Promotion of softening and ethylene synthesis in bartlett pears by 3-methylene oxindole

A purified preparation of 3-methylene oxindole (3-MeOx) was applied to Bartlett pears (Lyrus communis) by vacuum infiltration. The infiltrated fruit were kept at room temperature at atmospheric or at one-twentieth of an atmospheric tension. The rate of softening was markedly enhanced by the application of 0.1 and 1 mum 3-MeOx. At 10 mum 3-MeOx the promotive effect of the compound was diminished. All the employed concentrations of 3-MeOx exceeded the effect of applied ethylene. The enhancement of softening in fruit kept under hypobaric conditions suggests that the action of 3-MeOx is a direct one and not an indirect ethylene effect. 3-MeOx also showed stimulation in the onset of ethylene synthesis, shortening the time required to obtain the peak in ethylene synthesis from 5 days by the control to 3 days by 0.1 mum and 2 days by 1 mum of the applied compound. As with softening, 3-MeOx at 10 mum diminished the rate of ethylene synthesis.The results suggest that 3-MeOx could function as a senescence promoter in fruit. Also, since auxins retard ripening while 3-MeOx promotes ripening, the action of 3-MeOx may be considered as that of an auxin antagonist. The occurrence and the mode of action of 3-MeOx as a possible senescence factor in fruit are discussed.     

Auxin activity of 3-methyleneoxindole in wheat

A product of the enzymatic oxidation of indole-3-acetic acid, 3-methyleneoxindole, is at least 50-fold more effective than indole-3-acetic acid in stimulating the growth of wheat (Triticum vulgare, red variety) coleoptiles. Ethylenediaminetetra-acetic acid can antagonize the growth-stimulating properties of the parent compound, indole-3-acetic acid, presumably by chelating Mn²⁺, which is required for the enzymatic oxidation of indole-3-acetic acid. The growth stimulating effect of 3-methyleneoxindole, a product of the blocked reaction, on the other hand, is still evident in the presence of ethylenedia-minetetraacetic acid. In the presence of 2-mercaptoethanol, indole-3-acetic acid fails to stimulate the elongation of wheat coleoptiles. The property of binding to sulfhydryl compounds including 2-mercaptoethanol is unique to 3-methyleneoxindole among indole-3-acetic acid and its oxidation products. These findings suggest that 3-methyleneoxindole is an obligatory intermediate in indole-3-acetic acid induced elongation of wheat coleoptiles.     

Novel oxindole derivatives and their biological activity

The antifungal activity of fourteen novel derivatives of oxindole with side chain was studied using representatives of toxinogenic, phytopathogenic and dermatophytic filamentous fungi. Derivatives with exocyclic C=C bond in position C-3 exhibited a higher antifungal activity compared with derivatives with an exocyclic C−C bond in the same position. The strongest antifungal effects were shown by 3-(-2-thienoylmethylidene)-indol-2(3H)-ones.     

