Pyrrolizidine alkaloids, sometimes referred to as necine bases, are a group of naturally occurring alkaloids based on the structure of pyrrolizidine. Pyrrolizidine alkaloids are produced by plants as a defense mechanism against insect herbivores. More than 660 PAs and PA N-oxides have been identified in over 6,000 plants, and about half of them exhibit hepatotoxicity. They are found frequently in plants in the Boraginaceae, Asteraceae, Orchidaceae and Fabaceae families; less frequently in the Convolvulaceae and Poaceae, and in at least one species in the Lamiaceae. It has been estimated that 3% of the world’s flowering plants contain pyrrolizidine alkaloids. Honey can contain pyrrolizidine alkaloids, as can grains, milk, offal and eggs. To date, there is no international regulation of PAs in food, unlike those for herbs and medicines. Unsaturated pyrrolizidine alkaloids are hepatotoxic, that is, damaging to the liver. PAs also cause hepatic veno-occlusive disease and liver cancer. PAs are tumorigenic. Disease associated with consumption of PAs is known as pyrrolizidine alkaloidosis. Of concern is the health risk associated with the use of medicinal herbs that contain PAs, notably borage leaf, comfrey and coltsfoot in the West, and some Chinese medicinal herbs. Some ruminant animals, for example cattle, showed no change in liver enzyme activities or any clinical signs of poisoning when fed plants containing pyrrolizidine alkaloids. Yet Australian studies have demonstrated toxicity Sheep, goats and cattle are much more resistant and tolerate much higher PA dosages, thought to be due to thorough detoxification via PA-destroying rumen microbes. Males react more sensitively than females and fetuses and children. PA is also used as a defense mechanism for some organisms such as Utetheisa ornatrix. Utetheisa ornatrix caterpillars obtain these toxins from their food plants and use them as a deterrent for predators. PAs protect them from most of their natural enemies. The toxins stay in these organisms even when they metamorphose into adult moths, continuing to protect them throughout their adult stage.
Ecology
Many plants contain pyrrolizidine alkaloids, and in turn there are many insects which consume the plants and build up the alkaloids in their bodies. For example, male queen butterflies utilize pyrrolizidine alkaloids to produce pheromones useful for mating. The butterfly Danaus chrysippus is known to obtain pyrrolizidine alkaloids in their diet and store these chemicals, making them toxic and unpalatable to predators. Greta oto, the glasswing butterfly, uses pyrrolizidine alkaloids for both toxicity in the adult moth and pheromone production in the male butterfly. The garden tiger moth also stores these compounds as a caterpillar, using them for larval and adult defense.
Plants species containing pyrrolizidine alkaloids
Adenostyles alliariae
Adenostyles glabra
Ageratum conyzoides
Ageratum houstonianum
Anchusa officinalis
Arnebia euchroma
Borago officinalis
Cacalia hastata
Cacalia hupehensis
Chromolaena odorata
Cordia myxa
Crassocephalum crepidioides
Crotalaria albida
Crotalaria assamica
Crotalaria crispat
Crotalaria dura
Crotalaria globifera
Crotalaria mucronata
Crotalaria sesseliflora
Crotalaria spectabilis
Crotalaria tetragona
Crotalaria retusa
Cynoglossum amabile
Cynoglossum lanceolatum
Cynoglossum officinale
Cynoglossum zeylanicum
Echium plantagineum
Echium vulgare
Emilia sonchifolia
Eupatorium cannabinum
Eupatorium chinense
Eupatorium fortunei
Eupatorium japonicum
Eupatorium purpureum
Farfugium japonicum
Gynura bicolor
Gynura divaricata
Gynura segetum
Heliotropium amplexicaule
Heliotropium europaeum
Heliotropium indicum
Heliotropium popovii
Lappula intermedia
Ligularia cymbulifera
Ligularia dentata
Ligularia duiformis
Ligularia heterophylla
Ligularia hodgsonii
Ligularia intermedia
Ligularia lapathifolia
Ligularia lidjiangensis
Ligularia platyglossa
Ligularia tongolensis
Ligularia tsanchanensis
Ligularia vellerea
Liparis nervosa
Lithospermum erythrorhizon
Neurolaena lobata
Petasites japonicus
Senecio alpinus
Senecio argunensis
Senecio brasiliensis
Senecio chrysanthemoides
Senecio cineraria
Senecio glabellus
Senecio integrifolius var. fauriri
Senecio interggerrimus
Senecio jacobaea
Senecio lautus
Senecio linearifolius
Senecio madagascariensis
Senecio nemorensis
Senecio quadridentatus
Senecio riddelli
Senecio scandens
Senecio vulgaris
Syneilesis aconitifolia
Symphytum officinale
Tussilago farfara
The effect of PAs in humans, that is PAILDs, of epidemic proportions was recorded after a long field-level epidemiological investigation in the northern region of Ethiopia- Tigray.
Classification
One classification is based on the substitution pattern of the pyrrolizidine ring. This part of the structure is normally referred to as necine bases. The three largest groups are based on the three necine bases platynecine, heliotridine and retronecine.
