Wild again: recovery of a beneficial Cannabis seed endophyte from low domestication genotypes
Wild again: recovery of a beneficial Cannabis seed endophyte from low domestication genotypes
Background: beyond carrying the plant embryo, seeds harbour intricate microbial communities whose transmission across successive plant generations can significantly influence the ecological and evolutionary dynamics of plant–microbe symbioses. The process of plant domestication has potential repercussions in genes involved in plant-microbiome interactions. However, the extent to which breeding can impact the seed microbiome is sparsely explored. Cannabis is a high-value crop but sparsely subjected to agricultural innovations established in other crop species during the last century. Here, we conduct a large-scale analysis of the bacterial seed microbiome of Cannabis across different domestication grades and investigate the potential of seed-associated endophytes as plant growth-promoting agents under both controlled and field conditions.
Results: analysis of Cannabis seed endophyte composition and diversity across 46 plant genotypes revealed 813 different bacterial genera with a predominance of Gammaproteobacteria, Bacilli, Actinobacteria and Alphaproteobacteria but a genotype-specific microbiome. The assessment of domestication and breeding on microbial assembly revealed a higher bacterial diversity in low domestication genotypes (Shannon index, H′: 1.21 vs. 1.05) and a higher homogeneity in bacterial composition caused by line development. Further, a seed bacterial isolate (Bacillus frigoritolerans C1141) associated with low domestication genotypes, and with genes associated with bio-fertilization, bioremediation and phytohormone production, increased plant growth by 42.3% at the time of harvest, under field conditions.
Conclusion: this study addresses critical knowledge gaps related to the assembly of the Cannabis seed-endophytic microbiome. It reveals that Cannabis breeding is linked to alterations of seed microbial communities, which potentially led to the loss of bacteria with functional significance. These results highlight the importance of preserving seed microbiomes in plant breeding to support sustainable plant health and growth enhancement in Cannabis.
Cannabis/microbiology, Seeds/microbiology, Endophytes/genetics, Genotype, Bacteria/classification, Domestication, Microbiota/genetics, Symbiosis
Lobato, Carolina
8f50850f-98e0-47de-89a7-8f294e8c3ea1
de Freitas, João Machado
0c564c4c-8bbe-4dac-a920-4481550edb9a
Habich, Daniel
b0c684a9-ee99-496e-96f3-9a9bb0b6d283
Kögl, Isabella
6c36578a-e357-44d8-a104-d316d84898ef
Berg, Gabriele
5bc6c28c-525d-4f45-b167-5af82c888c6d
Cernava, Tomislav
a13d65aa-2529-479a-ba90-69ebbc4ba07f
15 November 2024
Lobato, Carolina
8f50850f-98e0-47de-89a7-8f294e8c3ea1
de Freitas, João Machado
0c564c4c-8bbe-4dac-a920-4481550edb9a
Habich, Daniel
b0c684a9-ee99-496e-96f3-9a9bb0b6d283
Kögl, Isabella
6c36578a-e357-44d8-a104-d316d84898ef
Berg, Gabriele
5bc6c28c-525d-4f45-b167-5af82c888c6d
Cernava, Tomislav
a13d65aa-2529-479a-ba90-69ebbc4ba07f
Lobato, Carolina, de Freitas, João Machado, Habich, Daniel, Kögl, Isabella, Berg, Gabriele and Cernava, Tomislav
(2024)
Wild again: recovery of a beneficial Cannabis seed endophyte from low domestication genotypes.
Microbiome, 12 (1), [239].
(doi:10.1186/s40168-024-01951-5).
Abstract
Background: beyond carrying the plant embryo, seeds harbour intricate microbial communities whose transmission across successive plant generations can significantly influence the ecological and evolutionary dynamics of plant–microbe symbioses. The process of plant domestication has potential repercussions in genes involved in plant-microbiome interactions. However, the extent to which breeding can impact the seed microbiome is sparsely explored. Cannabis is a high-value crop but sparsely subjected to agricultural innovations established in other crop species during the last century. Here, we conduct a large-scale analysis of the bacterial seed microbiome of Cannabis across different domestication grades and investigate the potential of seed-associated endophytes as plant growth-promoting agents under both controlled and field conditions.
Results: analysis of Cannabis seed endophyte composition and diversity across 46 plant genotypes revealed 813 different bacterial genera with a predominance of Gammaproteobacteria, Bacilli, Actinobacteria and Alphaproteobacteria but a genotype-specific microbiome. The assessment of domestication and breeding on microbial assembly revealed a higher bacterial diversity in low domestication genotypes (Shannon index, H′: 1.21 vs. 1.05) and a higher homogeneity in bacterial composition caused by line development. Further, a seed bacterial isolate (Bacillus frigoritolerans C1141) associated with low domestication genotypes, and with genes associated with bio-fertilization, bioremediation and phytohormone production, increased plant growth by 42.3% at the time of harvest, under field conditions.
Conclusion: this study addresses critical knowledge gaps related to the assembly of the Cannabis seed-endophytic microbiome. It reveals that Cannabis breeding is linked to alterations of seed microbial communities, which potentially led to the loss of bacteria with functional significance. These results highlight the importance of preserving seed microbiomes in plant breeding to support sustainable plant health and growth enhancement in Cannabis.
Text
s40168-024-01951-5
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More information
Accepted/In Press date: 15 October 2024
Published date: 15 November 2024
Keywords:
Cannabis/microbiology, Seeds/microbiology, Endophytes/genetics, Genotype, Bacteria/classification, Domestication, Microbiota/genetics, Symbiosis
Identifiers
Local EPrints ID: 502911
URI: http://eprints.soton.ac.uk/id/eprint/502911
ISSN: 2049-2618
PURE UUID: e54af85a-8247-4940-aa25-7f141223d4da
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Date deposited: 11 Jul 2025 17:05
Last modified: 22 Aug 2025 02:38
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Contributors
Author:
Carolina Lobato
Author:
João Machado de Freitas
Author:
Daniel Habich
Author:
Isabella Kögl
Author:
Gabriele Berg
Author:
Tomislav Cernava
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