Plant responses to H2S and SO2 fumigation. II. Differences in metabolism of H2S and SO2 in spinach

Fumigation of spinach (Spinacia oleracea L. cvs Estivato and Monosa) with H₂S or SO, for 1 to 6 days resulted in accumulation of sulfhydryl (SH) compounds in the shoots of both H₂S- and SO₂-exposed plants. The sulfate concentration in shoots of SO₂-exposed plants increased linearly with time. SH accumulation showed saturation kinetics as a function of time as well as H₂S concentration, ascribed to the internal H₂S concentration in the plant and the availability of substrates for glutathione synthesis, respectively. SH compounds accumulated more at lower exposure temperatures, whereas sulfate accumulation was more pronounced at higher temperatures. These results are discussed in relation to the possible foliar uptake of H₂S and SO₂, the temperature dependence of uptake and the water solubility of these gases. The possibility of SO₂-induced H₂S emission rather than sulfate accumulation as a source for SH accumulation is also discussed. Cessation of fumigation resulted in a decrease in SH compounds and sulfate content that could be accounted for by sulfur metabolism and growth, respectively.     

The effect of short-term H2S fumigation on water-soluble sulphydryl and glutathione levels in spinach

Abstract. Short-term fumigation of Spinacia oleracea with 380 μg m⁻³ H₂S (250 ppb) resulted in a rapid accumulation of water-soluble SH-compounds in the shoots. After 1 h exposure a substantial increase in the SH-content was already detectable and maximal accumulation, three- to four-fold that in control plants, was observed after 24 h of exposure. Irradiation during H₂S exposure only slightly affected the rate and level of SH-accumulation. H₂S fumigation did not affect the water-soluble SH-content of the roots. Glutathione was the sole water-soluble SH-compound accumulating upon exposure to H₂S. It was calculated that during the first hour of exposure to 380 μg m⁻³ H₂S 39% of the possible absorbed H₂S was converted into glutathione. The SH-content of the water-soluble proteins of the shoots was not affected by H₂S exposure. When fumigation was stopped, a rapid decrease in glutathione content was observed and after 48 h the content was comparable to that of the control plants. Contrary to H₂S, SO₂ fumigation did not result in a rapid accumulation of glutathione in spinach shoots. The possible role of glutathione accumulation during H₂S fumigation is discussed.     

Effect of short-term dark incubation with sulfate, chloride and selenate on the glutathione content of spinach leaf discs

A 24 h incubation of leaf discs of spinach ( Spinacia oleracea L. cv. Estivato) in darkness with 50 and 100 m M sulfate resulted in a two- to three-fold increase in the level of glutathione (GSH), a compound which may serve as storage of excess reduced sulfur in the plant. The accumulated GSH was a small fraction (around 1%) of the sulfate taken up in the spinach leaf discs. Incubation of spinach leaf discs with 50 and 100 m M chloride resulted in only a 30% increase of the water-soluble non-protein-SH; the uptake of electrolytes was comparable to that observed with sulfate. This indicated that the increase of the GSH level upon incubation with sulfate was rather specific and not due to salinity. Incubation with 50 m M Na₂SO₄ did not affect water-soluble protein-SH content after 24 h. Addition of 1 and 10 m M selenate, an inhibitor of sulfate reduction, strongly reduced sulfate-induced GSH accumulation in spinach leaf discs, both in light and darkness. It was concluded that the sulfate-induced SH accumulation was due to a substantial de novo reduction of sulfate in darkness and subsequent incorporation of the reduced sulfur into GSH. The role of the sulfate concentration at the reaction site of ATP sulfurylase in the regulation of sulfur assimilation in the plant is discussed with respect to the low affinity of the enzyme for sulfate.     

Cysteine, γ-glutamyl-cysteine and glutathione contents of spinach leaves as affected by darkness and application of excess sulfur

In the light, glutathione was the major water-soluble, non-protein, sulfhydryl compound in leaves of spinach ( Spinacia oleracea L. cv. Estivato). In the dark, another sulfhydryl compound accumulated, which proved to be γ-glutamyl-cysteine. In the light, exposure of leaves to excess sulfur in the form of atmospheric H₂S (0.25 μl l⁻¹) resulted in considerably increased levels of glutathione and cysteine. In the dark, in addition to these thiols, levels of γ-glutamyl-cysteine were also enhanced considerably. When leaves of plants exposed to H₂S in the dark were illuminated, the dipeptide rapidly disappeared. At the same time, glutathione contents increased by approximately the same amount, indicating a light-dependent conversion of γ-glutamyl-cysteine into glutathione. Possible mechanisms for these light-induced changes in thiol metabolism are discussed.     

