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How Ancient Virus Got Cannabis High

Summary: Researchers provide the first cannabis chromosome map, revealing ancient viruses contributed to the evolution of marijuana.

Source: University of Toronto.

World’s first cannabis chromosome map reveals the plant’s evolutionary past and points to its future as potential medicine.

THC and CBD, bioactive substances produced by cannabis and sought by medical patients and recreational users, sprung to life thanks to ancient colonization of the plant’s genome by viruses, U of T researchers have found.

The finding is only one of the insights revealed by the long-awaited cannabis genome map detailing gene arrangement on the chromosomes, published recently in the journal Genome Research. Among other revelations are discovery of a gene responsible for the production of cannabichromene, or CBC, a lesser known cannabinoid, as the active substances in cannabis are known, and new insights into how strain potency is determined.

“The chromosome map is an important foundational resource for further research which, despite cannabis’ widespread use, has lagged behind other crops due to restrictive legislation,” says Tim Hughes, a professor in the Donnelly Centre for Cellular and Biomolecular Research and co-leader of the study. Hughes is also a professor in the Department of Molecular Genetics and Senior Fellow at the Canadian Institute for Advancement of Research.

The researchers expect the map will speed up breeding efforts to create new strains with desired medical properties as well as varieties that can be grown more sustainably, or with increased resistance to diseases and pests.

The study was a three-part collaboration between Tim Hughes’ team and those of Jonathan Page, of Aurora Cannabis and the University of British Columbia , and Harm van Bakel, of the Icahn School of Medicine at Mt Sinai in New York.

Hughes, Page and van Bakel first got together in 2011 when they released the first draft of cannabis genome which was too fragmented to reveal gene position on chromosomes.

The new map reveals how hemp and marijuana, which belong to the same species Cannabis sativa, evolved as separate strains with distinct chemical properties. Cannabis plants grown for drug use (“marijuana”) are abundant in psychoactive tetrahydrocannabinol, or THC, whereas hemp produces cannabidiol, or CBD, popular of late for its medicinal potential. Some people use CBD to relieve pain and it is also being tested as a treatment for epilepsy, schizophrenia and Alzheimer’s.

The enzymes making THC and CBD are encoded by THCA and CBDA synthase genes, respectively. Both are found on chromosome 6 of the ten chromosomes the cannabis genome is packaged into. There, the enzyme genes are surrounded by vast swathes of garbled DNA which came from viruses that colonized the genome millions of years ago. This viral DNA, or retroelements as it is known, made copies of itself that spread across the genome by jumping into other sites in the host cell’s DNA.

“Plant genomes can contain millions of retroelement copies,” says van Bakel, an assistant professor in the Icahn Institute for Data Science and Genomic Technology in New York and in the department of Genetics and Genome Sciences. “This means that linking genes on chromosomes is analogous to assembling a huge puzzle where three quarters of the pieces are nearly the same color. The combination of a genetic map and PacBio sequencing technology allowed us to increase the size of the puzzle pieces and find enough distinguishing features to facilitate the assembly process and pinpoint the synthase genes.”

The researchers believe that gene duplication of the ancestral synthase gene and expanding retroelements drove ancient cannabis to split into chemically distinct types. Humans subsequently selected for plants containing desirable chemistry such as high THC.

The gene sequences for the THCA and CBDA synthases are nearly identical supporting the idea that they come from the same gene which was duplicated millions of years ago. Over time, one or both gene copies became scrambled by invading retroelements, and by evolving separately, they eventually came to produce two different enzymes – CBDA synthase found in hemp (fibre-type), and THCA synthase in drug-type (marijuana).

Because the enzymes are so similar at the DNA level, until this study it was not even clear if they are encoded by separate genes or by two versions of the same gene. Adding to the confusion was the fact that most strains produce both CBD and THC despite breeders’ efforts to grow hemp varieties free from the mind-altering THC for users looking to avoid it.

cannabis leaf

The researchers expect the map will speed up breeding efforts to create new strains with desired medical properties as well as varieties that can be grown more sustainably, or with increased resistance to diseases and pests.NeuroscienceNews.com image is in the public domain.

The chromosome map now clearly shows that two distinct genes are at play which should make it possible to separate them during breeding to grow plants without THC.

Some psychoactive effects in medical strains could be coming from CBC, a lesser known cannabinoid that has unusual pharmacology including anti-inflammatory properties. The discovery of the gene responsible for CBC synthesis will make it possible for breeders to tailor its content in future varieties.

“Mainstream science has still not done enough because of research restrictions,” says Page, of UBC and Chief Scientific Officer at Aurora, one of Canada’s largest producers of medical cannabis. “Legalization and looming ease of research regulation really provide for opportunities for more research to be done. And Canada is leading the way.”

About this neuroscience research article

Funding: Canadian Institutes of Health and Research funded this study.

Source: Jovana Drinjakovic – University of Toronto
Publisher: Organized by NeuroscienceNews.com.
Image Source: NeuroscienceNews.com image is in the public domain.
Original Research: Open access research for “A physical and genetic map of Cannabis sativa identifies extensive rearrangement at the THC/CBD acid synthase locus” by Kaitlin U Laverty, Jake M Stout, Mitchell J Sullivan, Hardik Shah, Navdeep Gill, Larry Holbrook, Gintaras Deikus, Robert Sebra, Timothy R Hughes, Jonathan E Page and Harm van Bakel in Genome Research. Published September 7 2018.
doi:10.1101/gr.242594.118

Cite This NeuroscienceNews.com Article
University of Toronto”How Ancient Virus Got Cannabis High.” NeuroscienceNews. NeuroscienceNews, 27 November 2018.
<http://neurosciencenews.com/cannabis-high-virus-10259/>.
University of Toronto(2018, November 27). How Ancient Virus Got Cannabis High. NeuroscienceNews. Retrieved November 27, 2018 from http://neurosciencenews.com/cannabis-high-virus-10259/
University of Toronto”How Ancient Virus Got Cannabis High.” http://neurosciencenews.com/cannabis-high-virus-10259/ (accessed November 27, 2018).

Abstract

A physical and genetic map of Cannabis sativa identifies extensive rearrangement at the THC/CBD acid synthase locus

Cannabis sativa is widely cultivated for medicinal, food, industrial, and recreational use, but much remains unknown regarding its genetics, including the molecular determinants of cannabinoid content. Here, we describe a combined physical and genetic map derived from a cross between the drug-type strain ‘Purple Kush’ and the hemp variety ‘Finola’. The map reveals that cannabinoid biosynthesis genes are generally unlinked, but that aromatic prenyltransferase (AP), which produces the substrate for THCA and CBDA synthases (THCAS and CBDAS), is tightly linked to a known marker for total cannabinoid content. We further identify the gene encoding CBCA synthase (CBCAS) and characterize its catalytic activity, providing insight into how cannabinoid diversity arises in cannabis. Strikingly, THCAS and CBDAS (which determine the drug vs hemp chemotype) are contained within large (>250 kb) retrotransposon-rich regions that are highly non-homologous between drug- and hemp-type alleles, and are furthermore embedded within ~40 Mb of non-recombining repetitive DNA. The chromosome structures are similar to those in grains such as wheat, with recombination focused in gene-rich, repeat-depleted regions near chromosome ends. The physical and genetic map should facilitate further dissection of genetic and molecular mechanisms in this commercially and medically important plant.

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