Eukaryotic and prokaryotic DNA-polymerase. II. The role of internucleotide phosphate groups of a template in its binding with the enzyme

The affinity of different ligands (phosphate, nucleoside monophosphates, oligonucleotides) to the template binding site of DNA polymerase alpha from human placenta was estimated. To this goal, dependences of rate of the enzyme inactivation by the affinity reagent d(pT)2pC[Pt2+(NH3)2OH](pT)7 on the concentration of these ligands as competitive inhibitors were determined. Minimal ligands capable to bind with the template site of DNA polymerase alpha were shown to be triethylphosphate (Kd 600 microM) and phosphate (Kd 53 microM). Ligand affinity increases by the factor 1.71 per added monomer unit from phosphate to d(pT) and then for oligothymidylates d(Tp)nT (n 1 to 14). The partial ethylation of phosphodiester groups does not change the efficiency of the oligothymidylate binding with the enzyme. However, the complete ethylation of these groups lowers affinity of the oligothymidylates to the enzyme by 7-9 times. The decrease is comparable with the change of Pt2+-decathymidylate affinity to the enzyme caused by Mn2+-ions. The data obtained led to suggestion that an electrostatic contact (most likely, Me2+-dependent) of phosphodiester group with the enzyme takes place. The type of contact is confirmed by Gibbs' energy change 1.1-1.4 kcal/mole. Formation of a hydrogen bond with the oxygen atom of P = O group of the same phosphate is also assumed (delta G =--4.4 . . .--4.5 kcal/mole). The other internucleotide phosphates and all bases of oligonucleotides form neither hydrogen bonds nor electrostatic contacts with the template binding site. Gibbs' energy changes by 0.32 kcal/mole when the template is lengthened by one unit. We suppose that this value characterizes the energy gain in the transition of oligonucleotide template from aquous medium to the hydrophobic environement of the enzyme active site. Comparison of Km values of oligothymidylates and their partially or completely ethylated analogues as templates in the reaction of DNA polymerization catalysed by DNA polymerase alpha from human placenta and Klenow's fragment of E. coli DNA polymerase I suggests a similar mechanism of template recognition by both enzymes.     

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.     

The mechanism of recognition of templates by DNA polymerases from pro- and eukaryotes as revealed by affinity modification data.

Pt(2+)-containing derivatives of oligodeoxyribonucleotides were used to evaluate the ligand affinity to the template sites of Klenow fragment of DNA polymerase I from E. coli and DNA polymerase alpha from human placenta. The values of Kd and Gibb's energy (delta G degree) for the complexes of oligodeoxyribonucleotides and their derivatives with the template sites of these enzymes were determined from the effects protecting the enzyme from inactivation by Pt(2+)-containing oligonucleotides. Kd and delta G degree values of the complexes made by DNA polymerases and orthophosphate, triethylphosphate, d(pC)n, d(pT)n, d(pG)n, d(pA)n (where n = 1-25), heterooligonucleotides of various length and structure, and oligothymidylates with partially and completely ethylated internucleotide phosphates were evaluated. The obtained data enabled us to suggest 19-20 mononucleotide units of the template to interact with the protein. Only one template internucleotide phosphate forms a Me(2+)-dependent electrostatic contact (delta G = -1.1...-1.7 kcal/mol) and a hydrogen bond (delta G = -4.4...-4.9 kcal/mol) with the enzyme. It is likely that the mononucleoside units of the template form hydrophobic contacts with the enzymes. The efficiency of such interaction changes with the hydrophobicity of the bases: C less than T less than G approximately A. For both homo- and heterooligonucleotides the contributions of nucleoside units to the affinity of the templates to the enzymes is due to the complementary interactions with the primers. A hypothetical model for the template-primer interaction with DNA polymerases is suggested.     

