脱氮副球菌中异化亚硝酸盐还原酶的定位以及氧气对异化硝酸盐还原酶的调控
The location of dissimilatory nitrite reductase and the control of dissimilatory nitrate reductase by oxygen in Paracoccus denitrificans.
作者信息
Alefounder P R, Ferguson S J
出版信息
Biochem J. 1980 Oct 15;192(1):231-40. doi: 10.1042/bj1920231.
Abstract
- A method is described for preparing spheroplasts from Paracoccus denitrificans that are substantially depleted of dissimilatory nitrate reductase (cytochrome cd) activity. Treatment of cells with lysozyme + EDTA together with a mild osmotic shock, followed by centrifugation, yielded a pellet of spheroplasts and a supernatant that contained d-type cytochrome. The spheroplasts were judged to have retained an intact plasma membrane on the basis that less than 1% of the activity of a cytoplasmic marker protein, malate dehydrogenase, was released from the spheroplasts. In addition to a low activity towards added nitrite, the suspension of spheroplasts accumulated the nitrite that was produced by respiratory chain-linked reduction of nitrate. It is concluded that nitrate reduction occurs at the periplasmic side of the plasma membrane irrespective of whether nitrite is generated by nitrate reduction or is added exogenously. 2. Further evidence for the integrity of the spheroplasts was that nitrate reduction was inhibited by O2, and that chlorate was reduced at a markedly lower rate than nitrate. These data are taken as evidence for an intact plasma membrane because it was shown that cells acquire the capability to reduce nitrate under aerobic conditions after addition of low amounts of Triton X-100 which, with the same titre, also overcame the permeability barrier to chlorate reduction by intact cells. The close relationship between the appearance of chlorate reduction and the loss of the inhibitory effect of O2 on nitrate reduction also suggests that the later feature of nitrate respiration is due to a control on the accessibility of nitrate to its reductase rather than on the flow of electrons to nitrate reductase.
摘要
- 本文描述了一种从反硝化副球菌制备原生质球的方法,这些原生质球的异化硝酸盐还原酶(细胞色素cd)活性大幅降低。用溶菌酶+乙二胺四乙酸(EDTA)处理细胞,并进行轻度渗透压休克,然后离心,得到原生质球沉淀和含有d型细胞色素的上清液。基于细胞质标记蛋白苹果酸脱氢酶的活性从原生质球中释放的比例不到1%,判断原生质球保留了完整的质膜。除了对添加的亚硝酸盐活性较低外,原生质球悬浮液还积累了由呼吸链连接的硝酸盐还原产生的亚硝酸盐。结论是,无论亚硝酸盐是由硝酸盐还原产生还是外源添加,硝酸盐还原都发生在质膜的周质侧。2. 原生质球完整性的进一步证据是,硝酸盐还原受到氧气抑制,且氯酸盐的还原速率明显低于硝酸盐。这些数据被视为质膜完整的证据,因为已表明,在添加少量 Triton X-100 后,细胞在有氧条件下获得了还原硝酸盐的能力,相同滴度的 Triton X-100 也克服了完整细胞对氯酸盐还原的通透性障碍。氯酸盐还原的出现与氧气对硝酸盐还原抑制作用的丧失之间的密切关系也表明,硝酸盐呼吸的后一特征是由于对硝酸盐与其还原酶接触的控制,而非对电子流向硝酸盐还原酶的控制。
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