The genome encodes multiple bifunctional enzymes, such as DapF, which is capable of both diaminopimelic acid (DAP) epimerase and glutamate racemase activity. Our previous work demonstrated the bifunctional activity of chlamydial DapF and in a heterologous system (). In the present study, we employed a substrate competition strategy to demonstrate DapF function in We reasoned that, because DapF utilizes a shared substrate-binding site for both racemase and epimerase activities, only one activity can occur at a time. Therefore, an excess of one substrate relative to another must determine which activity is favored. We show that the addition of excess l-glutamate or -DAP (DAP) to resulted in 90% reduction in bacterial titers, compared to untreated controls. Excess l-glutamate reduced synthesis of DAP by to undetectable levels, thus confirming that excess racemase substrate led to inhibition of DapF DAP epimerase activity. We previously showed that expression of in a (racemase) Δ (epimerase) double mutant of rescues the d-glutamate auxotrophic defect. Addition of excess DAP inhibited growth of this strain, but overexpression of allowed the mutant to overcome growth inhibition. These results confirm that DapF is the primary target of these DAP and l-glutamate treatments. Our findings demonstrate that suppression of either the glutamate racemase or epimerase activity of DapF compromises the growth of Thus, a substrate competition strategy can be a useful tool for validation of an essential bifunctional enzyme.
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