MET17 and Hydrogen Sulfide Formation in Saccharomyces cerevisiae

Commercial isolates of Saccharomyces cerevisiae differ in the production of hydrogen sulfide (H₂S) during fermentation, which has been attributed to variation in the ability to incorporate reduced sulfur into organic compounds. We transformed two commercial strains (UCD522 and UCD713) with a plasmid overexpressing the MET17 gene, which encodes the bifunctional O-acetylserine/O-acetylhomoserine sulfhydrylase (OAS/OAH SHLase), to test the hypothesis that the level of activity of this enzyme limits reduced sulfur incorporation, leading to H₂S release. Overexpression of MET17 resulted in a 10- to 70-fold increase in OAS/OAH SHLase activity in UCD522 but had no impact on the level of H₂S produced. In contrast, OAS/OAH SHLase activity was not as highly expressed in transformants of UCD713 (0.5- to 10-fold) but resulted in greatly reduced H₂S formation. Overexpression of OAS/OAH SHLase activity was greater in UCD713 when grown under low-nitrogen conditions, but the impact on reduction of H₂S was greater under high-nitrogen conditions. Thus, there was not a good correlation between the level of enzyme activity and H₂S production. We measured cellular levels of cysteine to determine the impact of overexpression of OAS/OAH SHLase activity on sulfur incorporation. While Met17p activity was not correlated with increased cysteine production, conditions that led to elevated cytoplasmic levels of cysteine also reduced H₂S formation. Our data do not support the simple hypothesis that variation in OAS/OAH SHLase activity is correlated with H₂S production and release.     

Cysteine desulfhydrase activity in cucurbit plants: Stimulation by preincubation with l- or d-cysteine

Cysteine desulfhydrase activity in leaf discs of cucurbit plants is enhanced 2–4-fold by preincubation with l or d-cysteine. Preincubation with structural analogs of cysteine also stimulated the activity of the enzyme, but to a smaller extent. Maximal increase in cysteine desulfhydrase activity was observed by preincubation with 5 mM or higher concentrations of cysteine. Although not caused by activation, stimulation of the enzyme activity was half-maximal within less than 15 min. Whereas the increase in cysteine desulfhydrase activity by preincubation of leaf discs with cysteine was light independent, pretreatment of the entire plant with light or dark determined the leaf discs' potential for stimulation of the enzyme. Exposure to darkness for 4 hr reduced this potential by 60%. It is concluded that the potential for stimulation of cysteine desulfhydrase activity by preincubation with cysteine is regulated by a compound not synthesized, but metabolized, in the leaf tissue. This regulatory compound may be supplied to the leaves by long-distance transport.     

Role of o-acetylserine in hydrogen sulfide emission from pumpkin leaves in response to sulfate

In the presence of excess sulfate, cysteine synthesis in pumpkin (Cucurbita pepo) leaves is not limited by sulfate reduction, but by the availability of O-acetylserine. Feeding of O-acetylserine or its metabolic precursors S-acetyl-coenzyme-A and coenzyme A to leaf discs enhanced the incorportion of [³⁵S]sulfate into reduced sulfur compounds, mainly into cysteine, at the cost of lowered H₂S emission; the uptake and reduction of sulfate is not affected by these treatments. β-Fluoropyruvate, an inhibitor of the generation of S-acetyl-coenzyme A via pyruvate dehydrogenase, stimulated H₂S emission in response to sulfate. This stimulation is overcompensated by addition of O-acetylserine, S-acetyl-coenzyme A, or coenzyme A. These results indicate that, in the presence of high amounts of sulfate, excess sulfur is reduced and emitted as H₂S into the atmosphere. The H₂S emitted seems to be produced by liberation from a precursor of cysteine rather than by cysteine desulfhydration.     

In vitro synthesis of a mutagenic azide metabolite by cell-free bacterial extracts

Cell-free extracts of Salmonella typhimurium synthesize a mutagenic azide metabolite from sodium azide and O-acetylserine. S. typhimurium mutant DW379 (O-acetylserine sulfhydrylase-deficient) extracts were neither able to carry out this reaction nor produce the mutagenic azide metabolite in vivo. The in vitro reaction was inhibited by sulfide but not by l-cysteine. The catalytic activity responsible for the mutagenic metabolite synthesis was stable to brief heating up to 55°C and had a pH optimum between 7–7.4. These results suggest that the enzyme O-acetylserine sulfhydrylase catalyzes the reaction of azide with O-acetylserine to form a mutagenic azide metabolite.     

