Insights into plant regeneration: cellular pathways and DNA methylation dynamics

Lee, Seunga; Park, Young Seo; Rhee, Ji Hoon; Chu, Hyojeong; Frost, Jennifer M.; Choi, Yeonhee

doi:10.1007/s00299-024-03216-9

Plant Cell Rep

2024

DOI: 10.1007/s00299-024-03216-9

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Insights into plant regeneration: cellular pathways and DNA methylation dynamics

Seunga Lee,

Young Seo Park,

Ji Hoon Rhee

et al.

Abstract: Plants, known for their immobility, employ various mechanisms against stress and damage. A prominent feature is the formation of callus tissue—a cellular growth phenomenon that remains insufficiently explored, despite its distinctive cellular plasticity compared to vertebrates. Callus formation involves dedifferentiated cells, with a subset attaining pluripotency. Calluses exhibit an extraordinary capacity to reinitiate cellular division and undergo structural transformations, generating de novo shoots and roo… Show more

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2024

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Cited by 5 publications

References 98 publications

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Evaluation of the genetic uniformity, yield potential, and chilling-stress responses of tuber progeny of aneuploid caladium somaclonal variants in the second vegetative cycle

Xiang,

Zeng,

Wang

et al. 2024

Plant Cell Tiss Organ Cult

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Evaluation of the genetic uniformity, yield potential, and chilling-stress responses of tuber progeny of aneuploid caladium somaclonal variants in the second vegetative cycle

Xiang,

Zeng,

Wang

et al. 2024

Plant Cell Tiss Organ Cult

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DNA Hypomethylation Activates the RpMYB2‐Centred Gene Network to Enhance Regeneration of Adventitious Roots

Hussain,

Li,

Liu

et al. 2024

Plant Cell & Environment

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Plants, being immobile, are exposed to environmental adversities such as wind, snow and animals that damage their structure, making regeneration essential for their survival. The adventitious roots (ARs) primarily emerge from a detached explant to uptake nutrients; therefore, the molecular network involved in their regeneration needs to be explored. DNA methylation, a key epigenetic mark, influences molecular pathways, and recent studies suggested its role in regeneration. In our research, the application of 5‐azacytidine (5‐azaC), an inhibitor of DNA methylation, caused the earlier initiation and development of root primordia and consequently enhanced the AR regeneration rate in Robinia psuedoacacia L (black locust). The whole‐genome bisulfite sequencing (WGBS) revealed a decrease in global methylation and an increase in hypomethylated cytosine sites and regions across all contexts including CHH, CHG and mergedCG caused transcriptional variations in 5‐azaC‐treated sample. The yeast two‐hybrid (Y2H) assay revealed a RpMYB2‐centred network of transcriptionally activated transcription factors (TFs) including RpWRKY23, RpGATA23, RpSPL16 and other genes like RpSDP, RpSS1, RpBEN1, RpGULL05 and RpCUV with nuclear localization suggesting their potential co‐localization. Additionally, yeast one‐hybrid (Y1H) assay showed the interaction of RpMYB2 interactors, RpGATA23 and RpWRKY23, with promoters of RpSK6 and RpCDC48, and luciferase reporting assay (LRA) validated their binding with RpSK6. Our results revealed that hypomethylation‐mediated transcriptomic modifications activated the RpMYB2‐centred gene network to enhance AR regeneration in black locust hypocotyl cuttings. These findings pave the way for genetic modification to improve plant regeneration ability and increase wood production while withstanding environmental damage.

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An Efficient System for Agrobacterium-Mediated Transformation of Elite Cultivars in Brassica juncea

Fu,

Zhang,

et al. 2024

Horticulturae

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Efficient genetic transformation approaches play pivotal roles in both gene function research and crop breeding. However, stable transformation in mustard, particularly for different horticultural types, has not been systematically studied and well-established so far. In this study, we optimized the key factors in the genetic transformation of mustard, including the optical density value of Agrobacterium suspension, the age of explants, and the combination of phytohormones at different concentrations. As a result, the optimal conditions for the genetic transformation of leaf and stem mustard included hypocotyl explants derived from 4-day-old seedlings, infection by 0.8 OD600nm Agrobacterium suspension, and then re-differentiation on a medium containing 4 mg/L trans-zeatin (tZ) and 0.1 mg/L indoleacetic acid (IAA) for leaf mustard, and for stem mustard, re-differentiation on a medium containing 2 mg/L tZ and 0.4 mg/L IAA, with positive rates of 4.74% and 5.26%, respectively. Those for root mustard were hypocotyl explants derived from 8-day-old seedlings, infection by 0.2 OD600nmAgrobacterium suspension, and a medium containing 2 mg/L tZ and 0.1 mg/L IAA, with a positive rate of 4.42%. Overall, this work provides an effective tool for both the theoretical study and genetic improvement of Brassica juncea.

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Insights into plant regeneration: cellular pathways and DNA methylation dynamics

Cited by 5 publications

References 98 publications

Evaluation of the genetic uniformity, yield potential, and chilling-stress responses of tuber progeny of aneuploid caladium somaclonal variants in the second vegetative cycle

Evaluation of the genetic uniformity, yield potential, and chilling-stress responses of tuber progeny of aneuploid caladium somaclonal variants in the second vegetative cycle

DNA Hypomethylation Activates the RpMYB2‐Centred Gene Network to Enhance Regeneration of Adventitious Roots

An Efficient System for Agrobacterium-Mediated Transformation of Elite Cultivars in Brassica juncea

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