Results 191 to 200 of about 9,334 (285)

Editorial: Advances on the Biological Mechanisms Involved in Adventitious Root Formation: From Signaling to Morphogenesis. [PDF]

Front Plant Sci, 2022
Cardoso H, Peixe A, Bellini C, Porfírio S, Druege U.   +4 more
europepmc   +1 more source

De novo stolon organogenesis in potato leaf callus elicited by Agrobacterium tumefaciens stimulus

Journal of Integrative Plant Biology, EarlyView.
Agrobacterium tumefaciens triggers stolon regeneration from potato leaf callus independent of T‐DNA insertion, suggesting a strategy to reprogram callus identity and expand the potential of tissue regeneration. ABSTRACT Plant cells can undergo cellular reprogramming, enabling pluripotent callus formation from excised leaves.
Seung Yong Shin, Su‐Jin Park, Ji‐Sun Park, Ki‐Beom Moon, Jae Sun Moon, Hye Sun Cho, Hyun‐Soon Kim, Hyo‐Jun Lee   +7 more
wiley   +1 more source

Transcriptome of Two-Hybrid Poplar (<i>Populus alba</i> × <i>P. tomentiglandulosa</i>) During Adventitious Root Formation After Stem Cutting. [PDF]

Biology (Basel)
Byeon S, Lee IH.
europepmc   +1 more source

Key regulatory pathways, microRNAs, and target genes participate in adventitious root formation of Acer rubrum L. [PDF]

Sci Rep, 2022
Zhu W, Zhang M, Li J, Zhao H, Zhang K, Ge W.   +5 more
europepmc   +1 more source

SlGRF1 mediates gibberellin signaling to control cut‐budding in tomato

Journal of Integrative Plant Biology, EarlyView.
Upon wounding, cytokinin increases to initiate callus formation. Gibberellin enhances this, but later blocks bud formation by suppressing SlGRF1. Wounding‐induced protein SlGRF1 triggers buds via NAM1, EPF4, and ER2. Hormonal shifts control cut‐budding phases.
Yaping Xu, Yinhuan Xie, Huimin Jia, Qianqian Li, Xinqin Liu, Ting Ma, Zhaobo Lang, Qingfeng Niu   +7 more
wiley   +1 more source

Investigating the Mechanisms of Adventitious Root Formation in Semi-Tender Cuttings of <i>Prunus mume</i>: Phenotypic, Phytohormone, and Transcriptomic Insights. [PDF]

Int J Mol Sci
Wang X, Li Y, Li Z, Gu X, Wang Z, Qin X, Li Q.   +6 more
europepmc   +1 more source

Effects of Auxin (Indole-3-butyric Acid) on Adventitious Root Formation in Peach-Based Prunus Rootstocks. [PDF]

Plants (Basel), 2022
Justamante MS, Mhimdi M, Molina-Pérez M, Albacete A, Moreno MÁ, Mataix I, Pérez-Pérez JM.   +6 more
europepmc   +1 more source

FcMAPK4‐phosphorylated FcNOR activates FcERF5 to promote fig fruit softening through activation of FcPG12 expression

Journal of Integrative Plant Biology, EarlyView.
In Ficus carica fruit, the MAP kinase FcMAPK4 phosphorylates the NAC transcription factor FcNOR, which cooperates with ethylene response factor FcERF5 to activate the pectin degradation gene FcPG12, thereby promoting rapid softening of fig fruit. ABSTRACT Rapid softening of fig (Ficus carica L.) fruit during ripening leads to extremely short shelf life;
Yuan Wang, Zhiyi Fan, Yining Wang, Alexander Vainstein, Yuexuan Qiu, Yinan Sun, Huiqin Ma   +6 more
wiley   +1 more source

Genome-wide association study (GWAS) analyses of early anatomical changes in rose adventitious root formation. [PDF]

Sci Rep
Wamhoff D, Marxen A, Acharya B, Grzelak M, Debener T, Winkelmann T.   +5 more
europepmc   +1 more source

Decoding stress resilience in soybean: Regulatory networks and precision breeding under climate change

Journal of Integrative Plant Biology, EarlyView.
This review covers recent progress in the understanding of stress‐responsive regulatory networks in soybean and highlights emerging genomic and breeding strategies. Integrating molecular insights and precision breeding will help to accelerate the development of climate‐resilient soybean cultivars.
Ali Shahzad, Monan Sun, Shuangkang Pei, Xiaoyu Liu, Yinhe Zhang, Keheng Xu, Hongtao Gao, Yonggang Zhou, Haiyan Li   +8 more
wiley   +1 more source