DNA-polymerase alpha from human placenta. Effectiveness of interaction between oligothymidylates of different lengths and the template-binding site

Modification of human placenta DNA polymerase alpha by (pT)2pC[Pt2 + (NH3)2OH].(pT)7 was investigated. The linear time dependence of the enzyme activity logarithm suggested a pseudo-first order for modification. Kd value of enzyme-affinity reagent complex (0.5 microM) was estimated. The enzyme inactivation by the affinity reagent and protection from inactivation in the presence of oligonucleotides of varying length were used for determining Kd values of the enzyme-ligand complexes. Oligonucleotide d(pT)2pC(pT)7 (Kd 0.15 microM), d(Tp)9T (Kd 0.15 microM) and [d(Tp)9]ddT (Kd 0.15 microM) protected the enzyme from inactivation with equal efficiency. The protective action of oligothymidylates d(Tp)nT (where n changes from 3 to 14) strongly depended on the chain length, the Kd values diminishing from 5.3 to 0.0091 microM in the geometrical progression. The addition of one link to the oligothymidylate chain resulted in 1.71-fold increase in the oligonucleotide affinity for the enzyme specific site. Such a change corresponds to Gibbs energy change of about 0.32 kcal/mole. It is supposed that the monomer units of pentadecathymidylate (at least beginning with the third one) in d(Tp)14T-enzyme complex form neither hydrogen bonds nor electrostatic linkages with the enzyme. Kd values of oligonucleotides as templates are shown to reflect quite well the true affinity of template for the enzyme. This affinity increases in the presence of a primer. However, the ratio of the affinity for different oligonucleotides does not change in the presence or absence of a complementary primer.     

Utilization of ribonucleotides and RNA primers by Tetrahymena telomerase.

Telomerase is a ribonucleoprotein (RNP) DNA polymerase involved in telomere synthesis. A short sequence within the telomerase RNA component provides a template for de novo addition of the G-rich strand of a telomeric simple sequence repeat onto chromosome termini. In vitro, telomerase can elongate single-stranded DNA primers processively: one primer can be extended by multiple rounds of template copying before product dissociation. Telomerase will incorporate dNTPs or ddNTPs and will elongate any G-rich, single-stranded primer DNA. In this report, we show that Tetrahymena telomerase was able to incorporate a ribonucleotide, rGTP, into product polynucleotide. Synthesis of the product [d(TT)r(GGGG)]n was processive, suggesting that the chimeric product remained associated with the enzyme both at the active site and at a second, previously characterized, template-independent product binding site. As predicted by this finding, RNA-containing oligonucleotides served as primers for elongation. More than 3 nt of RNA at a primer 3' end decreased the quantity of product synthesis but increased the affinity of the primer for telomerase. Thus, RNA-containing primers were effective as competitive inhibitors of DNA primer elongation by telomerase. These results support the possible evolutionary origin of telomerase as an RNA-dependent RNA polymerase.     

Primer-mediated inhibition of the hydrolysis of template DNA by T5-induced DNA polymerase.

Bacteriophage T5-induced DNA polymerase has an associated 3′→5′ exonuclease activity for which both single-stranded and duplex DNA serve as substrate (1). In this report, we demonstrate that hydrolysis of single-stranded DNA homopolymers (template) is inhibited in the presence of complementary (Watson-Crick sense) oligonucleotides (primer). Almost complete inhibition is observed at a primer/template ratio of ? 0.1. Formation of “H-bonded” primer-template complex seems to be necessary for the inhibition of template hydrolysis because (a) similar amounts of noncomplementary oligonucleotides have no detectable effect on the rate of template hydrolysis, and (b) complementary oligonucleotides lose their inhibitory potential at temperatures where the H-bonded primer-template complex is expected to be unstable. From our data, it appears that the inhibition of template hydrolysis in the presence of primer molecules is due to the preferential binding of the enzyme at the 3′-OH terminus of the primer in the primer-template complex.     

Template specific inhibitor of mammalian DNA polymerases.

A study of the inhibition of mouse cellular DNA polymerases by poly-nucleotides and their vinyl analogs is presented. Poly(dT)-directed poly(dA) synthesis by representatives of all three classes of cellular DNA polymerase could be completely inhibited by poly(9-vinyladenine), although higher concentrations were required in the case of the gamma class enzyme. Studies on the mechanism of the inhibition using the alpha class DNA polymerase and different templates showed that the enzyme activity was inhibited in all cases where base-pairing between the vinyl polymer and the template occurred; poly(9-vinyladenine) did not interfere with the replication of templates to which it does not bind. The inhibition occurred shortly after addition of poly(9-vinyladenine) to ongoing reactions, yet the enzyme was not displaced from the template - primer complex.     

Partial purification and characterization of poly(dC)-dependent DNA polymerase and its stimulating factor

Poly(dC)-dependent dGMP incorporating activity without a primer molecule and its stimulating factor were partially purified by successive column chromatographies. Polymerase activity that was highly dependent on the stimulating factor was separated from similar activity that was not stimulated by this factor by native DNA-cellulose column chromatography. The factor stimulating activity was strictly dependent on dGTP as substrate and incorporated dGMP into the 3′-OH terminus of poly(dC). However, no terminal deoxynucleotidyl transferase (EC 2.7.7.31) activity was detected in the preparation. The activity also responded to heat-denatured calf thymus DNA and poly(dT) as template, although to a lesser extent. The activity was inhibited by dideoxyGTP and N-ethylmaleimide, and was decreased significantly by aphidicolin and β-lapachon.