How To Start Growing Cannabis
Do Seeds Produce Healthier Plants?
Compared to clones made using traditional methods, seeds produce plants that grow larger and are more disease resistant. Growing from seed also eliminates the risk of transferring "stowaway" pests such as mildew and gnats, which can show their face and cripple your garden after months of work. Plants grown from seed are reported to be heartier and larger because they establish what's called a taproot, which is the large central root that pokes out of a seed when it first germinates. The taproot grows straight down, anchoring the plant and sprouting all the lateral roots that extend outward. While clones might seem to save time because they're bigger when they enter your garden, it's not hard to plan ahead so that you have seedlings ready of similar size when you would normally buy or start new clones for your next grow cycle. When proper planning is used, seeds can easily replace clones in grow operations with high turnover (frequent harvests). Using plant DNA sex testing also drastically improves the cost-efficiency of growing from seed.
Plants that are started from seed have also been reported to produce a larger harvest than clones that are started at a comparable stage. Finally, the most important aspect of plant health that is affected by cloning is the acceleration of senescence (deterioration due to aging). Each time a clone is cut from a mother plant, it creates a minor stress of infection and tissue damage that accumulates negative consequences over time. Worse, if a clone is taken from a clone (which must be done after a mother becomes exhausted), then senescence will only be accelerated further each generation you get away from the original seed. The multitude of advantages that seeds offer regarding plant health and vigor make them invaluable to many growers.
Seeds vs. Tissue Culture
Many of the disadvantages inherent to clone growing can be overcome using plant tissue culture, however, this requires costly infrastructure and continuous maintenance of culture stocks. Cannabis plants grow very rapidly and a single plant is able to produce thousands of seeds. These factors diminish the potential commercial benefits of using tissue culture (a.k.a. micropropagation) to supply clone stocks. Further, seeds are stable for long periods of time under a wide variety of environmental conditions and are easily germinated with high success rates. An individual seed also requires less space to store it than a micro-propagated plant. When consistent genetics become available as seed stock, the cannabis industry will no longer be reliant on clones to produce a consistent product. Both of these methods (seed production and tissue culture) can produce disease-free and genetically predictable starting points; therefore, overhead costs of maintaining seed stocks vs. maintaining tissue culture stocks will become the major factor in determining how cannabis genetics are propagated in the future - and the clear winner is seeds.
Below is a list of reputable seed banks you can purchase seeds from. This is not an endorsement for any of the following sites. Always check your local laws surrounding cannabis before purchasing seeds online.
For more information about the differences between seeds and clones, check out these other great articles:
1. Daniel Zohary, “Unconscious Selection And The Evolution Of Domesticated Plants,” Economic Botany 58, No. 1 (January 1, 2004): 5–10
2. Doyle Mckey Et Al., “The Evolutionary Ecology Of Clonally Propagated Domesticated Plants,” New Phytologist 186, No. 2 (April 1, 2010): 318–32
3. Mohan P. A. Marimuthu Et Al., “Synthetic Clonal Reproduction Through Seeds,” Science 331, No. 6019 (February 18, 2011): 876–876
4. Rachel S. Meyer, Ashley E. Duval, And Helen R. Jensen, “Patterns And Processes In Crop Domestication: An Historical Review And Quantitative Analysis Of 203 Global Food Crops,” New Phytologist 196, No. 1 (October 1, 2012): 29–48
5. Rachel S. Meyer And Michael D. Purugganan, “Evolution Of Crop Species: Genetics Of Domestication And Diversification,” Nature Reviews Genetics 14 (November 18, 2013): 840.
6. Trevor A. Thorpe, “History Of Plant Tissue Culture,” Molecular Biotechnology 37, No. 2 (October 2007): 169–80