Bioprospecting Microbes and Enzymes for the Production of Pterocarpans and Coumestans

Overview

Journal Front Bioeng Biotechnol

Date 2023 May 15

PMID 37187887

Authors

Fernando Perez Rojo

J Jane Pillow

Parwinder Kaur

Affiliations

Soon will be listed here.

Abstract

The isoflavonoid derivatives, pterocarpans and coumestans, are explored for multiple clinical applications as osteo-regenerative, neuroprotective and anti-cancer agents. The use of plant-based systems to produce isoflavonoid derivatives is limited due to cost, scalability, and sustainability constraints. Microbial cell factories overcome these limitations in which model organisms such as offer an efficient platform to produce isoflavonoids. Bioprospecting microbes and enzymes can provide an array of tools to enhance the production of these molecules. Other microbes that naturally produce isoflavonoids present a novel alternative as production chassis and as a source of novel enzymes. Enzyme bioprospecting allows the complete identification of the pterocarpans and coumestans biosynthetic pathway, and the selection of the best enzymes based on activity and docking parameters. These enzymes consolidate an improved biosynthetic pathway for microbial-based production systems. In this review, we report the state-of-the-art for the production of key pterocarpans and coumestans, describing the enzymes already identified and the current gaps. We report available databases and tools for microbial bioprospecting to select the best production chassis. We propose the use of a holistic and multidisciplinary bioprospecting approach as the first step to identify the biosynthetic gaps, select the best microbial chassis, and increase productivity. We propose the use of microalgal species as microbial cell factories to produce pterocarpans and coumestans. The application of bioprospecting tools provides an exciting field to produce plant compounds such as isoflavonoid derivatives, efficiently and sustainably.

Citing Articles

Biosynthesis and metabolic engineering of isoflavonoids in model plants and crops: a review.

Wang L, Li C, Luo K Front Plant Sci. 2024; 15:1384091.

PMID: 38984160 PMC: 11231381. DOI: 10.3389/fpls.2024.1384091.

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