GENOTOXICITY OF THE PYRROLIZIDINE ALKALOIDS: ASSOCIATION WITH ADVERSE HEPATIC EFFECTS (ALKALINE ELUTION, CHEMICAL CARCINOGENESIS, ANTIMITOTIC EFFECTS).

PETRY, THOMAS WILLIAM.

January 1984

Pyrrolizidine alkaloids (PAs) produce a variety adverse hepatic effects, including acute toxicity, carcinogenicity and potent, persistent antimitotic effects. Additionally several have been evaluated as antineoplastic agents. PAs constitute significant health hazards to man and domestic animals. The mechanism(s) by which PAs induce these effects are not known. These studies were designed to test the hypothesis that some or all of the adverse hepatic effects and possibly the antineoplastic activity of PAs associate with or are mediated by a genotoxic interaction with cellular DNA. The first objective of the studies was to verify the in vivo gentoxicity of the PAs, in the process characterizing the type(s) of DNA damage induced. Hepatic DNA damage induced by the model PA monocrotaline (MCT) was assessed following i.p. administration to adult male Sprague-Dawley rats. DNA damage was characterized by the alkaline elution technique. MCT was found to induce both DNA-DNA interstrand and DNA-protein cross-links. No evidence was seen for the induction of DNA single-strand breaks, although the presence of small numbers of DNA single-strand breaks could have been masked by the overwhelming predominance of DNA cross-links. DNA-DNA interstrand cross-linking reached a maximum within 12 hr and thereafter decreased over a protracted period. By 96 hr post administration, the calculated cross-linking factor was no longer statistically different from zero (control). Further studies were performed to test the effects of agents known to modulate the formation/disposition of the proposed reactive intermediate and the toxic effects of the PAs. Consistent with its involvement in the mechanism of the toxicity of the PAs, genotoxicity was shown to modulate in the same direction and to similar degree as does the toxicity. Other PAs, or derivatives thereof, were evaluated in addition to MCT. Structural requirements for DNA cross-linking potential were shown to be similar to those required for the induction of toxic and antimitotic effects, again consistent with the involvement of DNA cross-linking in the mechanism of these effects. Indicine N-oxide however, an experimental antineoplastic agent, was shown not to mediate its cytotoxic effects via this mechanism.

Alkaloids -- Toxicology.

Genetic toxicology.

Bacterial 16S ribosomal DNA analysis of pyrrolizidine alkaloid detoxifying enrichments from the ovine rumen

Gray, Diane R.

05 February 1998

Bacterial cultures enriched from sheep rumen fluid have demonstrated the ability to detoxify pyrrolizidine alkaloids (seneciphylline and jacobine) in tansy ragwort (Senecio jacobaea). The microbes are difficult to isolate using classical anaerobic techniques, therefore, microbes from two different enrichment cultures demonstrating similar degradation activity were identified using their 16S ribosomal RNA genes. Gene sequences from a rich medium enrichment were matched to Clostridium bifermentans, Prevotella ruminicola, Escherichia coif, and from a minimal medium enrichment to, C. clostridiiforme, C. aminophilum, Streptococcus bovis, and Butyrivibrio fibrosolvens. There were no identical organisms between the two libraries, but the common genus was Clostridium. / Graduation date: 1998

Pyrrolizidines -- Toxicology

Tansy ragwort -- Toxicology

Alkaloids -- Toxicology

THEOPHYLLINE SERUM CONCENTRATIONS IN AMBULATORY PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE.

Bredon, James Wolfe.

January 1982

No description available.

Alkaloids -- Toxicology.

Lungs -- Diseases, Obstructive.

Metabolism of toxic plant alkaloids in livestock : comparative studies on the hepatic metabolism of pyrrolizidine alkaloids in sheep and cattle and of ergot alkaloids in an endophyte-resistant mouse model

Duringer, Jennifer Marie

30 April 2003

The pyrrolizidine alkaloids (PAs) and ergot alkaloids are known natural toxicants found in livestock forage. These alkaloids contribute to large economic losses in livestock throughout the world. An understanding of the mechanisms of toxicity and development of better diagnostic tools for better management practices was investigated. Variability exists in the toxicity of PAs in ruminants where cattle are more susceptible and sheep are more resistant. The mechanism of PA resistance in sheep has been attributed to hepatic metabolism or rumen microbial degradation of PAs to non-toxic moieties. The hepatic metabolism of the PA senecionine was investigated in cattle and sheep liver microsomes. The level of a toxic pyrrole metabolite 6,7-dihydro-7-hydroxy-1-hydroxymethyl-5H-pyrrolizine pyrrole (DHP) formed in cattle and sheep were similar. However, the level of a non-toxic N-oxide metabolite was greater in sheep than in cattle. Cytochrome P450 and flavin monooxygenases (FMOs) responsible for PA oxidative metabolism were similar in both ruminant species. Therefore, hepatic metabolism of PAs is not solely responsible for resistance observed in sheep versus cattle. Ergot alkaloids present in endophyte-infected plants also cause toxicity in livestock. HPLC is the typical method used to quantify ergot alkaloid content; however, it is costly and time-consuming. An enzyme-linked immunosorbent assay (ELISA) developed with lysergol as the hapten was evaluated to ascertain its feasibility as an analytical tool for the ergot alkaloids found in forage plants. The ELISA detected the presence of lysergic acid but was not a reliable assay for the ergopeptine alkaloids such as ergovaline. The genetic divergence in mice previously selected into ergot alkaloid susceptible and resistant lines was studied after ten generations of relaxed selection. Physiologically no difference was seen between the susceptible and resistant line for average daily weight gain. However, hepatic metabolism of the ergot alkaloid ergotamine showed differences between genders and between animals on diets containing no ergot alkaloids or a high concentration of ergot alkaloids. Four major biotransformation products were identified as hydroxylated ergotamine isomers based on mass spectroscopic analysis. / Graduation date: 2003

Livestock poisoning plants -- Toxicology

Ergot alkaloids -- Toxicology

Pyrrolizidines -- Toxicology

Hepatotoxicology

Evaluation of endophyte-infected tall fescue products, their interaction with Senecio jacobaea in ruminants, and detoxification of alkaloids by ammoniation or ensiling after grinding

Debessai, Woldu T.

26 August 1997

Graduation date: 1998

Tall fescue

Ergot alkaloids -- Toxicology

Tansy ragwort -- Toxicology

Beef cattle -- Feeding and feeds

Lambs -- Feeding and feeds