Inhibition of Ethylene Production in Penicillium digitatum

Production of ethylene by static cultures of Penicillium digitatum, which utilize glutamate and α-ketoglutarate as ethylene precursors, was inhibited by methionine, methionine sulfoxide, methionine sulfone, and methionine sulfoximine. Rhizobitoxine did not affect ethylene production but its ethoxy and methoxy analogues were effective inhibitors of ethylene production; its saturated methoxy analogue and kainic acid stimulated ethylene production. Tracer studies showed that the inhibitors blocked the conversion of [³H]glutamate into [³H]ethylene.

In shake cultures of this fungus, which utilize methionine as the ethylene precursor, rhizobitoxine and its unsaturated analogues all inhibited, while the saturated methoxy analogue stimulated ethylene production. In both types of cultures inhibition was irreversible and was diminished by increasing concentrations of the ethylene precursor. The inhibitory activity or lack of it by rhizobitoxine and its analogues appears to be a function of their structural resemblance to glutamate and methionine as well as of their size and stereoconfiguration. These data suggest similarities between the ethylene-forming system in the fungus and in higher plants despite differences in precursors under some cultural conditions.

     

Regulation of Auxin-induced Ethylene Production in Mung Bean Hypocotyls: Role of 1-Aminocyclopropane-1-Carboxylic Acid

Ethylene production in mung bean hypocotyls was greatly increased by treatment with 1-aminocyclopropane-1-carboxylic acid (ACC), which was utilized as the ethylene precursor. Unlike auxin-stimulated ethylene production, ACC-dependent ethylene production was not inhibited by aminoethoxyvinylglycine, which is known to inhibit the conversion of S-adenosylmethionine to ACC. While the conversion of methionine to ethylene requires induction by auxin, the conversion of methionine to S-adenosylmethionine and the conversion of ACC to ethylene do not. It is proposed that the conversion of S-adenosylmethionine to ACC is the rate-limiting step in the biosynthesis of ethylene, and that auxin stimulates ethylene production by inducing the synthesis of the enzyme involved in this reaction.     

Ethylene production by callus and suspension cells from cortex tissue of postclimacteric apples

Cortex tissue from postclimacteric `Golden Delicious' apples (Malus domestica, Borkh.) stored at 0 C for 9 months after harvest were induced to form callus in vitro. Cell suspension cultures were subsequently formed from calli. Of five media tested, only the medium of Schenk and Hildebrandt (Can J Bot 1972, 50: 192) and that of Uchimiya and Murashige (Plant Physiol 1974, 54: 936) allowed callus formation. During growth both the callus and cell cultures produced ethylene in a pattern which showed a rapid rise and then a fall as the culture grew. ¹⁴C-Labeled methionine was converted to labeled ethylene by the cell suspension cultures, which also could be inhibited from producing ethylene by a rhizobitoxine analog or free radical scavengers. Ethylene production in these cultures, like that in intact fruit tissue slices, could be stimulated by IAA or suppressed by N⁶-(γ,γ-dimethylallyl) adenosine and GA₃.     

Enhancement of wound-induced ethylene synthesis by ethylene in preclimacteric cantaloupe

Although intact fruits of unripe cantaloupe (Cucumis melo L.) produce very little ethylene, a massive increase in ethylene production occurred in response to excision. The evidence indicates that this wound ethylene is produced from methionine via 1-aminocyclopropanecarboxylic acid (ACC) as in ripening fruits. Excision induced an increase in both ACC synthase and the enzyme converting ACC to ethylene. Ethylene further increased the activity of the enzyme system converting ACC to ethylene. The induction by ethylene required a minimum exposure of 1 hour; longer exposure had increasingly larger effect. The response was saturated at approximately 3 microliters per liter ethylene and was inhibited by Ag⁺. Neither ethylene nor ACC had a promotive or inhibitory effect on ACC synthase beyond the effect attributable to wounding.     

Stimulation of ethylene production in tomato tissue by propionic Acid

Propionic acid (10⁻³m) increases ethylene production by about 30 to 60% in tissue from green and half-ripe tomatoes (Lycopersicon esculentum Mill. var. Homestead) but does not increase ethylene production in tissue from ripe fruit. Stimulation is not due to the conversion of propionic acid to ethylene but appears to be secondary in nature and to operate on the endogenous ethylene-forming system. Thus conversion of methionine to ethylene in green and half-ripe tomato tissue is increased in the presence of propionic acid. Inhibitors which affect the normal endogenous ethylene-forming system similarly affect the propionic acid-stimulated system. Endogenous propionic acid may play a role in the regulation of ethylene production in tomato tissues.     

