocyanate-Sensitive H+, K+-ATPase in Spicule Calcification in Embryos of the Sea Urchin, Hemicentrotus pulcherrimus

In embryos of the sea urchin, Hemicentrotus pulcherrimus , as well as in cultured cells derived from isolated micromeres, spicule formation was inhibited by allylisothiocyanate, an inhibitor of H⁺, K⁺-ATPase, at above 0.5 μM and was almost completely blocked at above 10 μM. Amiloride, an inhibitor of Na⁺, H⁺ antiporter, at above 100 μM exerted only slight inhibitory effect, if any, on spicule formation. Intravesicular acidification, determined using [ dimethylamine -¹⁴C]-aminopyrine as a pH probe, was observed in the presence of ATP and 200 mM KCl in microsome fraction obtained from embryos at the post gastrula stage, at which embryos underwent spicule calcification. Intravesicular acidification and K⁺-dependent ATPase activity were almost completely inhibited by allylisothiocyanate at 10 μM. Allylisothiocyanate-sensitive ATPase activity was found mainly in the mesenchyme cells with spicules isolated from prisms. H⁺, K⁺-ATPase, an H⁺ pump, probably mediates H⁺ release to accelerate CaCO₃ deposition from Ca²⁺, CO₂ and H₂O in the primary mesenchyme cells. Intravesicular acidification was stimulated by valinomycin at the late gastrula and the prism stages but not at the pluteus stage. K⁺ permeability probably increases after the prism stage to activate H⁺ release.     

Rhythms in magnesium ion inhibition and hysteretic properties of nitrate reductase in the CAM plant Bryophyllum fedtschenkoi

Nitrate reductase (NR, EC 1.6.6.1) was tested in crude extracts of leaves from Bryophyllum fedtschenkoi plants growing under alternating light/darkness as well as in excised leaves kept in continuous light or darkness. In most extracts NR activity was inhibited 20–80% by 5 m M Mg²⁺ A light or darkness shift (30 min darkness) during the first part of the photoperiod gave an increase in the Mg²⁺ inhibition and a decrease in NR activity. Magnesium ion inhibition of NR also showed diurnal variations. Strongest inhibition was found in extracts made during the latter part of the photoperiod and start of the dark period. Pre-incubation of crude extracts with ATP increased Mg²⁺ inhibition, indicating that phosphorylation of NR is involved in regulation of NR in Crassulacean acid metabolism (CAM) plants. In continuous light an increase in Mg²⁺ inhibition occurred after 20 h and 40 h, indicating a rhythm in the phosphorylation of NR. A delay in the production of nitrite in the assay (hysteresis) was generally seen in extracts susceptible to Mg²⁺ inhibition. The rhythms related to NR activity showed the same period length (20 h) as the rhythm in CO₂ exchange. However, in contrast to the rhythm in CO₂ exchange, NR rhythms were strongly damped in continuous light. In constant darkness the rhythms were even more damped. The results show that post-translational modification of CAM NR is influenced by light/darkness and by an endogenous rhythm.     

The role of darkness, GA and fusicoccin (FC) in breaking photodormancy in Phacelia tanacetifolia seeds

The germination of the negatively photoblastic seeds of Phacelia tanacetifolia Benth. (cv. Bleu Clair) is promoted by gibberellic acid and fusicoccin. In the dark, or in the light in the presence of fusicoccin, seed germination is accompanied by an increase of gibberellic acid-like substances. In these conditions, the inhibition of the synthesis of gibberellic acid-like substances does not prevent seed germination, but it affects the growth and the survival of the seedlings. Seed germination, growth, and survival of seedlings are discussed in relation to phytochrome, fusicoccin, and gibberellic acid-iite substances.     

