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The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry

Author
āļœāļđāđ‰āđ€āļ‚āļĩāļĒāļ™ James Reynolds
29 July 2024
Learn about the breakthrough technology of triploid cannabis genetics that Fast Buds is starting to explore.
29 July 2024
8 min read
The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry

āđ€āļ™āļ·āđ‰āļ­āļŦāļē:
āļ­āđˆāļēāļ™āđ€āļžāļīāđˆāļĄāđ€āļ•āļīāļĄ
  • 1. What is triploid genetics?
  • 2. The use of triploids in traditional and modern agriculture
  • 3. Triploid genetics in the cannabis industry
  • 4. How to make triploid cannabis?
  • 5. Benefits for the cannabis industry and consumers
  • 6. Challenges and considerations for triploid cannabis breeding
  • 7. Triploid genetics and autoflowering cannabis
  • 8. Conclusion
  • 8. a. References

Right now, the cannabis industry is on the verge of a new revolution thanks to the introduction of triploid genetics. For decades and even centuries, this technology has been applied to many traditional crops, enhancing their productivity and allowing us to enjoy seedless fruit and vegetables. Now, it’s about to transform the cannabis sector. Read on as we explore the origins, development, and applications of triploid genetics, as well as its future in cannabis cultivation.

What is Triploid Genetics?

Triploid genetics refers to organisms that have three sets of chromosomes (3n) instead of the usual two (2n) found in diploid organisms. This can be a natural phenomenon, or it can be induced artificially. In plants, triploidy is often a good thing, as it lets us enjoy bigger fruit without seeds. In cannabis, the results are expected to be the same – larger buds with no seeds in them.

 

The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry: The benefits vs diploid

Triploids: More of everything.

The Use of Triploids in Traditional and Modern Agriculture

You may not have heard the term ‘triploid’ before, but you definitely benefit from triploid plants on a daily basis. By simply looking around your kitchen, you’re likely to see enough examples. It's because the use of triploidy in agriculture isn't as novel an approach as one may think.


Farmers have been cultivating triploid plants for centuries – long before they started to understand the underlying genetics; in fact, long before the very word ‘genetics’ was coined. Early agricultural societies simply kept the plants they liked – more vigorous, uniform, and resistant, with bigger fruit and smaller seeds – and some of those plants displayed these characteristics because they were triploid.

The scientific understanding and deliberate creation of triploid plants began in earnest in the 20th century. Researchers discovered that they could make triploid plants using chemicals like colchicine, which disrupts normal cell division.


Colchicine, derived from the autumn crocus, interferes with microtubule formation right when the cells divide, which results in a double set of chromosomes ending up in the same cell.  With this discovery, the research of triploid genetics went into high gear, and the technology became mainstream.

Examples of Triploids in Agriculture

In modern agriculture, triploid genetics are everywhere. Here are some notable examples:

 

  • Watermelons. Triploid watermelons are seedless, making them more convenient and enjoyable for consumers. They also tend to be larger, most probably because no plant resources are diverted to seed production.

The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry: The benefits vs diploid: Watermelon, grapes, apples, bananas - triploids are common in agriculture

Triploid fruits are great, so we have high hopes for triploid cannabis too.
 

  • Bananas. Historically, this is one of the first crops to have benefited from triploid genetics. Initially, triploid bananas were a lucky mutation, which farmers then stabilized by selectively breeding their plants over centuries. Triploid bananas are sterile, producing fruit without seeds, which is a significant advantage for consumers.
  • Grapes. Grapes are another well-known example of using triploids to produce seedless fruit. People prefer seedless grapes both when they eat them fresh and as raisins. Another advantage of being triploid is  larger, more uniform fruit clusters. Farmers create triploid grapes through selective breeding and colchicine treatment.