Auxin activity and molecular structure of 2-alkylindole-3-acetic acids

2-Methylindole-3-acetic acid (2-Me-IAA) is a known auxin, but its 2-ethyl homologue has been considered inactive. Here we show that the compound previously bioassayed as 2-ethylindole-3-acetic acid (2-Et-IAA) was, in fact, 3-(3-methylindol-2-yl)propionic acid. The proper 2-Et-IAA and its 2-(n-propyl) homologue (2-Pr-IAA) are prepared, unambiguously characterized, and their auxin activity is demonstrated in the Avena coleoptile-section straight-growth test. Their half-optimal concentrations are approximately the same as for 2-Me-IAA (2 × 10^–5mol L^–1), and hence about ten times larger than for unsubstituted indole-3-acetic acid (IAA) and its derivatives alkylated in positions 4, 5, 6 or 7. The optimal response elicited by 2-Et-IAA and 2-Pr-IAA is about half that observed for 2-Me-IAA. These characteristics place the three 2-alkyl-IAAs along the borderline between the classes of strong and weak auxins, thus corroborating the results of interaction similarity analysis, a mathematical approach based on the capability of auxin molecules to participate in non-bonding interactions with a generalized receptor protein. X-ray diffraction analysis shows no explicit structural features to be blamed for the decrease in auxin activity caused by attaching a 2-alkyl substituent to the IAA molecule; sterical interference of the 3-CH₂COOH group and the 2-alkyl moiety is barely recognizable in the crystalline state. Quantum-chemical calculations and molecular dynamics simulations suggest that 2-alkyl-IAAs, in the absence of crystal-packing restraints, prefer conformations with the CH₂-COOH bond tilted to the heterocyclic ring system. Substantially higher conformational energy (and hence lower abundance) is predicted for planar conformers which were previously shown to prevail for IAA and many of its derivatives substituted in the benzene moiety of the indole nucleus. This shift in the rotational preferences of the -CH₂COOH moiety may be one of the reasons for the reduced plant-growth promoting activity of 2-alkyl-IAAs.     

Metabolic activity of 3-hydroxymethyl N-methyl piperidine (4-chlorophenoxy) acetate hydrochloride in obese rats

When chronically administered, 3-hydroxymethyl N-methyl piperidine (4-chlorophenoxy) acetate, hydrochloride, causes reduced food intake and weight gain in obese (fa/fa) rats. We observe an increase in free fatty acid concentration of obese (fa/fa) rats treated for 12 days.     

Anti-obesity activity of 3-hydroxymethyl N-methyl piperidine 4-chlorophenoxyacetate hydrochloride in mice treated with gold thioglucose

The 3-hydroxyméthyl N-méthyl piperidine 4-chlorophenoxyacetate, hydrochloride, A, a potent anorectic, reduces weight gain of gold thioglucose obese mice through a reduced body fat and a decrease in metabolic efficiency. Compound A has much less effect in the lean mice than in the obese models. In contrast with pair-fed obese or lean mice, the decreased food consumption cannot account for all the reduced weight gain of the obese controls. Basal lipolytic activity in parametrial adipose tissue is greater in obese mice treated with A then in controls. It seems that the stimulating effect of A on lipolysis could contribute to the weight reduction.     

Auxin activity of phenylacetic acid in tissue culture

The ability of phenylacetic acid (PAA), a naturally occurring auxin, to initiate and support growth of callus and suspension cultures of several species is reported. Callus tissue of tobacco (Nicotiana tabacum L. var. WI-38), initiated and maintained on a medium with 2,4-dichlorophenoxyacetic acid (2,4-D), was transferred to and maintained on media supplemented with 25–500 M PAA as the only plant growth regulator (PGR). Optimal concentrations of PAA were determined for tobacco callus proliferation in the dark (250 M PAA) and with a 16-h light/8-h dark photoperiod (500 M PAA). Tobacco suspension cultures were maintained for over 28 transfers in media containing 20–40 M PAA as the sole PGR. When tobacco callus tissue maintained on PAA-supplemented media for over 18 months was transferred to liquid media containing kinetin, plantlets were regenerated. Callus of sunflower (Helianthus annuus L. var. Russian Mammoth) proliferated on media containing PAA at 5–250 M as the sole PGR. Similar PAA concentrations inhibited normal development and promoted callus formation in tobacco and pea (Pisum sativum L. vars. common, Frogel, and Frimas) epicotyl tissue. PAA as the sole PGR did not support the growth of soybean (Glycine max (L.) Merrill var. Fiskeby) callus or suspension cultures. Chickpea (Cicer arietinum L. var. UC-5) and lentil (Lens culinaris Medic. var. Laird) callus cultures proliferated on media containing 25–500 M PAA, but habituation of the cultures was common. PAA was not toxic to tobacco, chickpea, and lentil tissues at levels as high as 500 M.Paper No. 88514 of the Journal Series of the Idaho Agricultural Experiment Station, Moscow, Idaho, USA.     