Effect of long-term H2S fumigation on photosynthesis in spinach. Correlation between CO2 fixation and chlorophyll a fluorescence

Spinach plunts (Spinacia oleracea L. cv. Monosa) were exposed to air with and without 0.25 μl l^-1 H₂S. Effects of H₂S exposure for up to 18 days on photosynthesis, dark respiration and on chlorophyll a fluorescence were studied. Dark respiration was not affected by H₂S fumigation. Photosynthetic CO₂ fixation decreased linearly with time in both control and fumigated plants. The rate of decrease in CO₂ fixation was faster in the fumigated plants; after 14 days of exposure the fumigated plants showed a decrease in CO₂ fixation of 23%äs compared with the control plants. The H₂S-induced decrease in CO₂ fixation was accompanied by a decrease in quenching of the chlorophyll fluorescence. The most characteristic change in chlorophyll fluorescence was a decreased difference between maximum and steady-state fluorescence [(P-T)/P), suggesting a reduced efficiency in the use of photochemical energy in photosynthesis. Differences in CO₂ fixation were more pronounced whcn measured at high light intensity; the maximum rate of CO₂ fixation at light saturation decreased significantly with time in the H₂S-exposed plants; after 14 days of H₂S exposure a decrease of more than 70% was noted. The decrease in CO₂ fixation could not be attributed to a decreased chlorophyll content; on the contrary, chlorophyll content even slightly increased during fumigation. The initial increase in CO₂ fixation rate with increasing light intensity was also reduced by prolonged H₂S fumigation, indicating an effect of H₂S fumigation on photosynthetic electron transport. Finally, the phytotoxicity of H₂S is discusscd in relation to the H₂S-induced changes in photosynthetic CO₂ fixation and chlorophyll a fluorescence, and the effect of H₂S on leaf development observed in earlier studies.     

Cysteine, γ-glutamyl-cysteine and glutathione contents of spinach leaves as affected by darkness and application of excess sulfur. II. Glutathione accumulation in detached leaves exposed to H2S in the absence of light is stimulated by the supply of glycine to the petiole

When illuminated leaf discs and detached leaves of spinach ( Spinacia oleracea L. cv. Estivato) were exposed to 0.4 and 0.25 μl 1^-1 H₂S, respectively, pool sizes of cysteine and glutathione increased. In the dark, apart from these compounds, the level of γ-glutamyl-cysteine also increased. Incubation of leaf discs with 1.0 m M buthionine sulfoximine (BSO) resulted in the accumulation of cysteine only, both in the light and in darkness. When glycine was supplied to the petioles of detached leaves exposed to H₂S in the dark, the accumulation of glutathione was stimulated, while γ-glutamyl-cysteine accumulation was prevented completely. Glycolate and glyoxylate, precursors of glycine in the glycolate pathway, had nearly the same effect as glycine. Although other amino acids were apparently taken up equally well as glycine when supplied to the petiole, they were much less effective, or not effective at all, in restoring glutathione synthesis in the dark. These results provide evidence, that H₂S-induced glutathione accumulation in spinach leaves in the dark is limited by the availability of glycine, giving rise to the accumulation of the metabolic precursor γ-glutamyl-cysteine.     

Effect of SO2, on the activity of adenosine 5'-phosphosulfate sulfotransferase from spruce trees (Picea abies) in fumigation chambers and under field conditions

The effect of SO₂ on adenosine 5'-phosphosulfate sulfotransferase activity and various other parameters of needles from spruce ( Picea abies L.) was studied using potted grafts in outdoor fumigation chambers and trees growing near a factory. In summer and autumn fumigation of grafted spruce, SO₂, decreased the extractable activity of adenosine 5'-phosphosulfate sulfotransferase to 12–50% of the controls, and reduced the amount of ³⁵S from sulphate incorporated into protein by excised branches to a comparable degree. SO₂ treatment in January and February inhibited the increase in adenosine 5'phosphosulfate sulfotransferase activity measured in the controls during this time. ATP-sulfurylase activity was less affected by SO₂. fumigation. In trees growing near a factory with high SO₂. emission, the activity of adenosine 5'-phosphosulfate sulfotransferase was about 35% of that of trees from a control area. The low enzyme activity was correlated with a high content of sulfate and compounds containing thiol groups.     

