Abstract
A unique conformation of deoxynucleoside triphosphate substrates bound to Escherichia coli DNA polymerase I has been determined by nuclear magnetic resonance techniques. The effects of Mn(II) bound at the active site of the enzyme on the longitudinal (T1p-1) and transverse (T2p-1) relaxation rates of the alpha, beta, and gamma phosphorus atoms and 5 protons of enzyme-bound thymidine 5'-triphosphate (dTTP) were measured at 40.5 MHz (31P), 100 and 220 MHz (1H). From frequency dependence of T1p-1, a correlation time of 7 X 10(-10) s and Mn(II) to proton distances of 10.4, 9.9, 10.3, 10.8, and 8.4 A were calculated for the --CH3, H6, H'1, H'2, and H'4 protons. The calculated Mn(II) to phosphorus distances of 4.2, 4.8, and 3.2 A for the alpha, beta, and gamma phosphorus atoms indicates that Mn(II) corrdinates directly only with the gamma-phosphoryl group and that a puckered triphpsphate conformation exists for the enzyme-bound dTTP. This differs from the binary Mn(II)-dTTP complex in which alpha, beta, and gamma phosphoryl coordination occurs, and a thymine-deoxyribose torsion angly (chi) about the glycosidic bond of 40 degrees is detected. The eight manganese-substrate distances on the enzyme are fit by a unique Mn-dTTP conformation, with a torsion angle equal to 90 degrees, indistinguishable from that found for a deoxynucleotidyl unit in double helical DNA-B. Hence, binding to DNA polymerase appears to adjust the conformation of dTTP for Watson-Crick basepairing. Similarly, the binding of Mn-dATP to DNA polymerase I increased the distances from Mn(II) to the H2, H8, H'1, and H'4 protons of dATP but the adenine-deoxyribose torsion angle of 90 degrees was preserved. Such preorientation of substrates could facilitate incorporation of the complementary nucleotide. When positioned within the DNA structure, the conformation of enzyme-bound Mn-dTTP requires an inline nucleophilic attack on the alpha phosphorus with Mn(II) promoting pyrophosphate departure.
Highlights
A unique conformation of deoxynucleoside triphosphate substrates bound to Escherichia coli DNA polymerase I has been determined by nuclear magnetic resonance techniques
In order to determine more directly the role of the bound divalent cation cofactor and the conformation of the deoxynucleotide substrate at the active site, we have studied the interaction of the Mn(I1) complex of homogeneous E. coli DNA polymerase I with thymidine 5’-triphosphate by ‘H and 31P magnetic relaxation measurements of dTTP
The 50” change in the thymine-deoxyribose torsional angle to a value (x = 90”) appropriate for base-pairing when Mn(I1). dTTP binds to polymerases from E. coli (Pol I) (Fig. 4) may well be an error-preventing mechanism
Summary
A unique conformation of deoxynucleoside triphosphate substrates bound to Escherichia coli DNA polymerase I has been determined by nuclear magnetic resonance techniques. In order to determine more directly the role of the bound divalent cation cofactor and the conformation of the deoxynucleotide substrate at the active site, we have studied the interaction of the Mn(I1) complex of homogeneous E. coli DNA polymerase I with thymidine 5’-triphosphate (dTTP) by ‘H and 31P magnetic relaxation measurements of dTTP. This technique, introduced in 1967 [5], is a standard method for characterizing the conformations of enzyme-bound coenzymes and substrates in solution, yielding results in accord with crystallographic data [5,6,7,8,9]. This conformation of enzymebound Mn(I1) .dTTP, despite the absence of template, is indistinguishable from that of a thymidylate unit in the Watson-
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