Auxin activity of phenylacetic acid in tissue culture

The ability of phenylacetic acid (PAA), a naturally occurring auxin, to initiate and support growth of callus and suspension cultures of several species is reported. Callus tissue of tobacco (Nicotiana tabacum L. var. WI-38), initiated and maintained on a medium with 2,4-dichlorophenoxyacetic acid (2,4-D), was transferred to and maintained on media supplemented with 25–500 μM PAA as the only plant growth regulator (PGR). Optimal concentrations of PAA were determined for tobacco callus proliferation in the dark (250 μM PAA) and with a 16-h light/8-h dark photoperiod (500 μM PAA). Tobacco suspension cultures were maintained for over 28 transfers in media containing 20–40 μM PAA as the sole PGR. When tobacco callus tissue maintained on PAA-supplemented media for over 18 months was transferred to liquid media containing kinetin, plantlets were regenerated. Callus of sunflower (Helianthus annuus L. var. Russian Mammoth) proliferated on media containing PAA at 5–250 μM as the sole PGR. Similar PAA concentrations inhibited normal development and promoted callus formation in tobacco and pea (Pisum sativum L. vars. common, Frogel, and Frimas) epicotyl tissue. PAA as the sole PGR did not support the growth of soybean (Glycine max (L.) Merrill var. Fiskeby) callus or suspension cultures. Chickpea (Cicer arietinum L. var. UC-5) and lentil (Lens culinaris Medic. var. Laird) callus cultures proliferated on media containing 25–500 μM PAA, but habituation of the cultures was common. PAA was not toxic to tobacco, chickpea, and lentil tissues at levels as high as 500 μM.     

Novel 3,3-disubstituted oxindole derivatives. Synthesis and evaluation of the anti-proliferative activity

3,3-Disubstituted oxindole derivatives bearing a nitrogen atom at the C-3 position have been synthesized starting from 3-alkyl oxindole through a metal free pathway. These derivatives have been tested in five human tumor cell lines (PC3, MCF7, SW620, MiaPaca2 and A375) and on primary cells (PBMCs) from healthy donors providing compound 6d showing a strong anticancer effect in all cancer lines on the low micromolar range.     

Candida antarctica lipase-B-catalyzed kinetic resolution of 1,3-dialkyl-3-hydroxymethyl oxindoles

Candida antarctica (CAL-B) lipase-catalyzed resolution of 1,3-dialkyl-3-hydroxymethyl oxindoles has been performed to obtain (R)-1,3-dialkyl-3-acetoxymethyl oxindoles with up to 99% ee and (S)-1,3-dialkyl-3-hydroxymethyl oxindoles with up to 78% ee using vinyl acetate as acylating agent and acetonitrile as solvent transforming (S)-3-allyl-3-hydroxymethyl oxindole to (3S)-1′-benzyl-5-(iodomethyl)-4,5-dihydro-2H-spiro[furan-3,3′-indolin]-2′-one. The optically active 3-substituted-3-hydroxymethyl oxindoles and spiro-oxindoles are among the key synthons in the synthesis of potentially biologically active molecules.     

Auxin controls Golgi-localized glucan synthetase activity in the maize mesocotyl

Decapitation or red light irradiation (R) inhibited growth and Golgi-localized glucan synthetase (GS I) activity in the mesocotyl of intact maize (Zea mays L.) seedlings. Applied auxin (indole-3-acetic acid) prevented the effects of R and of decapitation on both growth and GS I. Auxin applied several hours after irradiation prevented any further decline in GS I but did not restore it. Mesocotyl segments incubated in solution elongated in response to auxin but lost GS I with time regardless of the presence of exogenous auxin. An attached seed was necessary for maintenance of GS I in the dark-grown mesocotyl.Abbreviations GS glucan synthetase - IAA indole-3-acetic acid - R red light     

Physiological control of arginine decarboxylase activity in k-deficient oat shoots

