Salicylhydroxamic Acid-Resistant and Sensitive Components of Respiration in Chilling-Sensitive Plants Subjected to a Daily Short-Term Temperature Drop

Russian Journal of Plant Physiology - Salicylhydroxamic acid (SHAM) is used in studies of plant respiratory metabolism as a specific inhibitor of alternative cyanide-resistant oxidase (AOX). The...     

Effects of salicylhydroxamic acid on the proliferation of Atriplex and murine neuroblastoma cells, and on Drosophila egg laying and development

Salicylhydroxamic acid (SHAM) inhibits the proliferation of cultured plant (Atriplex halimus) and murine neuroblastoma cells with IC50 of 90 and 250 microM, respectively. After 2 h of application, SHAM induces an acceleration of the neuroblastoma cell cycle from G1/S to G2 phases and, after 6 h, it induces an accumulation of the cells in S phase and a cell swelling. Up to 300 microM, SHAM is not cytotoxic and does not induce electrophysiological differentiation of neuroblastoma cells. When Drosophila females are grown in media containing 0.6-1.25 mM SHAM, the rate and number of laid eggs are increased. Furthermore, SHAM stimulates the different development stages from embryo to adult. A general interpretation of the effects of SHAM on cell proliferation and differentiation is proposed.     

Salicylic Acid Interferes with Tobacco Mosaic Virus Replication via a Novel Salicylhydroxamic Acid-Sensitive Mechanism

Salicylic acid (SA) induces resistance to all plant pathogens, including bacteria, fungi, and viruses, but the mechanism by which SA engenders resistance to viruses is not known. Pretreatment of tobacco mosaic virus (TMV)-susceptible (nn genotype) tobacco tissue with SA reduced the levels of viral RNAs and viral coat protein accumulating after inoculation with TMV. Viral RNAs were not affected equally, suggesting that SA treatment interferes with TMV replication. Salicylhydroxamic acid (SHAM), an inhibitor of the mitochondrial alternative oxidase, antagonized both SA-induced resistance to TMV in nn genotype plants and SA-induced acquired resistance in resistant (NN genotype) tobacco. SHAM did not inhibit induction of the PR-1 pathogenesis-related protein or induction of resistance to Erwinia carotovora or Botrytis cinerea by SA. This indicates that SA induces resistance to TMV via a novel SHAM-sensitive signal transduction pathway (potentially involving alternative oxidase), which is distinct from that leading to resistance to bacteria and fungi.     

Trypanosoma brucei: trypanocidal effect of salicylhydroxamic acid plus glycerol in infected rats.

Rats inoculated with Trypanosoma brucei brucei EATRO 427 and having a high degree of parasitemia were treated with a series of intra-peritoneal injections of Salicylhydroxamic acid (SHAM) plus glycerol. Permanent cures were obtained with 380 mg/kg SHAM plus 3.8 g/kg glycerol, a dosage regime which was just sublethal. Using a regime with which permanent cure was obtained, the SHAM concentration in the blood plasma remained above 2 mmole/liter for about 20 min, while the glycerol concentration remained above 22 mmole/liter for about 1 hr. The brain concentration of SHAM was close to the plasma concentration. The concentration of glycerol in the brain remained far below the plasma concentration, reaching 6 to 8 mmole/liter between 1 and 2 hr after the beginning of treatment. Treatment with glycerol did not affect the mobility of the trypanosomes nor the survival of infected rats after treatment with suramin.     

Salicylhydroxamic Acid (SHAM) Inhibition of the Dissolved Inorganic Carbon Concentrating Process in Unicellular Green Algae

