Phytocannabinoids: Origins and Biosynthesis

Gülck, Thies; Møller, Birger Lindberg

doi:10.1016/j.tplants.2020.05.005

Cited by 215 publications

(231 citation statements)

References 150 publications

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“…In accordance with this domain structure, THCAS and CBDAS have been found to be catalytically active in the extracellular storage cavity of the glandular trichome and rely on covalently bound FAD and O2 for their activity (Sirikantaramas et al 2005;Rodziewicz et al 2019). CBCAS is less extensively studied, but considering its high sequence similarity with THCAS, probably shares these biochemical activities (Morimoto et al 1997;Gülck and Møller 2020). However, the latest phylogenetic classification of plant BBE-like genes was based on Arabidopsis sequences only (Brassicaceae) (Daniel et al 2016) and consequently lacks genes from Cannabis and related genera.…”

Section: The Cannabinoid Biosynthetic Pathwaymentioning

confidence: 73%

“…The two most abundant and well-known cannabinoids are ∆ 9 -tetrahydrocannabinol (THC) and cannabidiol (CBD), but more than 120 others have been identified in Cannabis (ElSohly et al 2017). Some other plant genera such as Rhododendron and Radula have also been found to make cannabinoids (Iijima et al 2017;Gülck and Møller 2020). THC is responsible for the psychoactive effect of Cannabis through its partial agonist activity at endocannabinoid receptors (Gaoni and Mechoulam 1964;Mechoulam and Parker 2013).…”

Section: Introductionmentioning

confidence: 99%

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Origin and evolution of the cannabinoid oxidocyclase gene family

Velzen

Schranz

2020

Preprint

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Cannabis is an ancient crop representing a rapidly increasing legal market, especially for medicinal purposes. Medicinal and psychoactive effects of Cannabis rely on specific terpenophenolic ligands named cannabinoids. Recent whole-genome sequencing efforts have uncovered variation in multiple genes encoding the final steps in cannabinoid biosynthesis. However, the origin, evolution, and phylogenetic relationships of these cannabinoid oxidocyclase genes remain unclear. To elucidate these aspects we performed comparative genomic analyses of Cannabis, related genera within the Cannabaceae family, and selected outgroup species. Results show that cannabinoid oxidocyclase genes originated in the Cannabis lineage from within a larger gene expansion in the Cannabaceae family. Localization and divergence of oxidocyclase genes in the Cannabis genome revealed two main syntenic blocks, each comprising tandemly repeated cannabinoid oxidocyclase genes. By comparing these blocks with those in genomes from closely related species we propose an evolutionary model for the origin, neofunctionalization, duplication, and diversification of cannabinoid oxidocycloase genes. Based on phylogenetic meta-analyses, we propose a comprehensive classification of three main clades and seven subclades that is intended to aid unequivocal referencing and identification of cannabinoid oxidocyclase genes. Our data suggest that cannabinoid oxidocyclase gene copy number variation may have less functional relevance than previously thought. Instead, we propose that cannabinoid phenotype is primarily determined by presence/absence of single-copy genes. Increased sampling across Cannabis’ native geographic range is likely to uncover additional cannabinoid oxidocyclase gene sequence variation.Significance statementCannabis genome sequencing efforts have revealed extensive cannabinoid oxidocyclase gene variation. However, phylogenetic relationships and evolution of these genes remains unclear. Our meta analysis of currently available data reveals that these genes comprise three main clades and seven subclades that originated through Cannabis-specific gene duplication and divergence. Our new conceptual and evolutionary framework serves as a reference for future description and functional analyses of cannabinoid oxidocyclases.

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Section: The Cannabinoid Biosynthetic Pathwaymentioning

confidence: 73%

Section: Introductionmentioning

confidence: 99%

Origin and evolution of the cannabinoid oxidocyclase gene family

Velzen

Schranz

2020

Preprint

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“…Cannabinoid synthesis begins with the precursor molecules olivetolic acid and geranylpyrophosphate, which combine to form cannabigerolic acid (CBGA) (Shoyama et al, 1975;Fellermeier and Zenk, 1998;Fellermeier et al, 2001;Gülck and Møller, 2020). CBGA serves as the precursor to most other cannabinoids and is converted to Δ9-THCA (tetrahydrocannabinolic acid), CBDA (cannabidiolic acid), and CBCA (cannabichromenic acid) ( Figure 1).…”

Section: Cannabigerol and Cannabinoid Synthesismentioning

confidence: 99%

The Pharmacological Case for Cannabigerol

Nachnani

Raup‐Konsavage

Vrana

2020

J Pharmacol Exp Ther

121

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“…The quantity of CBGA will also be increased by simultaneous silencing of THCAS and CBDAS. Besides, silencing of both THCAS and CBDAS will expedite the production of minor cannabinoid, cannabichromenic acid (CBCA) which is difficult and expensive for pharmacological studies in clinical trials because of low abundance (Gülck and Møller, 2020).…”

Section: Targeting Phytochemical Pathway Genementioning

confidence: 99%

“…In cannabinoid synthesis, toxicity effects must be considered, as several cannabinoid pathway metabolites such as CBGA and THCA cause cell death via apoptosis in host plant (Sirikantaramas et al, 2005). In hemp, olivetolic acid synthesized in cytosol is transferred to plastid, where olivetolic acid and geranyl-PP are converted into CBGA, which is finally released to apoplast (Gülck and Møller, 2020). It will be critical to elucidate the mechanism underlying transport and accumulation of metabolites and apply it to better hemp phytochemical production in other plant species commercially ( Table 1).…”

Section: Alternative Platforms For Hemp Phytochemical Productionmentioning

confidence: 99%

Metabolic Engineering Strategies of Industrial Hemp (Cannabis sativa L.): A Brief Review of the Advances and Challenges

et al. 2020

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Industrial hemp (Cannabis sativa L.) is a diploid (2n = 20), dioecious plant that is grown for fiber, seed, and oil. Recently, there has been a renewed interest in this crop because of its panoply of cannabinoids, terpenes, and other phenolic compounds. Specifically, hemp contains terpenophenolic compounds such as cannabidiol (CBD) and cannabigerol (CBG), which act on cannabinoid receptors and positively regulate various human metabolic, immunological, and physiological functions. CBD and CBG have an effect on the cytokine metabolism, which has led to the examination of cannabinoids on the treatment of viral diseases, including COVID-19. Based on genomic, transcriptomic, and metabolomic studies, several synthetic pathways of hemp secondary metabolite production have been elucidated. Nevertheless, there are few reports on hemp metabolic engineering despite obvious impact on scientific and industrial sectors.In this article, recent status and current perspectives on hemp metabolic engineering are reviewed. Three distinct approaches to expedite phytochemical yield are discussed. Special emphasis has been placed on transgenic and transient gene delivery systems, which are critical for successful metabolic engineering of hemp. The advent of new tools in synthetic biology, particularly the CRISPR/Cas systems, enables environment-friendly metabolic engineering to increase the production of desirable hemp phytochemicals while eliminating the psychoactive compounds, such as tetrahydrocannabinol (THC).

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Phytocannabinoids: Origins and Biosynthesis

Cited by 215 publications

References 150 publications

Origin and evolution of the cannabinoid oxidocyclase gene family

Origin and evolution of the cannabinoid oxidocyclase gene family

The Pharmacological Case for Cannabigerol

Metabolic Engineering Strategies of Industrial Hemp (Cannabis sativa L.): A Brief Review of the Advances and Challenges

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