Saidha T, Na S Q, Li J Y, Schiff J A
Biology Department, Brandies University, Waltham, MA 02254.
Biochem J. 1988 Jul 15;253(2):533-9. doi: 10.1042/bj2530533.
We have previously shown that a sulphate activating system is present on the outside of the inner mitochondrial membrane of Euglena gracilis Klebs. var. bacillaris Cori, but efforts to couple this system to ATP produced from oxidative phosphorylation were unsuccessful. In the present work we show that the concentration of Pi ordinarily used to support oxidative phosphorylation in these mitochondria (10 mM) inhibits sulphate activation completely; by reducing the concentration of Pi 10-fold, both processes proceeded normally. Sulphate activation under these conditions is inhibited nearly completely by the uncouplers of oxidative phosphorylation dinitrophenol (0.1 mM) and carbonyl cyanide m-chlorophenylhydrazone (CCCP) (0.2 microM). Sulphate reduction to form free cysteine, most of which appears outside the organelle, and in the cysteine of mitochondrial protein can be demonstrated in the same preparations, is membrane-bound and is inhibited by chloramphenicol (100 micrograms/ml), NaN3 (5 mM), KCN (100 microM); dinitrophenol (0.1 mM) or CCCP (0.2 microM). Digitonin fractionation of the mitochondria into mitoplasts, outer membranes and an intermembrane fraction show that reduction of 35SO4(2-) to form free cysteine and cysteine of protein is located on the mitoplasts; adenosine 5'-phosphosulphate sulphotransferase, the first enzyme of sulphate reduction, is found in the same location. Sulphate activation is highly enriched in the mitochondrial fraction of Euglena; the small amount found in the chloroplast fraction can be attributed to mitochondrial contamination. Thus, in Euglena, sulphate activation and reduction are contained in a sulphate metabolizing centre on the outside of the mitochondrial inner membrane; this centre appears to supply the mitochondrion and the rest of the cell with the products of sulphate activation as well as with reduced sulphur in the form of cysteine. Mitochondria from wild-type Euglena cells and from W10BSmL, a mutant lacking plastids completely, appear to be similar in the properties studied.
我们之前已经表明,纤细裸藻(Euglena gracilis Klebs. var. bacillaris Cori)线粒体内膜外侧存在一个硫酸盐激活系统,但将该系统与氧化磷酸化产生的ATP偶联的尝试未成功。在本研究中,我们发现通常用于支持这些线粒体氧化磷酸化的无机磷酸盐(Pi)浓度(10 mM)会完全抑制硫酸盐激活;将Pi浓度降低10倍后,这两个过程均正常进行。在这些条件下,氧化磷酸化解偶联剂二硝基苯酚(0.1 mM)和羰基氰化物间氯苯腙(CCCP)(0.2 μM)几乎完全抑制硫酸盐激活。在相同的制剂中可以证明,硫酸盐还原形成游离半胱氨酸(其中大部分出现在细胞器外)以及线粒体蛋白中的半胱氨酸,该过程是膜结合的,并且受到氯霉素(100 μg/ml)、叠氮化钠(5 mM)、氰化钾(100 μM)、二硝基苯酚(0.1 mM)或CCCP(0.2 μM)的抑制。用洋地黄皂苷将线粒体分级分离为线粒体膜间腔、外膜和膜间组分,结果表明35SO4(2-)还原形成游离半胱氨酸和蛋白质中的半胱氨酸位于线粒体膜间腔;腺苷5'-磷酸硫酸磺基转移酶是硫酸盐还原的第一个酶,也位于相同位置。硫酸盐激活在裸藻的线粒体组分中高度富集;叶绿体组分中发现的少量该物质可归因于线粒体污染。因此,在裸藻中,硫酸盐激活和还原存在于线粒体内膜外侧的一个硫酸盐代谢中心;该中心似乎为线粒体和细胞的其他部分提供硫酸盐激活的产物以及半胱氨酸形式的还原态硫。野生型裸藻细胞和完全缺乏质体的突变体W10BSmL的线粒体在所研究的特性方面似乎相似。