Purification of serine acetyltransferase,a component of a multienzyme complex,by immunoadsorption and selective dissociation of the complex

An immunoadsorbent column chromatography procedure utilizing antibody to one component of a multienzyme complex has been utilized for purification of the second component of this complex. Rabbit immunoglobulin G (IgG) specific for the O-acetylserine sulfhydrylase component of the multienzyme complex cysteine synthetase was linked to Sepharose 4B resin. A crude preparation of cysteine synthetase was bound to a column of IgG-Sepharose, other proteins were removed by washing, and the serine acetyltransferase component of the complex was eluted with 50 mmO-acetylserine, which dissociates the complex of the two enzymes. This purification step produces about a 400-fold increase in specific activity.     

Isozyme-Specific Ligands for O-acetylserine sulfhydrylase,a Novel Antibiotic Target

The last step of cysteine biosynthesis in bacteria and plants is catalyzed by O-acetylserine sulfhydrylase. In bacteria, two isozymes, O-acetylserine sulfhydrylase-A and O-acetylserine sulfhydrylase-B, have been identified that share similar binding sites, although the respective specific functions are still debated. O-acetylserine sulfhydrylase plays a key role in the adaptation of bacteria to the host environment, in the defense mechanisms to oxidative stress and in antibiotic resistance. Because mammals synthesize cysteine from methionine and lack O-acetylserine sulfhydrylase, the enzyme is a potential target for antimicrobials. With this aim, we first identified potential inhibitors of the two isozymes via a ligand- and structure-based in silico screening of a subset of the ZINC library using FLAP. The binding affinities of the most promising candidates were measured in vitro on purified O-acetylserine sulfhydrylase-A and O-acetylserine sulfhydrylase-B from Salmonella typhimurium by a direct method that exploits the change in the cofactor fluorescence. Two molecules were identified with dissociation constants of 3.7 and 33 µM for O-acetylserine sulfhydrylase-A and O-acetylserine sulfhydrylase-B, respectively. Because GRID analysis of the two isoenzymes indicates the presence of a few common pharmacophoric features, cross binding titrations were carried out. It was found that the best binder for O-acetylserine sulfhydrylase-B exhibits a dissociation constant of 29 µM for O-acetylserine sulfhydrylase-A, thus displaying a limited selectivity, whereas the best binder for O-acetylserine sulfhydrylase-A exhibits a dissociation constant of 50 µM for O-acetylserine sulfhydrylase-B and is thus 8-fold selective towards the former isozyme. Therefore, isoform-specific and isoform-independent ligands allow to either selectively target the isozyme that predominantly supports bacteria during infection and long-term survival or to completely block bacterial cysteine biosynthesis.     

salmonella typhimurium/enzymol.

Cysteine synthetase from Salmonella typhimurium LT-2 displays a saturation curve for sulfide identical to that obtained with uncomplexed O-acetylserine sulfhydrylase, indicating substrate inhibition with a K_m of 0.1 ± 0.017 mm and a K₁ of 0.303 ± 0.194 mm. With both l-serine and acetyl CoA, however, cysteine synthetase exhibits two intermediary plateaus in the respective saturation curves. The time course of cysteine synthetase activity when the reaction is started by adding enzyme displays a pronounced lag phase. This lag is explained as being due to the buildup of a sufficient concentration of O-acetyl-l-serine to permit binding to O-acetylserine sulfhydrylase. This conclusion is substantiated by the fact that plots of $\text{1}\text{τ}$ against concentrations of both l-serine and acetyl CoA reflect the saturation curves for these substrates. In addition, the incubation of the complex with l-serine and acetyl CoA results in the accumulation of the intermediate products of the reaction sequence, CoA and O-acetyl-l-serine. Dissociation of the multienzyme complex under these conditions was ruled out by Sephadex G-200 chromatography of the complex after incubation with assay levels of the substrates of the reaction. Aggregation of cysteine synthetase was detected using disc gel electrophoresis and confirms earlier reports [Kredich, N. M., and Tomkins, G. M. (1966) J. Biol. Chem.241, 4955–4965]. Aggregation of O-acetylserine sulfhydrylase was also detected using the same technique.     

