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硫杆菌菌株C对[35S]硫代硫酸盐的氧化作用

[35S]thiosulphate oxidation by Thiobacillus strain C.

作者信息

Kelly D P, Syrett P J

出版信息

Biochem J. 1966 Feb;98(2):537-45. doi: 10.1042/bj0980537.

DOI:10.1042/bj0980537
PMID:5941348
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1264875/
Abstract
  1. Thiobacillus strain C oxidized [(35)S]thiosulphate completely to sulphate. 2. During thiosulphate oxidation [(35)S]sulphate was formed more rapidly from (S.(35)SO(3))(2-) than from ((35)S.SO(3))(2-). (35)S disappeared less rapidly from thiosulphate with ((35)S.SO(3))(2-) as substrate than with (S.(35)SO(3))(2-). 3. Thiosulphate labelled in both atoms was produced during ((35)S.SO(3))(2-) oxidation, but not during (S.(35)SO(3))(2-) oxidation. 4. No (35)S was precipitated as elementary sulphur either in the presence or absence of exogenous unlabelled sulphur. 5. During [(35)S]thiosulphate oxidation, appreciable quantities of [(35)S]trithionate accumulated and later disappeared. Other polythionates did not accumulate consistently. 6. [(35)S]Trithionate was formed initially at a greater rate from (S.(35)SO(3))(2-) than from ((35)S.SO(3))(2-), but subsequently at a similar rate from each. 7. Trithionate formed from (S.(35)SO(3))(2-) was labelled only in the oxidized sulphur atoms, but that formed from ((35)S.SO(3))(2-) was labelled in both oxidized and reduced atoms. The proportion of (35)S in the oxidized atoms increased as more trithionate accumulated. 8. The results eliminate some mechanisms of trithionate formation but are consistent both with a mechanism of thiosulphate oxidation based on an initial reductive cleavage of the molecule and with a mechanism in which thiosulphate undergoes an initial oxidative reaction.
摘要
  1. 硫杆菌菌株C将[³⁵S]硫代硫酸盐完全氧化为硫酸盐。2. 在硫代硫酸盐氧化过程中,(S.³⁵SO₃)²⁻比(³⁵S.SO₃)²⁻更快地形成[³⁵S]硫酸盐。以(³⁵S.SO₃)²⁻为底物时,硫代硫酸盐中³⁵S的消失速度比以(S.³⁵SO₃)²⁻为底物时慢。3. 在(³⁵S.SO₃)²⁻氧化过程中产生了两个原子都被标记的硫代硫酸盐,但在(S.³⁵SO₃)²⁻氧化过程中未产生。4. 无论是否存在外源未标记的硫,都没有³⁵S沉淀为单质硫。5. 在[³⁵S]硫代硫酸盐氧化过程中,大量的[³⁵S]连三硫酸盐积累,随后消失。其他多硫代酸盐没有持续积累。6. [³⁵S]连三硫酸盐最初由(S.³⁵SO₃)²⁻形成的速率比由(³⁵S.SO₃)²⁻形成的速率更快,但随后两者的形成速率相似。7. 由(S.³⁵SO₃)²⁻形成的连三硫酸盐仅在氧化的硫原子中被标记,但由(³⁵S.SO₃)²⁻形成的连三硫酸盐在氧化和还原的原子中都被标记。随着连三硫酸盐积累增多,氧化原子中³⁵S的比例增加。8. 这些结果排除了一些连三硫酸盐形成的机制,但与基于分子初始还原裂解的硫代硫酸盐氧化机制以及硫代硫酸盐经历初始氧化反应的机制均一致。

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[Biochemistry of autotrophic sulfur bacteria. IV. Studies on sulfur metabolism in Thiobaciilus thioparus with S35].[自养硫细菌的生物化学。IV. 用S³⁵对排硫硫杆菌硫代谢的研究]
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