Effect of increased concentration of soil CO2 on intermittent flushes of seed germination in Echinochloa crus-galli var. crus-galli

Soil-buried seeds of barnyardgrass ( Echinochloa crus-galli var. crus-galli ) germinated from April to June in three intermittent flushes. The later two flushes of germination occurred after heavy rainfall. Carbon dioxide concentration in soil air transiently increased to 30 dm³ m^–3 after the rainfall, probably due to the increase in soil temperature and water potential. Germination of exhumed seeds was stimulated by exposure to CO₂ at 30 dm³ m^–3. Fluctuating temperature, light, water, ethylene, and nitrate are known to promote seed germination in many species. However, of these environmental factors, within ranges found in the field, only CO₂ was effective in enhancing the germination of barnyardgrass seeds. We conclude that soil CO₂ is responsible for causing intermittent flushes of germination. Detection of vegetation gaps may be explained by the responsiveness of buried seeds to CO₂.     

Effect of darkness and CO2 starvation on NH4+ and NO3− assimilation in the unicellular alga Cyanidium caldarium

Cyanidium caldarium (Tilden) Geitler, a non-vacuolate unicellular alga, resuspended in medium flushed with air enriched with 5% CO₂, assimilated NH₄⁺ at high rates both in the light and in the dark. The assimilation of NO₃⁻, by contrast, was inhibited by 63% in the dark. In cell suspensions flushed with CO₂-free air, NH₄⁺ assimilation decreased with time both in the light and in the dark and ceased almost completely after 90 min. The addition of CO₂ completely restored the capacity of the alga to assimilate NH₄⁺. NO₃⁻ assimilation, by contrast, was 33% higher in the absence of CO₂ and was linear with time. It is suggested that NO₃⁻ and NH₄⁺ metabolism in C. caldarium are differently controlled in response to the light and carbon conditions of the cell.     

Enhancement of the light-triggered electrical response in plant cells following their de-energization with uncouplers

Light-triggered membrane potential changes in cells of a liverwort Anthoceros are greatly enhanced by the ionophorous uncouplers nigericin and monesin. Stimulation of the light-triggered electrical response (LTER) by nigericin occurred concomitantly with inhibition of a slow decline in the chlorophyll fluorescence, which suggests that the transmembrane pH gradient in thylakoids is not essential for generation of LTER at the plasma membrane. The extent of monensin-stimulated LTER remained high under a diminished driving force for the ionophore-induced proton-cation exchange across the plasma membrane (elevation of the external Na⁺ concentration from 1 to 50 m M ), which indicates that energy uncoupling in chloroplasts is more related to the electric response enhancement than the induction of the H⁺/K⁺(Na⁺) exchange at the plasma membrane. Enhancement of LTER by ionophores occurs in parallel with stimulation of light-triggered pH changes (alkalinization) in the vicinity of the cell surface, which suggests an association of trans-membrane H⁺ fluxes with LTER. The results are consistent with the hypothesis that illumination produces a temporary inhibition of the plasma membrane H⁺ pump with a subsequent activation of gated channels and transient rapid depolarization of the cell.     

Mycobiont-cyanobiont interactions during dark nitrogen fixation by the lichen Peltigera aphthosa

Acetylene reduction (nitrogenase activity) by excised cephalodia of Peltigera aphthosa Willd. slowly declined on transfer of the cephalodia from light to darkness. The decline was more rapid in the absence of CO₂ or when phosphoenolpyruvate carboxylase activity was inhibited by adding maleic acid or malonic acid. When glutamine synthetase (GS) activity was totally inhibited by adding l -methionine- dl -sulphoximine (MSX) the decline in nitrogenase activity in the absence of CO₂ still occurred. However, this loss of activity did not occur when the mycobiont was disrupted using digitonin (0.01 % w/v) and the fixed NH₄⁺ was released into the medium. The data suggest that dark CO₂ fixation by the fungus supplies carbon skeletons which remove newly fixed NH₄⁺ produced by the cyanobacterium. When such carbon skeletons are not available MH₄⁺ accumulates and inhibits nitrogenase activity even in the absence of GS activity. It is probable that NH₄⁺ and a product of GS exert independent inhibitory effects on nitrogenase activity.     

The appearance of a new molecular species of phosphoenolpyruvate carboxylase (PEPC) and the rapid induction of CAM in Sedum telephium L.

