Dormancy: A New Universal Terminology

Lang, Gregory A.

doi:10.21273/hortsci.22.5.817

Cited by 286 publications

(36 citation statements)

References 18 publications

(27 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Unfavorable external factors, such as nutrients, water and low temperature, would induce the growth to dormancy and will quickly resume growth in the absence of these unfavorable factors [44]. In accordance with the central roles of strigolactones in stress responses, strigolactones biosynthetic genes MAX1, MAX3 and MAX4 are influenced by drought, salt and ABA in Arabidopsis leaves, further supporting the notion that stress-mediated strigolactones homeostasis is essential for boosting plant resistance against environmental stresses [45].…”

Section: Regulated By Environmental Stressmentioning

confidence: 54%

Do Strigolactones Regulate BudWinter Dormancy and Charactrisitc Secondary Metabolism in Tea?

Lin¹,

Ziming²,

Li³

et al. 2021

Phyton

View full text Add to dashboard Cite

Tea (Camellia sinensis [L.] O. Kuntze.) is an important cash crop, which mainly uses tender shoots and young leaves for manufacturing. Due to the marketing characteristic that earlier made tea has higher price, the time of the breaking of winter dormancy buds in spring is extremely important in tea industry. Strigolactones are a group of carotenoids-derived metabolites which regulates bud outgrowth, shoot branching, tiller angle and environmental stress responses. The role of strigolactones in tea plant was briefly summarized in the current review, with an emphasis of the association of strigolactones on bud ecodormancy and shoot branching. The involvement of strigolactones on the biosynthesis of the tea characteristic metabolites flavonoids, caffeine and theanine were also discussed. Moreover, recent advances on the biosynthesis of strigolactones and its regulation by microRNAs and environmental stresses were also presented. This review provides a basis for future investigations underlying the mechanisms of strigolactones on bud winter dormancy and tea secondary metabolism.

show abstract

Section: Regulated By Environmental Stressmentioning

confidence: 54%

Do Strigolactones Regulate BudWinter Dormancy and Charactrisitc Secondary Metabolism in Tea?

Lin¹,

Ziming²,

Li³

et al. 2021

Phyton

View full text Add to dashboard Cite

show abstract

“…Perennial fruit species enter a dormancy phase in late autumn to ovoid the freezing temperature during winter in their respective habitat of origin [48]. Following the winter dormancy classification into endo and eco-dormancy, researchers have defined the concepts of chill and heat requirements, CR and HR respectively, to represent the climatic needs of buds for overcoming the dormant state [49]. CR and HR are considered as two main driver factors for the timing of budburst and bloom in temperate tree species [50].…”

Section: Discussionmentioning

confidence: 99%

Statistical Approach to Assess Chill and Heat Requirements of Olive Tree Based on Flowering Date and Temperatures Data: Towards Selection of Adapted Cultivars to Global Warming

Abou-Saaid¹,

Yaacoubi²,

Moukhli³

et al. 2022

Preprint

View full text Add to dashboard Cite

Delineating chilling and forcing periods is one of the challenging topics to understand how temperatures drive the timing of budburst and bloom in fruit tree species, especially when flowering data are limited to a short-term phenology data. Here, we investigated this question on olive trees, using flowering data collected over six years on 331 cultivars cultivated in the worldwide collection of Marrakech, Morocco. Using Partial Least Squares (PLS) approach on a long-term phenology (29 years) of Picholine Marocaine cultivar, we showed that the relevance of delineating chilling and forcing periods depends more on the variability of inter-annual temperatures than on the long-term datasets. In fact, chilling and forcing periods are similar between those delineated using datasets of 29 years and those of only six years (2014-2019). Furthermore, we demonstrated that the variability of inter-annual temperatures is the main factor explaining this pattern. We, then, used datasets of six years to assess chill and heat requirements, of 285 cultivars. We classified Mediterranean olive cultivars into four groups according to their chill requirements. Our results, using the kriging interpolation method, indicated that flowering dates of most of these cultivars (92%) were governed by both chilling and forcing temperatures.

show abstract

“…In temperate perennial plants, bud formation and winter dormancy ensure meristematic tissues (vegetative and reproductive) remain in a non-growing safer state, regardless of short temporary warmer periods, until a quantitative perception of environmental chilling fulfils the genetically-encoded chilling requirements of a given cultivar or variety [ 3 ]. This true dormancy (or endodormancy) term opposes to paradormancy and ecodormancy, which respectively refer to the quiescent state of buds repressed by correlative inhibition and dormancy-released buds requiring a period of warm temperatures prior to growth resumption and bud-break [ 4 ]. Since global warming is expected to reduce available winter chilling for satisfying winter dormancy release requirements, this climatic threat is potentially capable of impairing adaptability and yield in the case of crops [ 5 ], and even favouring the summer dormancy trait that enhances plant survival under extreme temperatures and summer droughts [ 6 ].…”

Section: Introductionmentioning

confidence: 99%

Evolutionary origin and functional specialization of Dormancy-Associated MADS box (DAM) proteins in perennial crops

et al. 2022

View full text Add to dashboard Cite

Background Bud dormancy is a phenological adaptation of temperate perennials that ensures survival under winter temperature conditions by ceasing growth and increasing cold hardiness. SHORT VEGETATIVE PHASE (SVP)-like factors, and particularly a subset of them named DORMANCY-ASSOCIATED MADS-BOX (DAM), are master regulators of bud dormancy in perennials, prominently Rosaceae crops widely adapted to varying environmental conditions. Results SVP-like proteins from recently sequenced Rosaceae genomes were identified and characterized using sequence, phylogenetic and synteny analysis tools. SVP-like proteins clustered in three clades (SVP1–3), with known DAM proteins located within SVP2 clade, which also included Arabidopsis AGAMOUS-LIKE 24 (AthAGL24). A more detailed study on these protein sequences led to the identification of a 15-amino acid long motif specific to DAM proteins, which affected protein heteromerization properties by yeast two-hybrid system in peach PpeDAM6, and the unexpected finding of predicted DAM-like genes in loquat, an evergreen species lacking winter dormancy. DAM gene expression in loquat trees was studied by quantitative PCR, associating with inflorescence development and growth in varieties with contrasting flowering behaviour. Conclusions Phylogenetic, synteny analyses and heterologous overexpression in the model plant Arabidopsis thaliana supported three major conclusions: 1) DAM proteins might have emerged from the SVP2 clade in the Amygdaloideae subfamily of Rosaceae; 2) a short DAM-specific motif affects protein heteromerization, with a likely effect on DAM transcriptional targets and other functional features, providing a sequence signature for the DAM group of dormancy factors; 3) in agreement with other recent studies, DAM associates with inflorescence development and growth, independently of the dormancy habit.

show abstract

Dormancy: A New Universal Terminology

Cited by 286 publications

References 18 publications

Do Strigolactones Regulate BudWinter Dormancy and Charactrisitc Secondary Metabolism in Tea?

Do Strigolactones Regulate BudWinter Dormancy and Charactrisitc Secondary Metabolism in Tea?

Statistical Approach to Assess Chill and Heat Requirements of Olive Tree Based on Flowering Date and Temperatures Data: Towards Selection of Adapted Cultivars to Global Warming

Evolutionary origin and functional specialization of Dormancy-Associated MADS box (DAM) proteins in perennial crops

Contact Info

Product

Resources

About