Cannabis sativa is dioecious, meaning male and female blossoms generally appear on separate plants. It is the resinous oil produced by the unpollinated mature female flowers that holds the greatest scientific and monetary value today. Although they can be found throughout the plant, this oil contains the highest concentration of hundreds of different secondary metabolites each with a potential array of medicinal properties (Andre, Hausman, and Guerriero 2016) (Flores-Sanchez and Verpoorte 2008b). While other secondary metabolites, including flavonoids, stilbenoids, lignans, and alkaloids all have important qualities, terpenoids, comprised of terpenes and cannabinoids, are the most widely acknowledged for their medical potential.

Before the 2012 legalization of its recreational use in Colorado and Washington, there was a particular and narrow focus on the major cannabinoids, cannabidiol (CBD) and tetrahydrocannabinol (THC), driven by the interests of the therapeutic sector. Since legalization, there has been a dramatic surge in academic publications on cannabis, with end-user demand fueling a wider understanding of properties and factors beyond the plants’ psychoactive components such as flavor (de la Fuente et al. 2020). A more sophisticated understanding of cannabis has flourished as a result (Romero et al. 2020).

It has been well documented that the ratio of phytocannabinoids is important for the successful treatment of specific diseases (Lowe et al. 2018) (McPartland and Russo 2001) (Gordon 2020) (Nelson 2018) (Goldstein 2016) (Rosenburg et al. 2015). With increased research and understanding of the entourage effect, there is a greater demand from physicians for full plant extract alongside the isolate form of the compound (Romano and Hazekamp 2018) (Russo 2019) (Ben-Shabat et al. 1998) (Blasco-Benito, Seijo-Vila, et al. 2018). The ratios of phytocannabinoids and terpenes are now being further investigated to better understand their effects when used in conjunction with one another (de la Fuente et al. 2020) (Heblinski et al. 2020). In turn, this drives demand for strains to be bred to produce ratios of secondary metabolites that are disease-specific and will therefore require less processing, potentially reducing the cost of the end product (Thomas and Pollard 2016). Safeguarding patients is the top priority, but many factors must be considered when cultivating medicinal crops, with the consistency of production of both biomass and active ingredients of particular importance. In response to biotic and abiotic stress, plants produce phytoalexins, a large group of diverse secondary metabolites, which can cause a reduction in biomass. In this review, we will take a brief look at how stress to the plants affects the production of secondary metabolites such as phytocannabinoids, terpenes, and flavonoids.