Towards Elucidating Carnosic Acid Biosynthesis in Lamiaceae: Functional Characterization of the Three First Steps of the Pathway in Salvia fruticosa and Rosmarinus officinalis
Abstract:Carnosic acid (CA) is a phenolic diterpene with anti-tumour, anti-diabetic, antibacterial and neuroprotective properties that is produced by a number of species from several genera of the Lamiaceae family, including Salvia fruticosa (Cretan sage) and Rosmarinus officinalis (Rosemary). To elucidate CA biosynthesis, glandular trichome transcriptome data of S. fruticosa were mined for terpene synthase genes. Two putative diterpene synthase genes, namely SfCPS and SfKSL, showing similarities to copalyl diphosphate… Show more
“…In a parallel series of experiments, CYP76AHs from rosemary and salvia known to accept miltiradiene as substrate were tested for their ability to use 13 R -manoyl oxide as a substrate. Transient expression of Ro CYP76AH4 (Zi and Peters, 2013), Ro FS1 and Sf FS (Božić et al, 2015) in N. benthamiana leaves able to synthesize 13 R -manoyl oxide demonstrated that Ro CYP76AH4 was able to efficiently convert 13 R -manoyl oxide to 11-oxo-13 R -manoyl, while Ro FS1 and Sf FS were able to produce 11-hydroxy manoyl oxide, in addition to 11-oxo-13 R -manoyl oxide (Figure 7). 10.7554/eLife.23001.017Figure 6.GC-MS analysis of miltiradiene-derived diterpenoids obtained by transient expression of CfCYP76AH15 in N. benthamiana leaves.( A ) Total ion chromatograms (TIC) of extracts transiently expressing CfCXS, CfGGPPS, CfTPS1 and CfTPS3 (miltiradiene biosynthesis genes) in combination with water (-) or CfCYP76AH15 .…”
Section: Resultsmentioning
confidence: 99%
“…Thus, it is likely that the ability of CYP76AHs to catalyze 11-oxo-13 R -manoyl oxide has evolved convergently in these plants (Figure 11). 10.7554/eLife.23001.023Figure 11.Phylogeny of known full-length CYP76AHs.The enzymes used are listed below with their accession numbers or source of publication: Cf CYP76AH15, KT382358; Cf CYP76AH17, KT382360; Cf CYP76AH8, KT382348; Cf CYP76AH11, KT382349; Cf CYP76AH16, KT382359; Cf CYP76AH9, KT382347; Cf CYP76AH10, KT382346; Cf CYP71D381, KT382342; Ro FS1, AJQ30187 (Božić et al, 2015); Sm CYP76AH3, KR140168 (Guo et al, 2016); Ro FS2, AJQ30188 (Božić et al, 2015); Sf FS, AJQ30186 (Božić et al, 2015); Ro CYP76AH4, (Zi and Peters, 2013); Ro CYP76AH5v1, (Zi and Peters, 2013); Ro CYP76AH5v2, (Zi and Peters, 2013); Ro CYP76AH6, (Zi and Peters, 2013); Ro CYP76AH7, (Zi and Peters, 2013); Sm CYP76AH1, AGN04215 (Guo et al, 2013); Sp CYP76AH24, ALM25796 (Ignea et al, 2016a). Coleus forskohlii enzymes are indicated by a solid black triangle.…”
Forskolin is a unique structurally complex labdane-type diterpenoid used in the treatment of glaucoma and heart failure based on its activity as a cyclic AMP booster. Commercial production of forskolin relies exclusively on extraction from its only known natural source, the plant Coleus forskohlii, in which forskolin accumulates in the root cork. Here, we report the discovery of five cytochrome P450s and two acetyltransferases which catalyze a cascade of reactions converting the forskolin precursor 13R-manoyl oxide into forskolin and a diverse array of additional labdane-type diterpenoids. A minimal set of three P450s in combination with a single acetyl transferase was identified that catalyzes the conversion of 13R-manoyl oxide into forskolin as demonstrated by transient expression in Nicotiana benthamiana. The entire pathway for forskolin production from glucose encompassing expression of nine genes was stably integrated into Saccharomyces cerevisiae and afforded forskolin titers of 40 mg/L.DOI:
http://dx.doi.org/10.7554/eLife.23001.001
