Photoperiod- and temperature-mediated control of growth cessation and dormancy in trees: a molecular perspective. Maurya, J. P. & Bhalerao, R. P. Annals of Botany, 120(3):351–360, September, 2017. doi abstract bibtex Background: How plants adapt their developmental patterns to regular seasonal changes is an important question in biology. The annual growth cycle in perennial long-lived trees is yet another example of how plants can adapt to seasonal changes. The two main signals that plants rely on to respond to seasonal changes are photoperiod and temperature, and these signals have critical roles in the temporal regulation of the annual growth cycle of trees. Scope: This review presents the latest findings to provide insight into the molecular mechanisms that underlie how photoperiodic and temperature signals regulate seasonal growth in trees. Conclusion: The results point to a high level of conservation in the signalling pathways that mediate photoperiodic control of seasonal growth in trees and flowering in annual plants such as arabidopsis. Furthermore, the data indicate that symplastic communication may mediate certain aspects of seasonal growth. Although considerable insight into the control of phenology in model plants such as poplar and spruce has been obtained, the future challenge is extending these studies to other, non-model trees.
@article{maurya_photoperiod-_2017,
title = {Photoperiod- and temperature-mediated control of growth cessation and dormancy in trees: a molecular perspective},
volume = {120},
issn = {1095-8290},
shorttitle = {Photoperiod- and temperature-mediated control of growth cessation and dormancy in trees},
doi = {10/gbx6rk},
abstract = {Background: How plants adapt their developmental patterns to regular seasonal changes is an important question in biology. The annual growth cycle in perennial long-lived trees is yet another example of how plants can adapt to seasonal changes. The two main signals that plants rely on to respond to seasonal changes are photoperiod and temperature, and these signals have critical roles in the temporal regulation of the annual growth cycle of trees.
Scope: This review presents the latest findings to provide insight into the molecular mechanisms that underlie how photoperiodic and temperature signals regulate seasonal growth in trees.
Conclusion: The results point to a high level of conservation in the signalling pathways that mediate photoperiodic control of seasonal growth in trees and flowering in annual plants such as arabidopsis. Furthermore, the data indicate that symplastic communication may mediate certain aspects of seasonal growth. Although considerable insight into the control of phenology in model plants such as poplar and spruce has been obtained, the future challenge is extending these studies to other, non-model trees.},
language = {eng},
number = {3},
journal = {Annals of Botany},
author = {Maurya, Jay P. and Bhalerao, Rishikesh P.},
month = sep,
year = {2017},
pmid = {28605491},
pmcid = {PMC5591416},
keywords = {Hybrid aspen (Populus tremula × P. tremuloides), Photoperiod, Picea, Plant Dormancy, Populus, Seasons, Temperature, Trees, dormancy, ecodormant, endodormant, growth cessation, phenology, seasonal growth},
pages = {351--360},
}
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Scope: This review presents the latest findings to provide insight into the molecular mechanisms that underlie how photoperiodic and temperature signals regulate seasonal growth in trees. Conclusion: The results point to a high level of conservation in the signalling pathways that mediate photoperiodic control of seasonal growth in trees and flowering in annual plants such as arabidopsis. Furthermore, the data indicate that symplastic communication may mediate certain aspects of seasonal growth. 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