Enrico Rolli

Effect of Cl-substitution on rooting-or cytokinin-like activity of diphenylurea derivatives

Twenty-eight Cl-substituted diphenylurea derivatives differing in either the number and the position of the substituents, or in the type of substitution, that is, symmetric or asymmetric, were synthesized. Their hypothetical enhancement of rooting activity was assayed using the mung bean shoot bioassay; their possible cytokinin-like activity was assessed using the betacyanin (so-called “amaranthin”) accumulation test and the tomato regeneration test. Seven Cl-substituted diphenylurea derivatives (2E, 4A, 4B, 4E, 4G, 6A, 6B) having two substituted phenyl rings showed the capacity to enhance adventitious root formation in mung bean shoots. Furthermore the presence of a halogen substituent was not sufficient to reach the adventitious rooting activities shown by the N,N ′-bis-(2,3-methylenedioxyphenylurea) and the N,N ′-bis-(3,4-methylenedioxyphenylurea), two diphenylurea derivatives for which an interaction with auxin was the first reported in enhancing adventitious root formation. Seven compounds (1B, 3E, 3D, 4B, 4E, 4F, 6B) showed cytokinin-like activity and three of them (4B, 4E, 6B) also evidenced rooting activity, once more demonstrating the wide action spectrum of diphenylurea derivatives.

In vitro micropropagation of the aquatic fern Marsilea quadrifolia L. and genetic stability assessment by RAPD markers

In order to conserve and multiply the aquatic fern Marsilea quadrifolia L., in a long-term in vitro procedure, the effects of different cytokinins, i.e., 6-benzylaminopurine, zeatine riboside, and N6-(2-isopentenyl)adenine, were investigated, varying their concentration and period of supplementation. No clear stimulatory effect on the de novo nodes produced per explant was detected when compared with hormone-free (HF) condition. On the contrary, the rhizome explant micropropagation was inhibited, the inhibition decreasing with the decreasing strength of cytokinins, though without reaching any significant enhancement. Since, as a consequence of the tissue culture procedure, the occurrence of somaclonal variation may introduce genomic alterations, genetic stability was assessed by random amplified polymorphic DNA (RAPD) analysis by comparing eight randomly selected micropropagated plants derived from repeated subcultures, with donor plant. Eighteen different primers generated 189 bands ranging from 100 to 3250 bp, and the same banding profiles were exhibited. No genomic alterations were evidenced in any of the micropropagated plants. Well-developed micropropagated plants were also successfully acclimatized under greenhouse condition. These positive results suggest that the in vitro HF micropropagation could be useful in the development of ex situ conservation programs of M. quadrifolia, even in order to possibly reintroduce the plants in their natural environment.

N,N′-bis-(2,3-methylenedioxyphenyl)urea and N,N′-bis-(3,4-methylenedioxyphenyl)urea interact with auxin in enhancing root formation of M26 apple (Malus pumila Mill.) stem slices

Stem slices cut from micropropagated cuttings of apple rootstock M26 were cultured in the presence of indole-3-butyric acid (IBA) plus N,N′-bis-(2,3-methylenedioxyphenyl)urea or N,N′-bis-(3,4-methylenedioxyphenyl)urea, to verify if there was an interaction between them in enhancing root formation. The N,N′-bis-(methylenedioxyphenyl)ureas were supplemented after, before and in the simultaneous presence of auxin. Our data demonstrate that only the simultaneous presence of auxin and N,N′-bis-(methylenedioxyphenyl)ureas in the culture medium enhanced root formation on M26 stem slices. The percentage of rooted slices obtained in the presence of the mixtures was significantly different from that obtained in the presence of low auxin concentration alone (1µM). Moreover both the percentage of rooted slices and the number of roots per slice obtained in these culture conditions was not significantly different to that of the optimal auxinic treatment in which the auxin concentration was threefold higher.