Benefits of Triploid Genetics in Agriculture

The benefits of triploid genetics in agriculture are unquestionable; otherwise, the technology wouldn’t have become so widespread. The benefits may differ from culture to culture, but the main ones are:

 

The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry: The benefits

Challenges and Limitations of Triploid Genetics

While triploid genetics offer many benefits and those clearly trump any disadvantages, there are also challenges and limitations to consider when embarking on a breeding project involving triploids:

 

The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry: The drawbacks

Triploid Genetics in the Cannabis Industry

The application of triploid genetics in cannabis is a relatively new but exciting frontier. Cannabis growers are constantly seeking ways to improve yield, potency, and overall cultivation experience, and triploid genetics could be the answer. Triploid cannabis plants could offer several advantages:

 

  • Increased Resin Production

Some research suggests that triploid cannabis plants could produce 40% more resin than their diploid counterparts, leading to higher yields of valuable cannabinoids, such as THC and CBD, as well as aromatic terpenes. Triploid cannabis strains have up to 30% THC on average, with raised levels of terpenes to match, which makes them particularly attractive for the production of concentrates and extracts.

 

  • Sterility

Triploid cannabis plants would be 98% sterile, eliminating the risk of accidental pollination and seed production in all-female gardens. This sterility ensures that growers can consistently produce high-quality sinsemilla (seedless buds), which is all the consumers want.

  • Increased Plant Size

Available research suggests that triploid cannabis has longer stocks and larger fan leaves with bigger and more densely packed stomata. This is especially valuable for hemp production, where the biomass matters the most, but in THC-rich cannabis, it’s also a valuable trait, as it increases metabolism and potentially leads to bigger yields.

 

  • Uniformity

Triploid cannabis plants tend to be more uniform in growth, making the canopy flat and maintaining an equal distance to the grow lights in large commercial greenhouses. The resulting uniformity in the size of the finished product is just as crucial.

 

  • Reduced Risk of Hermaphroditism

Hermaphroditism, or the presence of both male and female reproductive organs on the same plant, can be a significant problem for growers. Triploid plants are less likely to exhibit hermaphroditic traits, reducing the risk of self-pollination and seed production.

How to Make Triploid Cannabis?

Creating triploid cannabis involves several steps:

 

  • Step 1. Creating a Stable Tetraploid Line


The first step in the complex, delicate and tedious process of breeding a triploid cannabis strain is the creation of a tetraploid parent. Start with germinating normal, diploid seeds, and when the cotyledons appear and the growing point is revealed, begin to treat the seedlings with a colchicine solution.


When it’s applied on the growing point, colchicine causes the young plant’s cells to divide abnormally, with each getting a doubled set of chromosomes (4n). So, from the cotyledons up, the growing shoot is tetraploid.


At least, in theory. In practice, not all plants treated this way become tetraploid, and one needs sophisticated and expensive lab equipment to identify the chromosomal composition of your plant’s cells and confirm the success of the operation.

 

The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry: Infographic illustrating the production of triploids (phase 1)

On paper, it's all very straightforward.
 

When you’ve got a large enough collection of tetraploid plants, you can start breeding them in a normal way, preferably over several generations, until you have fixed the desired traits, such as cultivation characteristics and bud quality. This will also hopefully breed out any chance mutations or irregularities, and in the end, you get a stable inbred tetraploid strain.


On the flip side, you can be sure that no traces of colchicine, which is a toxic chemical, will make their way into the next-generation triploid plants or the final product. Whether diploid or triploid, your smoke will be totally safe.

 

  • Step 2. Crossing the Tetraploid with a Diploid


This step is no different from the normal breeding process. The breeder takes a tetraploid mother and a diploid father and crosses them to get a plant with a triple set of chromosomes. There is some variability to this process, and while the majority of offspring will in fact be triploid, you may see some diploid and tetraploid specimens as well. Again, you’ll need equipment for chromosomal analysis to identify and discard them.

 

The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry: Infographic illustrating the production of triploids (phase 2)

Genetic testing is needed to identify triploid cultivars and discard the rest.