Role of nucleoside components and internucleotide phosphate groups of oligodeoxyribonucleotide template in its binding to human DNA polymerase alpha

Affinity labelling of human placenta DNA polymerase alpha (EC 2.7.7.7) with the reactive oligodeoxyribonucleotide d(pT)2pC[Pt2+(NH3)2OH](pT)7 was used for quantitative analysis of enzyme interaction with oligodeoxyribonucleotides as templates. Dissociation constants and Gibb's energy values for different oligothymidylates d(pT)nT where n = 1-14 have been evaluated by competitive experiments of these ligands with Pt2+ reagent. The data obtained prove the formation of one Me2+-dependent electrostatic contact and a hydrogen bond between the enzyme and one phosphate of these templates. One may suppose that the hydrophobic interaction of any other monomeric link of oligodeoxyribonucleotides with the enzyme template site takes place.     

E. coli DNA polymerase. A study of the mechanism of primer binding using oligothymidylate analogs with ethylated internucleotide phosphate groups

The following individual diastereomers of oligothymidylate ethyl esters (the alkyl phosphodiester group is asymmetric with R or S configuration) have been prepared: d[(Tr)8Tp'(Et)T] (I), d[(Tp)8Tp'(Et)T] (II), d[(Tp)8Tp'(Et)TpT] (III), d[(Tp)8Tp' X (Et)TpT] (IV). A totally esterified analogue d[[(Tp(Et)7]T] (V) was obtained as a diastereomeric mixture. All oligothymidylate derivatives revealed substrate activity as primers of DNA polymerase with poly(dA) as a template. The values of the maximal reaction rates were equal to 14; 2,6; 68; 24 and 0,1% for oligothymidylates (I)-(V) with respect to Vm value (100%) for (Tp)9T. Km values of oligothymidylates (I)-(V), 2,7; 2,5; 0,51; 7,2 microM, were obtained in relation to Km for d[(Tp)9T] (0,4 microM). Diastereomers (I) and (II) were not destroyed by Klenow fragment of DNA polymerase I which has only 3'----5' exonuclease activity. However, these derivatives were hydrolyzed by complete DNA polymerase I due to its 5'----3' exonuclease activity, the reaction rate being 3-10 times lower than in case of d[(Tp)9T]. The data suggest an essential contribution to the primer binding from the positive enzyme group interaction with the 3'-end negatively charged phosphate group of oligonucleotide, together with the primer complementary interaction with the template. At least two phosphodiester groups of the oligonucleotide primer are essential for the reaction of polymerization following the correct binding.     

Dependence of 3'-5-exonuclease activity of a fragment of Klenow DNA polymerase I from Escherichia coli on the length and structure of the cleaved oligonucleotide

The Km and vmax values for oligothymidylates d(pT)2-16 in reaction of 3'-5'-exonuclease hydrolysis catalyzed by Klenow fragment were measured in the absence and presence of poly(dA) template without the poly(dA), the Km values for oligonucleotides are slightly dependent on their length. The rate of oligothymidylates hydrolysis increases with their length and for d(pT)16 it is about 190-times higher than for d(pT)2. The addition on poly(dA) does not lead to an essential change of the Km values for d(pT)2-16, but raises the rate of d(pT)2-7 hydrolysis 2-17-fold and at the same time lowers the efficiency of d(pT)8-16 hydrolysis. The Km values for d(pC)10, d(pA)19 and d(pT)10 are nearly the same. However the velocity of d(pC)10 hydrolysis is approximately 1,2 and 7,8-times higher than for d(pA)10 and d(pC)10, respectively d(pC)10, d(pA)10 and d(pT)10 under conditions of interaction with the template-binding site raise the rate of hydrolysis of d(pT)2 combined with the exonuclease center, with various efficiency. Under similar conditions, d(pT)8, d(pT)10 and d(pT)16 as templates activated hydrolysis of d(pT)2. The dependence of the Klenow fragment exonuclease activity both on the length and structure of the template and on the length of the hydrolyzed oligonucleotide was suggested.     