Diheteroarylurea derivatives as adventitious rooting adjuvants in mung bean shoots and M26 apple rootstock

The present research investigates the biological profile of eight symmetrical diheteroarylureas and phenylheteroarylureas, testing their hypothetical cytokinin-like activity and rooting activity. Cytokinin-like activity was assayed by the betacyanin (so-called amaranthin) accumulation test and by the tomato regeneration test. The rooting activity was assessed using the mung bean rooting test, the apple stem slice test and the rooting of apple microcuttings. Three compounds, 1,3-di(pyrazin-2-yl)urea (3a), 1,3-di(benzo[d]oxazol-5-yl)urea (3b) and 1,3-di(benzo[d]oxazol-6-yl)urea (3c), enhanced adventitious root formation in apple stem slice test, but only 3b and 3c were active in the mung bean rooting test. Compound 3b, that showed the best rooting activity, was also able to enhance the adventitious root formation in apple microcuttings. None of the compounds showed cytokinin-like activity.

Phytotoxic Effects and Phytochemical Fingerprinting of Hydrodistilled Oil, Enriched Fractions, and Isolated Compounds Obtained from Cryptocarya massoy (Oken) Kosterm. Bark.

The hydrodistilled oil of Cryptocarya massoy bark was characterized by GC‐FID and GC/MS analyses, allowing the identification of unusual C10 massoia lactone (3, 56.2%), C12 massoia lactone (4, 16.5%), benzyl benzoate (1, 12.7%), C8 massoia lactone (3.4%), δ‐decalactone (5, 1.5%), and benzyl salicylate (2, 1.8%) as main constituents. The phytotoxic activities of the oil, three enriched fractions (lactone‐rich, ester‐rich, and sesquiterpene‐rich), and four constituents (compounds 1, 2, 5, and δ‐dodecalactone (6)) against Lycopersicon esculentum and Cucumis sativus seeds and seedlings were screened. At a concentration of 1000 μl/l, the essential oil and the massoia lactone‐rich fraction caused a complete inhibition of the germination of both seeds, and, when applied on tomato plantlets, they induced an 85 and 100% dieback, respectively. These performances exceeded those of the well‐known phytotoxic essential oils of Syzygium aromaticum and Cymbopogon citratus, already used in commercial products for the weed and pest management. The same substances were also evaluated against four phytopathogenic bacteria and ten phytopathogenic fungi, providing EC50 values against the most susceptible strains in the 100–500 μl/l range for the essential oil and in the 10–50 μl/l range for compound 6 and the lactone‐rich fraction. The phytotoxic behavior was related mainly to massoia lactones and benzyl esters, while a greater amount of 6 may infer a good activity against some phytopathogenic fungi. Further investigations of these secondary metabolites are warranted, to evaluate their use as natural herbicides.

Optimisation of in vitro propagation of Hyssopus officinalis L. using two-node explants and N-phenyl-N’-benzothiazol-6-yl-urea (PBU), a new urea-type cytokinin

Summary An in vitro, vegetative propagation protocol for Hyssopus officinalis was optimised. The best results, in terms of multiplication factor (MF) and quality of shoots, were obtained using two-node explants cultured on Murashige and Skoog (MS) medium supplemented with 1.0 µM 6-benzylaminopurine (BAP). Shoots were rooted in the presence of indole-3-butyric acid (IBA), as auxin, and the well-developed plantlets were acclimatised under greenhouse conditions. The same MF value was obtained when two-node explants were cultured in the presence of 1.0 µM N-phenyl-N’-benzothiazol-6-yl-urea (PBU), a new derivative of urea showing cytokinin-like activity. Shoots obtained from the PBU treatment exhibited significantly better performance in terms of the percentage of micropropagated shoots that rooted and the mean number of roots per rooted shoot. These results demonstrate that PBU also exibits cytokinin-like activity during plant propagation.