SO2 and assimilatory sulfate reduction in beech leaves

The effect of SO₂ on the extractable activity of ATP sulfurylase (EC 2.7.7.4.). adenosine 5'-phosphosulfate sulfotransferase, ribulosebisphosphate carboxylase, chlorophyll, protein, sulfate, and amino acids was examined in leaves of potted grafts of beech ( Fagus sylvatica L.) treated in outdoor fumigation chambers. Addition of 0.025 and 0.075 μl SO₂ 1⁻¹ to unfiltered ambient air caused a decrease in the extractable activity of adenosine 5'-phosphosulfate sulfotransferase to about 20 to 30% of the controls. Neither the extractable activity of ATP sulfurylase and ribulosebisphosphate carboxylase nor the content in chlorophyll, total amino acids and protein were significantly affected by SO₂, but there was an increase in the sulfate content. Leaves treated with 0.075 μl SO₂ 1⁻¹ contained more alanine and cysteine and less serine than the controls. After transfer of the SO2-treated beech trees to control chambers there was an increase in adenosine 5'-phosphosulfate sulfotransferase activity, but no significant decrease in SO₂₋⁴-sulfur.     

Effect of SO32- on the activity of ribulose bisphosphate carboxylase from seedlings of Pinus silvestris

Abstract The effect of sulphite on ribulose bisphosphate carboxylase, extracted from needles of Pinus silvestris L., was studied in vitro at pH 8.15 and 25°C. 1 mM and higher concentrations of SO₃^2- inhibited the enzyme. The enzyme was activated either in the assay medium (2.5 – 20 mM HCO_3, 20 mM MgCl₂) or in 10 or 20 mM HCO₃^- and 20–25 mM MgCl₂. Linear reciprocal plots of the activity versus the substrate concentration were obtained, when the HCO₃^- concentration during activation was 4 mM or higher. When the enzyme was activated at high HCO₃^- and Mg²⁺ concentrations, the K_m(CO₂) was c. 27 μM. With respect to HCO₃^-. SO₃^2- inhibited the enzyme in a non-competitive fashion. The inhibition was similar, whether SO₃^2- was present during activation or not. Apparently. SO₃^2- did not interfere with the binding of CO₂ and Mg²⁺ at the activating site. The K₁ was 11–13 mM SO₃^2-. With respect to ribulose bisphosphate the inhibition was also noncompetitive. Similar results with respect to HCO₃^- were obtained for spinach, Spinacia oleracea L., which is contrary to earlier reports.     

High-light effects on CO2 fixation gradients across leaves

Chlorophyll fluorescence and internal patterns of ¹⁴CO₂ fixation were measured in sun and shade leaves of spinach after treatment with various light intensities. When sun leaves were irradiated with 2000μmol m^?2 s^?1 for 2h, F_V/F_M decreased by about 15%, but ¹⁴CO₂ fixation was unaffected, whereas shade leaves exhibited a 21% decrease in F_v/F_M and a 25% decrease in ¹⁴CO₂ fixation. Irradiation of sun and shade leaves with 4000μmol m^?1 for 4 h decreased F_V/F_M by 30% in sun leaves and 40% in shade leaves, while total ¹⁴CO₂ fixation decreased by 41% in sun leaves and 55% in shade leaves. After light treatment, gradients of CO₂ fixation across leaves were determined by measuring ¹⁴CO₂ fixed in paradermal leaf sections after a 10s pulse of ¹⁴CO₂. Gradients of ¹⁴CO₂ fixation in control sun and shade leaves were identified when expressed on a relative basis and normalized for leaf depth. Treatment of leaves with 2000 μmol PAR m^?2 s^?1 for 2h did not after patterns of carbon fixation across sun leaves, but slightly altered the pattern in shade leaves. In contrast, treatment of sun and shade leaves with 4000μmol m^?2 s^?1 for 4h decreased carbon fixation more in the palisade mesophyll cells than in the spongy mesophyll cells of sun and shade leaves, and fixation in medial tissue of shade leaves was dramatically decreased compared to the adaxial and abaxial tissue. The interaction between leaf anatomy and biochemical parameters involved in tolerance to photoinhibition in spinach is discussed.     

