sapogenins and methyl-jasmonate

Saponins are mainly amphipathic glycosides that posses many biological activities and confer potential health benefits to humans. Inspite of its medicinal attributes most of the triterpenes and enzymes involved in the saponin biosynthesis remains uncharacterized at the molecular level. Since the major steroidal components are present in the roots of A. racemosus our study is focussed on the comparative denovo transcriptome analysis of root versus leaf tissue and identifying some root specific transcripts involved in saponin biosynthesis using high-throughput next generation transcriptome sequencing.. After sequencing, de novo assembly and quantitative assessment, 126861 unigenes were finally generated with an average length of 1200 bp. Then functional annotation and GO enrichment analysis was performed by aligning all-unigenes with public protein databases including NR, SwissProt, and KEGG. Differentially expressed genes in root were initially identified using the RPKM method using digital subtraction between root and leaf. Twenty seven putative secondary metabolite related transcripts were experimentally validated for their expression in root or leaf tissue using q-RT PCR analysis. Most of the above selected transcripts showed preferential expression in root as compared to leaf supporting the digitally subtracted result obtained. The methyl jasmonate application induces the secondary metabolite related gene transcripts leading to their increased accumulation in plants. Therefore, the identified transcripts related to saponin biosynthesis were further analyzed for their induced expression after 3, 5 and 12 hours of exogenous application of Methyl Jasmonate in tissue specific manner.. In this study, we have identified a large set of cDNA unigenes from A. racemosus leaf and root tissue. This is the first transcriptome sequencing of this non-model species using Illumina, a next generation sequencing technology. The present study has also identified number of root specific transcripts showing homology with saponin biosynthetic pathway. An integrated pathway of identified saponin biosynthesis transcripts their tissue specific expression and induced accumulation after methyl jasmonate treatment was discussed.

Topics: Acetates; Computational Biology; Cyclopentanes; Gene Expression Profiling; Gene Expression Regulation, Plant; Genes, Plant; High-Throughput Nucleotide Sequencing; Magnoliopsida; Metabolic Networks and Pathways; Molecular Sequence Annotation; Oxylipins; Plant Leaves; Plant Roots; Reproducibility of Results; Sapogenins; Transcriptome

Ginseng (Panax ginseng C.A. Meyer) is one of the most popular medicinal herbs and contains pharmacologically active components, ginsenosides, in its roots. Ginsenosides, a class of tetracyclic triterpene saponins, are thought to be synthesized from dammarenediol-II after hydroxylation by the Cyt P450 (CYP) enzyme and then glycosylation by glycosyltransferase (GT). However, no genes encoding the hydroxylation and glycosylation in ginsenoside biosynthesis have been identified. Here, we identify protopanaxadiol synthase, which is a CYP enzyme (CYP716A47), to be involved in the hydroxylation of dammarenediol-II at the C-12 position to yield protopanaxadiol. Nine putative full CYP sequences were isolated from the expressed sequence tags (ESTs) of methyl jasmonate (MeJA)-treated adventitious ginseng roots. The CYP716A47 gene product was selected as the putative protopanaxadiol synthase because this gene was transcriptionally activated not only by MeJA treatment but also in transgenic ginseng that overexpresses squalene synthase and overproduces ginsenosides. In vitro enzymatic activity assays revealed that CYP716A47 catalyzed the oxidation of dammarenediol-II to produce protopanaxadiol. Ectopic expression of CYP716A47 in recombinant WAT21 yeasts that were fed dammarenediol-II yielded protopanaxadiol. Furthermore, co-expression of the dammarenediol synthase gene (PgDDS) and CYP716A47 in yeast yielded protopanaxadiol without adding dammarenediol-II. The chemical structures of the protopanaxadiol products from dammarenediol-II were confirmed using liquid chromatography-atmospheric pressure chemical ionization mass spectrometry (LC/APCIMS). Thus, CYP716A47 is a dammarenediol 12-hydroxylase that produces protopanaxadiol from dammarenediol-II.

Topics: Acetates; Biocatalysis; Biosynthetic Pathways; Chromatography, Liquid; Cyclopentanes; Cytochrome P-450 Enzyme System; DNA, Complementary; Expressed Sequence Tags; Gene Expression Regulation, Enzymologic; Gene Expression Regulation, Plant; Gene Library; Genes, Plant; Ginsenosides; Mass Spectrometry; Oxylipins; Panax; Phylogeny; Plants, Genetically Modified; RNA, Messenger; Saccharomyces cerevisiae; Sapogenins; Saponins; Sequence Analysis, DNA; Transcription, Genetic; Triterpenes

An efficient system to produce saikosaponins (saikosaponin-a and -d) in Bupleurum falcatum adventitious root fragments combined with signal transducers was developed. The roots are heterogeneous in terms of size and shape and sometimes form aggregates during cultivation. When the roots were cut to lengths of about 5 mm using a scalpel and cultivated, the root fragments did not form the aggregates, and root growth and saikosaponin production were not inhibited. After screening various signal transducers, it was clear that methyl jasmonate (MeJA) markedly promoted saikosaponin production. By comparing the effect of MeJA and related substances on saikosaponin production, we conclude that both the pentenyl and carboxylmethyl group of MeJA play an important role in the promotion of saikosaponin production. Addition of both 100 microM MeJA and 20 mM CaCl2 to the medium stimulated the content of saikosaponin in the root, with levels reaching 31.7 mg/g-dry root for 15 days of cultivation. A large amount of root fragments were prepared using a blender and cultivated (23 g-dry root/l) with 400 microM MeJA and 20 mM CaCl2, resulting in a high concentration of saikosaponins (747.3 mg/l).

Topics: Acetates; Calcium Chloride; Cyclopentanes; Oleanolic Acid; Oxylipins; Plants; Sapogenins; Saponins; Signal Transduction; Structure-Activity Relationship