光照和环境二氧化碳浓度对完整大麦幼苗硝酸盐同化的影响。
Influence of light and ambient carbon dioxide concentration on nitrate assimilation by intact barley seedlings.
机构信息
Plant Growth Laboratory/Department of Agronomy and Range Science, University of California, Davis, California 95616.
出版信息
Plant Physiol. 1979 Jun;63(6):1205-9. doi: 10.1104/pp.63.6.1205.
Abstract
The influence of light, dark, and ambient CO(2) on nitrate assimilation in 8- to 9-day-old barley seedlings was studied. To develop the photosynthetic apparatus fully, the seedlings were grown in nitrogen-free Hoagland solution for 5 days in darkness followed by 3 days in continuous light.The seedlings reduced nitrate and nitrite in both light and dark, although more slowly in darkness. The slower nitrate reduction in darkness was not due to decreased uptake, since the steady-state internal concentration of nitrate was doubled. The faster nitrate reduction in light was attributed to recent products of photosynthetic CO(2) fixation supplying reducing energy, possibly by shuttle reactions between chloroplasts and cytoplasm. In carbohydrate-deficient tissue, it appeared that recently fixed photosynthate could supply all of the energy required for nitrate reduction. When sufficient metabolites were present in the green tissue, light was not obligatory for the reduction of nitrate and nitrite.
摘要
研究了光照、黑暗和环境 CO₂对 8-9 天大的大麦幼苗硝酸盐同化的影响。为了充分发育光合作用器官,幼苗在黑暗中无氮 Hoagland 培养液中生长 5 天,然后在连续光照下生长 3 天。尽管在黑暗中速度较慢,但幼苗在光照和黑暗中均能还原硝酸盐和亚硝酸盐。黑暗中硝酸盐还原速度较慢并不是因为吸收减少,因为硝酸盐的稳态内部浓度增加了一倍。光照下硝酸盐还原速度较快归因于光合作用 CO₂固定的最近产物提供了还原能量,可能通过叶绿体和细胞质之间的穿梭反应。在碳水化合物缺乏的组织中,最近固定的光合作用产物似乎可以提供硝酸盐还原所需的全部能量。当绿色组织中存在足够的代谢物时,光照不是还原硝酸盐和亚硝酸盐的必要条件。
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