Methionine metabolism in apple tissue: implication of s-adenosylmethionine as an intermediate in the conversion of methionine to ethylene

If S-adenosylmethionine (SAM) is the direct precursor of ethylene as previously proposed, it is expected that 5′-S-methyl-5′-thioadenosine (MTA) would be the fragment nucleoside. When [Me-¹⁴C] or [³⁵S]methionine was fed to climacteric apple (Malus sylvestris Mill) tissue, radioactive 5-S-methyl-5-thioribose (MTR) was identified as the predominant product and MTA as a minor one. When the conversion of methionine into ethylene was inhibited by _l-2-amino-4-(2′-aminoethoxy)-trans-3-butenoic acid, the conversion of [³⁵S] or [Me¹⁴C]methionine into MTR was similarly inhibited. Furthermore, the formation of MTA and MTR from [³⁵S]methionine was observed only in climacteric tissue which produced ethylene and actively converted methionine to ethylene but not in preclimacteric tissue which did not produce ethylene or convert methionine to ethylene. These observations suggest that the conversion of methionine into MTA and MTR is closely related to ethylene biosynthesis and provide indirect evidence that SAM may be an intermediate in the conversion of methionine to ethylene.     

N-acetyl-L-cysteine in the presence of Cu<Superscript>2+</Superscript> induces oxidative stress and death of granule neurons in dissociated cultures of rat cerebellum

Addition into the culture medium of the antioxidant N-acetylcysteine (NAC, 1 mM) in the presence of Cu²⁺ (0.0005-0.001 mM) induced intensive death of cultured rat cerebellar granule neurons, which was significantly decreased by the zinc ion chelator TPEN (N,N,N′,N′-tetrakis(2-pyridylmethyl)ethylenediamine). However, the combined action of NAC and Zn²⁺ did not induce destruction of the neurons. Measurement of the relative intracellular concentration of Zn²⁺ with the fluorescent probe FluoZin-3 AM or of free radical production using a CellROX Green showed that incubation of the culture for 4 h with Cu²⁺ and NAC induced an intensive increase in the fluorescence of CellROX Green but not of FluoZin-3. Probably, the protective effect of TPEN in this case could be mediated by its ability to chelate Cu²⁺. Incubation of cultures in a balanced salt solution in the presence of 0.01 mM Cu²⁺ caused neuronal death already after 1 h if the NAC concentration in the solution was within 0.005–0.05 mM. NAC at higher concentrations (0.1–1 mM) together with 0.01mM Cu²⁺ did not cause the death of neurons. These data imply that the antioxidant NAC can be potentially harmful to neurons even in the presence of nanomolar concentrations of variable valence metals.     

Enhancement of ethylene formation by selenoamino acids

Selenomethionine and selenoethionine enhanced ethylene production in senescing flower tissue of Ipomoea tricolor Cav. and in auxin-treated pea (Pisum sativum L.) stem sections. This enhancement was fully inhibited by the aminoethoxy analog of rhizobitoxine. Methionine did not have a comparable promotive effect, and ethionine partly inhibited ethylene production. When [¹⁴C]methionine was applied to flower or pea stem tissue followed by treatment with unlabeled selenomethionine or selenoethionine, the specific radioactivity of the ethylene evolved was considerably reduced. The dilution of the specific radioactivity of ethylene by selenomethionine, and in pea stem sections also by selenoethionine, was greater than the dilution by nonradioactive methionine at the same concentration. These results indicate that both selenoamino acids serve as precursors of ethylene and that they are converted to ethylene more efficiently than is methionine.     

Auxin-induced Ethylene Production and Its Inhibition by Aminoethyoxyvinylglycine and Cobalt Ion

Auxin is known to stimulate greatly both C₂H₄ production and the conversion of methionine to ethylene in vegetative tissues, while amino-ethoxyvinylglycine (AVG) or Co²⁺ ion effectively block these processes. To identify the step in the ethylene biosynthetic pathway at which indoleacetic acid (IAA) and AVG exert their effects, [3-¹⁴C]methionine was administered to IAA or IAA-plus-AVG-treated mung bean hypocotyls, and the conversion of methionine to S-adenosylmethionine (SAM), 1-amino-cyclopropane-1-carboxylic acid (ACC), and C₂H₄ was studied. The conversion of methionine to SAM was unaffected by treatment with IAA or IAA plus AVG, but active conversion of methionine to ACC was found only in tissues which were treated with IAA and which were actively producing ethylene. AVG treatment abolished both the conversion of methionine to ACC and ethylene production. These results suggest that in the ethylene biosynthetic pathway (methionine → SAM → ACC → C₂H₄) IAA stimulates C₂H₄ production by inducing the synthesis or activation of ACC synthase, which catalyzes the conversion of SAM to ACC. Indeed, ACC synthase activity was detected only in IAA-treated tissues and its activity was completely inhibited by AVG. This conclusion was supported by the observation that endogenous ACC accumulated after IAA treatment, and that this accumulation was completely eliminated by AVG treatment. The characteristics of Co²⁺ inhibition of IAA-dependent and ACC-dependent ethylene production were similar. The data indicate that Co²⁺ exerts its effect by inhibiting the conversion of ACC to ethylene. This conclusion was further supported by the observation that when Co²⁺ was administered to IAA-treated tissues, endogenous ACC accumulated while ethylene production declined.     