Rates of photosynthetic O₂ evolution, for measuring K_0.5(CO₂ + HCO₃⁻) at pH 7, upon addition of 50 micromolar HCO₃⁻ to air-adapted Chlamydomonas, Dunaliella, or Scenedesmus cells, were inhibited up to 90% by the addition of 1.5 to 4.0 millimolar salicylhydroxamic acid (SHAM) to the aqueous medium. The apparent K₁(SHAM) for Chlamydomonas cells was about 2.5 millimolar, but due to low solubility in water effective concentrations would be lower. Salicylhydroxamic acid did not inhibit oxygen evolution or accumulation of bicarbonate by Scenedesmus cells between pH 8 to 11 or by isolated intact chloroplasts from Dunaliella. Thus, salicylhydroxamic acid appears to inhibit CO₂ uptake, whereas previous results indicate that vanadate inhibits bicarbonate uptake. These conclusions were confirmed by three test procedures with three air-adapted algae at pH 7. Salicylhydroxamic acid inhibited the cellular accumulation of dissolved inorganic carbon, the rate of photosynthetic O₂ evolution dependent on low levels of dissolved inorganic carbon (50 micromolar Na-HCO₃), and the rate of ¹⁴CO₂ fixation with 100 micromolar [¹⁴C] HCO₃⁻. Salicylhydroxamic acid inhibition of O₂ evolution and ¹⁴CO₂-fixation was reversed by higher levels of NaHCO₃. Thus, salicylhydroxamic acid inhibition was apparently not affecting steps of photosynthesis other than CO₂ accumulation. Although salicylhydroxamic acid is an inhibitor of alternative respiration in algae, it is not known whether the two processes are related.     

Do some plant responses to cytokinins involve the cyanide-resistant respiratory pathway?

A disengagement of the cyanide-resistant, alternative respiratory pathway in soybean (Glycine max (L.) Merr.) callus tissue was observed prior to the start of deoxyisoflavone production stimulated by addition of the cytokinin benzyladenine. To test whether this loss of alternativepathway activity was part of the response to cytokinin, inhibitors of the alternative pathway were assayed for their ability to elicit cytokinin-like responses. Salicylhydroxamic acid (SHAM) was found to produce a deoxyisoflavone difference spectrum similar to that observed following treatment of the callus tissue with benzyladenine, while propyl gallate (PG) was without effect. Both SHAM and PG were further tested for cytokinin-like activity in other bioassays. In two anti-senescence bioassays using leaf tissue (of Avena sativa L. and Xanthium pensylvanicum Wallr.) and in the Cucumis sativus L. bioassay which measures stimulation of weight gain by excised cotyledons, both SHAM and PG were effective cytokinins at 1 mM and 0.1 mM, respectively. In two other bioassays (betacyanin formation in Amaranthus caudatus L. seedlings and the soybean-callus celldivision assay), SHAM appeared to be toxic. These results substantiate the suggestion that effects on the alternative pathway may play a role in some cytokinin responses and further raise the question of what should be considered a true cytokinin response.Abbreviations BA benzyladenine - DMSO dimethyl sulfoxide - PG n-propylgallate - SHAM salicylhydroxamic acid     

Salicylhydroxamic acid-stimulated NADH oxidation by purified plasmalemma vesicles from wheat roots

Purified, right side-out plasmalemma vesicles were isolated from 7-day-old roots of dark-grown wheat ( Triticum aestivum L. cv. Drabant) by aqueous polymer two-phase partitioning. The oxygen consumption by these vesicles at pH 6.5 in the presence of 1 m M NADH [12–29 nmol (mg protein)⁻¹min⁻¹] was 66% inhibited by 1 m M KCN and ca 40% by 1 m M EDTA. It was unaffected by rotenone, antimycin A, carbonyl cyanide trifluoromethoxyphenylhydrazone (FCCP), mersalyl, chlorotetracycline + Ca²⁺, and EGTA. Salicylhydroxamic acid (SHAM) and its analogue, m -chlorobenzhydroxamic acid, stimulated the rate of oxygen consumption 10–20 fold in the presence of 1 m M NAD(P)H with an apparent K_m (SHAM) of ca 40 μ M (with NADH). The dependence of O₂ consumption on NADH concentration in the presence of SHAM (2 m M ) was sigmoidal, possibly due to endogenous catalase activity, and half-maximal rate was obtained at 1.5 m M . In the absence of SHAM the rate increased with increasing acidity and no pH optimum was detectable between pH 4.5 and 8.5. In the presence of SHAM an optimum was observed at pH 6.5 and 0.8 mol of H₂O₂ was produced for every 1 mol O₂ consumed. Endogenous catalase converted this H₂O₂ to O₂ and after complete conversion the stoichiometry was 2 mol NADH consumed for every mol O₃. SHAM was not consumed in the reaction. The possible involvement of a cytochrome P-450/420 system is discussed.     

