Abstract
The photoperiod, which is the length of the light period in the diurnal cycle of 24 h, is an important environmental signal. Plants have evolved sensitive mechanisms to measure the length of the photoperiod. Photoperiod sensing enables plants to synchronize developmental processes, such as the onset of flowering, with a specific time of the year, and enables them to alleviate the impact of environmental stresses occurring at the same time every year. During the last years, the importance of the photoperiod for plant responses to abiotic and biotic stresses has received increasing attention. In this review, we summarize the current knowledge on the signaling pathways involved in the photoperiod-dependent regulation of responses to abiotic (freezing, drought, osmotic stress) and biotic stresses. A central role of GIGANTEA (GI), which is a key player in the regulation of photoperiod-dependent flowering, in stress responses is highlighted. Special attention is paid to the role of the photoperiod in regulating the redox state of plants. Furthermore, an update on photoperiod stress, which is caused by sudden alterations in the photoperiod, is given. Finally, we will review and discuss the possible use of photoperiod-induced stress as a sustainable resource to enhance plant resistance to biotic stress in horticulture.
Highlights
Eukaryotes, including plants, adapt numerous life processes to regular rhythms of light and darkness
The photoperiod provides plants with information to synchronize their developmental program with the prevailing season
It is used to match the optimal conditions for offspring production and to alleviate the threats of seasonal stresses occurring at the same time every year
Summary
Eukaryotes, including plants, adapt numerous life processes to regular rhythms of light and darkness. The duration of the light period during this 24 h day-night cycle determines the photoperiod, which varies with the season and latitude (Jackson, 2009). Plants synchronize their physiological decisions with the correct time of the year to maximize growth and to produce offspring (Casal et al, 2004). Among the most prominent plant responses influenced by the photoperiod are the regulation of flowering time (Carré, 2001; Song et al, 2015), tuberization (Sarkar, 2010), bud setting, and dormancy (Jackson, 2009; Singh et al, 2017). Scent emission from flowers is under the control of the photoperiod (Hendel-Rahmanim et al, 2007) to mention just a few examples of photoperiod-regulated developmental processes in plants
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