Self-regulation of phytoalexin production: a non-biosynthetic enzyme controls alkaloid biosynthesis in cultured cells of Eschscholzia californica
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- 作者:Henriette Müller (1)
Michael Heinze (1)
Ramona Heinke (2)
Jürgen Schmidt (2)
Werner Roos (1) - 关键词:Plant secondary metabolism ; Phytoalexins ; Benzophenanthridine alkaloids ; Environmental stress ; Plant signal transfer ; Eschscholzia californica
- 刊名:Plant Cell, Tissue and Organ Culture
- 出版年:2014
- 出版时间:December 2014
- 年:2014
- 卷:119
- 期:3
- 页码:661-676
- 全文大小:1,417 KB
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文摘
Benzophenanthridine alkaloids are strong antimicrobials of Papaveraceae and attractive lead compounds for drug development. The cytotoxicity of these compounds requires the producing plant to limit the pathogen-triggered burst of biosynthesis. Cells of Eschscholzia californica excrete early benzophenanthridines to the cell wall, followed by re-uptake and reduction in the cytoplasm by the detoxifying enzyme sanguinarine reductase. We now discovered that this enzyme is a core component of self-control in alkaloid production. RNAi-based silencing of sanguinarine reductase gave rise to mutants that either show a complete stop of elicitor-triggered alkaloid production or a burst of biosynthesis that severalfold surpasses the wild type level. These unexpected phenotypes reflect impacts of substrate or product of sanguinarine reductase: the substrate, sanguinarine, inhibits phospholipase A2 at the plasma membrane, an initial component of the signal path towards expression of biosynthetic enzymes. The product, dihydrosanguinarine, inhibits enzymes of early biosynthesis, prior to reticuline formation. By tuning these steady states, sanguinarine reductase adjusts the capacity of alkaloid biosynthesis: a minimum activity is sufficient to prevent the blockade of the induction pathway by sanguinarine, while the full activity of the same enzyme causes a limitation of the biosynthetic flow?via dihydrosanguinarine.