Genetic Advances in Cannabis sativa L.: A Review of Recent Progress and Future Directions
Abstract
1. Introduction
2. Genome Architecture and Evolution of Cannabis sativa
3. Reference Genomes, Assemblies, and Pangenomics
Plastid Genome Diversity in Cannabis sativa
4. Sex Determination and Reproductive Biology
5. Genetics of Cannabinoid Biosynthesis
6. Genetic Basis of Fiber Quality and Quantity in Cannabis sativa
7. Genetic Basis of Seed Quality, Oil Composition, and Yield in Cannabis sativa
7.1. Seed Storage Proteins and Nutritional Quality
7.2. Oil Biosynthesis and Fatty Acid Composition
7.3. Seed Size, Yield and Genetic Control
7.4. Seed Retention and Seed Shattering
7.5. Genetic Variation and Breeding Potential
8. Genetic Basis of Disease Resistance in Industrial Hemp
9. Genetic Basis of Abiotic Stress Tolerance in Industrial Hemp
10. Functional Genomics and Genome Editing
10.1. The Functional Validation Gap
10.2. Transient Manipulation Toolkits for Rapid Functional Screening
10.3. Stable Transformation and CRISPR-Based Genome Editing
10.4. Bottlenecks in Genome Editing and Functional Genomics
10.5. Future Directions in Cannabis Genome Engineering
11. Molecular Breeding and Genetic Improvement Strategies
12. Challenges in Industrial Hemp Genetic Research
13. Future Perspectives
14. Conclusions
Supplementary Materials
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Abbreviations
| CBD | Cannabidiol |
| CBDAS | Cannabidiolic Acid Synthase |
| CBDA | Cannabidiolic Acid |
| CBGA | Cannabigerolic Acid |
| GS | Genomic Selection |
| GWAS | Genome-Wide Association Study |
| LTR | Long Terminal Repeat |
| MAS | Marker-Assisted Selection |
| Mb | Megabase |
| QTL | Quantitative Trait Locus |
| SNP | Single Nucleotide Polymorphism |
| SSR | Simple Sequence Repeat |
| THC | Tetrahydrocannabinol |
| THCAS | Tetrahydrocannabinolic Acid Synthase |
| THCA | Tetrahydrocannabinolic Acid |
| TRV | Tobacco Rattle Virus |
| VIGS | Virus-Induced Gene Silencing |
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| Trait | Candidate Genes | Mechanistic Biological Function | Breeding Targets and Applications |
|---|---|---|---|
| Cannabinoid Biosynthesis | DXS, GPPS, OLS, CBDAS, THCAS, and NBCS [93,94] | CBGA biosynthesis and enzymatic conversion into major cannabinoids (THC, CBD, and CBC). | Development of compliant low-THC cultivars and high-yield cannabinoid medicinal cultivars. |
| Seed Protein Quality | CsEde1 (A–D) and CsEde2 (A–C) [95,96] | Edestin storage protein synthesis and regulation of seed amino acid composition. | Improvement of protein quality, digestibility, and functional food applications. |
| Seed Oil Profiles | FAD2, FAD3, KCS, and SAD [19,97] | Fatty acid desaturation and elongation controlling PUFA composition and oil quality. | Optimization of nutritional oil profiles and enhanced oxidative stability. |
| Secondary Cell Wall Deposition and Tensile Strength | CesA4, CesA7, CesA8, CsCESA/CSL gene families, and IRX [98] | Cellulose and hemicellulose biosynthesis governing fiber strength, flexibility, and cell wall architecture. | Improvement of fiber yield, tensile strength, and textile processing quality. |
| Fiber Quality and Lignification | C4H, CCR, and CAD [99] | Lignin biosynthesis and deposition within secondary cell walls. | Reduction in lignin content and improved fiber-processing efficiency. |
| Flowering Time | FT, CO, and FLD [75] | Photoperiod-mediated regulation of floral transition and reproductive development. | Adaptation to diverse environments and development of regionally optimized cultivars. |
| Stress Tolerance | DREB, NAC, WRKY, and MYB [100,101,102] | Regulation of drought, salinity, and heat stress responses through transcriptional and cellular defense pathways. | Development of climate-resilient cultivars with stable productivity under abiotic stress. |