STUDIES ON THE PATHWAY OF SULFIDE PRODUCTION IN A COPPER-ADAPTED YEAST

Metabolism of some sulfur-containing substances was studiedin a copper-resistant strain of yeast (R), its parent strain(P) and respiratory-deficient(RD) mutants from them. The resultsobtained are as follows:

1. Using sulfate, sulfite and thiosulfate as sulfur sources, Rproducedmore H₂S than P, and both of these had the activityhigher than their RD mutants. All of them produced a large amountof H₂S from cysteine, but only little from methionine, cysteinesulfinic acid and S-sulfocysteine.
2. From sulfite and thiosulfate,P and R produced more H₂S inaerobicthan in anaerobic condition.With sulfate and cysteine, however,H₂S production did not differunder those conditions.
3. In both P and R, the sulfate-to-sulfiteand sulfite-to-sulfidereactions were remarkably lowered byiron and zinc deficiencies.But the cysteine-to-sulfide reactionwas not affected by themetal-deficiencies.
4. H₂S productionfrom sulfate was remarkably depressed by highconcentrationsof pantothenate.
5. Rates of reaction steps on a plausible pathway from sulfatetosulfide and to organic sulfur compounds areestimated forthe strainsused. R is characterized by its largecapacity ofthe reaction step from sulfate to sulfite, and excessivesulfitethus formed is liberatedas sulfide not by the way ofcysteine.

¹Present address: Research Reactor Institute, Kyoto University,Kumatori-cho, Sennan-gun, Osaka     

Participation of Peroxidase in the Metabolism of 3,4-Dihydroxyphenylalanine and Hydrogen Peroxide in Vacuoles of Vicia faba L. Mesophyll Cells

When leaves of Vicia faba were treated with H₂O₂ or visiblelight in the presence of methyl viologen (MV), the orange-redcompound dopachrome was formed transiently and melanin was accumulated.With the darkening of leaves, the level of 3,4-dihydroxyphenylalanine(DOPA) decreased and then recovered to the original level uponaddition of 1 mM H₂O₂. However, if leaves were incubated inthe presence of 10 mM H₂O₂, the level of DOPA decreased againafter the increase. The time course of the changes in levelsof DOPA observed during the accumulation of melanin as a resultof illumination in the presence of MV was very similar to thatobserved after the addition of 10 mM H₂O₂. Illumination of leavesin the absence of MV did not result in any accumulation of melanin,but the level of DOPA changed slightly. When isolated mesophyllcells were incubated in the dark, the level of DOPA decreased.Illumination of the cells stimulated this decrease. Tropolone,an inhibitor of phenol oxidase, did not inhibit and actuallystimulated the H₂O₂- and light-induced oxidation of DOPA andaccumulation of melanin in leaves. Tropolone also stimulatedthe decrease in the levels of DOPA both in the dark and in thelight in isolated mesophyll cells. These data suggest that aperoxidase-H₂O₂ system, and not phenol oxidase, participatesin the oxidation of DOPA. When DOPA was oxidized by a basicperoxidase isolated from V.faba leaves, an intermediate, whichwas perhaps dopaquinone and which was reducible by ascorbate,was formed. Based on the data, a discussion is presented ofthe physiological significance of the oxidation of DOPA by peroxidasein vacuoles. (Received March 4, 1991; Accepted May 21, 1991)     

Enzymatic synthesis of l-cysteine by O-acetylserine sulfhydrylase of 3-chloro-l-alanine resistant Bacillus sphaericus L-118

The regulatory properties of serine-O-transacetylase and O-acetylserine sulfhydrylase have been investigated with 3-chloro-l-alanine resistant Bacillus sphaericus L-118. The enhancement of O-acetylserine sulfhydrylase formation by 3-chloro-l-alanine was observed and this effect was counteracted by corepressor l-cysteine. O-Acetylserine sulfhydrylase occurring in B. sphaericus L-118 can catalyse β-replacement reaction of 3-chloro-l-alanine in the presence of a high concentration of sodium hydrosulfide to form l-cysteine. The optimal reaction conditions for l-cysteine production were studied using resting cells. Under optimal conditions, about 80% of the added 3-chloro-l-alanine could be converted to l-cysteine. The highest yield achieved was 70 mg of l-cysteine per 1.0 ml of the reaction mixture.     

