不同光周期条件下，[植物名称未给出]花序茎的回旋转头运动和生长对微重力的响应

Circumnutation and Growth of Inflorescence Stems of in Response to Microgravity under Different Photoperiod Conditions.

作者信息

Wu Yuanyuan, Xie Junyan, Wang Lihua, Zheng Huiqiong

机构信息

CAS Center for Excellence in Molecular Plant Sciences, Chinese Academy of Sciences, Shanghai 200032, China.

University of Chinese Academy of Sciences, Beijing 100049, China.

出版信息

Life (Basel). 2020 Mar 18;10(3):26. doi: 10.3390/life10030026.

DOI:10.3390/life10030026

PMID:32197304

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7151594/

Abstract

Circumnutation is a periodic growth movement, which is an important physiological mechanism of plants to adapt to their growth environments. Gravity and photoperiod are two key environmental factors in regulating the circumnutation of plants, but the coordination mechanism between them is still unknown. In this study, the circumnutation of inflorescence stems was investigated on board the Chinese recoverable satellite SJ-10 and the Chinese spacelab TG-2. Plants were cultivated in a special plant culture chamber under two photoperiod conditions [a long-day (LD) light: dark cycle of 16:8 h, and a short-day (SD) light: dark cycle of 8:16 h]. The plant growth and movements were followed by two charge-coupled device (CCD) cameras. The parameter revealed a daily (24 h) modulation on both TG-2 and SJ-10, under both the LD and the SD conditions. The inhibition of circumnutation was more apparent by microgravity under the SD in comparison with that under the LD condition, suggesting the synergistic effects of the combined microgravity and photoperiod on the circumnutation in space. In addition, an infradian rhythm (ca. 21 days long) on the TG-2 was also observed.

摘要

植物的螺旋生长运动是一种周期性的生长运动，是植物适应生长环境的重要生理机制。重力和光周期是调节植物螺旋生长运动的两个关键环境因素，但它们之间的协调机制尚不清楚。在本研究中，利用中国返回式卫星SJ-10和中国太空实验室TG-2对花序茎的螺旋生长运动进行了研究。植物在特殊的植物培养箱中，在两种光周期条件下培养[长日照（LD），光照：黑暗周期为16:8小时；短日照（SD），光照：黑暗周期为8:16小时]。通过两台电荷耦合器件（CCD）相机跟踪植物的生长和运动。该参数显示，在TG-2和SJ-10上，在长日照和短日照条件下，每天（24小时）都有调节作用。与长日照条件相比，短日照条件下微重力对螺旋生长运动的抑制作用更明显，这表明微重力和光周期对空间中螺旋生长运动具有协同作用。此外，在TG-2上还观察到了一种亚日节律（约21天）。

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Circumnutation and Growth of Inflorescence Stems of in Response to Microgravity under Different Photoperiod Conditions.不同光周期条件下，[植物名称未给出]花序茎的回旋转头运动和生长对微重力的响应

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不同光周期条件下，[植物名称未给出]花序茎的回旋转头运动和生长对微重力的响应

Circumnutation and Growth of Inflorescence Stems of in Response to Microgravity under Different Photoperiod Conditions.

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