Control of methionine synthesis by lysine in Lemna minor

When Lemna minor was cultured in the presence of 0.25 mM l-lysine, the concentration of free methionine and formyl and methyl tetrahydrofolate (THFA) were decreased. l-lysine, l-homoserine, l-threonine and l-methionine at concentrations up to 8 mM did not affect N¹⁰-formyl THFA synthetase (E.C. 6.3.4.3) and N⁵,N¹⁰-methylene THFA reductase (E.C. 1.1.1.68). In contrast, serine hydroxymethyltransferase (E.C. 2.1.2.1) activity was inhibited by lysine. This inhibition gave a sigmoidal curve when plotted for a range of l-lysine or THFA concentrations. Exogenous lysine also reduced the incorporation of glycine [¹⁴C] and serine [3-¹⁴C] into free and protein methionine. Lysine, which is known to control synthesis of homocysteine in L. minor, may also regulate production of C-1 units for methionine synthesis by inhibition of serine hydroxymethyltransferase.     

Carbohydrates Stimulate Ethylene Production in Tobacco Leaf Discs : II. Sites of Stimulation in the Ethylene Biosynthesis Pathway

Galactose, sucrose, and glucose (50 millimolar) applied to tobacco leaf discs (Nicotiana tabacum L. cv `Xanthi') during a prolonged incubation (5-6 d) markedly stimulated ethylene production which, in turn, could be inhibited by aminoethoxyvinylglycine (2-amino-4-(2′-aminoethoxy)-trans-3-butenoic acid) (AVG) or Co²⁺ ions. These three tested sugars also stimulated the conversion of l-[3,4-¹⁴C]methionine to [¹⁴C]1-amino-cyclopropane-1-carboxylic acid (ACC) and to [¹⁴C]ethylene, thus indicating that the carbohydrates-stimulated ethylene production proceeds from methionine via the ACC pathway. Sucrose concentrations above 25 mm considerably enhanced ACC-dependent ethylene production, and this enhancement was related to the increased respiratory carbon dioxide. However, sucrose by itself could directly promote the step of ACC conversion to ethylene, since low sucrose concentrations (1-25 mm) enhanced ACC-dependent ethylene production also in the presence of 15% CO₂.     

Somatic embryogenesis and plant regeneration in garden leek

High frequency plant regeneration via somatic embryogenesis has been induced from in vitro shoot-base cultures of seedlings of garden leek (Allium porrum L.). Four main steps are involved in the procedure using BDS medium:

- shoot multiplication with 17.6 mM benzyladenine;

- induction of nodular callus from the in vitro shoot base with 9 mM 2,4-dichlorophenoxyacetic acid;

- initiation of embryogenic callus from nodular callus with 9 mM 2,4-dichlorophenoxyacetic acid +7.6 mM abscisic acid;

- plant regeneration from embryogenic callus with 9.8 mM N⁶-(2-isopentenyl)adenine.

The presence of 2,4-dichlorophenoxyacetic acid in the medium and light conditions were shown to be essential for nodular callus induction and somatic embryogenesis. Abscisic acid was not a prerequiste for somatic embryogenesis, but it significantly increased the frequency.     

Efficiency of indoleacetic acid,gibberellic acid and ethylene synthesized in vitro by Fusarium culmorum strains with different effects on cereal growth

