Two mutant forms of fumarase C from E. coli have been made using PCR and recombinant DNA. The recombinant form of the protein included a histidine arm on the C-terminal facilitating purification. Based on earlier studies, two different carboxylic acid binding sites, labeled A- and B-, were observed in crystal structures of the wild type and inhibited forms of the enzyme. A histidine at each of the sites was mutated to an asparagine. H188N at the A-site resulted in a large decrease in specific activity, while the H129N mutation at the B-site had essentially no effect. From the results, we conclude that the A-site is indeed the active site, and a dual role for H188 as a potential catalytic base is proposed. Crystal structures of the two mutant proteins produced some unexpected results. Both mutations reduced the affinity for the carboxylic acids at their respective sites. The H129N mutant should be particularly useful in future kinetic studies because it sterically blocks the B-site with the carboxyamide of asparagine assuming the position of the ligand's carboxylate. In the H188N mutation at the active site, the new asparagine side chain still interacts with an active site water that appears to have moved slightly as a result of the mutation.
Two artificial transaminases were assembled by linking a pyridoxamine derivative within an engineered fatty acid binding protein. The goal of mimicking a native transamination site by stabilizing a cationic pyridoxamine ring system was approached using two different strategies. First, the scaffold of intestinal fatty acid binding protein (IFABP) was tailored by molecular modeling and site-directed mutagenesis to position a carboxylate group close to the pyridine nitrogen of the cofactor. When these IFABP mutants (IFABP-V60C/L38K/E93E and -V60C/E51K/E93E) proved to be unstable, a second approach was explored. By N-methylation of the pyridoxamine, a cationic cofactor was created and tethered to Cys60 of IFABP-V60C/L38K and -V60C/E51K; this latter strategy had the effect of permanently installing a positive charge on the cofactor. These chemogenetic assemblies catalyze the transamination between alpha-ketoglutarate and various amino acids with enantioselectivities of up to 96% ee. The pH profile of the initial rates is bell shaped and similar to native aminotransferases. The k(cat) values and the turnover numbers for these new constructs are the highest achieved to date in our system. This success was only made possible by the unique flexibility of the underlying enzyme design concept employed, which permits full control of both the protein scaffold and the catalytically active group.
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