Physiological effects of a long term exposure to low concentrations of NH3, NO2 and SO2 on Douglas fir (Pseudotsuga menziesii)

The above-ground parts of two years old seedlings of Douglas fir (Pseudotsuga menziesii) were exposed to filtered air, NH₃, NO₂₊, SO₂ (66, 96 and 95 μg m^?3, respectively), to a mixture of NO₂+NH₃ (55 + 82 μg m^?3) or SO₂+NO₂ (128 + 129 μg m^?3), for 8 months in fumigation chambers. Both chlorophyll fluorescence and gas exchange measurements were carried out on shoots which had sprouted at the beginning of the exposure period. The chlorophyll fluorescence measurements were performed after 3 and 5 months of exposure (average shoot age 70 and 140 days, respectively). Light response curves of electron transport rate (J) were determined, in which J was deduced from chlorophyll fluorescence. In addition, light response curves of net CO₂ assimilation were determined after 5 months of exposure. After 3 months of exposure (average shoot age 70 days) all exposure treatments showed a lower maximum electron transport rate (J_max) as compared to the control shoots (filtered air). A large reduction (45%) was observed for shoots exposed to SO₂+NO₂. During the exposure period between 3 and 5 months (average shoot age 70 and 140 days, respectively) a decrease of J_max was observed for all treatments. J_max had further declined some time after termination of the exposure, when average shoot age was 310 days. Shoots exposed to SO₂ and SO₂+NO₂ also showed a reduction in maximum net CO₂ assimilation (P_max) as compared to the control shoots. However, shoots exposed to NO₂ showed no reduction and even a higher P_max was observed for shoots exposed to NH₃ or NO₂+NH₃. Needles of these treatments also showed a higher chlorophyll content which might explain the contradictory results obtained for these treatments: the increased amount of photosynthetic units counteracts the reduction in J_max and consequently no reduction in P_max is measured. Shoots exposed to SO₂ and SO₂+NO₂ also showed a reduction in maximum stomatal conductance (g_s). However, the stomatal opening was larger than could be expected on basis of their (maximum) CO₂ assimilation rate. Consequently, water use efficiency of these shoots was lower than that of the control shoots. Also shoots exposed to NO₂ had a lower water use efficiency due to a significantly higher maximum g_s. Shoots exposed to NH₃ showed a high transpiration rate in the dark, indicating imperfect stomatal closure.     

Physiological effects of long term exposure to low concentrations of SO2 and NH3 on poplar leaves

Shoots of poplar (Populus euramericana L. cv. Flevo) were exposed to filtered air, SO₂, NH₃ or a mixture of SO₂ and NH₃ for 7 weeks in fumigation chambers. After this exposure gas exchange measurements were carried out using a leaf chamber. As compared to leaves exposed to filtered air, leaves pretreated with 112 μg m^?3 SO₂ showed a small reduction in maximum CO₂ assimilation rate (P_max) and stomatal conductance (g_s). They also showed a slightly higher quantum yield and dark respiration. In addition, the fluorescence measurements indicated that the Calvin cycle of the leaves pretreated with 112 μg m^?3 SO₂ was more rapidly activated after transition from dark to light. An exposure to 64 μg m^?3 NH₃ had a positive effect on P_max, stomatal conductance and NH₃ uptake of the leaves. This positive effect was counteracted by an SO₂ concentration of 45 μg m^?3. The exposure treatments appeared to have no effect on the relationship between net CO₂-assimilation and g_s. Also, no injury of the leaf cuticle or of epidermal cells was observed. Resistance analysis showed that NH₃ transfer into the leaf can be estimated from data on the boundary layer and stomatal resistance for H₂O transfer and NH₃ concentration at the leaf surface, irrespective of whether the leaves are exposed for a short or long time to NH₃ or to a mixture of NH₃ and SO₂. In contrast SO₂ uptake into the leaves was only partly correlated to the stomatal resistance. The results suggest a large additional uptake of this gas by the leaves. The possibility of a difference in path length between SO₂ and H₂O molecules is proposed.     