Three different Fusarium culmorum strains having a pathogenic, a deleterious (deleterious rhizosphere microorganism), or a promoting (plant growth promoting fungus) effect on plant growth were studied for their ability to synthesize in vitro the phytohormones indoleacetic acid (IAA), gibberellic acid (GA), and ethylene. All the phytohormones tested were synthesized in cultures supplemented with wide concentration ranges of glucose and tryptophan or methionine (precursors of phytohormone synthesis). The amounts of these secondary metabolites synthesized by the particular strains were found to be significantly different. The non-pathogenic PGPF strain (DEMFc2) synthesized the highest amounts of IAA and GA, a fact that could be responsible for the growth-promoting properties of this strain. A pathogenic strain synthesized the highest amount of ethylene, which could be responsible for the negative effect of this strain on plant growth. F. culmorum isolates with a high capacity for IAA synthesis also have a high capacity for GA synthesis and irrespective of the growth conditions, a high positive correlation (R > 0.9) between the concentrations of synthesized IAA and GA in F. culmorum cultures was found. It is worth mentioning that the optimal conditions for the growth of F. culmorum isolates and the synthesis of the individual phytohormones differed from one another. The optimal growth conditions were 1.0% of glucose and 9.9 mM of methionine or 6.0 mM of tryptophan. The optimal conditions for ethylene synthesis were 0.5% of glucose and 6.6 mM of methionine, whereas 1.0% of glucose and 9.0 mM of tryptophan were optimal for IAA and GA synthesis.     

Ethylene synthesis and growth of tomato hypocotyls: Induction by auxin and fusicoccin and inhibition by vanadate

The effects of fusicoccin (FC) on growth and ethylene synthesis of tomato (Lycopersicon esculentum Mill.) hypocotyls were compared to those of indole-3-acetic acid (IAA). Fusicoccin promoted both growth and ethylene production maximally at <2M. Growth was stimulated to a slightly greater extent by FC as compared to IAA, while ethylene synthesis rates in response to FC were about 50% less than those induced by IAA. Cycloheximide (0.5 M) inhibited auxin-induced growth by 80% but had no effect on FC-induced growth; ethylene production was inhibited to the same extent (58%) when induced by either IAA or FC. Both IAA and FC caused tissue contents of 1-aminocyclopropane-1-carboxylic acid (ACC) and malonyl-ACC to increase, indicating that like IAA, FC induces ethylene synthesis by stimulating the formation of ACC. Orthovanadate, a potent inhibitor of proton-translocating plasma membrane ATPases, reduced both IAA- and FC-induced growth and ethylene synthesis at concentrations less than 1 mM, with ethylene synthesis being approximately 10 times more sensitive to inhibition than growth. Vanadate did not affect tissue ACC levels, slightly reduced total ACC production, and inhibited conversion of ACC to ethylene. However, significant inhibition of in vivo ethylene-forming enzyme activity required high concentrations of vanadate (1 mM) and was less effective than inhibition by cobaltous ion. The site of action of vanadate in inhibiting ethylene synthesis remains unclear, but the ion did not prevent the elevation of tissue ACC levels in response to IAA or FC. It is unlikely, therefore, that stimulation of plasma membrane H⁺-ATPase activity is required for the induction of ACC synthase by IAA and FC.     

An Exported Inducer Peptide Regulates Bacteriocin Production in Enterococcus faecium CTC492

Production of the bacteriocins enterocin A and enterocin B in Enterococcus faecium CTC492 was dependent on the presence of an extracellular peptide produced by the strain itself. This induction factor (EntF) was purified, and amino acid sequencing combined with DNA sequencing of the corresponding gene identified it as a peptide of 25 amino acids. The gene encodes a prepeptide of 41 amino acids, including a 16-amino-acid leader peptide of the double-glycine type. Environmental factors influenced the level of bacteriocin production in E. faecium CTC492. The optimal pH for bacteriocin production was 6.2. At pH 5.5, growth was slow, and very little bacteriocin was formed. The presence of NaCl or ethanol (EtOH) was also inhibitory to bacteriocin production, and at high concentrations of these solutes, no bacteriocin production was observed. The induction factor induced its own synthesis, and by dilution of the culture 10⁶ times or more, nonproducing cultures were obtained. Bacteriocin production was induced in these cultures by addition of EntF. The response was linear, and low bacteriocin production could be induced by about 10⁻¹⁷ M EntF. This response was attenuated by low pH or the presence of high concentrations of NaCl or EtOH, and 300 times more EntF was needed to induce detectable bacteriocin production in the presence of 6.5% NaCl. High levels of bacteriocin production in cultures grown at low pH or in the presence of high concentrations of NaCl or EtOH were obtained by addition of sufficient amounts of EntF.     

Effect of polyamines on ethylene production

The polyamines putrescine, cadaverine, spermidine and spermine reduced the amount of ethylene produced by senescing petals of Tradescantia but they did not prevent anthocyanin leakage from these same petals. These polyamines also inhibited auxin-mediated ethylene production by etiolated soybean hypocotyls to less than 7 % of the control. The basic amino acids lysine and histidine reduced the amount of auxin-induced ethylene produced by soybean hypocotyls by ca 50 %. In the hypocotyls, methionine was unable to overcome the inhibition caused by the polyamines. The polyamines spermidine and spermine inhibited ethylene production induced by the application of 1-aminocyclopropane-1-carboxylic acid and they also reduced the endogenous content of this amino acid in the treated tissues.     

