Larvae of Creatonotos transiens (Lepidoptera, Arctiidae) and Zonocerus variegatus (Orthoptera, Pyrgomorphidae) ingest 14C-labeled senecionine and its N-oxide with the same efficiency but sequester the two tracers exclusively as N-oxide. Larvae of the non-sequestering Spodoptera littoralis eliminate efficiently the ingested alkaloids. During feeding on the two alkaloidal forms transient levels of senecionine (but not of the N-oxide) are built up in the haemolymph of S. littoralis larvae. Based on these results, senecionine [*80]N-o~ide was fed to C. transiens larvae and Z. variegatus adults. The senecionine Noxide recovered from the haemolymph of the two insects shows an almost complete loss of "0 label, indicating reduction of the orally fed N-oxide in the guts, uptake of the tertiary alkaloid and its re-N-oxidation in the haemolymph. The enzyme responsible for N-oxidation is a soluble mixed function monooxygenase. It was isolated from the haemolymph of the sequestering arctiid Tyria jacobaeue and purified to electrophoretic homogeneity. The enzyme is a flavoprotein with a native M , of 200000 and a subunit M , of 51 000. It shows a pH optimum at 7.0, has its maximal activity at a temperature of 40-45°C and an isoelectric point at pH 4.9. The reaction is strictly NADPH-dependent (K,,, 1.3 pM). From 20 pyrrolizidine alkaloids so far tested as substrates, the enyzme N-oxidizes only alkaloids with structural elements which are essential for hepatotoxic and genotoxic pyrrolizidine alkaloids (i.e. 1,2-double bond, esterification of the allylic hydroxyl group, presence of a second free or esterified hydroxyl group at carbon 7). A great variety of related alkaloids and xenobiotics were tested as substrate, none was accepted. The K, values of senecionine, monocrotaline and heliotrine, representing the three main types of pyrrolizidine alkaloids, are 1.3 pM, 12.5 pM and 290 pM, respectively. The novel enzyme was named senecionine N-oxygenase (SNO). The enzyme was partially purified from two other arctiids. The three SNOs show the same general substrate specificity but differ in their affinities towards the main structural types of pyrrolizidine alkaloids. The enzymes from the two generalists (Creatonotos transiens and Arctia caja) display a broader substrate affinity than the enzyme from the specialist (Tyria jacobaeae). The two molecular forms of pyrrolizidine alkaloids, the lipophilic protoxic tertiary amine and its hydrophilic nontoxic N-oxide are discussed in respect to their bioactivation and detoxification in mammals and their role as defensive chemicals in specialized insects. Pyrrolizidine-alkaloid-sequestering insects store the alkaloids as nontoxic N-oxides which are reduced in the guts of any potential insectivore. The lipophilic tertiary alkaloid is absorbed passively and then bioactivated by cytochrome P-450 oxidase.Keywords: Tyria jacobaeae (Lepidoptera, Arctiidae) ; pyrrolizidine alkaloid; alkaloid uptake; senecionine N-oxygenase ; chemical defense.Pyrrolizidine alkaloids are unique among the some 20 000 p...
Synthetic compounds mimicking cannabis-like effects are a recent trend. Currently, these so-called synthetic cannabinoids are the largest and fastest growing class of newly appearing designer drugs. Many national authorities are continuously adapting their regulations to keep pace with the permanently changing variety of compounds. We have analyzed eight herbal smoking blends containing synthetic cannabinoids. Altogether, nine compounds could be identified, namely AM-2201, AM-2201-pMe (MAM-2201), AM-1220, AM-1220-azepane, UR-144, XLR-11, JWH-122-pentenyl, AM-2232, and STS-135. Newly appearing compounds were isolated by column chromatography and their structures elucidated by 1D- and 2D-nuclear magnetic resonance (NMR) experiments. In addition, the compounds were investigated by electron ionization-mass spectrometry (EI-MS) and electrospray ionization-tandem mass spectrometry (ESI-MS/MS) to complete the physicochemical dataset. Based on the purified compounds a universal gas chromatography-mass spectrometry (GC-MS) method was developed for the identification and quantification of these compounds in commercial smoking blends. By applying this method, up to five different compounds could be found in such products showing total concentrations from 72 to 303 mg/g smoking blend while individual compounds ranged from 0.4 to 303 mg/g. (1)H NMR spectra of the chiral compounds AM-1220 and its azepane-isomer recorded in the presence of 1 equivalent of (R)-(+)-α-methoxy-α-trifluoromethylphenylacetic acid (MTPA, Mosher's acid) showed them to be racemic mixtures.
