Determination of the Chemical Pathway for 4-Chlorobenzoate:Coenzyme A Ligase Catalysis

Abstract

4-Chlorobenzoate:coenzyme A ligase (4-CBA:CoA ligase) catalyzes the first step of the 4-CBA degradation pathway of Pseudomonas sp. strain CBS3. In this reaction, 4-CBA-CoA thioester synthesis is coupled to ATP cleavage. The studies described in this paper examine the intermediacy of 4-chlorobenzoyl−adenosine 5‘-phosphate diester (4-CBA-AMP) in the ligase reaction. The 4-CBA-AMP adduct was isolated from the ligase reaction mixture generated from magnesium adenosine 5-triphosphate (MgATP) and 4-CBA in the absence of CoA. The structure of the 4-CBA-AMP was verified by ¹H-, ¹³C-, and ³¹P-nuclear magnetic resonance analysis. Single-turnover reactions carried out with ¹⁴C-labeled 4-CBA in a rapid quench apparatus demonstrated formation of the enzyme·4-CBA-AMP·MgPP_i complex from the enzyme·4-CBA·MgATP complex at a rate of 135 s^-1. The rate of ligand release from the enzyme·4-CBA-AMP·MgPP_i complex was measured at 0.013 s^-1. Single-turnover reactions of [¹⁴C]-4-CBA, MgATP, and CoA catalyzed by the ligase revealed that the 4-CBA-AMP intermediate formed reaches a maximum level of 25% of the starting 4-CBA within 10 ms and then declines with the formation of the 4-CBA-CoA. The rates of the adenylation and thioesterification partial reactions, determined by kinetic simulation of the rate data, are nearly equal (135 and 100 s^-1). Substitution of CoA with the slow substrate pantetheine did not significantly alter the rate of the adenylation step but did reduce the rate of the thioesterification step to 2 s^-1. The maximum level of 4-CBA-AMP reached during the single-turnover reaction of 4-CBA, MgATP, and pantetheine corresponded to one-half of the starting 4-CBA.