Plant organ cultures as masked mycotoxin biofactories: Deciphering the fate of zearalenone in micropropagated durum wheat roots and leaves

“Masked mycotoxins” senso strictu are conjugates of mycotoxins resulting from metabolic pathways activated by the interplay between pathogenic fungi and infected plants. Zearalenone, an estrogenic mycotoxin produced by Fusarium spp, was the first masked mycotoxin ever described in the literature, but its biotransformation has been studied to a lesser extent if compared to other compounds such as deoxynivalenol. We presented herein the first application of organ and tissue culture techniques to study the metabolic fate of zearalenone in durum wheat, using an untargeted HR-LCMS approach. A complete, quick absorption of zearalenone by uninfected plant organs was noticed, and its biotransformation into a large spectrum of phase I and phase II metabolites has been depicted. Therefore, wheat organ tissue cultures can be effectively used as a biocatalytic tool for the production of masked mycotoxins, as well as a replicable model for the investigation of the interplay between mycotoxins and wheat physiology.

Zearalenone uptake and biotransformation in micropropagated Triticum durum Desf. plants: a xenobolomic approach.

A model was set up to elucidate the uptake, translocation, and metabolic fate of zearalenone (ZEN) in durum wheat. After treatment with ZEN, roots and shoots were profiled with LC-HRMS. A comprehensive description of in planta ZEN biotransformation and a biotechnological evaluation of the model were obtained. Up to 200 μg ZEN were removed by each plantlet after 14 days. Most ZEN and its masked forms were retained in roots, while minimal amounts were detected in leaves. Sixty-two chromatographic peaks were obtained, resulting in 7 putative phase I and 18 putative phase II metabolites. ZEN16Glc and ZEN14Glc were most abundant in roots, sulfo-conjugates and zearalenol derivatives were unable to gain systemic distribution, while distinct isomers of malonyl conjugates were found in leaves and roots. This study underlines the potential ZEN occurrence in plants without an ongoing Fusarium infection. Micropropagation may represent a tool to investigate the interplay between mycotoxins and wheat.

Identification of acetylated derivatives of zearalenone as novel plant metabolites by high-resolution mass spectrometry

AbstractZearalenone (ZEN) major biotransformation pathways described so far are based on glycosylation and sulfation, although acetylation of trichothecenes has been reported as well. We investigated herein the ZEN acetylation metabolism route in micropropagated durum wheat leaf, artificially contaminated with ZEN. We report the first experimental evidence of the formation of novel ZEN acetylated forms in wheat, attached both to the aglycone backbone as well as on the glucose moiety. Thanks to the advantages provided by high-resolution mass spectrometry, identification and structure annotation of 20 metabolites was achieved. In addition, a preliminary assessment of the toxicity of the annotated metabolites was performed in silico focusing on the toxicodynamic of ZEN group toxicity. All the metabolites showed a worse fitting within the estrogen receptor pocket in comparison with ZEN. Nevertheless, possible hydrolysis to the respective parent compounds (i.e., ZEN) may raise concern from the health perspective because these are well-known xenoestrogens. These results further enrich the biotransformation profile of ZEN, providing a helpful reference for assessing the risks to animals and humans. Graphical abstractᅟ

An optimized method for in vitro propagation of African baobab (Adansonia digitata L.) using two-node segments

Adansonia digitata L. (African baobab), is an important multi-purpose tree, whose distribution is at present limited to wild or semi-domesticated individuals widespread in Africa. Its distribution is threatened by seedling clearance for other land use and potentially by overharvesting induced by growing commercial use of baobab fruit. Recently, efforts have been made to establish baobab domestication and conservation strategies, with mixed results due to the low germinability of baobab seeds, a factor that hinders the possibility of developing commercial A. digitata plantations. Here, micropropagation was tested as a method for clonal propagation of explants from in vivo-grown seedlings. In vitro shoot multiplication was achieved by enhanced axillary bud proliferation of sterilized two-node segments. Bud break was dependent on cytokinin supply, but the combination of 1.0 or 10.0 μM zeatin riboside and 10.0 μM indole-3-butyric acid (IBA) increased the formation of microshoots after 8 weeks of culture. Regenerated microshoots rooted successfully in in vitro nutrient medium containing 10.0 μM IBA and normally grew in a greenhouse after acclimatization.