小球藻中乙醇酸利用的途径。
The pathway of glycollate utilization in Chlorella pyrenoidosa.
作者信息
Lord J M, Merrett M J
出版信息
Biochem J. 1970 May;117(5):929-37. doi: 10.1042/bj1170929.
Abstract
- Exogenous glycollate was rapidly metabolized in both the light and the dark by photoautotrophically grown Chlorella pyrenoidosa. 2. The incorporation of (14)C from [1-(14)C]glycollate by these cells was inhibited by the tricarboxylic acid-cycle inhibitors monofluoroacetate, diethylmalonate and arsenite, and also by alpha-hydroxypyrid-2-ylmethanesulphonate and isonicotinylhydrazine. 3. Short-term kinetic experiments showed over 80% of the total (14)C present in the soluble fraction from the cells to be in glycine and serine after 10s. This percentage decreased with time whereas the percentage radioactivity in glycerate increased for up to 30s then remained steady. The percentage of the total radioactivity present in citrate increased over the experimental period. Malate was the only other tricarboxylic acid-cycle intermediate to become labelled. 4. The kinetic and inhibitor experiments supported the following pathway of glycollate incorporation: glycollate --> glyoxylate --> glycine --> serine --> hydroxypyruvate --> glycerate --> 3-phosphoglycerate --> 2-phosphoglycerate --> phosphoenolpyruvate --> pyruvate --> acetyl-CoA. 5. The specific activities of the enzymes catalysing this metabolic sequence in cell-free extracts were great enough to account for the observed rate of glycollate metabolism of 0.25mumol/h per mg dry wt. of cells in the light.
摘要
- 外源乙醇酸在光照和黑暗条件下均能被光合自养生长的小球藻迅速代谢。2. 这些细胞对[1-(14)C]乙醇酸中(14)C的掺入受到三羧酸循环抑制剂单氟乙酸、二乙基丙二酸和亚砷酸盐的抑制,也受到α-羟基吡啶-2-基甲磺酸盐和异烟酰肼的抑制。3. 短期动力学实验表明,10秒后细胞可溶性部分中总(14)C的80%以上存在于甘氨酸和丝氨酸中。该百分比随时间下降,而甘油酸中的放射性百分比在长达30秒内增加,然后保持稳定。在实验期间,柠檬酸盐中总放射性的百分比增加。苹果酸是唯一另一种被标记的三羧酸循环中间产物。4. 动力学和抑制剂实验支持以下乙醇酸掺入途径:乙醇酸→乙醛酸→甘氨酸→丝氨酸→羟基丙酮酸→甘油酸→3-磷酸甘油酸→2-磷酸甘油酸→磷酸烯醇丙酮酸→丙酮酸→乙酰辅酶A。5. 在无细胞提取物中催化该代谢序列的酶的比活性足以解释在光照下观察到的细胞每毫克干重0.25μmol/h的乙醇酸代谢速率。
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