Harper J E
United States Department of Agriculture, University of Illinois, Urbana, Illinois 61801.
Plant Physiol. 1981 Dec;68(6):1488-93. doi: 10.1104/pp.68.6.1488.
Studies were conducted to quantitate the evolution of nitrogen oxides (NO((x))) from soybean [Glycine max (L.) Merr.] leaves during in vivo nitrate reductase (NR) assays with aerobic and anaerobic gas purging. Anaerobic gas purging (N(2) and argon) consistently resulted in greater NO((x)) evolution than did aerobic gas purging (air and O(2)). The evolution of NO((x)) was dependent on gas flow rate and on NO(2) (-) formation in the assay medium; although a threshold level of NO(2) (-) appeared to exist beyond which the rate of NO((x)) evolution did not increase further.The loss of NO((x)) from in vivo NR assays under gas purging explains partially, but not stoichiometrically, the decrease in NO(2) (-) accumulation in in vivo NR assay medium with young soybean leaves. The lack of stoichiometry between NO((x)) evolution and apparent NO(2) (-) loss suggests that other mechanisms are also involved in loss of NO(2) (-) or inhibition of formation of NO(2) (-) during anaerobic and aerobic incubation conditions imposed on the in vivo NR assay of soybean. The mechanism of NO((x)) evolution under the assay conditions imposed and the relevance of this phenomenon to intact plants remains unclear.
开展了多项研究,以定量测定在有氧和无氧气体吹扫条件下进行体内硝酸还原酶(NR)测定时,大豆[Glycine max (L.) Merr.]叶片中氮氧化物(NO((x)))的释放情况。与有氧气体吹扫(空气和O(2))相比,无氧气体吹扫(N(2)和氩气)始终导致更多的NO((x))释放。NO((x))的释放取决于气体流速和测定介质中NO(2) (-)的形成;尽管似乎存在一个NO(2) (-)的阈值水平,超过该水平后NO((x))的释放速率不会进一步增加。在气体吹扫条件下,体内NR测定中NO((x))的损失部分解释了(但并非化学计量地)幼嫩大豆叶片体内NR测定介质中NO(2) (-)积累的减少。NO((x))释放与明显的NO(2) (-)损失之间缺乏化学计量关系,这表明在对大豆进行体内NR测定时,在厌氧和好氧培养条件下,其他机制也参与了NO(2) (-)的损失或NO(2) (-)形成的抑制。在施加的测定条件下NO((x))释放的机制以及这种现象与完整植株的相关性仍不清楚。