Genetic diversity, population structure, and cannabinoid variation in feral Cannabis sativa germplasm from the United States

Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th through 20th centuries have escaped production and established feralized populations across the United States. To maximize the potential of...

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Published in	Scientific reports Vol. 15; no. 1; pp. 20423 - 13
Main Authors	Aina, Ademola, Wenger, Jonathan P., Stanton, Eliot, Majumdar, Chandrani Gon, ElSohly, Mahmoud, Weiblen, George D., Ellison, Shelby
Format	Journal Article
Language	English
Published	London Nature Publishing Group UK 01.07.2025 Nature Portfolio
Subjects	631/158/670 631/208/182 631/208/2491 631/208/711 Cannabinoids Cannabinoids - analysis Cannabinoids - genetics Cannabinoids - metabolism Cannabis Cannabis - chemistry Cannabis - classification Cannabis - genetics Conservation Feral Gas Chromatography-Mass Spectrometry Genetic diversity Genetic Variation Genotype Germplasm Humanities and Social Sciences multidisciplinary Phylogeny Principal Component Analysis Science Science (multidisciplinary) Seeds - genetics United States United States Cannabinoids Germplasm Genetic diversity Feral Conservation Cannabis
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ISSN	2045-2322 2045-2322
DOI	10.1038/s41598-025-07912-8

