Overexpression and RNAi-mediated Knockdown of Two 3ß-hydroxy-Δ5-steroid dehydrogenase Genes in Digitalis lanata Shoot Cultures Reveal Their Role in Cardenolide Biosynthesis.

3ß-hydroxy-Δ5-steroid dehydrogenases (3ßHSDs) are supposed to be involved in 5ß-cardenolide biosynthesis. Here, a novel 3ßHSD (Dl3ßHSD2) was isolated from Digitalis lanata shoot cultures and expressed in E. coli. Recombinant Dl3ßHSD1 and Dl3ßHSD2 shared 70% amino acid identity, reduced various 3-oxopregnanes and oxidised 3-hydroxypregnanes, but only rDl3ßHSD2 converted small ketones and secondary alcohols efficiently. To explain these differences in substrate specificity, we established homology models using borneol dehydrogenase of Salvia rosmarinus (6zyz) as the template. Hydrophobicity and amino acid residues in the binding pocket may explain the difference in enzyme activities and substrate preferences. Compared to Dl3ßHSD1, Dl3ßHSD2 is weakly expressed in D. lanata shoots. High constitutive expression of Dl3ßHSDs was realised by Agrobacterium-mediated transfer of Dl3ßHSD genes fused to the CaMV-35S promotor into the genome of D. lanata wild type shoot cultures. Transformed shoots (35S:Dl3ßHSD1 and 35S:Dl3ßHSD2) accumulated less cardenolides than controls. The levels of reduced glutathione (GSH), which is known to inhibit cardenolide formation, were higher in the 35S:Dl3ßHSD1 lines than in the controls. In the 35S:Dl3ßHSD1 lines cardenolide levels were restored after adding of the substrate pregnane-3,20-dione in combination with buthionine-sulfoximine (BSO), an inhibitor of GSH formation. RNAi-mediated knockdown of the Dl3ßHSD1 yielded several shoot culture lines with strongly reduced cardenolide levels. In these lines, cardenolide biosynthesis was fully restored after addition of the downstream precursor pregnan-3ß-ol-20-one, whereas upstream precursors such as progesterone had no effect, indicating that no shunt pathway could overcome the Dl3ßHSD1 knockdown. These results can be taken as the first direct proof that Dl3ßHSD1 is indeed involved in 5ß-cardenolide biosynthesis.

RNAi-mediated gene knockdown of progesterone 5ß-reductases in Digitalis lanata reduces 5ß-cardenolide content.

KEY MESSAGE: Studying RNAi-mediated DlP5ßR1 and DlP5ßR2 knockdown shoot culture lines of Digitalis lanata, we here provide direct evidence for the participation of PRISEs (progesterone 5ß-reductase/iridoid synthase-like enzymes) in 5ß-cardenolide formation. Progesterone 5ß-reductases (P5ßR) are assumed to catalyze the reduction of progesterone to 5ß-pregnane-3,20-dione, which is a crucial step in the biosynthesis of the 5ß-cardenolides. P5ßRs are encoded by VEP1-like genes occurring ubiquitously in embryophytes. P5ßRs are substrate-promiscuous enone-1,4-reductases recently termed PRISEs (progesterone 5ß-reductase/iridoid synthase-like enzymes). Two PRISE genes, termed DlP5ßR1 (AY585867.1) and DlP5ßR2 (HM210089.1) were isolated from Digitalis lanata. To give experimental evidence for the participation of PRISEs in 5ß-cardenolide formation, we here established several RNAi-mediated DlP5ßR1 and DlP5ßR2 knockdown shoot culture lines of D. lanata. Cardenolide contents were lower in D. lanata P5ßR-RNAi lines than in wild-type shoots. We considered that the gene knockdowns may have had pleiotropic effects such as an increase in glutathione (GSH) which is known to inhibit cardenolide formation. GSH levels and expression of glutathione reductase (GR) were measured. Both were higher in the Dl P5ßR-RNAi lines than in the wild-type shoots. Cardenolide biosynthesis was restored by buthionine sulfoximine (BSO) treatment in Dl P5ßR2-RNAi lines but not in Dl P5ßR1-RNAi lines. Since progesterone is a precursor of cardenolides but can also act as a reactive electrophile species (RES), we here discriminated between these by comparing the effects of progesterone and methyl vinyl ketone, a small RES but not a precursor of cardenolides. To the best of our knowledge, we here demonstrated for the first time that P5ßR1 is involved in cardenolide formation. We also provide further evidence that PRISEs are also important for plants dealing with stress by detoxifying reactive electrophile species (RES).