The cyclodextrin-accelerated cleavage of thiocarboxylic S-esters.
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概要
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The effect of α- and β-cyclodextrins on the cleavage of the thiocarboxylic <I>S</I>-esters, <I>S</I>-<I>p</I>-nitrophenyl thioacetate (<B>1</B>) and <I>S</I>-ethyl <I>p</I>-nitrothiobenzoate (<B>3</B>), was compared with their effect on the cleavage of the corresponding oxygen esters, <I>p</I>-nitrophenyl acetate (<B>2</B>) and ethyl <I>p</I>-nitrobenzoate (<B>4</B>). The rate constants of α- or β-cyclodextrin-accelerated cleavage of <B>1</B> (1.5×10<SUP>−2</SUP> or 4.8×10<SUP>−2</SUP> s<SUP>−1</SUP> at pH 10.5, 25 °C) were almost identical with the values of <B>2</B> (1.6×10<SUP>−2</SUP> or 4.2×10<SUP>−2</SUP> s<SUP>−1</SUP>), definitely showing the rate-determining formation of tetrahedral intermediates. The cleavage of <B>3</B> was accelerated by α- and β-cyclodextrins, whereas the cleavage of <B>4</B> was decelerated by β-cyclodextrin but was not affected by α-cyclodextrin. The contrast in the effect of cyclodextrins on <B>3</B> and <B>4</B> was ascribed to the difference of the rate of breakdown of the tetrahedral intermediates to products, caused by different p<I>K</I>'s of the leaving groups of <B>3</B> (10.5) and <B>4</B> (16.0). The formation of tetrahedral intermediates confirmed in the cyclodextrinaccelerated hydrolyses of esters further strengthened the previous proposal that cyclodextrin is an excellent model of serine proteases, since these intermediates are also formed in enzymatic reactions.
- 公益社団法人 日本化学会の論文
著者
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Komiyama Makoto
Department Of Chemistry And Biotechnology Faculty Of Engineering The University Of Tokyo
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Bender Myron
Departments of Chemistry and Biochemistry, Northwestern University
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