Effect of micrografting technique on growth and cold resistance of tea (Camellia sinensis) plant
Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants. In our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyl...
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| Published in | BMC plant biology Vol. 25; no. 1; pp. 746 - 9 |
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| Main Authors | , , , , , , , , |
| Format | Journal Article |
| Language | English |
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England
BioMed Central Ltd
02.06.2025
BioMed Central BMC |
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| Abstract | Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants.
In our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyledons, epicotyl with cotyledons, tea varieties] and scion (red branch, green branch) grafting combinations were used to estimate the survival rate, plant growth, the compatibility behavior, and cold tolerance of grafted seedlings. Our results showed that the higher survival rate and shooting rate were observed in radicle (obtained from the germinated seed diameter ≥ 15 mm, D3) as the rootstock. Also, the same growth indicators were found in the green branch as scion and radicle as rootstock (GB\R) were higher than that of other grafting combinations. In addition, the grafted seedlings of LJ43 as rootstock had the best growth rate, and the vascular bundle bridge was completely established in SCZ as scion and LJ43 as rootstock (SCZ/LJ43) graft combination, accompanied with a higher survival rate, shoot rate and leaf number of new shoots and cold tolerance in field experiments.
Our findings provide a viable tea micrografting method, which has the potential to substitute traditional tea cuttings for tea seedling propagation and thus meet the requirements of tea cultivation. |
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| AbstractList | Background Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants. Results In our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyledons, epicotyl with cotyledons, tea varieties] and scion (red branch, green branch) grafting combinations were used to estimate the survival rate, plant growth, the compatibility behavior, and cold tolerance of grafted seedlings. Our results showed that the higher survival rate and shooting rate were observed in radicle (obtained from the germinated seed diameter [greater than or equal to] 15 mm, D3) as the rootstock. Also, the same growth indicators were found in the green branch as scion and radicle as rootstock (GB\R) were higher than that of other grafting combinations. In addition, the grafted seedlings of LJ43 as rootstock had the best growth rate, and the vascular bundle bridge was completely established in SCZ as scion and LJ43 as rootstock (SCZ/LJ43) graft combination, accompanied with a higher survival rate, shoot rate and leaf number of new shoots and cold tolerance in field experiments. Conclusion Our findings provide a viable tea micrografting method, which has the potential to substitute traditional tea cuttings for tea seedling propagation and thus meet the requirements of tea cultivation. Keywords: Camellia sinensis, Micrografting, Rootstock and scion selection, Cold tolerance Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants.BACKGROUNDMicrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants.In our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyledons, epicotyl with cotyledons, tea varieties] and scion (red branch, green branch) grafting combinations were used to estimate the survival rate, plant growth, the compatibility behavior, and cold tolerance of grafted seedlings. Our results showed that the higher survival rate and shooting rate were observed in radicle (obtained from the germinated seed diameter ≥ 15 mm, D3) as the rootstock. Also, the same growth indicators were found in the green branch as scion and radicle as rootstock (GB\R) were higher than that of other grafting combinations. In addition, the grafted seedlings of LJ43 as rootstock had the best growth rate, and the vascular bundle bridge was completely established in SCZ as scion and LJ43 as rootstock (SCZ/LJ43) graft combination, accompanied with a higher survival rate, shoot rate and leaf number of new shoots and cold tolerance in field experiments.RESULTSIn our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyledons, epicotyl with cotyledons, tea varieties] and scion (red branch, green branch) grafting combinations were used to estimate the survival rate, plant growth, the compatibility behavior, and cold tolerance of grafted seedlings. Our results showed that the higher survival rate and shooting rate were observed in radicle (obtained from the germinated seed diameter ≥ 15 mm, D3) as the rootstock. Also, the same growth indicators were found in the green branch as scion and radicle as rootstock (GB\R) were higher than that of other grafting combinations. In addition, the grafted seedlings of LJ43 as rootstock had the best growth rate, and the vascular bundle bridge was completely established in SCZ as scion and LJ43 as rootstock (SCZ/LJ43) graft combination, accompanied with a higher survival rate, shoot rate and leaf number of new shoots and cold tolerance in field experiments.Our findings provide a viable tea micrografting method, which has the potential to substitute traditional tea cuttings for tea seedling propagation and thus meet the requirements of tea cultivation.CONCLUSIONOur findings provide a viable tea micrografting method, which has the potential to substitute traditional tea cuttings for tea seedling propagation and thus meet the requirements of tea cultivation. Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants. In our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyledons, epicotyl with cotyledons, tea varieties] and scion (red branch, green branch) grafting combinations were used to estimate the survival rate, plant growth, the compatibility behavior, and cold tolerance of grafted seedlings. Our results showed that the higher survival rate and shooting rate were observed in radicle (obtained from the germinated seed diameter ≥ 15 mm, D3) as the rootstock. Also, the same growth indicators were found in the green branch as scion and radicle as rootstock (GB\R) were higher than that of other grafting combinations. In addition, the grafted seedlings of LJ43 as rootstock had the best growth rate, and the vascular bundle bridge was completely established in SCZ as scion and LJ43 as rootstock (SCZ/LJ43) graft combination, accompanied with a higher survival rate, shoot rate and leaf number of new shoots and cold tolerance in field experiments. Our findings provide a viable tea micrografting method, which has the potential to substitute traditional tea cuttings for tea seedling propagation and thus meet the requirements of tea cultivation. Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants. In our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyledons, epicotyl with cotyledons, tea varieties] and scion (red branch, green branch) grafting combinations were used to estimate the survival rate, plant growth, the compatibility behavior, and cold tolerance of grafted seedlings. Our results showed that the higher survival rate and shooting rate were observed in radicle (obtained from the germinated seed diameter [greater than or equal to] 15 mm, D3) as the rootstock. Also, the same growth indicators were found in the green branch as scion and radicle as rootstock (GB\R) were higher than that of other grafting combinations. In addition, the grafted seedlings of LJ43 as rootstock had the best growth rate, and the vascular bundle bridge was completely established in SCZ as scion and LJ43 as rootstock (SCZ/LJ43) graft combination, accompanied with a higher survival rate, shoot rate and leaf number of new shoots and cold tolerance in field experiments. Our findings provide a viable tea micrografting method, which has the potential to substitute traditional tea cuttings for tea seedling propagation and thus meet the requirements of tea cultivation. BackgroundMicrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants.ResultsIn our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyledons, epicotyl with cotyledons, tea varieties] and scion (red branch, green branch) grafting combinations were used to estimate the survival rate, plant growth, the compatibility behavior, and cold tolerance of grafted seedlings. Our results showed that the higher survival rate and shooting rate were observed in radicle (obtained from the germinated seed diameter ≥ 15 mm, D3) as the rootstock. Also, the same growth indicators were found in the green branch as scion and radicle as rootstock (GB\R) were higher than that of other grafting combinations. In addition, the grafted seedlings of LJ43 as rootstock had the best growth rate, and the vascular bundle bridge was completely established in SCZ as scion and LJ43 as rootstock (SCZ/LJ43) graft combination, accompanied with a higher survival rate, shoot rate and leaf number of new shoots and cold tolerance in field experiments.ConclusionOur findings provide a viable tea micrografting method, which has the potential to substitute traditional tea cuttings for tea seedling propagation and thus meet the requirements of tea cultivation. Abstract Background Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not been fully explored in tea plants. Results In our study, different rootstocks [radicle (obtained from the germination in seed), epicotyl without cotyledons, epicotyl with cotyledons, tea varieties] and scion (red branch, green branch) grafting combinations were used to estimate the survival rate, plant growth, the compatibility behavior, and cold tolerance of grafted seedlings. Our results showed that the higher survival rate and shooting rate were observed in radicle (obtained from the germinated seed diameter ≥ 15 mm, D3) as the rootstock. Also, the same growth indicators were found in the green branch as scion and radicle as rootstock (GB\R) were higher than that of other grafting combinations. In addition, the grafted seedlings of LJ43 as rootstock had the best growth rate, and the vascular bundle bridge was completely established in SCZ as scion and LJ43 as rootstock (SCZ/LJ43) graft combination, accompanied with a higher survival rate, shoot rate and leaf number of new shoots and cold tolerance in field experiments. Conclusion Our findings provide a viable tea micrografting method, which has the potential to substitute traditional tea cuttings for tea seedling propagation and thus meet the requirements of tea cultivation. |
| ArticleNumber | 746 |
| Audience | Academic |
| Author | Cheng, Yaohua Yang, Qi Long, Linxin Li, Yeyun Lin, Mengling Wang, Hongying Zhou, Ziwen Zhang, Xianchen Ban, Qiuyan |
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| Keywords | Camellia sinensis Micrografting Rootstock and scion selection Cold tolerance |
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| Snippet | Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique has not... Background Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this... BackgroundMicrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this technique... Abstract Background Micrografting technology has gained popularity in model plants, with the advantages of a wide grafting range and small space. However, this... |
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| SubjectTerms | Abiotic stress Botanical research Camellia sinensis Camellia sinensis - growth & development Camellia sinensis - physiology Cold Cold resistance Cold Temperature Cold tolerance Cold weather Cotyledons Environmental aspects Field tests Germination Grafting Growth Hardiness Immunological tolerance Leaves Low temperature resistance Methods Micrografting Photosynthesis Physiological aspects Plant growth Plant Roots - growth & development Plants Propagation Rootstock and scion selection Rootstocks Seedlings Seedlings - growth & development Seedlings - physiology Seeds Survival Tea Tea (Plant) |
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| Title | Effect of micrografting technique on growth and cold resistance of tea (Camellia sinensis) plant |
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