Abscisic acid catabolism enhances dormancy release of grapevine buds

Zheng, Chuanlin; Acheampong, Atiako Kwame; Shi, Zhaowan; Mugzech, Amichay; Halaly-Basha, Tamar; Shaya, Felix; Sun, Yufei; Colova, Violeta; Mosquna, Assaf; Ophir, Ron; Galbraith, David W.; Or, Etti

doi:10.1111/pce.13371

Cited by 63 publications

(59 citation statements)

References 71 publications

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“…In plants, abscisic acid (ABA) plays a crucial role in regulating bud dormancy including its induction, maintenance and release (Lenton, Perry, & Saunders, ; Zheng et al, , ). ABA also plays an important role in host–pathogen interactions (Mohr & Cahill, ; Qi et al, ).…”

Section: Resultsmentioning

confidence: 99%

Transcriptome analysis reveals a complex array of differentially expressed genes accompanying a source‐to‐sink change in phytoplasma‐infected sweet cherry leaves

Tan

Wang

Davis

et al. 2019

Annals of Applied Biology

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Sweet cherry (Prunus avium) in China has recently been affected by a destructive disease that is characterised by symptoms of floral virescence and witches'-broom growths. The etiological agent of the disease is a subgroup 16SrV-B phytoplasma that is closely related to 'Candidatus Phytoplasma ziziphi.' A previous study revealed that photosynthetic activity had significantly declined in symptomatic leaves of the diseased sweet cherry trees. For a deeper view into the infection, we performed a comparative transcriptomic analysis. A total of 62,410 unigenes were identified; among them, 1,675 were differentially expressed in symptomatic leaves of diseased versus asymptomatic leaves of healthy plants. Phytoplasma infection induced the up-regulation of a suite of genes involved in carbohydrate metabolism, fatty acid biosynthesis, phenylpropanoid biosynthesis and flavonoid biosynthesis. Expression profiles of genes related to amino acid metabolism, hormone metabolism, and signal transductions were also altered in leaves of phytoplasma-infected trees. Findings from this study offer clues to understanding host responses to the phytoplasma infection and disease induction in sweet cherry trees. The constellation of differentially regulated genes identified in the present study may be explored as biomarkers for early detection of phytoplasma infection and as potential targets for disease control. K E Y W O R D S phytoplasma infection, Prunus avium, transcriptome

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Section: Resultsmentioning

confidence: 99%

Transcriptome analysis reveals a complex array of differentially expressed genes accompanying a source‐to‐sink change in phytoplasma‐infected sweet cherry leaves

Tan

Wang

Davis

et al. 2019

Annals of Applied Biology

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“…Pear and apple dormancy is induced by low temperatures rather than the photoperiod (Heide and Prestrud ), whereas in poplar, short‐day conditions induce dormancy (Olsen et al, ). Although the environmental cues for establishing dormancy vary among species, ABA is considered to be the key phytohormone for dormancy induction and maintenance (Li, Xu, et al, ; Tylewicz et al, ; Zheng, Acheampong, Shi, Mugzech, et al, ). In poplar, ABA signaling promotes plasmodesmata closure, which is a crucial process during dormancy in response to short‐day conditions (Tylewicz et al, ), and helps regulate the onset of bud dormancy.…”

Section: Discussionmentioning

confidence: 99%

“…However, a long‐term exposure to low temperatures leads to endo‐dormancy release and a decrease in the ABA content of buds, likely due to the downregulated expression of ABA biosynthesis genes ( XERICO and NECD ) and the upregulated expression of an ABA catabolism gene ( CYP707A ) (Li et al, ; Zheng et al, ). The overexpression of VvCYP707A4 in grape decreases the ABA level and significantly enhances bud break (Zheng et al, ). Thus, ABA is involved in dormancy maintenance.…”

Section: Introductionmentioning

confidence: 99%

ABA‐responsive ABRE‐BINDING FACTOR3 activatesDAM3expression to promote bud dormancy in Asian pear

