A1 Vertaisarvioitu alkuperäisartikkeli tieteellisessä lehdessä
Structure and enzymatic mechanism of a moonlighting dUTPase
Tekijät: Leveles I, Nemeth V, Szabo JE, Harmat V, Nyiri K, Bendes AA, Papp-Kadar V, Zagyva I, Rona G, Ozohanics O, Vekey K, Toth J, Vertessy BG
Kustantaja: INT UNION CRYSTALLOGRAPHY
Julkaisuvuosi: 2013
Journal: Acta crystallographica section D : structural biology
Tietokannassa oleva lehden nimi: ACTA CRYSTALLOGRAPHICA SECTION D-STRUCTURAL BIOLOGY
Lehden akronyymi: ACTA CRYSTALLOGR D
Vuosikerta: 69
Aloitussivu: 2298
Lopetussivu: 2308
Sivujen määrä: 11
ISSN: 2059-7983
DOI: https://doi.org/10.1107/S0907444913021136
Tiivistelmä
Genome integrity requires well controlled cellular pools of nucleotides. dUTPases are responsible for regulating cellular dUTP levels and providing dUMP for dTTP biosynthesis. In Staphylococcus, phage dUTPases are also suggested to be involved in a moonlighting function regulating the expression of pathogenicity-island genes. Staphylococcal phage trimeric dUTPase sequences include a specific insertion that is not found in other organisms. Here, a 2.1 angstrom resolution three-dimensional structure of a phi 11 phage dUTPase trimer with complete localization of the phage-specific insert, which folds into a small beta-pleated mini-domain reaching out from the dUTPase core surface, is presented. The insert mini-domains jointly coordinate a single Mg2+ ion per trimer at the entrance to the threefold inner channel. Structural results provide an explanation for the role of Asp95, which is suggested to have functional significance in the moonlighting activity, as the metal-ion-coordinating moiety potentially involved in correct positioning of the insert. Enzyme-kinetics studies of wild-type and mutant constructs show that the insert has no major role in dUTP binding or cleavage and provide a description of the elementary steps (fast binding of substrate and release of products). In conclusion, the structural and kinetic data allow insights into both the phage-specific characteristics and the generally conserved traits of phi 11 phage dUTPase.
Genome integrity requires well controlled cellular pools of nucleotides. dUTPases are responsible for regulating cellular dUTP levels and providing dUMP for dTTP biosynthesis. In Staphylococcus, phage dUTPases are also suggested to be involved in a moonlighting function regulating the expression of pathogenicity-island genes. Staphylococcal phage trimeric dUTPase sequences include a specific insertion that is not found in other organisms. Here, a 2.1 angstrom resolution three-dimensional structure of a phi 11 phage dUTPase trimer with complete localization of the phage-specific insert, which folds into a small beta-pleated mini-domain reaching out from the dUTPase core surface, is presented. The insert mini-domains jointly coordinate a single Mg2+ ion per trimer at the entrance to the threefold inner channel. Structural results provide an explanation for the role of Asp95, which is suggested to have functional significance in the moonlighting activity, as the metal-ion-coordinating moiety potentially involved in correct positioning of the insert. Enzyme-kinetics studies of wild-type and mutant constructs show that the insert has no major role in dUTP binding or cleavage and provide a description of the elementary steps (fast binding of substrate and release of products). In conclusion, the structural and kinetic data allow insights into both the phage-specific characteristics and the generally conserved traits of phi 11 phage dUTPase.
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