Sumit G Gandhi1, Vidushi Mahajan, Yashbir S Bedi. 1. Plant Biotechnology Division, Indian Institute of Integrative Medicine (CSIR-IIIM), Council of Scientific and Industrial Research, Canal Road, Jammu Tawi, 180001, India, sumit@iiim.ac.in.
Abstract
MAIN CONCLUSION: Medicinal and aromatic plants are known to produce secondary metabolites that find uses as flavoring agents, fragrances, insecticides, dyes and drugs. Biotechnology offers several choices through which secondary metabolism in medicinal plants can be altered in innovative ways, to overproduce phytochemicals of interest, to reduce the content of toxic compounds or even to produce novel chemicals. Detailed investigation of chromatin organization and microRNAs affecting biosynthesis of secondary metabolites as well as exploring cryptic biosynthetic clusters and synthetic biology options, may provide additional ways to harness this resource. Plant secondary metabolites are a fascinating class of phytochemicals exhibiting immense chemical diversity. Considerable enigma regarding their natural biological functions and the vast array of pharmacological activities, amongst other uses, make secondary metabolites interesting and important candidates for research. Here, we present an update on changing trends in the biotechnological approaches that are used to understand and exploit the secondary metabolism in medicinal and aromatic plants. Bioprocessing in the form of suspension culture, organ culture or transformed hairy roots has been successful in scaling up secondary metabolite production in many cases. Pathway elucidation and metabolic engineering have been useful to get enhanced yield of the metabolite of interest; or, for producing novel metabolites. Heterologous expression of putative plant secondary metabolite biosynthesis genes in a microbe is useful to validate their functions, and in some cases, also, to produce plant metabolites in microbes. Endophytes, the microbes that normally colonize plant tissues, may also produce the phytochemicals produced by the host plant. The review also provides perspectives on future research in the field.
MAIN CONCLUSION: Medicinal and aromatic plants are known to produce secondary metabolites that find uses as flavoring agents, fragrances, insecticides, dyes and drugs. Biotechnology offers several choices through which secondary metabolism in medicinal plants can be altered in innovative ways, to overproduce phytochemicals of interest, to reduce the content of toxic compounds or even to produce novel chemicals. Detailed investigation of chromatin organization and microRNAs affecting biosynthesis of secondary metabolites as well as exploring cryptic biosynthetic clusters and synthetic biology options, may provide additional ways to harness this resource. Plant secondary metabolites are a fascinating class of phytochemicals exhibiting immense chemical diversity. Considerable enigma regarding their natural biological functions and the vast array of pharmacological activities, amongst other uses, make secondary metabolites interesting and important candidates for research. Here, we present an update on changing trends in the biotechnological approaches that are used to understand and exploit the secondary metabolism in medicinal and aromatic plants. Bioprocessing in the form of suspension culture, organ culture or transformed hairy roots has been successful in scaling up secondary metabolite production in many cases. Pathway elucidation and metabolic engineering have been useful to get enhanced yield of the metabolite of interest; or, for producing novel metabolites. Heterologous expression of putative plant secondary metabolite biosynthesis genes in a microbe is useful to validate their functions, and in some cases, also, to produce plant metabolites in microbes. Endophytes, the microbes that normally colonize plant tissues, may also produce the phytochemicals produced by the host plant. The review also provides perspectives on future research in the field.
Authors: Heiko Rischer; Matej Oresic; Tuulikki Seppänen-Laakso; Mikko Katajamaa; Freya Lammertyn; Wilson Ardiles-Diaz; Marc C E Van Montagu; Dirk Inzé; Kirsi-Marja Oksman-Caldentey; Alain Goossens Journal: Proc Natl Acad Sci U S A Date: 2006-03-24 Impact factor: 11.205
Authors: Karel Miettinen; Lemeng Dong; Nicolas Navrot; Thomas Schneider; Vincent Burlat; Jacob Pollier; Lotte Woittiez; Sander van der Krol; Raphaël Lugan; Tina Ilc; Robert Verpoorte; Kirsi-Marja Oksman-Caldentey; Enrico Martinoia; Harro Bouwmeester; Alain Goossens; Johan Memelink; Danièle Werck-Reichhart Journal: Nat Commun Date: 2014-04-07 Impact factor: 14.919
Authors: Sandra S A Soetaert; Christophe M F Van Neste; Mado L Vandewoestyne; Steven R Head; Alain Goossens; Filip C W Van Nieuwerburgh; Dieter L D Deforce Journal: BMC Plant Biol Date: 2013-12-20 Impact factor: 4.215
Authors: Vincent A Ricigliano; Vincent P Sica; Sonja L Knowles; Nicole Diette; Dianella G Howarth; Nicholas H Oberlies Journal: Phytochemistry Date: 2020-09-25 Impact factor: 4.072
Authors: Wojciech Makowski; Aleksandra Królicka; Anna Nowicka; Jana Zwyrtková; Barbara Tokarz; Ales Pecinka; Rafał Banasiuk; Krzysztof Michał Tokarz Journal: Appl Microbiol Biotechnol Date: 2021-01-15 Impact factor: 4.813