The good thing is that long before this step, no traces of colchicine, which is a toxic chemical, are left in either the seeds or the plants. Your smoke will be totally safe.

 

  • Step 3. Selection


To be truly outstanding, cannabis strains require rigorous selection, and triploid plants are no exception. One may need to pair up many tetraploid and diploid parents to get a winning combination. However, once this happens, you can keep the cross as a mother plant and use it to produce marketable tetraploid seeds of premium quality.

Benefits for the Cannabis Industry and Consumers

Cash-crop growers may see their cycles reduced by an average of 7 days, bringing down electricity bills and reducing the overall carbon footprint. At the end of this shortened cycle, the yields could be just the same or even more abundant (by 10-20% if following best practices), and thanks to denser trichomes, you may expect a 3-5% increase in THC. The larger and denser buds of triploids will also be more appealing to the consumer.

Challenges and Considerations for Triploid Cannabis Breeding

While the potential benefits of triploid cannabis are significant, there are also challenges and considerations to address:

 

  • Breeding Expertise

The process of creating and propagating triploid cannabis plants is complex and requires specialized knowledge and equipment. Breeders must carefully manage the use of chemicals like colchicine and employ advanced techniques, such as somatic hybridization and tissue culture, to streamline the process and achieve success.

 

  • Achieving Genetic Stability

Maintaining genetic stability in triploid cannabis plants is essential for ensuring consistent quality and performance. Breeders must monitor and manage genetic variations to prevent unwanted traits from emerging.

 

  • Regulatory Compliance and Consumer Acceptance

The use of chemicals and genetic manipulation of plants raises regulatory considerations. Growers and breeders must ensure that their practices comply with local, state, and federal regulations to avoid legal issues. Consumer acceptance isn’t a given either, as consumers need to be reassured – through education and transparency – that triploid genetics are safe.

 

The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry: Challenges and considerations

Due to many challenges, triploid genetics remains a Big League game.

Triploid Genetics and Autoflowering Cannabis

Autoflowering cannabis, is another area where triploid genetics could be a breakthrough. By combining the benefits of triploidy with autoflowering traits, we could develop plants that:

 

  • Mature more rapidly. Preliminary research has shown that triploidy may result in a 7-days shorter life cycle on average. If this feature is stabilized, autoflowers can consistently produce in under two months from seeds, allowing for a faster turnover and multiple harvests per year.
  • Are more resinous and potent. Autoflowers have already come a long way from what they were at the dawn of autoflowering evolution. Now, the best of them are just as potent and aromatic as photoperiod strains. The introduction of triploidy would take these traits to the next level.
  • Remain sterile. While autoflowers are usually feminized and are supposed to produce unseeded female buds all the time, accidental pollination is an ever-present risk even in the best-maintained gardens. Using triploid genetics could bring this risk down virtually to zero.
  • Better adapt to adverse conditions. Autoflowers are bred from Ruderalis, a feral Siberian subspecies known for its hardiness, and the ability of autoflowers to adapt to very harsh environments is one of their main attractions. This feature could be enhanced even further with triploidy.

 

The Potential of Triploid Genetics in Revolutionizing the Cannabis Industry: A Fast Buds employee in a cannabis-cultivation facility

Fast Buds: Always a hotbed of innovation.


As autoflowers make the staple of our collection, we at Fast Buds eagerly embrace this innovative yet time-proven technology that promises better results to our customers. As we extend our lineup of autoflowering strains and also venture into the fast-flowering and photoperiod domains, we’re focusing on triploids as the most promising way of delivering the best cannabis seeds on the market. This work has already begun.

Conclusion

The potential of triploid genetics in the cannabis industry is immense. By leveraging this technology, growers can produce plants with superior traits, benefiting both the industry and consumers. As research continues and breeding techniques advance, triploid cannabis may soon become a staple in modern cultivation, heralding a new era of innovation and excellence in the field. The combination of triploid and autoflowering genetics further enhances the possibilities, offering rapid, high-quality, and consistent cannabis products.

References