Chlorophyll Metabolism in Higher Plants VI. Involvement of Peroxidase in Chlorophyll Degradation

The following phenolics were found to be essential for peroxidase-dependentchlorophyll bleaching: 2,4-dichlorophenol (DCP), p-coumaricacid (HCA), phenol, p-hydroxyphenylacetic acid, p-hydroxybenzoicacid, p-hydroxyacetophenone, resorcinol and umbelliferone. Mostof them are monophenols with electron-attracting groups at thep-position. The short-lived radicals generated by horseradishperoxidase (HRP)-phenolics-H₂O₂ reaction might be involved inthis reaction. Tobacco leaf enzyme preparation with peroxidaseactivity for guaiacol could also degrade chlorophyll with suchphenolics. In addition, tobacco leaf methanol extract couldsubstitute for chlorophyll bleaching as an electron donor inthe absence of phenolics. In place of free H₂O₂, the glycolate-glycolateoxidase (GOX) system could degrade chlorophyll in [peroxidase$phenolics]-dependentbleaching. This chlorophyll bleaching system was inhibited by peroxidaseinhibitors, radical scavengers, reducing reagents, and carotenoids.Ascorbate and glutathione stopped chlorophyll bleaching withGSSG reductase and NADPH. The role of ascorbate and glutathionein peroxidase activity for controlling the chlorophyll degradationrate is discussed. (Received January 28, 1985; Accepted July 23, 1985)     

H2O2-mediated permeability II: importance of tyrosine phosphatase and kinase activity

We previously reportedthat exposure of endothelial cells to H₂O₂results in a loss of cell-cell apposition and increased endothelialsolute permeability. The purpose of this study was to determine howtyrosine phosphorylation and tyrosine phosphatases contribute tooxidant-mediated disorganization of endothelial cell junctions. Wefound that H₂O₂ caused a rapid decrease in total cellular phosphatase activity that facilitates a compensatory increase in cellular phosphotyrosine residues.H₂O₂ exposure also results in increasedendothelial monolayer permeability, which was attenuated by pp60, aninhibitor of src kinase. Inhibition of protein tyrosinephosphatase activity by phenylarsine oxide (PAO) demonstrated a similarpermeability profile compared with H₂O₂,suggesting that tyrosine phosphatase activity is important inmaintaining a normal endothelial solute barrier. Immunofluorescence shows that H₂O₂ exposure caused a loss ofpan-reactive cadherin and -catenin from cell junctions that was notblocked by the src kinase inhibitor PP1.H₂O₂ also caused -catenin to dissociate fromthe endothelial cytoskeleton, which was not prevented by PP1. Finally,we determined that PP1 did not prevent cadherin internalization. Thesedata suggest that oxidants like H₂O₂ produce biological effects through protein phosphotyrosine modifications bydecreasing total cellular phosphatase activity combined with increasedsrc kinase activity, resulting in increased endothelial solute permeability.

     

H(2)O(2) and ethanol act synergistically to gate ryanodine receptor/calcium-release channel

