Abstract
In methanogens, the acetyl-CoA decarbonylase synthase (ACDS) complex, which has five different subunits, catalyzes synthesis and cleavage of acetyl-CoA according to the reaction: CO2 + 2H+ + 2e- + CH3-H4SPt + CoA <--> acetyl-CoA + H4SPt + H2O, where H4SPt and CH3-H4SPt are tetrahydrosarcinapterin and N5-methyl-tetrahydrosarcinapterin, respectively. We have dissociated the ACDS complex into three protein components by limited proteolytic digestion. Catalysis of acetyl-CoA synthesis was lost in parallel with the loss of the intact beta subunit; however, no decrease in activity was detected in any of three partial reactions found to be catalyzed by distinct protein components of the proteolyzed ACDS complex: (a) CO dehydrogenase, catalyzed by the alpha epsilon component, (b) CH3-H4pteridine:cob(I)amide-protein methyltransferase, catalyzed by the intact gamma subunit and fragments of the delta subunit, and (c) acetyltransferase, catalyzed by a truncated form of the beta subunit. The results indicated that the beta subunit is responsible for binding CoA and acetyl-CoA and suggested that acetyl-enzyme formation occurs on the beta subunit. A value of 5.5 x [H+]-1 M-1 was determined for the equilibrium constant of the following reaction at pH 7.5 and 25 degrees C: CH3-H4SPt + cob(I)amide-protein + H+ <--> H4SPt + CH3-cob(III)amide-protein.
Highlights
In methanogens, the acetyl-CoA decarbonylase synthase (ACDS) complex, which has five different subunits, catalyzes synthesis and cleavage of acetyl-CoA according to the reaction: CO2 ؉ 2H؉ ؉ 2e؊ ؉ CH3-H4SPt ؉ CoA a acetyl-CoA ؉ H4SPt ؉ H2O, where H4SPt and CH3-H4SPt are tetrahydrosarcinapterin and N5-methyltetrahydrosarcinapterin, respectively
Catalysis of acetyl-CoA synthesis was lost in parallel with the loss of the intact  subunit; no decrease in activity was detected in any of three partial reactions found to be catalyzed by distinct protein components of the proteolyzed ACDS complex: (a) CO dehydrogenase, catalyzed by the ␣⑀ component, (b) CH3-H4pteridine:cob(I)amide-protein methyltransferase, catalyzed by the intact ␥ subunit and fragments of the ␦ subunit, and (c) acetyltransferase, catalyzed by a truncated form of the  subunit
The ability of limited proteolytic digestion to cause dissociation of the M. barkeri ACDS complex was investigated by reaction of the enzyme complex with chymotrypsin followed by anion-exchange chromatography
Summary
The acetyl-CoA decarbonylase synthase (ACDS) complex, which has five different subunits, catalyzes synthesis and cleavage of acetyl-CoA according to the reaction: CO2 ؉ 2H؉ ؉ 2e؊ ؉ CH3-H4SPt ؉ CoA a acetyl-CoA ؉ H4SPt ؉ H2O, where H4SPt and CH3-H4SPt are tetrahydrosarcinapterin and N5-methyltetrahydrosarcinapterin, respectively. The overall reaction of acetyl-CoA synthesis or cleavage may be divided into several possible partial reactions. One of these is CO:acceptor oxidoreductase (CO dehydrogenase). The multienzyme complex from Methanosarcina barkeri is composed of five different subunits, possibly arranged in an ␣66␥6␦6⑀6 structure with the individual subunits of molecular masses of 89, 60, 50, 48, and 20 kDa, respectively [3]. The complex contains CO:acceptor oxidoreductase, Co--methylcobamide:tetrahydropteridine methyltrans-
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