Growing Weed ? How to get CBD and THC out of YEAST

The yeast that people have used for millennia to brew alcoholic drinks has now been engineered to produce cannabinoids — chemicals with medicinal and sometimes mind-altering properties found in cannabis.

The feat1, described on 27 February in Nature , turns a sugar in brewer’s yeast ( Saccharomyces cerevisiae ) called galactose into tetrahydrocannabinol (THC), the main psychoactive compound in cannabis ( Cannabis sativa ). The altered yeast can also produce cannabidiol (CBD), another major cannabinoid that’s attracted attention lately for its potential therapeutic benefits, including its anti-anxiety and pain-relief effects.

The hope is that this fermentation process will enable manufacturers to produce THC, CBD and rare cannabinoids that are found in trace amounts in nature more cheaply, efficiently and reliably than conventional plant-based cultivation.

Previous work2,3 described constructing parts of the cannabinoid production line in yeast, but not the complete process. The latest study is the first that has “put it all together and shown that it actually works inside one cell, which is cool”, says Kevin Chen, chief executive of Hyasynth Bio in Montreal, Canada, one of at least ten companies working to produce cannabinoids in engineered yeast, bacteria or algae.

Researchers have produced anti-malaria drugs for commercial purposes, as well as opiates in the lab, using similar yeast-grown methods before. But the technology for making cannabinoids is nowhere near ready for market. David Kideckel, a cannabis analyst with AltaCorp Capital in Toronto, Canada, predicts that it will be another 18–24 months before synthetic cannabinoids are cost-effective enough to sell to either pharmaceutical companies or the general public.

Craft brew

To build their cannabinoid factory in yeast, synthetic biologist Jay Keasling at the University of California, Berkeley, and his colleagues modified several genes found in S. cerevisiae, and introduced others from five types of bacteria and from the cannnabis plant. In total, they needed to make 16 genetic modifications to transform galactose into inactive forms of THC or CBD. Heating the cannabinoids switches them into their active forms. The team produced roughly 8 milligrams per litre of THC and lower levels of CBD.

But those yields would need to increase by at least 100-fold for the cost to be competitive with plant-extracted cannabinoids, says Jason Poulos, chief executive of Librede, a company in Carlsbad, California, that holds the first patent on a process for making cannabinoids from sugars in yeast.

Scientists at Demetrix, a company formed by Keasling in 2015 to work on this problem, have already boosted the cannabinoid yield of this process by several orders of magnitude, says Jeff Ubersax, chief executive of the firm in Emeryville, California.

Keasling and his team have also been able to engineer their yeast to transform various fatty acids into cannabinoids that don’t occur in nature. It’s possible to screen these compounds for therapeutic properties; if any show promise, they could be patentable because they don’t occur naturally. That aspect of newly created cannabinoids could help to build interest among drug companies, few of which have actively explored cannabis-based medicines.

“The pharmaceutical industry will really lap those molecules up,” says Vikramaditya Yadav, a chemical engineer at the University of British Columbia in Vancouver, Canada, who is working with InMed Pharmaceuticals in Vancouver to produce cannabinoids using bacteria4.

No plants needed

But some argue that yeast-based fermentation might not be the best way of making cannabinoids. Toronto-based Trait Biosciences, for example, is genetically engineering cannabis to produce water-soluble cannabinoids for the beverage industry. They’re also trying to modify their plants so that every tissue, not just the resin glands that normally secrete cannabinoids, can produce novel cannabis-derived compounds. “Everything you can do in yeast, you can do in the plant itself with far greater yield and purity,” says Trait’s chief strategic officer Ronan Levy.

And earlier this month, biochemist Jim Bowie of the University of California, Los Angeles, described5 a process for turning sugar into CBD without the need for the reactions to occur inside a cell. His team managed to produce a precursor to the inactive forms of THC and CBD in commercially viable amounts, and the researchers are aiming to develop the approach through a start-up called Invizyne Technologies.

“Cells are a useful vehicle for producing that pathway, but we don’t want the cells,” says Bowie. “We want the damn pathway.”

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Other explorations

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Cannabinoids in high concentrations are cytotoxic. Which is one of the issues with production in yeast.

the plant even pushes the enzymes producing cannabinoids into the extra cellular space…

Anyone who thinks they can ignore the chemistry AND the biology and produce cannabinoids in any old plant cell in high enough concentrations to make harvesting them viable is likely in for a disappointing time imo.

Glycosylation might solve the “how do we store these hydrophobic metabolites in an aqueous environment” problem, but unless it wrecks the “cannabinoid-ness”, I don’t see that it addresses the cytotoxicity.

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I can already hear the whispered gasps of hideous TC test tube failures… “k-kill…us…”

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If they can draw out cannabinoids simultaneously, they might have the chance to overcome the toxicity issue.

This seems self contradictory – going up two orders of magnitude is already a 100x increase at least. Unless they mean this low result is already the product of being 100x better than whatever they started with.

It’s going to be tough to make yeast compete with a plant that gets 30% yield…

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Just as a data point, oxycodone is still derived from poppy extract, and poppies yield much lower than cannabis.

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So how many years do you think it will take before ordinary people can get hold of this yeast?

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Um, Never!

Never, but don’t worry. The yeast pathway is not one that is viable or even attractive to most normal people.

Imagine a cascade of fermentation tanks thousands of gallons in size each just growing out yeast into a broth that is less than 1% of your target cannabinoid.

I interviewed for an engineering position with Demetrix last year and the direction they’re headed is the rare, novel cannabinoids that arent produced through plant pathways. This method will never replace plant cultivation and extraction, but it can be a good method of producing not-insignificant amounts of the really rare cannabinoids.

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Although, if you happen to pick up a warehouse for really cheap to live in, you’ll have the room to be able to do it!

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My understanding is that most of the presently viablr pathways allow for a ballpark [1000…10000]:1 production ratio. So, 1 to 10 metric tons of yeast to 1 kg cannabinoids produced.

It’s certainly not viable for common cannabinoids. Trace/rare ones? Maybe, if one of them cures some terrible or common disease or there is otherwise substantial demand.

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Following a feasibility study on the production of baker’s yeast, the pre-engineering for a yeast plant designed for a daily capacity of 10,000 kg based on molasses was carried out in 2015

Depends on the cost I guess… I mean seems like it would be possible to use the left over yeast for something idk

That one hell of a ratio! What the fuck do you do with 1-10 metric fuck tons of yeast? Can it be reused, or does it have to be trashed? Can it maybe be converted to something else after the generation of the cannabinoids?

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My understanding is that the post-extraction yeast can be sold, though it’s likely not a large $ amount, though better than paying to have it removed.

Maybe animal feed or something.

I love this stuff, we were talking in another thread recently about an adjunct of this topic. I love it.

What I find most promising is not that the yeast is making CBD or THC; it’s that it can likely be configured to produce ANY cannabinoid we desire, perhaps, particularly the hard to grow cannabinoids?

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Yeah those are the only ones that make sense from an economic standpoint. It takes a lot of infrastructure to extract 10,000 kg of yeast to get a single kg of product. That product needs to be worth a whole lot more than $500/kg to make it worth the investment.

As MagisterChemist pointed out, oxy is still derived from poppies, and google suggests that an acre of poppy cultivation yields 3-6kg of raw opium.

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