Effect of Salicylhydroxamic Acid on Endosperm Strength and Embryo Growth of Lactuca sativa L. cv Waldmann''s Green Seeds

Salicylhydroxamic acid (SHAM) stimulated germination of photosensitive lettuce (Lactuca sativa L. cv Waldmann's Green) seeds in darkness. To determine whether SHAM acts on the embryo or the endosperm, we investigated separately effects of SHAM on growth potential of isolated embryos as well as on endosperm strength. Embryo growth potential was quantified by incubating decoated embryos in various concentrations of osmoticum and measuring subsequent radicle elongation. Growth potential of embryos isolated from seeds pretreated with 4 millimolar SHAM was equal to that of untreated controls. Rupture strength of endosperm tissue excised from seeds pretreated with SHAM was 33% less than that of controls in the micropylar region. To determine if the embryo must be in contact with the endosperm for SHAM to weaken the endosperm, some endosperms were incubated with SHAM only after dissection from seeds. Rupture strength of SHAM-treated, isolated endosperms in the micropylar region was 25% less than that of untreated controls. There was no difference in rupture strength in the cotyledonary region of endosperm isolated from seeds treated with SHAM in buffer or buffer alone. SHAM therefore stimulates germination not by enhancing embryo growth potential, but by weakening the micropylar region of the endosperm enclosing the embryo.     

Inhibition by Salicylhydroxamic Acid, BW755C, Eicosatetraynoic Acid, and Disulfiram of Hypersensitive Resistance Elicited by Arachidonic Acid or Poly-l-Lysine in Potato Tuber

The hypothesis that arachidonic acid (AA) induction of sesquiterpene accumulation and browning in potato (Solanum tuberosum) is mediated by a lipoxygenase metabolite of AA was tested using lipoxygenase inhibitors. Salicylhydroxamic acid (SHAM) and 3-amino-1-(3-trifluoromethylphenyl)-2-pyrazoline hydrochloride (BW755C) delayed the response to AA. Inhibition by eicosatetraynoic acid (ETYA) was more persistent. These results are consistent with previous reports that SHAM and BW755C are reversible inhibitors of lipoxygenase and easily oxidized by potato while ETYA acts as an irreversible inhibitor. Disulfiram (tetraethylthiuram disulfide) also inhibited AA elicitor activity. SHAM was most effective if applied at the time of AA treatment, having no effect if applied 6 hours afterward. SHAM was effective in the presence of MES or MOPS buffers but not in acetate-buffered or unbuffered solutions; neither BW755C nor ETYA exhibited this restriction. However, SHAM, BW755C, and ETYA also were inhibitors of browning and sesquiterpene accumulation elicited in potato by poly-l-lysine, which, unlike AA, is not a lipoxygenase substrate. SHAM effectiveness also was restricted to 6 hours after treatment with poly-l-lysine. While the results with AA support a role for lipoxygenase, those with poly-l-lysine may be evidence that these compounds are having other effects in potato tissue.     

Salicylhydroxamic acid enhances the NADH-oxidase activity of peroxidase in pea mitochondrial and chloroplast suspensions

Salicylhydroxamic acid (SHAM), an alternative oxidase inhibitor of plant mitochondria, enhances the NADH-oxidase activity in mitochondrial and chloroplast suspensions obtained from pea roots or leaves, respectively. This reaction is inhibited by the washing of mitochondria or chloroplasts and is observed in supernatants after the removal of the organelles by centrifugation. The reaction is sensitive to CN^– and to antioxidant propyl gallate. The NADH oxidation is also enhanced by 2,4-dichlorophenol or phenol, but not salicylic acid. The acceleration of NADH oxidation by phenolic compounds is observed with presence of commercial horseradish peroxidase and is connected with the involvement of these compounds in NADH-dependent peroxidase reaction. SHAM and 2,4-dichlorophenol significantly enhance the destruction of nuclei in guard cells of pea leaf epidermis caused by the generation of reactive oxygen species during the oxidation of exogenous NADH by apoplastic peroxidase.     