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Abstract	Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th through 20th centuries have escaped production and established feralized populations across the United States. To maximize the potential of feral Cannabis germplasm, determining the genetic structure and cannabinoid profile is crucial for selection and breeding of new compliant regionally adapted hemp cultivars. To resolve this, a collection of feral Cannabis , comprising 760 plants across twelve US states were sequenced using Genotyping-by-Sequencings (GBS), genotyped at the cannabinoid synthase ( CBDAS) gene, and subject to gas chromatography-mass spectrometry (GC-MS) to assess cannabinoid profiles. Clustering analyses by ADMIXTURE and Principal Component Analysis (PCA) stratified the germplasm into five clusters (Mississippi-River, West North Central-b, West North Central-a, New York, and Indiana). The cannabinoid genotyping assay resolved the feral collections into Type I - B2/B2 (6%), Type II - B2/B1 (15%), and Type III - B1/B1 (78%). Total cannabinoid content ranged from 0.21 to 4.73%. The assessment of genetic diversity, population structure, and cannabinoid profile of the US feral Cannabis collection provides critical information and germplasm resources to develop new and improve existing hemp cultivars.
AbstractList	Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th through 20th centuries have escaped production and established feralized populations across the United States. To maximize the potential of feral Cannabis germplasm, determining the genetic structure and cannabinoid profile is crucial for selection and breeding of new compliant regionally adapted hemp cultivars. To resolve this, a collection of feral Cannabis , comprising 760 plants across twelve US states were sequenced using Genotyping-by-Sequencings (GBS), genotyped at the cannabinoid synthase ( CBDAS) gene, and subject to gas chromatography-mass spectrometry (GC-MS) to assess cannabinoid profiles. Clustering analyses by ADMIXTURE and Principal Component Analysis (PCA) stratified the germplasm into five clusters (Mississippi-River, West North Central-b, West North Central-a, New York, and Indiana). The cannabinoid genotyping assay resolved the feral collections into Type I - B2/B2 (6%), Type II - B2/B1 (15%), and Type III - B1/B1 (78%). Total cannabinoid content ranged from 0.21 to 4.73%. The assessment of genetic diversity, population structure, and cannabinoid profile of the US feral Cannabis collection provides critical information and germplasm resources to develop new and improve existing hemp cultivars. Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th through 20th centuries have escaped production and established feralized populations across the United States. To maximize the potential of feral Cannabis germplasm, determining the genetic structure and cannabinoid profile is crucial for selection and breeding of new compliant regionally adapted hemp cultivars. To resolve this, a collection of feral Cannabis, comprising 760 plants across twelve US states were sequenced using Genotyping-by-Sequencings (GBS), genotyped at the cannabinoid synthase (CBDAS) gene, and subject to gas chromatography-mass spectrometry (GC-MS) to assess cannabinoid profiles. Clustering analyses by ADMIXTURE and Principal Component Analysis (PCA) stratified the germplasm into five clusters (Mississippi-River, West North Central-b, West North Central-a, New York, and Indiana). The cannabinoid genotyping assay resolved the feral collections into Type I - B2/B2 (6%), Type II - B2/B1 (15%), and Type III - B1/B1 (78%). Total cannabinoid content ranged from 0.21 to 4.73%. The assessment of genetic diversity, population structure, and cannabinoid profile of the US feral Cannabis collection provides critical information and germplasm resources to develop new and improve existing hemp cultivars.Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th through 20th centuries have escaped production and established feralized populations across the United States. To maximize the potential of feral Cannabis germplasm, determining the genetic structure and cannabinoid profile is crucial for selection and breeding of new compliant regionally adapted hemp cultivars. To resolve this, a collection of feral Cannabis, comprising 760 plants across twelve US states were sequenced using Genotyping-by-Sequencings (GBS), genotyped at the cannabinoid synthase (CBDAS) gene, and subject to gas chromatography-mass spectrometry (GC-MS) to assess cannabinoid profiles. Clustering analyses by ADMIXTURE and Principal Component Analysis (PCA) stratified the germplasm into five clusters (Mississippi-River, West North Central-b, West North Central-a, New York, and Indiana). The cannabinoid genotyping assay resolved the feral collections into Type I - B2/B2 (6%), Type II - B2/B1 (15%), and Type III - B1/B1 (78%). Total cannabinoid content ranged from 0.21 to 4.73%. The assessment of genetic diversity, population structure, and cannabinoid profile of the US feral Cannabis collection provides critical information and germplasm resources to develop new and improve existing hemp cultivars. Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th through 20th centuries have escaped production and established feralized populations across the United States. To maximize the potential of feral Cannabis germplasm, determining the genetic structure and cannabinoid profile is crucial for selection and breeding of new compliant regionally adapted hemp cultivars. To resolve this, a collection of feral Cannabis, comprising 760 plants across twelve US states were sequenced using Genotyping-by-Sequencings (GBS), genotyped at the cannabinoid synthase (CBDAS) gene, and subject to gas chromatography-mass spectrometry (GC-MS) to assess cannabinoid profiles. Clustering analyses by ADMIXTURE and Principal Component Analysis (PCA) stratified the germplasm into five clusters (Mississippi-River, West North Central-b, West North Central-a, New York, and Indiana). The cannabinoid genotyping assay resolved the feral collections into Type I - B2/B2 (6%), Type II - B2/B1 (15%), and Type III - B1/B1 (78%). Total cannabinoid content ranged from 0.21 to 4.73%. The assessment of genetic diversity, population structure, and cannabinoid profile of the US feral Cannabis collection provides critical information and germplasm resources to develop new and improve existing hemp cultivars. Abstract Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th through 20th centuries have escaped production and established feralized populations across the United States. To maximize the potential of feral Cannabis germplasm, determining the genetic structure and cannabinoid profile is crucial for selection and breeding of new compliant regionally adapted hemp cultivars. To resolve this, a collection of feral Cannabis, comprising 760 plants across twelve US states were sequenced using Genotyping-by-Sequencings (GBS), genotyped at the cannabinoid synthase (CBDAS) gene, and subject to gas chromatography-mass spectrometry (GC-MS) to assess cannabinoid profiles. Clustering analyses by ADMIXTURE and Principal Component Analysis (PCA) stratified the germplasm into five clusters (Mississippi-River, West North Central-b, West North Central-a, New York, and Indiana). The cannabinoid genotyping assay resolved the feral collections into Type I - B2/B2 (6%), Type II - B2/B1 (15%), and Type III - B1/B1 (78%). Total cannabinoid content ranged from 0.21 to 4.73%. The assessment of genetic diversity, population structure, and cannabinoid profile of the US feral Cannabis collection provides critical information and germplasm resources to develop new and improve existing hemp cultivars.
ArticleNumber	20423
Author	Stanton, Eliot Majumdar, Chandrani Gon Aina, Ademola ElSohly, Mahmoud Wenger, Jonathan P. Weiblen, George D. Ellison, Shelby
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Keywords	Cannabinoids Germplasm Genetic diversity Feral Conservation Cannabis
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Snippet	Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th... Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during the 18th... Abstract Cannabis sativa is one of the earliest plants to be domesticated for fiber, food and medicine. Seed from Cannabis grown for industrial purposes during...
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SubjectTerms	631/158/670 631/208/182 631/208/2491 631/208/711 Cannabinoids Cannabinoids - analysis Cannabinoids - genetics Cannabinoids - metabolism Cannabis Cannabis - chemistry Cannabis - classification Cannabis - genetics Conservation Feral Gas Chromatography-Mass Spectrometry Genetic diversity Genetic Variation Genotype Germplasm Humanities and Social Sciences multidisciplinary Phylogeny Principal Component Analysis Science Science (multidisciplinary) Seeds - genetics United States
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Title	Genetic diversity, population structure, and cannabinoid variation in feral Cannabis sativa germplasm from the United States
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