Ethylene formation by cultures of Escherichia coli

Growth of Escherichia coli strain B SPAO on a medium containing glucose, NH₄Cl and methionine resulted in production of ethylene into the culture headspace. When methionine was excluded from the medium there was little formation of ethylene. Ethylene formation in methionine-containing medium occurred for a brief period at the end of exponential growth. Ethylene formation was stimulated by increasing the medium concentration of Fe³⁺ when it was chelated to EDTA. Lowering the medium phosphate concentration also appeared to stimulate ethylene formation. Ethylene formation was inhibited in cultures where NH₄Cl remained in the stationary phase. Synthesis of the ethylene-forming enzyme system was determined by harvesting bacteria at various stages of growth and assaying the capacity of the bacteria to form ethylene from methionine. Ethylene forming capacity was greatest in cultures harvested immediately before and during the period of optimal ethylene formation. It is concluded that ethylene production by E. coli exhibits the typical properties of secondary metabolism.Abbreviations HMBA 2-Hydroxy-4-methylthiobutyric acid (methionine hydroxy analogue) - KMBA 2-keto-4-methylthiobutyric acid - MOPS 3-[N-morpholino] propanesulphonic acid     

Regulatory Role of Cystathionine-γ-Synthase and de novo Synthesis of Methionine in Ethylene Production during tomato Fruit Ripening

The essential amino acid methionine is a substrate for the synthesis of S-adenosyl-methionine (SAM), that donates its methyl group to numerous methylation reactions, and from which polyamines and ethylene are generated. To study the regulatory role of methionine synthesis in tomato fruit ripening, which requires a sharp increase in ethylene production, we cloned a cDNA encoding cystathionine γ-synthase (CGS) from tomato and analysed its mRNA and protein levels during tomato fruit ripening. CGS mRNA and protein levels peaked at the “turning” stage and declined as the fruit ripened. Notably, the tomato CGS mRNA level in both leaves and fruit was negatively affected by methionine feeding, a regulation that Arabidopsis, but not potato CGS mRNA is subject to. A positive correlation was found between elevated ethylene production and increased CGS mRNA levels during the ethylene burst of the climacteric ripening of tomato fruit. In addition, wounding of pericarp from tomato fruit at the mature green stage stimulated both ethylene production and CGS mRNA level. Application of exogenous methionine to pericarp of mature green fruit increased ethylene evolution, suggesting that soluble methionine may be a rate limiting metabolite for ethylene synthesis. Moreover, treatment of mature green tomato fruit with the ethylene-releasing reagent Ethephon caused an induction of CGS mRNA level, indicating that CGS gene expression is regulated by ethylene. Taken together, these results imply that in addition to recycling of the methionine moieties via the Yang pathway, operating during synthesis of ethylene, de novo synthesis of methionine may be required when high rates of ethylene production are induced.     

Generation of one-carbon units in methionine-supplemented Euglena cells

The possible effect of L-methionine supplements on the folate metabolism of division-synchronized Euglena gracilis (strain Z) cells has been examined. Cells receiving 1 mM L-methionine for four cell cycles were examined for folate derivatives, prior to and during cell division. Before cell division, methionine-supplemented cells contained less formylfolate but more methylfolate than unsupplemented cells. During division, both types of folates were present in lower concentrations in the supplemented cells. Growth in methionine for 10 and 34 hr also increased the levels of free aspartate, threonine, serine, cysteine and methionine relative to the controls. Methionine-supplemented cells contained ca 50% of the 10-formyltetrahydrofolate synthetase (EC 6.3.4.3) activity per cell of unsupplemented control cultures and specific enzyme activity was reduced ca 90%. Supplemented cells contained almost twice as much serine hydroxymethyltransferase (EC 2.1.2.1) activity per cell but comparable levels of glycollate dehydrogenase. Growth in methionine also reduced the incorporation of formate-¹⁴C] into serine, RNA, DNA, adenine and protein methionine. In contrast, incorporation of glycine-[2-¹⁴C] and serine-[3-¹⁴C] into folate-related products was not greatly altered by this treatment. Levels of radioactivity in these products suggested that formate was a more important C₁ unit source than glycine or serine when growth occurred in unsupplemented medium. It is concluded that methionine reduces formylfolate production by an effect on the cellular levels of formyltetrahydrofolate synthetase.