AMP and NaF each taken separately were shown to activate DNA polymerization catalyzed by Klenow fragment of DNA polymerase I by means of interaction of AMP or NaF with 3'----5'-exonuclease center of the enzyme. In the presence of NaF which is a selective inhibitor of 3'----5'-exonuclease center, AMP is an inhibitor of polymerization competitive with respect to dATP. Ki values and the pattern of inhibition with respect to dATP were determined for AMP, ADP, ATP, carboxymethylphosphonyl-5'-AMP, Pi, PPi, PPPi, methylenediphosphonic acid and its ethylated esters, phosphonoformic acid, phosphonoacetic acid and its ethylated esters as well as for some bicarbonic acids in the reactions of DNA polymerization catalyzed by Klenow fragment of DNA polymerase I (in the presence of NaF) and DNA polymerase alpha from human placenta in the presence of poly(dT) template and r(pA)10 primer. All nucleotides and their analogs were found to be capable of competing with dATP for the active center of the enzyme. Most of the analogs of PPi and phosphonoacetic acid are inhibitors of Klenow fragment competitive with respect to dATP. Nowever these analogs display a mixed-type inhibition in the case of human DNA polymerase alpha. We postulated a similar mechanism of interaction for dNTP with both DNA-polymerases. It is suggested that each phosphate group of PPi makes equal contribution to the interaction with DNA polymerases and that the distance between the phosphate groups is important for this interaction. beta-phosphate of NTP or dNTP is suggested to make negligible contribution to the efficiency of the formation of enzyme complexes with dNTP. beta-phosphate is likely to be an essential point of PPi interaction with the active center of proteins during the cleavage of the alpha-beta-phosphodiester bond of dNTP in the reaction of DNA polymerization.