The effect of K-deficiency on the putrescine biosynthetic enzyme, arginine decarboxylase (ADC), was investigated by growing oat (Avena sativa L. var Victory) plants on a low-K, but otherwise complete nutrient medium in washed quartz sand for up to 18 days. Enzyme activity rose as the concentration of KCl was dropped to 0.6 millimolar or below. However, growth was not inhibited significantly at 0.6 millimolar KCl. ADC activity increased in the whole shoot of K-deficient oats throughout the period of 6 to 18 days, but remained constant in normal plants. At 18 days, ADC activity in entire K-deficient shoots was 6 times greater than in normal shoots, while in the first (oldest) leaf, ADC specific activity increased to more than 30 times the specific activity in the first leaf of normal plants. This effect was due to a moderate rise in total ADC activity in the first leaf between 6 and 18 days, accompanied by a significant decline in protein content. Replacing K⁺ with Na⁺ or Li⁺ significantly inhibited the increase in ADC activity in K-deficient oats, while Rb⁺ depressed the specific activity to a level below that in normal plants. An alternative putrescine biosynthetic enzyme, ornithine decarboxylase, was also examined. The specific activity of a pelletable form of the enzyme was increased 2-fold in the shoots of K-deficient oats.     

Auxin structure/activity relationships: Benzoic acids and phenols

The results of self-consistent field molecular orbital calculations on auxins of the benzoic acid and phenolic types are not inconsistent with the view that a positively charged site at about 0.5 nm from an acidic group could contribute to the reversible binding of an auxin to its receptor molecule.     

Occurrence of avenanthramides and hydroxycinnamoyl-CoA:hydroxyanthranilate N-hydroxycinnamoyltransferase activity in oat seeds

Oat phytoalexins, avenanthramides, occur as constitutive components in seeds. The amounts of each avenanthramide were analyzed. The composition of avenanthramides in dry seeds was different from that in elicitor-treated leaves. In seeds, avenanthramide C was most abundant with an amount two times larger than that of avenanthramide A or B. On the other hand, avenanthramide A was the major component in elicitor-treated leaves. The total amount of avenanthramides in seeds increased 2.5 times during imbibition for 48 h although the composition did not change. The hydroxycinnamoyl-CoA:hydroxyanthranilate N-hydroxycinnamoyltransferase (HHT, EC 2.3.1.-) activity, which is responsible for the final condensation step in the avenanthramide biosynthesis, was detected in dry seeds. The activity was localized in endosperm and scutellum, and slightly increased during 48-h imbibition. The enzyme was partially purified by anion exchange chromatography from both dry seeds and elicitor-treated leaves The activity was separated into two peaks by chromatography, indicating that HHT consists of at least two isoforms. The substrate specificities of HHT isoforms from seeds were different from each other.     

Auxin signalling is involved in cadmium-induced glutathione-S-transferase activity in barley root

Transient exposure of barley roots to Cd, IAA or H₂O₂ for 30 min resulted in a significant root growth inhibition. Cd significantly increased the GST activity of roots 6 h after the end of short-term treatment. This increase was more relevant in root segment containing differentiation zone than in root segment just immediately behind the root apex. In contrast to Cd treatment, the short-term exposure of barley roots to IAA resulted in a significant increase of GST activity along the whole root tip and this increase was detectable already 3 h after the treatment with 10 μM IAA. Similarly to IAA, exogenously applied 10 mM H₂O₂ for 30 min caused significant increase of GST activity along the whole root tip 6 h after the treatment. This increase was already detectable 3 h after the exposure, but only in the differentiation zone of root tip. Auxin influx or signalling inhibitor considerable decreased the Cd- or IAA-induced GST activity in barley root tips. The strong activation of GST even after a brief exposure of barley roots to Cd support the crucial role of GST in the Cd-induced stress response in which presumably IAA and H₂O₂ play an important signalling role including the activation of GST.