Objective To assess the feasibility of the rbcL sequence of chloroplast DNA as a genetic marker to identify Cannabis sativa L. Methods The rbcL sequences in 62 Cannabis sativa L. samples, 10 Humulus lupulus samples and 10 Humulus scandens DNA samples were detected, and 96 rbcL sequences of the Cannabaceae family were downloaded from Genbank. Sequence alignment was performed by MEGA X software, the intraspecific and interspecific Kimura-2-Parameter （K2P） genetic distances were calculated, and the system clustering tree was constructed. Results The rbcL sequence length acquired by sequencing of Cannabis sativa L. and Humulus scandens were 617 bp and 649 bp, respectively, and two haplotypes of Cannabis sativa L. were observed in the samples. The BLAST similarity search results showed that the highest similarity between the sequences acquired by sequencing and Cannabis sativa L. rbcL sequences available from Genbank was 100%. The genetic distance analysis showed that the maximum intraspecific genetic distance （0.004 9） of Cannabis sativa L. was less than the minimum interspecific genetic distance （0.012 9）. The results of median-joining network and system clustering tree analysis showed that Cannabis sativa L. and other members of the Cannabaceae family were located in different branches. Conclusion The rbcL sequence could be used as a DNA barcode for identifying Cannabis sativa L., and combined with comparative analysis of the rbcL sequence and system cluster analysis could be a reliable and effective detection method for Cannabis sativa L. identification in forensic investigation.
Cannabis/genetics* ; Genetic Markers ; Sequence Analysis, DNA

Cannabis sativa,with a long history of cultivation, is a traditional industrial crop widely used for food, textiles, and me-dicine. This study discussed industrial C. sativa and medicinal C. sativa. According to the characteristics of management policies of C. sativa in different periods, we divided the development stages of C. sativa into three stages and analyzed the changes in breeding and cultivation goals under the influence of policies. Meanwhile, a comprehensive analysis was carried out based on the breeding conditions of industrial C. sativa in China. Because of the vast territory of China, the differences in agricultural planting environment, economic development, and social development in the southern and northern areas result in different used parts of C. sativa. To be speci-fic, flowers and leaves are used in Yunnan, fiber in Heilongjiang, and seeds in Shanxi. The breeding of C. sativa varieties highlights fiber, seeds, or both of them. As the value of cannabidiol is explored, medicinal C. sativa has been approved in recent years. Based on the cultivation characteristics and value of industrial C. sativa, it is proposed that industrial C. sativa has a broad application prospect as an important industrial crop, and the existing products contain almost no tetrahydrocannabinol. The cultivation of C. sativa should be rationally guided to promote the development of the C. sativa industry. Moreover, it is recommended to actively apply advanced breeding techniques such as molecular breeding to overcome the problems of the uncertainty of the existing induced breeding and the excessively long hybrid breeding cycle, and develop high value-added applications such as medicinal products of C. sativa to enhance the exploitation of the economic value of C. sativa.
Cannabidiol/analysis* ; Cannabis/genetics* ; China ; Dronabinol ; Plant Breeding

OBJECTIVE: To screen the AFLP primers with good diversity to distinguish various species of Cannabis. METHODS: The AFLP was used to analyze the genetic diversity of 12 species of Cannabis using 55 primer combinations. RESULTS: A total of 285 AFLP bands were obtained using five primer combinations with better diversity, among which 99 bands were polymorphic and 10 bands were special, with 47-76 bands amplified in each pair of primers. CONCLUSION AFLP may has good resolution in the diversity study of Cannabis. It may provide an essential basis for further study of the genetic diversity of Cannabis.
Amplified Fragment Length Polymorphism Analysis/methods* ; Cannabis/genetics* ; DNA, Plant/genetics* ; Forensic Genetics ; Genetic Variation ; Polymorphism, Genetic