Abstract
The development progression of medical cannabis plants includes a vegetative growth phase under long photoperiod, followed by a reproductive phase under short photoperiod. Establishment of plant architecture at the vegetative phase affects its reproduction potential under short photoperiod. Nitrogen (N) is a main component of many metabolites that are involved in central processes in plants, and is therefore a major factor governing plant development and structure. We lack information about the influence of N nutrition on medical cannabis functional-physiology and development, and plant N requirements are yet unknown. The present study therefore investigated the developmental, physiological, and chemical responses of medical cannabis plants to N supply (30, 80, 160, 240, and 320 mgL−1 N) under long photoperiod. The plants were cultivated in an environmentally controlled growing room, in pots filled with soilless media. We report that the morpho-physiological function under long photoperiod in medical cannabis is optimal at 160 mgL−1 N supply, and significantly lower under 30 mgL−1 N, with visual deficiency symptoms, and 75 and 25% reduction in plant biomass and photosynthesis rate, respectively. Nitrogen use efficiency (NUE) decreased with increasing N supply, while osmotic potential, water use efficiency, photosynthetic pigments, and total N and N-NO3 concentrations in plant tissues increased with N supply. The plant ionome was considerably affected by N supply. Concentrations of K, P, Ca, Mg, and Fe in the plant were highest under the optimal N level of 160 mgL−1 N, with differences between organs in the extent of nutrient accumulation. The majority of the nutrients tested, including P, Zn, Mn, Fe, and Cu, tended to accumulate in the roots > leaves > stem, while K and Na tended to accumulate in the stem > leaves > roots, and total N, Ca, and Mg accumulated in leaves > roots > stem. Taken together, the results demonstrate that the optimal N level for plant development and function at the vegetative growth phase is 160 mgL−1 N. Growth retardation under lower N supply (30–80 mgL−1) results from restricted availability of photosynthetic pigments, carbon fixation, and impaired water relations. Excess uptake of N under supply higher than 160 mgL−1 N, promoted physiological and developmental restrictions, by ion-specific toxicity or indirect induced restrictions of carbon fixation and energy availability.
Highlights
The Cannabis sativa industry is rapidly evolving worldwide, with an escalating demand for agricultural products for the medicinal and recreational markets (UNODC, 2018; Chouvy, 2019)
In a study that focused on K nutrition, we reported that the response of medical cannabis to K at the vegetative growth phase varied between genotypes, revealing genetic differences within the C. sativa species to mineral nutrition (Saloner et al, 2019); 60 mgL−1 K was the lowest K concentration optimal for growth and metabolism; and 240 ppm was excessive and detrimental for development and function in one genotype, but stimulated rather than restricted development in the other genotype (Saloner et al, 2019)
Iron was supplied chelated with EDDHSA, Zn, Mn, and Cu were chelated with EDTA, and B and Mo were added with the fertilizers B-7000 and Bar-Koret (Israel chemicals, Tel-Aviv, Israel), respectively
Summary
The Cannabis sativa industry is rapidly evolving worldwide, with an escalating demand for agricultural products for the medicinal and recreational markets (UNODC, 2018; Chouvy, 2019). The development progression includes establishment of the vegetative plant body under long photoperiod, followed by a reproductive development stage under short photoperiod. During growth under long photoperiod, the main stem of the cannabis plants branches monopodially, producing alternate lateral branches. Following a transition to short photoperiod, the development of the shoot changes, and the apical buds of the main stem and of primary branches, as well as lateral buds, develop inflorescences that are the basis for commercial yield in drug-type cannabis. Plant architecture at the end of the long photoperiod profoundly affects its reproduction potential and yield capacity under short photoperiod. Cannabis is propagated by rooted cuttings (Cervantes, 2006; Caplan, 2018) and many nurseries are focusing nowadays on growth under long photoperiod, in an attempt to produce high-standard plants
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