Abstract
BackgroundCasbene synthase (CS) is responsible for the first committed step in the biosynthesis of phorbol esters (PE) in the Euphorbiaceae. PE are abundant in the seeds of the biofuel crop Jatropha curcas and its toxicity precludes the use of the protein-rich cake obtained after oil extraction as an animal feed and the toxicity of the fumes derived from burning PE containing biofuel is also a matter of concern. This toxicity is a major hindrance to exploit the potential of this crop as a source of raw material to produce biodiesel. For this reason, the current research on J. curcas is mainly focused on the understanding of the biosynthesis and site of synthesis of PE, as an avenue for the development of genotypes unable to synthesize PE in its seeds.ResultsHere, we present targeted proteomics assays (SRM and PRM) to detect and quantify CS in leaves, endosperm, and roots of two J. curcas genotypes with contrasting levels of PE. These assays were based on the use of reference isotopic labeled synthetic peptides (ILSP) predicted from 12 gene models of CS from the J. curcas genome.ConclusionOur targeted proteomics methods were able to detect and quantify, for the first time, CS gene products and demonstrate the distribution of CS isoforms only in roots from J. curcas genotypes with a high and low concentration of PE. These methods can be expanded to monitor CS, at the protein level, in different tissues and genotypes of J. curcas.
Highlights
Casbene synthase (CS) is responsible for the first committed step in the biosynthesis of phorbol esters (PE) in the Euphorbiaceae
Casbene synthase was first studied in the castor plant (Ricinus communis) [10], where it catalyses the synthesis of the phytoalexin casbene from Geranyl geranyl diphosphate (GGDP); ensuing studies [6, 11] led to the cloning of a J. curcas CS gene (JcCSH) coding for a protein with high sequence similarity with the CS from R. communis
The chromatogram of seed extracts from the High phorbol ester levels (HPE) genotype is shown in Fig. 1, where the presence of five peaks between 17.5–22.5 min. are shown, while seed extracts of the HPE genotype did not show any detectable signal in the same retention time window, confirming the contrasting levels of PE in these two genotypes
Summary
Casbene synthase (CS) is responsible for the first committed step in the biosynthesis of phorbol esters (PE) in the Euphorbiaceae. PE are abundant in the seeds of the biofuel crop Jatropha curcas and its toxicity precludes the use of the protein-rich cake obtained after oil extraction as an animal feed and the toxicity of the fumes derived from burning PE containing biofuel is a matter of concern. This toxicity is a major hindrance to exploit the potential of this crop as a source of raw material to produce biodiesel. Ha et al [14] determined this physical gene cluster is located on chromosome 3
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