Abstract
(+)-Catechin is an important antioxidant of green tea (Camelia sinensis (L.) O. Kuntze). Catechin is known for its positive role in anticancerous activity, extracellular matrix degradation, cell death regulation, diabetes, and other related disorders. As a result of enormous interest in and great demand for catechin, its biosynthesis using metabolic engineering has become the subject of concentrated research with the aim of enhancing (+)-catechin production. Metabolic flux is an essential concept in the practice of metabolic engineering as it helps in the identification of the regulatory element of a biosynthetic pathway. In the present study, an attempt was made to analyze the metabolic flux of the (+)-catechin biosynthesis pathway in order to decipher the regulatory element of this pathway. Firstly, a genetically encoded fluorescence resonance energy transfer (FRET)-based nanosensor (FLIP-Cat, fluorescence indicator protein for (+)-catechin) was developed for real-time monitoring of (+)-catechin flux. In vitro characterization of the purified protein of the nanosensor showed that the nanosensor was pH stable and (+)-catechin specific. Its calculated Kd was 139 µM. The nanosensor also performed real-time monitoring of (+)-catechin in bacterial cells. In the second step of this study, an entire (+)-catechin biosynthesis pathway was constructed and expressed in E. coli in two sets of plasmid constructs: pET26b-PT7-rbs-PAL-PT7-rbs-4CL-PT7-rbs-CHS-PT7-rbs-CHI and pET26b-T7-rbs-F3H-PT7-rbs- DFR-PT7-rbs-LCR. The E. coli harboring the FLIP-Cat was transformed with these plasmid constructs. The metabolic flux analysis of (+)-catechin was carried out using the FLIP-Cat. The FLIP-Cat successfully monitored the flux of catechin after adding tyrosine, 4-coumaric acid, 4-coumaroyl CoA, naringenin chalcone, naringenin, dihydroquercetin, and leucocyanidin, individually, with the bacterial cells expressing the nanosensor as well as the genes of the (+)-catechin biosynthesis pathway. Dihydroflavonol reductase (DFR) was identified as the main regulatory element of the (+)-catechin biosynthesis pathway. Information about this regulatory element of the (+)-catechin biosynthesis pathway can be used for manipulating the (+)-catechin biosynthesis pathway using a metabolic engineering approach to enhance production of (+)-catechin.
Highlights
Antioxidants are compounds that are intrinsic to the defence system of living cells
These proteins have the ability to adopt the helix grip fold with an internal cavity, and structural analyses of these proteins have suggested that binding of (+)-catechin induces conformational changes in critical regions, which makes it fit to be used as the reporter element for our sensor. (+)-Catechin binding is associated with the closed conformation of loop L5 and involves both polar and hydrophobic interaction
A genetically-encoded fluorescence resonance energy transfer (FRET)-based nanosensor (FLIP-Cat) was successfully developed for real-time monitoring of the flux of (+)-catechin in living cells
Summary
Antioxidants are compounds that are intrinsic to the defence system of living cells. They are synthesized by cells against the negative impact of free radicals. (+)-Catechin is one of the most popular and powerful sources of antioxidants. It is recognized for antihypertensive, anti-diabetic, anti-thrombogenic, and anti-proliferative activities and has a vital role to play in the molecular mechanisms of cell death regulation, extracellular matrix degradation, and angiogenesis [5,6,7,8,9,10]. In plants, (+) catechin acts as an infection inhibiting factor and an allelochemical [12].
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