In this study, seven commercial "spice-like" products available on the German market were analyzed. They all contained significant amounts of synthetic cannabinoids and had distinctly different compositions of these adulterants. All synthetic cannabinoids were extracted and purified by different chromatographic techniques from the respective product. The structures of all compounds were elucidated by nuclear magnetic resonance spectroscopy and further characterized by mass spectrometry (MS) and ultraviolet and infrared spectroscopy to generate a full data set of each compound. Altogether, eight compounds were identified, and one deuterium-labeled cannabinoid was used as internal standard. Four products contained only one individual compound, while three products contained mixtures of two compounds. Among the eight isolated compounds, six were already known from recent publications (JWH-081, JWH-210, JWH-122, AM2201, RCS-4, and JWH-203), but the published data were not always complete. In addition, two unknown compounds (AM2201-pMe, RCS-4-(N-Me)) were isolated. Overall, compounds from three distinct classes of synthetic cannabinoids could be identified, characterized, and compared. The MS data of the different subclasses allowed the postulation of some general key fragmentations to distinguish between these subclasses. In addition, we established a general method using an isotopically labeled internal standard (JWH-018-D(3)) to quantify synthetic cannabinoids in herbal mixtures. The total content of the synthetic cannabinoids ranged from 77.5 to 202 mg/g, while individual compounds were detected from 19.3 to 202 mg/g in these products. The spectroscopic data for all compounds mentioned here were collected and added en bloc as Electronic supplementary material to this manuscript.
Sulfite oxidase (EC 1.8.3.1) from the plant Arabidopsis thaliana is the smallest eukaryotic molybdenum enzyme consisting of a molybdenum cofactor-binding domain but lacking the heme domain that is known from vertebrate sulfite oxidase. While vertebrate sulfite oxidase is a mitochondrial enzyme with cytochrome c as the physiological electron acceptor, plant sulfite oxidase is localized in peroxisomes and does not react with cytochrome c. Here we describe results that identified oxygen as the terminal electron acceptor for plant sulfite oxidase and hydrogen peroxide as the product of this reaction in addition to sulfate. The latter finding might explain the peroxisomal localization of plant sulfite oxidase. 18 O labeling experiments and the use of catalase provided evidence that plant sulfite oxidase combines its catalytic reaction with a subsequent non-enzymatic step where its reaction product hydrogen peroxide oxidizes another molecule of sulfite. In vitro, for each catalytic cycle plant SO will bring about the oxidation of two molecules of sulfite by one molecule of oxygen. In the plant, sulfite oxidase could be responsible for removing sulfite as a toxic metabolite, which might represent a means to protect the cell against excess of sulfite derived from SO 2 gas in the atmosphere (acid rain) or during the decomposition of sulfur-containing amino acids. Finally we present a model for the metabolic interaction between sulfite and catalase in the peroxisome. Sulfite oxidases (SO)3 from vertebrates (published as EC 1.8.3.1) play an essential role in sulfur detoxification by catalyzing the reaction (1), which is the terminal step in the oxidative degradation of cysteine and methionine. Different electron acceptors were reported to interact with vertebrate SO including cytochrome c, ferricyanide, and oxygen (2-4). In mammals, SO is localized in the intermembrane space of mitochondria (5) where electrons derived from sulfite are passed to cytochrome c, the physiological electron acceptor. Vertebrate SO is a homodimeric protein with monomers subdivided into a Moco domain and a heme domain, as verified by the atomic structure of chicken SO (6).Recently we have described plant SO (7) from Arabidopsis thaliana, which is the fourth molybdenum enzyme present in plants in addition to nitrate reductase, xanthine dehydrogenase, and aldehyde oxidase. Cloning and characterization of plant SO was possible by using sequence homologies to the mammalian counterpart. However, in contrast to the animal enzyme plant SO lacks the heme domain, which is evident from the amino acid sequence, its enzymological and spectral properties (7), and the atomic structure (8). Also its subcellular localization differs from that of animals, in plants we showed SO to be localized in peroxisomes (9). SO is wide spread and highly conserved within the plant kingdom; the SO gene is present in higher and lower plants, and the protein encoded seems to be highly conserved because antibodies directed against Arabidopsis SO detect proteins of the correct size...
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