We examined theeffect of low concentrations of H₂O₂ on theCa²⁺-release channel/ryanodine receptor (RyR) to determineif H₂O₂ plays a physiological role in skeletalmuscle function. Sarcoplasmic reticulum vesicles from frog skeletalmuscle and type 1 RyRs (RyR1) purified from rabbit skeletal muscle wereincorporated into lipid bilayers. Channel activity of the frog RyR wasnot affected by application of 4.4 mM (0.02%) ethanol. Openprobability (P_o) of such ethanol-treated RyRchannels was markedly increased on subsequent addition of 10 µMH₂O₂. Increase of H₂O₂to 100 µM caused a further increase in channel activity. Applicationof 4.4 mM ethanol to 10 µM H₂O₂-treated RyRsactivated channel activity. Exposure to 10 or 100 µMH₂O₂ alone, however, failed to increaseP_o. Synergistic action of ethanol andH₂O₂ was also observed on the purified RyR1 channel, which was free from FK506 binding protein (FKBP12).H₂O₂ at 100-500 µM had no effect onpurified channel activity. Application of FKBP12 to the purified RyR1drastically decreased channel activity but did not alter the effects ofethanol and H₂O₂. These results suggest thatH₂O₂ may play a pathophysiological, butprobably not a physiological, role by directly acting on skeletalmuscle RyRs in the presence of ethanol.

     

Differential modulation of voltage-dependent K+ currents in colonic smooth muscle by oxidants

The effect of oxidants on voltage-dependent K⁺ currents was examined in mouse colonic smooth muscle cells. Exposure to either chloramine-T (Ch-T), an agent known to oxidize both cysteine and methionine residues, or the colon-specific oxidant monochloramine (NH₂Cl) completely suppressed the transient outward K⁺ current (I_to) while simultaneously enhancing the sustained delayed rectifier K⁺ current (I_dr). In contrast, the cysteine-specific oxidants hydrogen peroxide (H₂O₂) and 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) exhibited partial and slow suppression of I_to by inducing a shift in channel availability of -18 mV without affecting I_dr. After enhancement by NH₂Cl or Ch-T, I_dr was sensitive to 10 mM tetraethylammonium but not to other K⁺ channel blockers, suggesting that it represented activation of the resting I_dr and not a separate K⁺ conductance. Extracellular dithiothreitol (DTT) partially reversed the effect of H₂O₂ and DTNB on I_to but not the actions of NH₂Cl and Ch-T on either I_dr or I_to. Dialysis of myocytes with GSH (5 mM) or DTT (5 mM) prevented suppression of I_to by H₂O₂ and DTNB but did not alter the effects of NH₂Cl or Ch-T on either I_dr or I_to. Ch-T and NH₂Cl completely blocked I_to generated by murine K_v4.1, 4.2, and 4.3 in Xenopus oocytes, an effect not reversible by intracellular DTT. In contrast, intracellular DTT reversed the effect of H₂O₂ and DTNB on the cloned channels. These results suggest that I_to is suppressed via modification of both methionine and cysteine residues, whereas enhancement of I_dr likely results from methionine oxidation alone. colon; colitis; redox; ion channel     

A Comparative Study on the Effects of H2S and SO2 Fumigation on the Growth and Accumulation of Sulphate and Sulphydryl Compounds in Trifolium pratense L., Glycine max Merr. and Phaseolus vulgaris L.

Maas, F. M., De Kok, L. J., Peters, J. L. and Kuiper, P. J.C. 1987. A comparative study on the effects of H₂S and SO₂ fumigationon the growth and accumulation of sulphate and sulphydryl compoundsin Trifolium pratense L., Glycine max Merr. and Phaseolus vulgarisL.—J. exp. Bot. 38: 1459-1469. The effects of 0—25 mm³ dm³ H₂S and SO₂ on growth andsulphur content of shoots of Trifolium pratense, Glycine maxand Phaseolus vulgaris were studied. After 2 weeks of fumigationthe yield of T. pralense was reduced by 32% by H₂S, but notaffected by SO₂. Yield of G. max was not affected by H₂S, butreduced by 20% by SO₂, whereas that of P. vulgaris was increasedby 11% by H₂S and not affected by SO₂. Increases in sulphydrylcontent were already observed after 24 h of exposure to H₂Sand SO₂ in all plants. The increase was greatest in T. pratenseand smallest in P. vulgaris and, except for T. pratense, alwaysgreater in the H₂S-exposed than the SO₂-exposed plants. Oneday of exposure resulted in an increase in sulphate contentonly in the SO₂-fumigated plants, with the highest accumulationin T. pratense and the lowest in P. vulgaris. After 2 weeksan increase in sulphate content was also observed in the H₂S-exposedplants. This increase was also highest in T. pratense and lowestin P. vulgaris. Transpiration rate was not affected by a 24 h exposure to H₂Sor SO₂ and was highest in T. pratense, intermediate in G. maxand lowest in P. vulgaris. The order of theoretical rates of deposition of H₂S and SO₂correlated with the observed increases in sulphydryl contentduring the first 24 h of exposure in both H₂S and SO₂-fumigatedplants and with the increase in sulphate content in the SO₂-exposedplants. The increases in sulphydryl content were only 8% ofthe theoretical H₂S and SO₂-deposition fluxes, whereas sulphateaccumulation accounted for at least 57% of the theoretical SO₂-depositionflux. Key words: Air pollution, clover, French bean, Glutathione, Soybean, sulphur metabolism.     

