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Chromosome-level genome assembly of Ophiorrhiza pumila reveals the evolution of camptothecin biosynthesis
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Chromosome-level genome assembly of Ophiorrhiza pumila reveals the evolution of camptothecin biosynthesis
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Journal Article
Chromosome-level genome assembly of Ophiorrhiza pumila reveals the evolution of camptothecin biosynthesis
2021
Overview
Plant genomes remain highly fragmented and are often characterized by hundreds to thousands of assembly gaps. Here, we report chromosome-level reference and phased genome assembly of
Ophiorrhiza pumila
, a camptothecin-producing medicinal plant, through an ordered multi-scaffolding and experimental validation approach. With 21 assembly gaps and a contig N50 of 18.49 Mb,
Ophiorrhiza
genome is one of the most complete plant genomes assembled to date. We also report 273 nitrogen-containing metabolites, including diverse monoterpene indole alkaloids (MIAs). A comparative genomics approach identifies strictosidine biogenesis as the origin of MIA evolution. The emergence of strictosidine biosynthesis-catalyzing enzymes precede downstream enzymes’ evolution post γ whole-genome triplication, which occurred approximately 110 Mya in
O. pumila
, and before the whole-genome duplication in
Camptotheca acuminata
identified here. Combining comparative genome analysis, multi-omics analysis, and metabolic gene-cluster analysis, we propose a working model for MIA evolution, and a pangenome for MIA biosynthesis, which will help in establishing a sustainable supply of camptothecin.
Ophiorrhiza pumila
is a medicinal plant that can produce the anti-cancer monoterpene indole alkaloid (MIA) camptothecin. Here, the authors report its genome assembly and propose a working model for MIA evolution and biosynthesis through comparative genomics, synteny, and metabolic gene cluster analyses.
Publisher
Nature Publishing Group UK,Nature Publishing Group,Nature Portfolio
Subject