Preparation of 5- and 6-(aminomethyl)fluorescein.

5(6)-Carboxyfluorescein is protected as the diacetate then reduced to 5(6)-(hydroxymethyl)fluorescein diacetate. The separated isomers are subjected to a Mitsunobu reaction with dibenzyl imidodicarbonate, yielding diprotected 5- and 6-(aminomethyl)fluorescein diacetate. Methanolysis of the acetates followed by deprotection with HBr/acetic acid gives 5- and 6-(aminomethyl)fluorescein hydrobromide.     

Phytophthora palmi分泌的10.6kD蛋白激发烟草的过敏反应

从疫霉菌Ｐｈｙｔｏｐｈｔｈｏｒａ ｐａｌｍｉｖｏｒａ Ｂｕｔｌｅｒ的培养滤液中分离出分子量为１０．６ｋＤ的不含糖基的耐热蛋白．这种１０．６ｋ蛋白能诱导烟草（Ｎｉｃｏｔｉａｎａ ｔａｂａｃｕｍ Ｌ．）叶片发生过敏性坏死反应。而疫霉菌另一种Ｐ．ｍｅｌｏｎｉｓ Ｋａｔｓｕｒａ的培养滤液中不含这种类似蛋白,不能诱导烟草叶片发生过敏反应。利用共聚焦激光扫描显微镜,以荧光探剂ＦＤＡ（ｆｌｕｏｒｅｓｃｅｉｎ ｄ     

Glycolate metabolism in algal chloroplasts: inhibition by salicylhydroxamic acid (SHAM)

Unicellular green algae such as Chlamydomonas and Dunaliella excrete small amounts of glycolate during active photosynthesis. This phenomenon has been explained by the fact that these algae do not have leaf-type peroxisomes and glycolate oxidase; instead, they have a limited capacity to metabolise glycolate in their mitochondria by a membrane-associated glycolate dehydrogenase. Salicylhydroxamic acid (SHAM), an inhibitor of alternative oxidase in plant and algal mitochondria, stimulates glycolate excretion by the algae or their isolated chloroplasts 5-fold. In the presence of SHAM, cells of Chlamydomonas or Dunaliella grown with high-CO₂ (5% CO₂ in air, v/v) or adapted with air levels of CO₂ excreted glycolate at a rate of about 14 µmol glycolate mg⁻¹ Chl h⁻¹. Aminooxyacetate (AOA), an inhibitor of aminotransferases, also increases glycolate excretion by the algal cells or chloroplasts but at a lower rate (about 50%) than SHAM. The algal, light dependent, SHAM-sensitive glycolate oxidizing system in the chloroplasts appears to be the primary site for glycolate oxidation, and it is different and more active then the minor mitochondrial glycolate dehydrogenase.     

Elicitation of the Hypersensitive Responses in Tabacco by a10.6 kD Proteinaceous Elicitor from Phytophthora palmi

A 10.6 kD heat resistant, proteinacious elicitor was purified from the culture filtrate of Phytophthora palmivora Butler but not from P. melonis Katsura. The 10.6 kD elicitor is a holoprotein devoid of glycoside. It can cause hypersensitive necrosis of the detached tobacco ( Nicotiatna tabacum L. ) leaves 48 h post-inoculation with dosages of above 40 μg. Four cell types were investigated by using Confocal microscopy, and 2' ,7'-dichlorodihydrofluorescein diacetate (DCFDA) as a probe of H2O2 production. It was showed that oxidative burst occurred in cultured suspension cells as well as in mesophyll cells, epidermal cells and guard cells within 10 min upon the elicitor treatment. The hypersensitive cell death appeared 6 h after the treatment when inoculated with fluorescein diacetate (FDA) as indicator of cell viability. These results suggest that H2O2 accumulation was the main cause of the hypersensitive cell death in tobacco induced by the 10.6 kD elicitor. This 10.6 kD elicitor may belong to the family of elicitins.     

