Mechanism of Product Chain Length Determination and the Role of a Flexible Loop in Escherichia coli Undecaprenyl-pyrophosphate Synthase Catalysis

The Escherichia coli undecaprayl-pyrophosphate synthase (UPPs) structure has been solved using the single wavelength anomalous diffraction method. The putative substrate-binding site is located near the end of the βA-strand with Asp-26 playing a critical catalytic role. In both subunits, an elongated hydrophobic tunnel is found, surrounded by four β-strands (βA-βB-βD-βC) and two helices (α2 and α3) and lined at the bottom with large residues Ile-62, Leu-137, Val-105, and His-103. The product distributions formed by the use of the I62A, V105A, and H103A mutants are similar to those observed for wild-type UPPs. Catalysis by the L137A UPPs, on the other hand, results in predominantly the formation of the C₇₀ polymer rather than the C₅₅ polymer. Ala-69 and Ala-143 are located near the top of the tunnel. In contrast to the A143V reaction, the C₃₀ intermediate is formed to a greater extent and is longer lived in the process catalyzed by the A69L mutant. These findings suggest that the small side chain of Ala-69 is required for rapid elongation to the C₅₅ product, whereas the large hydrophobic side chain of Leu-137 is required to limit the elongation to the C55 product. The roles of residues located on a flexible loop were investigated. The S71A, N74A, or R77A mutants displayed 25-200-fold decrease in k_cat values. W75A showed an 8-fold increase of the FPP K_m value, and 22-33-fold increases in the IPP K_m values were observed for E81A and S71A. The loop may function to bridge the interaction of IPP with FPP, needed to initiate the condensation reaction and serve as a hinge to control the substrate binding and product release.