The Senescence Process in Oat Leaves and its Regulation by Oxygen Concentration and Light Irradiance

The regulation of senescence by oxygen-concentration, lightirradiance and H₂O₂ has been studied in leaf segments of Avenasativa L. cv. Suregrain. The development of the components of the senescence process,for example chlorophyll breakdown, proteolysis (as soluble aminoacids), hydroperoxides (as malondi-aldehyde) and permeability(as conductivity) is accelerated in light as the O₂-tensionincreases. In darkness, 0.3% O₂ accelerates increases in hydroperoxides,permeability and proteolysis and delays the chlorophyll break-down,but 0.0005% O₂ delays all the components studied. In every casethe hydroperoxide content, permeability and proteolysis areclosely related. Any treatment inducing an increase in membranepermeability causes chlorophyll bleaching (photo-oxidation)if leaf segments are then treated with light in an atmospherecontaining oxygen. Light has a modulating effect on the senescenceprocess. An irradiance lower or higher than 40 W m^–2 hasan accelerating effect on the senescence process. (Received September 7, 1985; Accepted July 30, 1985)     

Activity of ascorbate-dependent H2O2-scavenging enzymes and leaf chlorosis are enhanced in magnesium- and potassium-deficient leaves, but not in phosphorus-deficient leaves

The effect of phosphorus (P), potassium (K), and magnesium (Mg)deficiency on the development of leaf symptoms (chlorosis andnecrosis) and activities of ascorbate-dependent H₂O₂ scavengingenzymes (ascorbate peroxidase, monodehydroascorbate reductase,dehydroascorbate reductase, and glutathione reductase) was studiedin bean (Phaseolus vulgans) plants over a 12 d period of growthin nutrient solution. With increasing plant age Mg- and K-deficientleaves developed severe interveinal chlorosis and, accordingly,chlorophyll concentrations were reduced. However, in P-deficientleaves neither chlorosis nor necrosis appeared; the leaves remaineddark green and even at an advanced stage of P deficiency, chlorophyllconcentrations were still higher than those of control plants.In K- and, particularly, Mg-deficient leaves with an increasein severity of leaf chlorosis, activity of ascorbate-dependentH₂O₂- scavenging enzymes was progressively increased. In contrast,in P-deficient leaves, as in leaves of the control plants, activityof H₂O₂-scavenging enzymes remained at a low level over the12 d period. Accordingly, compared with P-deficient and controlplants, Mg- and K-deficient leaves with elevated anti-oxidativepotential showed much higher resistance to chlorophyll destructionby the herbicide paraquat. Elevated levels of H₂O₂-scavengingenging enzymes in Mg- and K-deficient leaves indicate a higherproduction of H₂O₂ and related toxic O₂ species. It Is suggestedthat in Mg- and K-deficient leaves, utilization of photoreductantsin CO₂ fixation is restricted because of impaired export andthus accumulation of photosynthates. This disturbance mightlead to enhanced photoreduction of molecular O₂ to toxic O₂species causing chlorophyll destruction (chlorosis), a processwhich is not important in P-deficient leaves where export ofsucrose is not affected. Key words: Bean, hydrogen peroxide detoxification, leaf chlorosis, magnesium nutrition, oxygen activation, phosphorus nutrition, potassium nutrition     