| Defense Traits | NBS-LRR, WRKY, and PR genes [103] | Pathogen recognition and activation of immune signaling pathways. | Enhancement of resistance to fungal and bacterial diseases and reduction in crop losses. |
| Method | Application | Example of Cannabis-Specific Target | Advantages | Limitations |
|---|---|---|---|---|
| QTL Mapping | Population-based; links traits to chromosomes. | Plant height, biomass, flowering time, CBD/THC variation [119] and seed size [124]. | Reliable for major-effect loci; foundational for markers. | Low resolution; slow due to outcrossing nature. |
| GWAS (Genome-Wide Association Study) | Population-based; maps traits across diverse germplasm. | Flowering time, architecture, cannabinoids, and stress tolerance loci (WRKY/NAC/MYB clusters) [100,147]. | Captures natural variation; high-resolution mapping. | Requires large populations; confounded by population structure. |
| SNP Genotyping and Marker Development | High-throughput screening; marker development (MAS). | Cultivar identification, sexing, and chemotype panels (1.5K HASCH, 20-SNP panels) [25,148]. | Early seedling sexing/chemotype prediction; cost-effectiveness. | Requires prior discovery; poor for complex polygenic traits. |
| RNA-seq (Transcriptomics) | Expression profiling across tissues or abiotic/biotic stressors. | Sex-linked/male-biased genes; transcripts for environmental sex plasticity [149,150]. | Global expression profiles; identifies candidate pathway genes. | Correlation only; highly tissue-, time-, and condition-specific. |
| Protoplast Transient Expression Assays | Transient; rapid subcellular and promoter analysis. | PEG-mediated system in isolated hemp cells for functional validation [151]. | Fast feedback (24–48 h); bypasses whole-plant regeneration. | Short expression window; highly sensitive to tissue age/genotype. |
| Virus-Induced Gene Silencing (VIGS) | Transient; rapid gene knockdown. | Silencing of PDS and ChlI for validation; cannabinoid/pigment pathways [152,153]. | Fast pipeline; eliminates tissue culture/regeneration needs. | Temporary effects; variable knockdown; uneven systemic spread. |
| Agrobacterium-Mediated Transformation | Stable; gene introduction and trait engineering. | Transgenic calli expressing AtNPR1 (disease) and bar (herbicide) genes [154]. | Heritable genome integration; permanent transgenic lines. | Very time-consuming; bottlenecked by poor regeneration. |
| CRISPR/Cas9 Genome Editing | Stable; precise gene knockout or knockin. | Knockout of CsPDS1 (albino phenotype proof of concept) [146]. | High precision; definitive causal validation of gene function. | Off-target risks; limited by recalcitrant tissue regeneration. |
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Daundasekara, K.C.; Thennakoon, K.P.; Wickramasinghe, J.S.; Woldesenbet, S.; Delhom, C.; Chandra, S.; Weerasooriya, A.D. Genetic Advances in Cannabis sativa L.: A Review of Recent Progress and Future Directions. Plants 2026, 15, 2088. https://doi.org/10.3390/plants15132088
Daundasekara KC, Thennakoon KP, Wickramasinghe JS, Woldesenbet S, Delhom C, Chandra S, Weerasooriya AD. Genetic Advances in Cannabis sativa L.: A Review of Recent Progress and Future Directions. Plants. 2026; 15(13):2088. https://doi.org/10.3390/plants15132088
Chicago/Turabian StyleDaundasekara, Kasuni C., Kalpani P. Thennakoon, Jivendra S. Wickramasinghe, Selamawit Woldesenbet, Christopher Delhom, Suman Chandra, and Aruna D. Weerasooriya. 2026. "Genetic Advances in Cannabis sativa L.: A Review of Recent Progress and Future Directions" Plants 15, no. 13: 2088. https://doi.org/10.3390/plants15132088
APA StyleDaundasekara, K. C., Thennakoon, K. P., Wickramasinghe, J. S., Woldesenbet, S., Delhom, C., Chandra, S., & Weerasooriya, A. D. (2026). Genetic Advances in Cannabis sativa L.: A Review of Recent Progress and Future Directions. Plants, 15(13), 2088. https://doi.org/10.3390/plants15132088

