The molecular mechanism of substrate analogue interaction with Escherichia coli dUTPase was investigated, using the non-hydrolyzableBinding of this analogue induces a difference in the far UV circular dichroism (CD) spectrum arguing for a significant change in protein conformation. The spectral shift is strictly Mg 2+ -dependent, does not appear with dUDP instead of K K,L L-imido-dUTP and is not elicited if the flexible C-terminal arm is deleted from the protein by limited tryptic digestion. Involvement of the C-terminal arm in K K,L Limido-dUTP binding is consistent with the finding that this analogue protects against tryptic hydrolysis at Arg-141. Near UV CD of ligand-enzyme complexes reveals a characteristic difference in the microenvironments of enzyme-bound dUDP and K K,L L-imido-dUTP, a difference not observable in C-terminally truncated dUTPase. The results suggest that (i) closing of the active site during the catalytic cycle, through the movement of the C-terminal arm, requires the presence of the complete triphosphate moiety of the substrate in complex with Mg 2+ , and (ii) after catalytic cleavage the active site pops open to facilitate product release.z 1998 Federation of European Biochemical Societies.
Prevention of incorporation of dUTP into DNA is essential for maintenance of the genetic information. Prompt and specific removal of dUTP from the nucleotide pool, as expedited by the ubiquitous enzyme dUTPase, is therefore required for full viability in most biological systems. Conserved structural features perpetuate specificity in choice of substrate, which is crucial as hydrolysis of the structurally closely related nucleotides dTTP, dCTP and UTP would debilitate DNA and RNA synthesis. The most common family of dUTPases is the homotrimeric variety where X-ray structures are available for one bacterial, one mammalian and two retroviral dUTPases. These four enzymes have similar overall structural layouts, but the interactions that stabilise the trimer vary markedly, ranging from exclusively hydrophobic to water-mediated interactions. Trimeric dUTPases contain five conserved sequence motifs, positioned at the subunit interfaces where they contribute to the formation of the active sites. Each of the three identical active sites per trimer is built of residues contributed by all three subunits. One subunit provides residues involved in base and sugar recognition, where a beta-hairpin acts to maintain exquisite selectivity, while a second subunit contributes residues for phosphate interactions. The third subunit supplies a glycine-rich consensus motif located in the flexible C-terminal part of the subunit, known from crystallographic studies to cover the active site in the presence of substrate and certain substrate analogues. All dUTPases studied require the presence of a divalent metal ion, preferably Mg(2+), for optimal activity. The putative position of the essential metal ion has been identified in the structure of one retroviral dUTPase. Structure-function studies are essential if the properties of dUTPases are to be understood fully in relation to their biological role. In this review the structural arrangement of the homotrimeric dUTPases is discussed in the context of active site geometry, achievement of specificity and subunit interactions.
Cryocooled crystals of a mercury complex of Escherichia coli dUTPase diffract to atomic resolution. Data to 1.05 A resolution were collected from a derivative crystal and the structure model was derived from a Fourier map with phases calculated from the coordinates of the Hg atom (one site per subunit of the trimeric enzyme) using the program ARP/wARP. After refinement with anisotropic temperature factors a highly accurate model of the bacterial dUTPase was obtained. Data to 1.45 A from a native crystal were also collected and the 100 K structures were compared. Inspection of the refined models reveals that a large part of the dUTPase remains rather mobile upon freezing, with 14% of the main chain being totally disordered and with numerous side chains containing disordered atoms in multiple discrete conformations. A large number of those residues surround the active-site cavity. Two glycerol molecules (the cryosolvent) occupy the deoxyribose-binding site. Comparison between the native enzyme and the mercury complex shows that the active site is not adversely affected by the binding of mercury. An unexpected effect seems to be a stabilization of the crystal lattice by means of long-range interactions, making derivatization a potentially useful tool for further studies of inhibitor-substrate-analogue complexes of this protein at very high resolution.
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