Pyrrolizidine metabolism

Hartmann T, Ober D (2000) Biosynthesis and Metabolism of Pyrrolizidine Alkaloids in Plants and Specialized Insect Herbivores. 209. 207-243 Haseley SR, Kamerling JP, Vliegenthart JFG (2002) Unravelling Carbohydrate Interactions with Biosensors Using Surface Plasmon Resonance (SPR) Detection. 218 93-114... 

Lin G, Cui Y-Y, Liu X-Q and Wang Z-T (2002b), Species differences in the in vitro metabolic activation of the hepatotoxic pyrrolizidine alkaloids clivorine , Chem Res Toxicol, 15, 1421-1428. 

Extensive metabolic work continues with the pyrrolizidine alkaloids many of which are known toxic principles of plants responsible for conditions such as irreversible hemorrhagic liver necrosis, megalocytosis, and cancer. Considerable interest remains in the metabolism of pyrrolizidine alkaloids and their A-oxides to metabolic pyrroles thought to participate in molecular events associated with the above-mentioned toxicities. The chemistry and pharmacological properties of the pyrrolizidine alkaloids is authoritatively discussed by Wrobel in Volume 26 of this treatise. 

Segall and coworkers described the in vitro mouse hepatic microsomal metabolism of the alkaloid senecionine (159) (Scheme 34). Several pyrrolizidine alkaloid metabolites were isolated from mouse liver microsomal incubation mixtures and identified (222, 223). Preparative-scale incubations with mouse liver microsomes enabled the isolation of metabolites for mass spectral and H-NMR analysis. Senecic acid (161) was identified by GC-MS comparison with authentic 161. A new metabolite, 19-hydroxysenecionine (160), gave a molecular ion consistent with the addition of one oxygen atom to the senecionine structure. The position to which the new oxygen atom had been added was made evident by the H-NMR spectrum. The three-proton doublet for the methyl group at position 19 of senecionine was absent in the NMR spectrum of the metabolite and was replaced by two signals (one proton each) at 3.99 and 3.61 ppm for a new carbinol methylene functional group. All other H-NMR spectral data were consistent for the structure of 160 as the new metabolite (222). 

Monocrotaline (170) has been the subject of extensive metabolic study with mammalian and microbiological systems. Pyrrolizidine alkaloids such as monocrotaline require metabolic activation to the corresponding pyrrole derivatives or dehydro alkaloids before they are capable of forming covalent bonds with critical macromolecules within the cell. The X-ray structure of dehydromonocrotaline has recently been determined (226), and the ability of dihydroretronicine derived from monocrotaline to react with deoxyguanosine has been demonstrated in vitro (225). 

Xia et al. reported on the metabolism of lasiocarpine (prototype heliotridine pyrrolizidine alkaloids) by F344 rat liver microsomes, and isolated 6,7-dihydro-7-hydroxy-l -hydroxymcthyl-5//-pyrrolizinc (DHP)-derived DNA adducts, thus showing the potential use of such DHP-derived DNA adducts as biomarkers of exposure and tumorigenicity for all pyrrolizidine alkaloids <2006MI1001-02>. 

Figure 2.12 Metabolic activation by the liver of pyrrolizidine alkaloid to the toxic pyrrole (liver bound and highly toxic) and the glutathione conjugate (excretion metabolite).

Huxtable, R.J. and Cooper, R.A. (2000). Pyrrolizidine alkaloids physicochemical correlates of metabolism and toxicity, in Tu, A.T. and Gaffield W., Eds., Natural and selected synthetic toxins biological implications, American Chemical Society, Washington, D.C., pp. 100-117. 

Ornithine is a metabolically quite active amino acid, and the important precursor of pyrrolidine nucleus, which is found in pyrrolizidine alkaloids. Ornithine itself is a non-protein amino acid formed mainly from L-glumate in plants, and synthesized from the urea cycle in animals as a result of the reaction catalyzed by enzymes in arginine. 

There exists evidence that some insects store dietary alkaloids derived from natural sources. Figure 98 presents insect species that are known to accumulate pyrrolizidine alkaloids during different developmental stages. The larvae and adults of these insects can metabolize pyrrolizidine alkaloids in current physiological activities. These alkaloids are not toxic for these organisms. Moreover, there is observed trace accumulation of a portion of these compounds in the liver. There is no definitive purpose for these traces. Generally, the opinion presented in 1888 by Stahl in Germany that the accumulation of alkaloids is for defensive purposes has been most often cited in the research literature. 

Mattocks, A. R. 1972. Acute hepatoxicity and pyrrolic metabolities in rats dosed with pyrrolizidine alkaloids. Chemistry-Biology Interaction, 5 227-242. 

Hartmann, T. and Ober, D. (2000). Biosynthesis and metabolism of pyrrolizidine alkaloids in plants and specialized insect herbivores. Topics in Current Chemistry 209 207-243. 

Figure 6.7 The structure of the pyrrolizidine alkaloid monocrotaline and the microsomal enzyme-mediated metabolic activation of the pyrrolizidine alkaloid nucleus.

The N-oxide of indicine (49) exhibits anti-tumour activity in experimental tumour systems, without some of the toxic effects associated with other pyrrolizidine alkaloids. The N-oxides of echinatine and europine show similar anti-tumour activity against P 388 lymphocytic leukaemia tumours.23 Indicine N-oxide is metabolized to the free base in rabbits and humans,62 although the N-oxide is the more active anti-tumour agent. It has been suggested that the conversion of indicine N-oxide into indicine is not essential for its anti-tumour activity.63 Indicine N-oxide is the first pyrrolizidine alkaloid to be tested as an anti-tumour agent in humans. The toxicity and pharmacokinetics of this compound have been studied in 29 patients with advanced cancers.64 The major toxic effect was myelosuppression, but acute liver damage was not observed. 

Biosynthesis and Metabolism of Pyrrolizidine Alkaloids in Plants and Specialized Insect Herbivores... 

The toxicity of plants that contain pyrrolizidine alkaloids has been discussed in an earlier volume of this series (163), and the relationship between the toxic nature of the plants and the metabolism of their alkaloids by the victim has been reviewed (164). Since the toxicity of the pyrrolizidine alkaloids in mammals seems to be due to their metabolites rather than to the alkaloids themselves (164), considerable effort has been expended in the identification of the metabolites produced both in vivo and in vitro by mammalian systems. The material summarized in Table V (165-172) is supplementary to that discussed in reference 164. 

Many pyrrolizidine alkaloids are metabolized to toxic pyrrole metabolites in the liver by mixed-function oxidases. The structural and chemical features necessary for the formation of these metabolites have been discussed.77 The most important features, in addition to the 3-hydroxymethyl-3-pyrroline system, are steric hindrance to hydrolysis of the ester, lipophilic character (favouring attack by the hepatic microsomal enzymes), and the presence of a conformation that allows preferential oxidation of the pyrroline ring rather than 7V-oxidation. The alkylating activities of a series of these pyrrole derivatives have been examined.78... 

Figure 9.2. Metabolism of pyrrolizidine alkaloids (PAs) in Senecio vernalis. The substrates for alkaloid biosynthesis, putrescine and spermidine, are derived from primary metabolism. Homospermidine, synthesized by homospermidine synthase (HSS), is the first pathway specific intermediate. It is exclusively incorporated into the necine base moiety of senecionine A-oxide, the backbone structure of all PAs found in this Senecio species. During allocation from the roots as site of synthesis to the shoots, it is chemically modified to provide the species specific PA-pattem.

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