TY - JOUR
T1 - Establishment of a shortened annual cycle system; a tool for the analysis of annual re-translocation of phosphorus in the deciduous woody plant (Populus alba L.)
AU - Kurita, Yuko
AU - Baba, Kei'ichi
AU - Ohnishi, Miwa
AU - Anegawa, Aya
AU - Shichijo, Chizuko
AU - Kosuge, Keiko
AU - Fukaki, Hidehiro
AU - Mimura, Tetsuro
N1 - Funding Information:
Acknowledgments We would like to offer our heartfelt thanks to Prof. Shinobu Satoh for his advice about culture conditions for the establishment of a shortened annual cycle. We also greatly appreciate Dr. Rob Reid (University of Adelaide, Adelaide, Australia) and Dr. Shanti S. Sharma (Himachal Pradesh University, Shimla, India) for their kind discussion and correction of this manuscript. This work was supported by a Grant-in-Aid for Scientific Research of Innovative Areas from the Japanese Ministry of Education, Sports, Culture, Science, and Technology on ‘‘Perceptive plants (22120006)’’. YK is grateful for a SUNBOR Scholarship.
PY - 2014/6
Y1 - 2014/6
N2 - The supply of phosphorus, the essential element for plant growth and development, is often limited in natural environments. Plants employ multiple physiological strategies to minimize the impact of phosphate deficiency. In deciduous trees, phosphorus is remobilized from senescing leaves in autumn and stored in other tissues for reuse in the following spring. We previously monitored the annual changes in leaf phosphate content of white poplar (Populus alba) growing under natural conditions and found that about 75 % of inorganic and 60 % of organic leaf phosphates observed in May were remobilized by November. In order to analyze this process (such annual events), we have established a model system, in which an annual cycle of phosphate re-translocation in trees can be simulated under laboratory conditions by controlling temperature and photoperiod (='shortened annual cycle'). This system evidently allowed us to monitor the annual changes in leaf color, phosphate remobilization from senescent leaves, and bud break in the next spring within five months. This will greatly facilitate the analysis of cellular and molecular mechanisms of annual phosphate re-translocation in deciduous trees.
AB - The supply of phosphorus, the essential element for plant growth and development, is often limited in natural environments. Plants employ multiple physiological strategies to minimize the impact of phosphate deficiency. In deciduous trees, phosphorus is remobilized from senescing leaves in autumn and stored in other tissues for reuse in the following spring. We previously monitored the annual changes in leaf phosphate content of white poplar (Populus alba) growing under natural conditions and found that about 75 % of inorganic and 60 % of organic leaf phosphates observed in May were remobilized by November. In order to analyze this process (such annual events), we have established a model system, in which an annual cycle of phosphate re-translocation in trees can be simulated under laboratory conditions by controlling temperature and photoperiod (='shortened annual cycle'). This system evidently allowed us to monitor the annual changes in leaf color, phosphate remobilization from senescent leaves, and bud break in the next spring within five months. This will greatly facilitate the analysis of cellular and molecular mechanisms of annual phosphate re-translocation in deciduous trees.
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U2 - 10.1007/s10265-014-0634-2
DO - 10.1007/s10265-014-0634-2
M3 - Article
C2 - 24848773
AN - SCOPUS:84903478145
SN - 0918-9440
VL - 127
SP - 545
EP - 551
JO - Journal of Plant Research
JF - Journal of Plant Research
IS - 4
ER -