假单胞菌F2对2-糠酸的代谢
The metabolism of 2-furoic acid by Pseudomanas F2.
作者信息
Trudgill P W
出版信息
Biochem J. 1969 Jul;113(4):577-87. doi: 10.1042/bj1130577.
Abstract
- Pseudomonas F2 isolated by enrichment culture on 2-furoic acid and grown with it as carbon source oxidized the compound with a Q(o) (2) of 170mul./mg. dry wt./hr. and the overall consumption of 2.5mumoles of oxygen/mumole of substrate. 2. In the presence of 1mm-sodium arsenite, oxygen uptake was restricted to 0.54mumole/mumole of 2-furoate oxidized, with the formation of 0.86mumole of 2-oxoglutarate/mumole of 2-furoate. 3. Cell suspensions, disrupted in a French pressure cell and centrifuged at 27000g, yielded supernatants capable of catalysing the slow oxidation of 2-furoate (0.17mumole/mg. of protein/hr.). 4. Fractionation of 27000g supernatants at 200000g yielded a soluble enzyme fraction capable of catalysing the oxidation of 2-furoate only in the presence of added 200000g pellet or of Methylene Blue. 5. The 2-furoate-stimulated uptake of oxygen or the anaerobic reduction of Methylene Blue by dialysed 27000g supernatant required the addition of ATP and CoA, and the rate of oxygen uptake was further enhanced by the addition of magnesium chloride and NAD(+). 6. The role of ATP and CoA in the formation of 2-furoyl-CoA was demonstrated by the accumulation of 2-furoylhydroxamic acid in the presence of hydroxylamine. 7. Dialysed 200000g supernatant, treated with Dowex 1, required the addition of ATP, CoA and Methylene Blue before it could oxidize 2-furoate to 2-oxoglutarate, which was trapped in unitary stoicheiometric yield as its phenylhydrazone. Magnesium chloride and NAD(+) were not stimulatory in this system. The oxidation of 2-furoate to 2-oxoglutarate was not inhibited by substrate analogues, metal ion-chelating agents, thiol-active compounds or inhibitors of cytochrome-mediated electron transport. 8. No evidence was obtained for the intervention of 2,5-dioxovalerate as an intermediate in 2-oxoglutarate formation.
摘要
- 通过在2-糠酸上进行富集培养分离得到的假单胞菌F2,并以其作为碳源进行培养,该菌氧化该化合物时的Q(o) (2)为170微升/毫克干重/小时,每微摩尔底物消耗2.5微摩尔氧气。2. 在存在1毫摩尔亚砷酸钠的情况下,氧气摄取量限制为每氧化1微摩尔2-糠酸盐摄取0.54微摩尔氧气,同时每微摩尔2-糠酸盐形成0.86微摩尔2-氧代戊二酸。3. 在法国压力细胞中破碎并在27000g下离心的细胞悬液产生的上清液能够催化2-糠酸盐的缓慢氧化(0.17微摩尔/毫克蛋白质/小时)。4. 在200000g下对27000g上清液进行分级分离,得到一种可溶性酶级分,该级分仅在添加200000g沉淀或亚甲蓝的情况下能够催化2-糠酸盐的氧化。5. 透析后的27000g上清液对2-糠酸盐刺激的氧气摄取或亚甲蓝的厌氧还原需要添加ATP和辅酶A,并且添加氯化镁和NAD(+)可进一步提高氧气摄取速率。6. 在存在羟胺的情况下2-糠酰异羟肟酸的积累证明了ATP和辅酶A在2-糠酰辅酶A形成中的作用。7. 用Dowex 1处理的透析后的200000g上清液在能够将2-糠酸盐氧化为2-氧代戊二酸之前需要添加ATP、辅酶A和亚甲蓝,2-氧代戊二酸以其苯腙形式以单一化学计量产率被捕获。氯化镁和NAD(+)在该系统中无刺激作用。2-糠酸盐氧化为2-氧代戊二酸不受底物类似物、金属离子螯合剂、硫醇活性化合物或细胞色素介导的电子传递抑制剂的抑制。8. 未获得2,5-二氧代戊酸作为2-氧代戊二酸形成中间体介入的证据。
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