“…In a parallel series of experiments, CYP76AHs from rosemary and salvia known to accept miltiradiene as substrate were tested for their ability to use 13 R -manoyl oxide as a substrate. Transient expression of Ro CYP76AH4 (Zi and Peters, 2013), Ro FS1 and Sf FS (Božić et al, 2015) in N. benthamiana leaves able to synthesize 13 R -manoyl oxide demonstrated that Ro CYP76AH4 was able to efficiently convert 13 R -manoyl oxide to 11-oxo-13 R -manoyl, while Ro FS1 and Sf FS were able to produce 11-hydroxy manoyl oxide, in addition to 11-oxo-13 R -manoyl oxide (Figure 7). 10.7554/eLife.23001.017Figure 6.GC-MS analysis of miltiradiene-derived diterpenoids obtained by transient expression of CfCYP76AH15 in N. benthamiana leaves.( A ) Total ion chromatograms (TIC) of extracts transiently expressing CfCXS, CfGGPPS, CfTPS1 and CfTPS3 (miltiradiene biosynthesis genes) in combination with water (-) or CfCYP76AH15 .…”
Section: Resultsmentioning
confidence: 99%
“…Thus, it is likely that the ability of CYP76AHs to catalyze 11-oxo-13 R -manoyl oxide has evolved convergently in these plants (Figure 11). 10.7554/eLife.23001.023Figure 11.Phylogeny of known full-length CYP76AHs.The enzymes used are listed below with their accession numbers or source of publication: Cf CYP76AH15, KT382358; Cf CYP76AH17, KT382360; Cf CYP76AH8, KT382348; Cf CYP76AH11, KT382349; Cf CYP76AH16, KT382359; Cf CYP76AH9, KT382347; Cf CYP76AH10, KT382346; Cf CYP71D381, KT382342; Ro FS1, AJQ30187 (Božić et al, 2015); Sm CYP76AH3, KR140168 (Guo et al, 2016); Ro FS2, AJQ30188 (Božić et al, 2015); Sf FS, AJQ30186 (Božić et al, 2015); Ro CYP76AH4, (Zi and Peters, 2013); Ro CYP76AH5v1, (Zi and Peters, 2013); Ro CYP76AH5v2, (Zi and Peters, 2013); Ro CYP76AH6, (Zi and Peters, 2013); Ro CYP76AH7, (Zi and Peters, 2013); Sm CYP76AH1, AGN04215 (Guo et al, 2013); Sp CYP76AH24, ALM25796 (Ignea et al, 2016a). Coleus forskohlii enzymes are indicated by a solid black triangle.…”
Forskolin is a unique structurally complex labdane-type diterpenoid used in the treatment of glaucoma and heart failure based on its activity as a cyclic AMP booster. Commercial production of forskolin relies exclusively on extraction from its only known natural source, the plant Coleus forskohlii, in which forskolin accumulates in the root cork. Here, we report the discovery of five cytochrome P450s and two acetyltransferases which catalyze a cascade of reactions converting the forskolin precursor 13R-manoyl oxide into forskolin and a diverse array of additional labdane-type diterpenoids. A minimal set of three P450s in combination with a single acetyl transferase was identified that catalyzes the conversion of 13R-manoyl oxide into forskolin as demonstrated by transient expression in Nicotiana benthamiana. The entire pathway for forskolin production from glucose encompassing expression of nine genes was stably integrated into Saccharomyces cerevisiae and afforded forskolin titers of 40 mg/L.DOI:
http://dx.doi.org/10.7554/eLife.23001.001
“…Next to miltiradiene and abietatriene (a spontaneous oxidation product), monohydroxylated derivatives thereof were observed to accumulate (Figure b; Brückner et al ., ). Interestingly, none of these derivatives were reported in a more recent study, in which CPP synthase and miltiradiene synthase from Salvia fruticosa were combined with different P450s to produce ferruginol from miltiradiene, indicating that an additional biosynthetic step may outcompete the endogenous conversion (Božić et al ., ).…”
Section: Engineering Of (Novel) Diterpenoids In Photosynthetic Organismsmentioning
