A curcumin direct protein (DiPro) biosensor for cell-free prototyping

In synthetic biology, biosensors are routinely coupled to a gene expression cascade for detecting small molecules and physical signals. We posit that an alternative direct protein (DiPro) biosensor mechanism, could provide a new opportunity for rapid detection of specific chemicals. Herein, we reveal a fluorescent curcumin DiPro biosensor, based on the Escherichia coli double bond reductase (EcCurA) as a detection system. We characterise the curcumin DiPro biosensor and propose enhanced fluorescence is generated through π-π stacking between protein and ligand. Using a cell-free synthetic biology approach, we use the DiPro biosensor to fine-tune 10 reaction parameters (cofactor, substrate, and enzyme levels), assisted through acoustic liquid handling robotics. Overall, we increase curcumin DiPro biosensor fluorescence by 80-fold. We propose a generic DiPro biosensor fluorescence mechanism that can be further exploited for a wider range of chemicals that share intrinsic fluorescence and have a suitable binding protein.

12-Oxophytodienoic Acid Reductase 3 (OPR3) Functions as NADPH-Dependent α,β-Ketoalkene Reductase in Detoxification and Monodehydroascorbate Reductase in Redox Homeostasis

Arabidopsis (Arabidopsis thaliana) 12-oxophytodienoic acid reductase isoform 3 (OPR3) is involved in the synthesis of jasmonic acid (JA) by reducing the α,β-unsaturated double bond of the cyclopentenone moiety in 12-oxophytodienoic acid (12-OPDA). Recent research revealed that JA synthesis is not strictly dependent on the peroxisomal OPR3. The ability of OPR3 to reduce trinitrotoluene suggests that the old yellow enzyme homolog OPR3 has additional functions. Here, we show that OPR3 catalyzes the reduction of a wide spectrum of electrophilic species that share a reactivity toward the major redox buffers glutathione (GSH) and ascorbate (ASC). Furthermore, we show that 12-OPDA reacts with ASC to form an ASC-12-OPDA adduct, but in addition OPR3 has the ability to regenerate ASC from monodehydroascorbate. The presented data characterize OPR3 as a bifunctional enzyme with NADPH-dependent α,β-ketoalkene double-bond reductase and monodehydroascorbate reductase activities (MDHAR). opr3 mutants showed a slightly less-reduced ASC pool in leaves in line with the MDHAR activity of OPR3 in vitro. These functions link redox homeostasis as mediated by ASC and GSH with OPR3 activity and metabolism of reactive electrophilic species.

12-oxophytodienoic acid reductase 3 (OPR3) functions as NADPH-dependent α,β-ketoalkene reductase in detoxification and monodehydroascorbate reductase in redox homeostasis

Arabidopsis (Arabidopsis thaliana) 12-oxophytodienoic acid reductase isoform 3 (OPR3) is involved in the synthesis of jasmonic acid by reducing the α,β-unsaturated double bond of the cyclopentenone moiety in 12-oxo-phytodienoic acid. Recent research revealed that jasmonic acid synthesis is not strictly dependent on the peroxisomal OPR3. In addition, OPR3 is able to reduce trinitrotoluene suggesting that the old yellow enzyme homologue OPR3 has additional functions. Here we demonstrate that OPR3 catalyzes the reduction of a wide spectrum of electrophilic species that share a reactivity towards the major redox buffers glutathione (GSH) and ascorbate (ASC). Furthermore, we demonstrate that OPDA reacts with ascorbate to form an ASC-OPDA adduct, but in addition OPR3 has the ability to regenerate ASC from monodehydroascorbate (MDHA). The presented data characterize OPR3 as a bifunctional enzyme with NADPH-dependent α,β-ketoalkene double bond reductase and monodehydroascorbate reductase activities (MDHAR). opr3 mutants exhibited a slightly less reduced ASC pool in leaves in line with the MDHAR activity of OPR3 in vitro. These functions link redox homeostasis as mediated by ASC and GSH with OPR3 activity and metabolism of reactive electrophilic species (RES).

Jasmonate promotes artemisinin biosynthesis by activating the TCP14-ORA complex inArtemisia annua

Artemisia annuaproduces the valuable medicinal component, artemisinin, which is a sesquiterpene lactone widely used in malaria treatment. AaORA, a homolog of CrORCA3, which is involved in activating terpenoid indole alkaloid biosynthesis inCatharanthus roseus, is a jasmonate (JA)–responsive and trichome-specific APETALA2/ETHYLENE-RESPONSE FACTOR that plays a pivotal role in artemisinin biosynthesis. However, the JA signaling mechanism underlying AaORA-mediated artemisinin biosynthesis remains enigmatic. Here, we report that AaORA forms a transcriptional activator complex with AaTCP14 (TEOSINTE BRANCHED 1/CYCLOIDEA/PROLIFERATING CELL FACTOR 14), which is also predominantly expressed in trichomes. AaORA and AaTCP14 synergistically bind to and activate the promoters of two genes,double bond reductase 2(DBR2) andaldehyde dehydrogenase 1(ALDH1), both of which encode enzymes vital for artemisinin biosynthesis. AaJAZ8, a repressor of the JA signaling pathway, interacts with both AaTCP14 and AaORA and represses the ability of the AaTCP14-AaORA complex to activate theDBR2promoter. JA treatment induces AaJAZ8 degradation, allowing the AaTCP14-AaORA complex to subsequently activate the expression ofDBR2, which is essential for artemisinin biosynthesis. These data suggest that JA activation of the AaTCP14-AaORA complex regulates artemisinin biosynthesis. Together, our findings reveal a novel artemisinin biosynthetic pathway regulatory network and provide new insight into how specialized metabolism is modulated by the JA signaling pathway in plants.

Transient Transformation of Artemisinic Aldehyde ∆ 11 (13) Double Bond Reductase (dbr2) Gene into Artemisia annua L.

Global demand of antimalarial drug artemisinin has a gap with production capacity from existing sources since the low content of this compound from Artemia annua L. Genetic engineering-based strategy for A. annua plant on key enzymes in artemisinin biosynthetic pathway is needed. Artemisinic aldehyde ∆ 11 (13) double bond reductase (dbr2) is one of the key enzyme on artemisinin biosynthesis which was studied in this research. Agrobacterium tumefaciens-mediated transformation of A. annua using dbr2 was carried out. Synthetic dbr2 was ligated into pCAMBIA1303 and transformed into Escherichia coli DH5α. pCAMBIA1303-dbr2 plasmid was transformed to A. tumefaciens AGL1. Leaves of A. annua were infected by positive transformant of recombinant A. tumefaciens (OD600 ≈ 1) supplemented with acetosyringone 50 ppm, and Silwet S-408 0.02%. Samples were incubated in desiccators connected with vacuum pump, this method is called infiltration vacuum. Leaves were covered in dark for 45 min, and co-cultivated on MS co-cultivation media for 3 days. All leaves were washed in 300 ppm cefotaxime and divided into 2 parts; 3 leaves for GUS histochemical assay and 300 mg of leaves for HPLC analysis. Transient transformation was done in triplicate. In GUS histochemical assay, pCAMBIA1303 and pCAMBIA-dbr2 showed positive blue spot where coefficient of variance was less than 5%. PCR analysis for genomic DNA of transformed A. annua showed a positive result of inserted dbr2 recombinant indicated by migration profile and direct sequencing analysis. It could be concluded that pCAMBIA-dbr2 construct and transformation into A. annua have been successfully performed.