Yang

et al. 2020

Plant Cell & Environment

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Bud dormancy is indispensable for the survival of perennial plants in cold winters.Abscisic acid (ABA) has essential functions influencing the endo-dormancy status. Dormancy-associated MADS-box/SHORT VEGETATIVE PHASE-like genes function downstream of the ABA signalling pathway to regulate bud dormancy. However, the regulation of DAM/SVP expression remains largely uncharacterized. In this study, we confirmed that endo-dormancy maintenance and PpyDAM3 expression are controlled by the ABA content in pear (Pyrus pyrifolia) buds. The expression of pear ABRE-BINDING FACTOR3 (PpyABF3) was positively correlated with PpyDAM3 expression. Furthermore, PpyABF3 directly bound to the second ABRE in the PpyDAM3 promoter to activate its expression. Interestingly, both PpyABF3 and PpyDAM3 repressed the cell division and growth of transgenic pear calli. Another ABA-induced ABF protein, PpyABF2, physically interacted with PpyABF3 and disrupted the activation of the PpyDAM3 promoter by PpyABF3, indicating DAM expression was precisely controlled. Additionally, our results suggested that the differences in the PpyDAM3 promoter in two pear cultivars might be responsible for the diversity in the chilling requirements. In summary, our data clarify the finely tuned regulatory mechanism underlying the effect of ABA on DAM gene expression and provide new insights into ABA-related bud dormancy regulation. K E Y W O R D S ABF3, Abscisic acid, bud dormancy, DAM, pear

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“…Our results suggested that the primary perception and signal cascade to initiate bud burst arises within the bud and are independent of de novo transport of phytohormones or other mobile elements from the cane. In fact, very recently, the induction of in situ catabolism of ABA was demonstrated to be essential for bud break in grapevine (Zheng et al , 2018). Moreover, the authors showed that the transgenic expression of the ABA catabolic enzyme VvA8H-CYP707A4 resulted in enhancement of bud break in grapevine, and reduced apical dominance (Zheng et al , 2018).…”

Section: Discussionmentioning

confidence: 99%

“…In fact, very recently, the induction of in situ catabolism of ABA was demonstrated to be essential for bud break in grapevine (Zheng et al , 2018). Moreover, the authors showed that the transgenic expression of the ABA catabolic enzyme VvA8H-CYP707A4 resulted in enhancement of bud break in grapevine, and reduced apical dominance (Zheng et al , 2018). Also recently, a transcriptomic study on Prunus mume suggested that low temperature results in the up-regulation of C-repeat binding factor genes, which directly promotes six dormancy associated MADS-box genes to establish dormancy.…”

Section: Discussionmentioning

confidence: 99%

Physiological regulation of bud burst in grapevine

Signorelli

Shaw

Hermawaty

et al. 2018

Preprint

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Supplementary Movies: 1. 34 2 Word count: 7794 35 36 Highlights 37• The apoplastic pore size between the grapevine bud and the mother vine is 38 dynamically regulated in the transition to bud burst. 39• The molecular exclusion size of the apoplastic connection between the bud and cane 40 is calculated 2.1 nm prior to the initiation of bud burst. 41• The structural heterogeneity of the bud explains the spatial variance in tissue oxygen 42 status, and the meristematic core is oxygenated during the initiation of bud burst. 43• Long distance maternal signals are not a requirement for bud burst. 44 45Abstract 46 The physiological constraints on bud burst in woody perennials, including the prerequisite for 47 vascular development remain unresolved. Both light and tissue oxygen status have emerged 48 as important cues for vascular development in other systems, however, light requirement 49 appears to be facultative in grapevine, and the information related to the spatial variability of 50 oxygen in buds is unclear. Here, we analysed apoplastic development at early stages of 51 grapevine bud burst and combined molecular modelling with histochemical techniques to 52 determine the pore size of cell walls in grapevine buds. The data demonstrate that quiescent 53 grapevine buds were impermeable to apoplastic dyes (acid fuchsin and eosin Y) until after 54 bud burst was established. The molecular exclusion size was calculated to be 2.1 nm, which 55 would exclude most macromolecules except simple sugars and phytohormones. In vivo 56 experiments show that grapevine buds were able to resume growth even following excision 57 from the cane, and that the outer scales of grapevine buds may participate in the biochemical 58 repression of bud burst. Furthermore, we demonstrate that the tissue oxygen partial pressure 59 data correlated well with structural heterogeneity within the bud and differences in tissue 60 density. These data consolidate evidence that the meristematic core becomes rapidly 61 oxygenated during bud burst. Taken together, and when put in the context of earlier studies, 62 these data provide solid evidence that the physiological and biochemical events that initiate 63 bud burst reside within the bud, and question the role of long distance signalling in this 64 developmental transition. 65 66

show abstract

Abscisic acid catabolism enhances dormancy release of grapevine buds

Cited by 63 publications

References 71 publications

Transcriptome analysis reveals a complex array of differentially expressed genes accompanying a source‐to‐sink change in phytoplasma‐infected sweet cherry leaves

Transcriptome analysis reveals a complex array of differentially expressed genes accompanying a source‐to‐sink change in phytoplasma‐infected sweet cherry leaves

ABA‐responsive ABRE‐BINDING FACTOR3 activatesDAM3expression to promote bud dormancy in Asian pear

Physiological regulation of bud burst in grapevine

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