SUMMARYWith tens of thousands of characterized members, terpenoids constitute the largest class of natural compounds that are synthesized by all living organisms. Several terpenoids play primary roles in the maintenance of cell membrane fluidity, as pigments or as phytohormones, but most of them function as specialized metabolites that are involved in plant resistance to herbivores or plant-environment interactions. Terpenoids are an essential component of human nutrition, and many are economically important pharmaceuticals, aromatics and potential next-generation biofuels. Because of the often low abundance in their natural source, as well as the demand for novel terpenoid structures with new or improved bioactivities, terpenoid biosynthesis has become a prime target for metabolic engineering and synthetic biology projects. In this review we focus on the creation of new-to-nature or tailor-made plant-derived terpenoids in photosynthetic organisms, in particular by means of combinatorial biosynthesis and the activation of silent metabolism. We reflect on the characteristics of different potential photosynthetic host organisms and recent advances in synthetic biology and discuss their utility for the (heterologous) production of (novel) terpenoids.
“…Due to the biological significance of carnosol, carnosic acid and tanshinones, there is increasing need for improved or alternative methods of production of these metabolites. As a result, efforts aiming to elucidate the related biosynthetic pathways has led to the identification of several enzymatic steps, not only in S. miltiorrhiza [ 24 , 25 ] but also in other species [ 26 , 27 ]. Specifically, diterpene synthases catalyzing the same enzymatic reactions with SmCDS and SmKSL have been identified in Rosmarinus officinalis [ 26 ] and in Salvia fruticosa [ 27 ].…”
Section: Introductionmentioning
confidence: 99%
“…As a result, efforts aiming to elucidate the related biosynthetic pathways has led to the identification of several enzymatic steps, not only in S. miltiorrhiza [ 24 , 25 ] but also in other species [ 26 , 27 ]. Specifically, diterpene synthases catalyzing the same enzymatic reactions with SmCDS and SmKSL have been identified in Rosmarinus officinalis [ 26 ] and in Salvia fruticosa [ 27 ]. Identification of ferruginol synthase in S. miltiorrhiza , R. officinalis and S. fruticosa enabled the synthesis of ferruginol in yeast cells [ 22 , 27 ].…”
BackgroundSalvia diterpenes have been found to have health promoting properties. Among them, carnosic acid and carnosol, tanshinones and sclareol are well known for their cardiovascular, antitumor, antiinflammatory and antioxidant activities. However, many of these compounds are not available at a constant supply and developing biotechnological methods for their production could provide a sustainable alternative. The transcriptome of S.pomifera glandular trichomes was analysed aiming to identify genes that could be used in the engineering of synthetic microbial systems.ResultsIn the present study, a thorough metabolite analysis of S. pomifera leaves led to the isolation and structure elucidation of carnosic acid-family metabolites including one new natural product. These labdane diterpenes seem to be synthesized through miltiradiene and ferruginol. Transcriptomic analysis of the glandular trichomes from the S. pomifera leaves revealed two genes likely involved in miltiradiene synthesis. Their products were identified and the corresponding enzymes were characterized as copalyl diphosphate synthase (SpCDS) and miltiradiene synthase (SpMilS). In addition, several CYP-encoding transcripts were identified providing a valuable resource for the identification of the biosynthetic mechanism responsible for the production of carnosic acid-family metabolites in S. pomifera.ConclusionsOur work has uncovered the key enzymes involved in miltiradiene biosynthesis in S. pomifera leaf glandular trichomes. The transcriptomic dataset obtained provides a valuable tool for the identification of the CYPs involved in the synthesis of carnosic acid-family metabolites.Electronic supplementary materialThe online version of this article (doi:10.1186/s12864-015-2147-3) contains supplementary material, which is available to authorized users.
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