NADH-dependent O-deethylation of p-nitrophenetole with rabbit liver microsomes.

A previous paper in this series (C. K. Mathews, (1972) J. Biol. Chem.247, 7430) showed that deoxynucleoside triphosphate pools expand manyfold when DNA synthesis is blocked genetically in infection by bacteriophage T4. This paper describes a more detailed analysis of this phenomenon. The key approach involves labeling with thymine or thymidine under conditions of infection where both phage and host bear mutations that inactivate thymidylate synthetase. Principal findings include the following: (1) Nucleotides in the expanded pools are derived in roughly equal measure from breakdown of host cell DNA and from nucleotide synthesis de novo after infection. (2) Thymidine diphosphate pool expansion is comparable, in rate and extent, to thymidine triphosphate pool expansion, but thymidine monophosphate pools accumulate much less. (3) The rate of expansion of the total thymine nucleotide pool following temperature upshift in infection by a temperature-sensitive gene 45 mutant is approximately equal to the rate of thymine incorporation into DNA immediately preceding the upshift. (4) Similarly, when DNA synthesis is restored by a downshift, the total thymine nucleotide pool drains at a rate commensurate with that of thymine incorporation into DNA. (5) Under these latter conditions the dTTP pool begins to drain earlier than the dTDP pool, suggesting that dTTP is the more proximal DNA precursor in this system.