Synthesis of chlorinated fluoresceins for labeling proteins

Two novel chlorinated fluoresceins 4,7,2',7'-tetrachloro-6-(5-carboxypentyl)fluorescein (8a) and 4,7,4',5'-tetra-chloro-6-(5-carboxypentyl)fluorescein (8b) were synthesized as fluorescent probes for labeling proteins. These two fluoresceins contain 6-aminohexanoic acid as spacer linker to minimize the fluorescence quenching of the fluorescein molecules by the proteins to be labeled.     

The use of fluorogenic esters to detect viable bacteria by flow cytometry

The ability of flow cytometry (FCM) to detect viable bacteria after staining with a range of fluorogenic esters was investigated with several bacterial species. The dyes studied were the fluorescein diacetate (FDA) derivatives carboxyfluorescein diacetate, 2',7'-bis-(2-carboxyethyl)-5(6)-carboxyfluorescein acetoxymethyl ester and calcein acetoxymethyl ester, as well as ChemChrome B, a commercially-available stain for the detection of viable bacteria in suspension. No one dye was found to be universal but ChemChrome B dye stained the widest number of Gram-positive and Gram-negative species, whereas the FDA derivatives preferentially stained Gram-positive bacteria. The use of ChemChrome B to detect viable bacteria in environmental samples was investigated further by studying the survival of Klebsiella pneumoniae in lakewater. During survival studies, a higher number of viable bacteria were detected both by direct viable counts and FCM after staining with rhodamine 123 and ChemChrome B than by colony-forming units, suggesting the presence of viable but nonculturable cells. These results demonstrate the potential use of FCM to enumerate viable bacteria in natural waters.     

Determination of the physical environment within the Chlamydia trachomatis inclusion using ion-selective ratiometric probes

Chlamydia trachomatis is an obligate intracellular bacterium with a biphasic life cycle that takes place entirely within a membrane-bound vacuole termed an inclusion. The chlamydial inclusion is non-fusogenic with endosomal or lysosomal compartments but intersects a pathway involved in transport of sphingomyelin from the Golgi apparatus to the plasma membrane. The physical conditions within the mature chlamydial inclusion are unknown. We used ratiometric imaging with membrane-permeant, ion-selective fluorescent dyes for microanalyis of the physical environment within the inclusion. Determination of H+, Na+, K+ and Ca(2+) concentrations using CFDA (carboxy fluorescein diacetate) or BCECF-AM (2',7'-bis (2-carboxyethyl)-5,6-carboxyfluorescein acetoxymethyl ester, SBFI-AM, PBFI-AM and fura-PE3-acetomethoxyester (Fura-PE3-AM), respectively, indicated that all ions assayed within the lumenal space of the inclusion approximated the concentrations within the cytoplasm. Stimulation of purinergic receptors by addition of extracellular ATP triggered a dynamic Ca(2+) response that occurred simultaneously within the cytoplasm and interior of the inclusion. The chlamydial inclusion thus appears to be freely permeable to cytoplasmic ions. These results have implications for nutrient acquisition by chlamydiae and may contribute to the non-fusogenicity of the inclusion with endocytic compartments.     

Evidence for a significant contribution by peroxidase-mediated O2 uptake to root respiration of Brachypodium pinnatum

This study describes the O₂ uptake characteristics of intact roots of Brachypodium pinnatum. In the presence of 25 mM salicylhydroxamic acid (SHAM), concentrations of KCN below 3.5 νM had no effect on the rate of root respiration, whereas in the absence of 25 mM SHAM a significant inhibition of approx. 18% was observed. This indicates that an O₂-consuming reaction, not associated with the cytochrome pathway, the alternative pathway or the “residual component”, operates in the absence of any inhibitors in roots of B. pinnatum. We demonstrate here that this fourth O₂-consuming reaction is mediated by a peroxidase. A peroxidase which catalyzed O₂ reduction in the presence of NADH was readily washed from the roots of B. pinnatum. This peroxidase was stimulated by 5 mM SHAM, whereas ascorbic acid, catalase, catechol, gentisic acid, low concentrations potassium cyanide (3.5 μM), sodium azide, sodium sulfide, superoxide dismutase and high concentrations SHAM (25 mM) inhibited this reaction. Except for high concentrations of SHAM and concentrations of KCN higher than approx. 3.5 μM, these effectors could not be used to inhibit the peroxidase-mediated O₂ uptake in intact roots of B. pinnatum. Concentrations of SHAM below 10 mM stimulated O₂ uptake up to 15% of the control rate, depending on concentration, whereas 25 mM SHAM inhibited O₂ uptake by 35%. The stimulation at low concentrations resulted from a SHAM-stimulated peroxidase activity, whereas 25 mM SHAM completely inhibited both the peroxidase-mediated O₂ uptake and the activity of the alternative pathway. A method is presented for determining the relative contributions of each of the four O₂-consuming reactions, i.e. the cytochrome pathway, the alternative pathway, the “residual component” and the peroxidase-mediated O₂ uptake. The peroxidase-mediated O₂ uptake contributed 21% to the total rate of oxygen uptake in roots of B. pinnatum, the cytochrome pathway contributed 41%, the alternative pathway 14% and the “residual component” 24%.     