Abstract. When detached leaves of Sedum telephium are incubated in the absence of water, a rapid switch from C₃ photosynthesis to CAM (as indicated by the onset of day-to-night fluctuations in titratable acidity. ΔH⁺) occurs within the first dark period. The C₃-CAM switch in intact plants occurs within 3 5d. Extractable activity of phospho enol pyruvate carboxylase (PEPC) increases five-fold in intact plants during CAM induction; however, during rapid CAM induction in detached leaves, there is only a very small increase in PEPC activity. Fractionation by anion exchange chromatography of crude extracts from leaves of intact plants subjected to water deficit shows that CAM induction is associated with the appearance of a molecular species of PEPC termed PEPC I. PEPC I is barely detectable in well-watered plants which are not performing CAM. The major form in these plants is termed PEPC II. In leaves from intact plants, there is a significant positive correlation between PEPC I activity and ΔH⁺ during a period of increasing water deficit. PEPC I exhibits day to night fluctuations in malate sensitivity, being less sensitive during the dark period. In contrast, PEPC II is more sensitive to inhibition by malate and has no day to night fluctuation in sensitivity. In detached leaves deprived of water, a small increase in PEPC I capacity is detected at the end of the first dark period (20 h after the start of treatment). The results suggest that PEPC I is required for attainment of maximum nocturnal malic acid synthesis. There is a significant correlation between leaf water status (relative water content), ΔH⁺, total PEPC and PEPC I activity suggesting that the internal water status of the plant may be a trigger for CAM induction. Abscisic acid applied to detached leaves does not cause nocturnal acidification.     

Heterotrophic (Dark) CO2 Fixation by Euglena gracilis. Possible regulation by tricarboxylic acid cycle intermediates

SYNOPSIS. Heterotrophic (dark) CO₂ fixation by Euglena gracilis strain Z varies with phase of batch culture and mode of nutrition. Dark CO₂ fixation increased transiently during the growth of cells under photoautotrophic (CO₂, light) and heterotrophic (glucose, dark) conditions. Cells grown heterotrophically with acetate or ethanol had no transient increase in fixation. The addition of acetate to a heterotrophically growing culture during the period of increasing dark CO₂ fixation resulted in rapid elimination of this fixation. The results suggest that dark CO₂ fixation in Euglena functions in anaplerotic feeding of the tricarboxylic acid cycle, drained by biosyntheses during growth. Induction of the glyoxylate cycle by acetate may provide an alternate source of tricarboxylic cycle intermediates, obviating the requirement for dark CO₂ fixation as a source of the intermediates.     

Inhibition of the glucose and amino-acid carriers of Lemna gibba by pretreatment with HgCl2

The electrical resting potential across the plasmalemma of Lemna gibba L. (G 1) cells is −230 to −250 mV and the diffusion potential in the presence of 1 mol m⁻³ KCN + 1 mol m⁻³ salicylhydroxamic acid is about −100 mV. A concentration of 0.01 mol m⁻³ HgCl₂ depolarises the transmembrane electrical potential in a largely reversible way. When the cells after 16 min of HgCl₂-application are returned to Hg-free solution, the transmembrane electrical potential is only depolarised by 24 × 13 mV (SD, n = 13) compared with the potential prior to HgCl₂ treatment. In contrast, a 16 min pretreatment with HgCl₂ followed by a wash with mercury-free solution reduces the transient depolarisations of transmembrane potential observed after addition of 5 mol m⁻³ D-glncose or 1 mol m⁻³ L-alaoine to about 60% of controls. These transient depolarisations are due to the onset of solute uptake. Accordingly, HgCl₂-pretreatment inhibits uptake of ¹⁴C-3-O-methyl- d -glucose by more than 50% and uptake of ¹⁴C- l -alanine by more than 70%. Washing with 1 mol m⁻³ 1,4-dithiothreitol does not reverse this inhibition. It is, therefore, concluded that Hg²⁺ irreversibly binds to essential SH-groups of the H⁺-hexose and the H⁺-amino-acid cotransport carriers of Lemna gibba and inhibits these carriers without appreciably affecting the electrogenic proton-extrusion pump.