Season‐long characterization of high‐cannabinoid hemp (Cannabis sativa L.) reveals variation in cannabinoid accumulation, flowering time, and disease resistance
George M. Stack,
Jacob A. Toth,
Craig H. Carlson,
Ali R. Cala,
Mariana I. Marrero‐González,
Rebecca L. Wilk,
Deanna R. Gentner,
Jamie L. Crawford,
Glenn Philippe,
Jocelyn K. C. Rose,
Donald R. Viands,
Christine D. Smart,
Lawrence B. Smart
Affiliations
George M. Stack
Horticulture Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Jacob A. Toth
Horticulture Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Craig H. Carlson
Horticulture Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Ali R. Cala
Plant Pathology & Plant Microbe Biology Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Mariana I. Marrero‐González
Horticulture Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Rebecca L. Wilk
Horticulture Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Deanna R. Gentner
Horticulture Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Jamie L. Crawford
Plant Breeding and Genetics Section School of Integrative Plant Science Cornell University Ithaca NY USA
Glenn Philippe
Plant Biology Section School of Integrative Plant Science Cornell University Ithaca NY USA
Jocelyn K. C. Rose
Plant Biology Section School of Integrative Plant Science Cornell University Ithaca NY USA
Donald R. Viands
Plant Breeding and Genetics Section School of Integrative Plant Science Cornell University Ithaca NY USA
Christine D. Smart
Plant Pathology & Plant Microbe Biology Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Lawrence B. Smart
Horticulture Section School of Integrative Plant Science Cornell UniversityCornell AgriTech Geneva NY USA
Abstract Given the dramatic rise in high‐cannabinoid hemp (Cannabis sativa L.) production in the last decade, there is an increasingly urgent need to characterize available germplasm and develop knowledge to accelerate the breeding of uniform and stable cultivars. Despite persistent cultivation of hemp cultivars for grain and or fiber around the world, the diversity and genetic underpinning of key traits for breeding and cultivation are poorly understood. For 30 high‐cannabidiol hemp cultivars replicated on two field sites, we sought to evaluate yield, agronomic performance, and disease resistance while also conducting a detailed study of cannabinoid accumulation over the course of floral maturation. We observed significant variation in both within and among cultivars. During the growing season, the plants clustered into five groups by growth rate and varied in flowering time from photoperiod insensitive to photoperiod sensitive with very short critical photoperiods. Based on the observed ratio of total potential cannabidiol (CBD) to total potential tetrahydrocannabinol (THC), there was segregation for cannabinoid chemotype in some seeded cultivar populations. Analysis of cannabichromene (CBC) production revealed that some cultivars had a discretely lower CBD:CBC ratio than the others. There was a continuous range of powdery mildew severity by cultivar, with one that had little to no observed powdery mildew suggesting it might have genetic resistance. Biomass production at harvest was strongly influenced by location and cultivar, and there was variation by cultivar in the relative cannabinoid production in shoot tip samples compared with whole plant samples. While our results provide preliminary guidance regarding relative performance of current cultivars, our analyses indicate a need for additional hemp breeding to provide stable, uniform, and legally compliant cultivars with improved disease resistance and flowering times optimized for the latitudes of different growing locations.
