Novel Cognitions in Allelopathy: Implications from the Horizontal Natural Product Transfer

Whereas the translocation of allelochemicals between plants is well established, a related general transfer of genuine specialized metabolites has not been considered so far. The elucidation of the so-called Horizontal Natural Product Transfer revealed that alkaloids, such as nicotine and pyrrolizidine alkaloids, which are leached out from decomposing alkaloid-containing plants (donor plants), are indeed taken up by the roots of plants growing in the vicinity (acceptor plants). Further studies demonstrated that phenolic compounds, such as coumarins or stilbenes, are also taken up by acceptor plants. Contemporary analyses from co-cultivation experiments outlined that natural products are not exclusively transferred from dead and rotting donor plant materials, but also from vital plants. In analogy to xenobiotics, the imported specialized metabolites might also be modified within the acceptor plants. As known from the uptake of xenobiotics, the import of specialized metabolites is also generally due to a simple diffusion of the substances across the biomembranes and does not require a carrier. The uptake depends in stricto sensu on the physicochemical properties of the certain compound. This article presents a current overview of the phenomenon of Horizontal Natural Product Transfer and discusses its relevance for our understanding of allelopathic interactions. The knowledge that specialized metabolites might in general be readily translocated from one plant into others should significantly contribute to our understanding of plant-plant interactions and-in particular-to the evolution of typical allelopathic effects, such as inhibition of growth and germination of potential competitors.

Automated summary

This article discusses the phenomenon of Horizontal Natural Product Transfer and its importance in understanding plant-plant interactions. It reveals that specialized metabolites, such as alkaloids and phenolic compounds, can be transferred from donor plants to acceptor plants. This finding contributes to our understanding of allelopathic effects and the evolution of plant interactions.