Generation of H2O2 in Brain Mitochondria

Generation of H2O2 by rat brain mitochondria using succinate and glycerol-1-phosphate as substrates has been demonstrated. Earlier workers were unable to detect this activity in sucrose-Tris buffer. We found that this was due to a lag in the expression of activity in sucrose medium. Using phosphate buffer (50 mM), good rates are now obtained. Generation of H2O2 by rat brain mitochondria required the presence of antimycin A and was dependent on the substrates succinate and glycerol-1-phosphate. Low rates were obtained with NAD+-linked substrates and none with choline, glutamate, and NADH. The Km and Vmax values for H2O2 generation were considerably lower than the corresponding values for the respective dehydrogenase activity, measured by dye reduction. Oxygen-radical scavengers inhibited H2O2 generation, suggesting oxygen radical involvement. Depletion of ubiquinone from mitochondria resulted in loss of H2O2 generation. Reconstitution of such depleted particles with ubiquinone restored the capacity to generate H2O2 in a concentration-dependent manner. Levels of H2O2 production were found to be maximal in cerebellum. Brain mitochondria from rabbit, hamster, mouse, and guinea pig also have the capacity to generate H2O2 on oxidation of glycerol-1-phosphate.     

An in vivo analysis of the effect of SO2 fumigation on photosynthesis in Zea mays.

Fumigation of leaves with SO₂ can reduce the capacity for photosynthetic CO₂ uptake even in the absence of visible symptoms of damage. In vitro studies suggest that this invisible injury to intact leaves could be affected by damage to each of the main stages in the photosynthetic process. Reduced stomatal apertures may also reduce photosynthesis following SO₂ fumigation. The responses of CO₂ uptake by leaves to intercellular CO₂ concentration and to absorbed light provide information for quantitative separation of the in vivo contribution of the different stages of photosynthesis to reduction in overall rate. This study uses these techniques to examine the basis of reduction in CO₂ uptake in Zea mays cv. LG11 leaves following short-term fumigation with SO₂. Fumigation with 33 μmol m^–3 SO₂ for 30 min reduced light saturated CO₂ uptake by about one-third. An even greater reduction in light limited CO₂ uptake was observed and with no significant change in light absorptance this was attributed to a reduced quantum yield of photosynthesis. The light saturated CO₂ uptake rate and the stomatal conductance decreased in parallel. However, the relationship of CO₂ uptake to the intercellular CO₂ concentration suggested that the reduced stomatal conductance did not account for the reduced rate of CO₂ uptake following fumigation. Both the initial slope and plateau of this relationship were significantly reduced, suggesting that both carboxylation efficiency and capacity for regeneration of CO₂ acceptor were diminished by SO₂ fumigation. The operating intercellular CO₂ concentration indicated that both processes were co-limiting, before and after fumigation. The time required for induction of photosynthetic CO₂ uptake on illumination was approximately doubled following SO₂ fumigation, showing that fumigation impairs the ability of the photosynthetic apparatus to adapt to fluctuations in light level.     

Growth of coniferous trees exposed to SO2 and O3 using an open-air fumigation system

Scots pine (Pinus sylvestris L.), Norway spruce (Picea abies (L.) Karst.) and Sitka spruce (Picea sitchensis Bong. Carr.) were planted as 2-year-old seedlings in an open-air fumigation facility at Liphook in southern England in March 1985. The soil was a humoferric podzol of pH 4. SO₂ fumigation began in May 1987 and continued until December 1990. Long-term mean SO₂ concentrations were 4,13 and 22 nmol mo^?1. Three plots, one at each SO₂ level, were also exposed to O₃ at an average of 1–3.times the ambient level. O₃ fumigation ran from March to December 1988, May to December 1989 and February to December 1990. Each species reacted differently to treatment. Scots pine showed no growth response to either pollutant, although other work on the site demonstrated a number of deleterious effects of SO₂ on this species, including increased leaf loss and foliar injury. Stem basal diameter growth of Norway spruce was depressed in SO₂-treated plots. In contrast, extension growth of shoots of Sitka spruce increased in SO₂-treated plots, in apparent response to codeposition of NH₃-N. However, diameter growth of Sitka spruce main stems did not increase. No effects of O₃ on growth were recorded for any species.