Dihydrofluorescein diacetate is superior for detecting intracellular oxidants: comparison with 2',7'-dichlorodihydrofluorescein diacetate, 5(and 6)-carboxy-2',7'-dichlorodihydrofluorescein diacetate, and dihydrorhodamine 123.

To detect intracellular oxidant formation during reoxygenation of anoxic endothelium, the oxidant-sensing fluorescent probes, 2',7'-dichlorodihydrofluorescein diacetate, dihydrorhodamine 123, or 5(and 6)-carboxy-2',7'-dichlorodihydrofluorescein diacetate were added to human umbilical vein endothelial cells during reoxygenation. None of these fluorescent probes were able to differentiate the controls from the reoxygenated cells in the confocal microscope. However, dihydrofluorescein diacetate demonstrated fluorescence of linear structures, consistent with mitochondria, in reoxygenated endothelium. This work tests the hypothesis that dihydrofluorescein diacetate is a better fluorescent probe for detecting intracellular oxidants because it is more reactive toward specific oxidizing species. To investigate this, dihydrofluorescein diacetate was exposed to various oxidizing species (hydrogen peroxide, superoxide [KO2], peroxynitrite, nitric oxide, horseradish peroxidase, ferric iron, xanthine oxidase, cytochrome c, and lipoxygenase) and compared with the three other popular probes. Though oxidized dihydrofluorescein has higher molar fluorescence, comparison of the reactions of dihydrofluorescein with these other three probes in a cell-free system indicates that dihydrofluorescein is sometimes less fluorescent than the other probes. In addition, we find that the reactivity of all of the probes is very complex. Based on the results reported here, it is no longer appropriate to think of these probes as detecting a specific oxidizing species in cells, such as H2O2, but rather as detectors of a broad range of oxidizing reactions that may be increased during intracellular oxidant stress. Cell-loading studies indicate that dihydrofluorescein achieves higher intracellular concentrations than the second brightest intracellular probe, 2',7'-dichlorodihydrofluorescein. This fact and its higher molar fluorescence may account for the superior brightness of dihydrofluorescein diacetate. Dihydrofluorescein diacetate may be a superior fluorescent probe for many cell-based studies.     

Salicylhydroxamic acid inhibits myeloperoxidase activity.

Salicylhydroxamic and benzohydroxamic acids were found to bind to the resting state of myeloperoxidase and inhibit ligand binding to the heme iron. An ionizable group on the enzyme with pKa = 4 affects salicylhydroxamic acid binding; binding occurs when this group is not protonated. The binding of the heme iron ligands (e.g. cyanide, nitrite, and chloride) is probably controlled by the same ionizable group. The equilibrium dissociation constant of the salicylhydroxamic acid-myeloperoxidase complex is about 2 x 10(-6) M, and the association rate constant is 7.4 x 10(6) M-1.s-1. Salicylhydroxamic acid serves as a donor to the higher oxidation state of myeloperoxidase and thereby inhibits guaiacol oxidation. Salicylhydroxamic acid was also found to bind to intestinal peroxidase and lactoperoxidase. Salicylhydroxamic acid binding to all three mammalian peroxidases was about 3 orders of magnitude stronger than benzohydroxamic acid binding. We conclude that the salicylhydroxamic and benzohydroxamic acids bind in the distal heme cavity of these peroxidases and interact with the heme ligand binding site.