过氧化氢参与了黑暗诱导的盐地碱蓬叶片甜菜红素积累

该文比较研究了黑暗和光照条件下C₃盐生植物盐地碱蓬(Suaeda salsa)叶片甜菜红素积累和H₂O₂含量及其抗氧化酶活性的关系,实验分析了甜菜红素体外抗氧化性能,以期揭示诱导盐地碱蓬甜菜红素积累的可能机制以及甜菜红素积累的生理生态意义。结果表明:暗期处理和营养液中加入一定浓度的H₂O₂都明显促进盐地碱蓬叶片H₂O₂含量、甜菜红素的含量、超氧化物歧化酶(SOD)和过氧化氢酶(CAT)的活性,而且叶片中 H₂O₂含量与甜菜红含量、SOD和CAT活性具有正相关性;盐地碱蓬甜菜红素体外清除羟自由基的能力明显强于维生素C,而清除超氧阴离子能力低于维生素C。这些结果表明:黑暗作为一种环境胁迫因子诱导盐地碱蓬叶片甜菜红素的积累可能是由自由基介导的,甜菜红素的积累可能与提高植物的抗氧化能力有关。     

Hydrogen peroxide is involved in the acclimation of the Mediterranean shrub, Cistus albidus L., to summer drought

This study evaluated the possible role of hydrogen peroxide(H₂O₂) in the acclimation of a Mediterranean shrub, Cistus albidusL., to summer drought growing under Mediterranean field conditions.For this purpose, changes in H₂O₂ concentrations and localizationthroughout a year were analysed. H₂O₂ changes in response toenvironmental conditions in parallel with changes in abscisicacid (ABA) and oxidative stress markers, together with ligninaccumulation, xylem and sclerenchyma differentiation, and leafarea were also investigated. During the summer drought, leafH₂O₂ concentrations increased 11-fold, reaching values of 10µmol g^–1 dry weight (DW). This increase occurredmainly in mesophyll cell walls, xylem vessels, and sclerenchymacells in the differentiation stage. An increase in ABA levelspreceded that of H₂O₂, but both peaked at the same time in conditionsof prolonged stress. C. albidus plants tolerated high concentrationsof H₂O₂ because of its localization in the apoplast of mesophyllcells, xylem vessels, and in differentiating sclerenchyma cells.The increase in ABA, and consequently of H₂O₂, in plants subjectedto drought stress might induce a 3.5-fold increase in ascorbicacid (AA), which maintained and even decreased its oxidativestatus, thus protecting plants from oxidative damage. Afterrecovery from drought following late-summer and autumn rainfall,a decrease in ABA, H₂O₂, and AA to their basal levels (60 pmolg^–1 DW, 1 µmol g^–1 DW, and 20 µmol g^–1DW) was observed. Key words: Abscisic acid, ascorbate, ascorbate oxidative status, Cistus albidus, hydrogen peroxide, leaf plasticity, lignin, Mediterranean shrubs, oxidative markers, summer drought Received 29 July 2008; Revised 15 September 2008 Accepted 8 October 2008     

Carotenoid photobleaching induced by photosystem II action in the membrane fragments of the blue-green alga Anabaena variabilis : Action of O2

Carotenoid photobleaching induced by photosystem II action wasstudied using membrane fragments of the blue-green alga Anabaenavariabilis. Special attention was paid to the action of O₂. Carotenoid photobleaching elicited by carbonyl cyanide m-chlorophenylhydrazone(CCCP) depended on O₂. However, the addition of H₂O₂, sodiumsilicotungstate or potassium ferricyanide (Ferri), an electronacceptor for reaction center II action, removed the O₂-dependency.These results indicate that O₂ acts as the electron acceptorfor this reaction. When both CGCP and Ferri were present, a short illumination(0.25 sec) caused a rapid photobleaching followed by a slowrecovery in the subsequent dark period. The spectrum of theabsorption decrease in the light was identical with that ofthe absorption increase in the subsequent dark, indicating thata reversible process is involved in the carotenoid photobleaching.The size in the dark recovery relative to the light bleachingbecame larger under anaerobic conditions and smaller under higherpartial pressure of O₂. The reuslts were interpreted as indicatingthat O₂ does not function in the primary process including areversible bleaching step, but is involved in the slow and irreversiblebleaching process. (Received April 3, 1978; )