Conjugated polymers containing main chain azoarene repeat units are synthesized by a dinickel catalyzed N=N coupling reaction of aromatic diazides. The polymerization exhibits broad substrate scope and is compatible with heterocycles commonly featured in high performance organic materials, including carbazole, thiophene, propylenedioxythiophene (ProDOT), diketopyrrolopyrrole (DPP), and isoindigo. Copolymerizations can be carried out using monomer mixtures, and monoazide chain stoppers can be used to install well-defined end groups. Azopolymers possess unique properties owing to the functionality of the azo linkages. For example, protonation at nitrogen results in LUMO lowering and red-shifted absorption bands. Additionally, N=N bonds possess low-lying π* levels, allowing azopolymers to be reversibly reduced under mild conditions.
Fatty acid biosynthetic enzymes exploit the reactivity of acyl- and malonyl-thioesters for catalysis. Here we synthesize acetyl/malonyl-CoA analogs with esters or amides in place of the thioester and characterize their behavior as substrates or inhibitors of the E. coli FabH ketosynthase. The acetyl- and malonyl-oxa(dethia)CoA analogs undergo extremely slow hydrolysis in the presence of FabH or C112Q mutant, which mimics the acyl-enzyme intermediate. Decarboxylation of malonyl-oxa(dethia)CoA by FabH or C112Q mutant was not detected. The amide analogs were completely stable to enzyme activity as expected. In enzyme assays, acetyl-oxa(dethia)CoA is surprisingly slightly activating, while acetyl-aza(dethia)CoA is a moderate inhibitor. The malonyl-oxa/aza(dethia)CoAs are inhibitors with Ki’s near the Km of malonyl-CoA. For comparison, we determine the FabH catalyzed decomposition rates for acetyl/malonyl-CoA, revealing some fundamental catalytic traits of FabH. The stable and inhibitory properties of the substrate analogs makes them promising for structure-function studies to undercover the basis of FabH cooperativity and enzyme:substrate interactions.
Fatty acid and polyketide biosynthetic enzymes exploit the reactivity of acyl- and malonyl-thioesters for catalysis. A prime example is FabH, which initiates fatty acid biosynthesis in many bacteria and plants. FabH performs an acyltransferase reaction with acetyl-CoA to generate an acetyl-S-FabH acyl-enzyme intermediate and subsequent decarboxylative Claisen-condensation with a malonyl-thioester carried by an acyl carrier protein (ACP). We envision that crystal structures of FabH with substrate analogues can provide insight into the conformational changes and enzyme/substrate interactions underpinning the distinct reactions. Here, we synthesize acetyl/malonyl-CoA analogues with esters or amides in place of the thioester and characterize their stability and behavior as Escherichia coli FabH substrates or inhibitors to inform structural studies. We also characterize the analogues with mutant FabH C112Q that mimics the acyl-enzyme intermediate allowing dissection of the decarboxylation reaction. The acetyl- and malonyl-oxa(dethia)CoA analogues undergo extremely slow hydrolysis in the presence of FabH or the C112Q mutant. Decarboxylation of malonyl-oxa(dethia)CoA by FabH or C112Q mutant was not detected. The amide analogues were completely stable to enzyme activity. In enzyme assays with acetyl-CoA and malonyl-CoA (rather than malonyl-ACP) as substrates, acetyl-oxa(dethia)CoA is surprisingly slightly activating, while acetyl-aza(dethia)CoA is a moderate inhibitor. The malonyl-oxa/aza(dethia)CoAs are inhibitors with K i’s near the K m of malonyl-CoA. For comparison, we determine the FabH catalyzed decomposition rates for acetyl/malonyl-CoA, revealing some fundamental catalytic traits of FabH, including hysteresis for malonyl-CoA decarboxylation. The stability and inhibitory properties of the substrate analogues make them promising for structure–function studies to reveal fatty acid and polyketide enzyme/substrate interactions.
Acetyl-CoA is a reactive metabolite that non-productively hydrolyzes in a number of enzyme active sites on the crystallization time frame. In order to elucidate enzyme:acetyl-CoA interactions leading to catalysis, acetyl-CoA substrate analogs are needed. One possible analog for use in structural studies is acetyl-oxa(dethia)CoA (AcOCoA), where the thioester sulfur of CoA is replaced by an oxygen. Here we present structures of chloramphenicol acetyltransferase III (CATIII) and E. coli ketoacylsynthase III (FabH) from crystals grown in the presence of partially hydrolyzed AcOCoA and the respective nucleophile. Based on the structures, the behaviour of AcOCoA differs between the enzymes, with FabH reacting with AcOCoA and CATIII being unreactive. The structure of CATIII reveals insight into the catalytic mechanism, with one active site of the trimer having relatively clear electron density for AcOCoA and chloramphenicol, and the other active sites having weaker density for AcOCoA. One FabH structure has a hydrolyzed AcOCoA product oxa(dethia)CoA (OCoA) and the other FabH structure has an acyl-enzyme intermediate with OCoA. Together these structures provide preliminary insight into the use of AcOCoA for enzyme structure-function studies with different nucleophiles.
Acetyl coenzyme A (acetyl-CoA) is a reactive metabolite that nonproductively hydrolyzes in a number of enzyme active sites in the crystallization time frame. In order to elucidate the enzyme–acetyl-CoA interactions leading to catalysis, acetyl-CoA substrate analogs are needed. One possible analog for use in structural studies is acetyl-oxa(dethia)CoA (AcOCoA), in which the thioester S atom of CoA is replaced by an O atom. Here, structures of chloramphenicol acetyltransferase III (CATIII) and Escherichia coli ketoacylsynthase III (FabH) from crystals grown in the presence of partially hydrolyzed AcOCoA and the respective nucleophile are presented. Based on the structures, the behavior of AcOCoA differs between the enzymes, with FabH reacting with AcOCoA and CATIII being unreactive. The structure of CATIII reveals insight into the catalytic mechanism, with one active site of the trimer having relatively clear electron density for AcOCoA and chloramphenicol and the other active sites having weaker density for AcOCoA. One FabH structure contains a hydrolyzed AcOCoA product oxa(dethia)CoA (OCoA), while the other FabH structure contains an acyl-enzyme intermediate with OCoA. Together, these structures provide preliminary insight into the use of AcOCoA for enzyme structure–function studies with different nucleophiles.
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