The emission of floral scent from Lilium ‘siberia-in response to light intensity and temperature
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  • 作者:Zenghui Hu (1)
    Huixiu Zhang (1)
    Pingsheng Leng (1)
    Jing Zhao (1)
    Wenhe Wang (1)
    Shudong Wang (1)
  • 关键词:Floral scent ; Light intensity ; Lilium ‘siberia-/li> Temperature
  • 刊名:Acta Physiologiae Plantarum
  • 出版年:2013
  • 出版时间:May 2013
  • 年:2013
  • 卷:35
  • 期:5
  • 页码:1691-1700
  • 全文大小:426KB
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  • 作者单位:Zenghui Hu (1)
    Huixiu Zhang (1)
    Pingsheng Leng (1)
    Jing Zhao (1)
    Wenhe Wang (1)
    Shudong Wang (1)

    1. College of Landscape Architecture, Beijing University of Agriculture, 102206, Beijing, People’s Republic of China
文摘
Floral scent is an important part of volatile compounds emitted from plants, and is influenced by many environmental factors. In this study, the floral scent emitted from Lilium ‘siberia- a common breed of lily, was collected by dynamic headspace at different levels of light intensity (0, 100, 300, 600, 1,000, and 1,500?μmol?m??s?) and temperature (10, 20, 30, and 40?°C). Using the automated thermal desorption-gas chromatography/mass spectrometry (ATD-GC/MS) technique, the components and release amounts were subsequently identified to investigate the influence of light and temperature on the emission of floral scent. The results revealed that the numbers and release amounts of floral scent components were significantly influenced by light intensity and temperature, showing the similar pattern: first increasing and then decreasing. After light intensity treatment, the maximum numbers and release amounts mainly appeared at 600 and 1,000?μmol?m??s?. For temperature treatment, 30?°C resulted in the highest numbers and release amounts of the floral scent components. At different levels of light intensity and temperature, terpenoid compounds showed the highest numbers and release amounts among the component categories. α-Ocimene and linalool were the two terpenoid compounds with the highest release amounts, and accounted for the highest proportion. The results obtained provide evidence that both light intensity and temperature trigger the emission of floral scent. The particular response mechanisms must be investigated in future research.

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