Protein-nucleic acid interactions in reactions catalyzed by eukaryotic and prokaryotic DNA-polymerases

A new method of estimation of dissociation constants for ligands and free energies of its binding based on the affinity modification of active centers in the presence of competitive ligands was developed. This method is designed for the analysis of protein-nucleic acid interactions in template systems. Deoxyoligoribonucleotides containing the reactive residue of cis-aquadihydroxydiaminoplatinum (II) and oligonucleotides ethylated at phosphate groups were used for the study of interactions of human placental DNA-polymerase alpha and the Klenow fragment of DNA-polymerase I from E. coli with templates and primers. A model was constructed which postulates the formation of a single Me2+-dependent electrostatic bond and of a hydrogen bond by one of template phosphates with the enzyme active center. Similar bonds form the basis for the enzyme interaction with the 3'-terminal phosphate group of the primer. Other monomeric units of the template are likely to interact with the enzyme by forming hydrophobic bonds. Other mononucleotide units of the primer are involved in complementary interactions with the template. The primer activity of dNMP and NMP in these systems has been demonstrated for the first time. The efficiency of dNMP, dNDP and dNTP interaction with DNA-polymerase was estimated from the affinity modification of the enzymes by dNTP and dNMP imidazolides. The key role of the template-primer interaction in the formation of the dNTP-binding site of DNA-polymerases was demonstrated. A significant contribution of dNTP gamma-phosphate to the template--dependent specific tuning of substrate dNTP was revealed.     

Effect of bases noncomplementary to the template on the effectiveness of primer interaction with DNA-polymerase alpha from the human placenta

The comparison of the Km and Vmax values for the various primers was carried out. The primers were either completely complementary to the template or contained the non-complementary bases in different positions from the 3'-end. The number of the bases from the 3'-end to the noncomplementary nucleotide but not the primers length was supposed to determine the efficiency of the interaction of the primers containing noncomplementary bases with the enzyme. The Km values for d[(pC) (pT)7] (1.2 microM), d[(pC)3(pT)7] (2.5 microM, d[(pT)2pC(pT)7] (1.4 microM)d[(pT)4pC(pT)5(4.3 microM); d[(pT)7pC(pT)2] (11 microM) are comparable with the Km values for d(pT)7 (1.4 microM); d(pT)5 (4.2 microM) and d(pT)3 (15 mkM), respectively, but not for the decathymidilate d[(Tp)9T] (0.23 microM). The complementary interaction between the first nucleotide from the 3'-end of the primer and the template appear to play the particular role in the interaction of the enzyme with the primer. The Km values for d[(pT)10pC] and d[(pA)9pC] (with the corresponding templates) are 38 and 6 times the ones for d[(Tp)10T] and d(pA)10. However, the Km values for d[(pA)9p(rib)] (0.56 microM) which contains the deoxyribozylurea residue at the 3'-end is practically equal to the Km for d(pA)9 (0.56 microM). The Vmax values for d[(pT)10pC] and d[(pA)9pC] are 1.7 and 2.3 times the values for d[(Tp)10T] and d(pA)10, respectively. The primer affinity decreases, just as its conversion rate increases when the noncomplementary base in the primer is transferred from the 5'-to 3'-end; that results in the rate of primers elongation decrease in total.     

Inhibition of in vitro DNA chain elongation of 5-trifluoromethyl-2'-deoxyuridine residue in the template.

5-Trifluoromethyl-2'-deoxyuridine (CF3dUrd) is incorporated into the DNA of mammalian cells in culture. We have synthesized oligonucleotides that allows site specific introduction of CF3dUrd residue into synthetic DNA oligonucleotide. We described here the utilization of these oligonucleotides as template for in vitro DNA synthesis. When CF3dUrd residue located at an internucleotide site in the template, the chain elongation was partially arrested one nucleotide after or before the CF3dUrd residue of template using Escherichia coli polymerase I (Klenow fragment) or human polymerase alpha (pol alpha). These results suggested that a mechanism of antitumor activity of CF3dUrd is inhibition of DNA replication.     

The effect of bases non-complementary to the template on the efficacy of primer interaction with the Klenow fragment of DNA polymerase I from Escherichia coli

The comparison of the Km and Vmax values for the primers was carried out. The primers were either completely complementary to the template or contained non-complementary bases at different positions with respect to the 3'-end. The addition of NaF, selectively inhibiting 3'----5'-exonuclease activity of the enzyme, was shown to result in the increase of Vmax values by 10% and 30% for complementary and partially complementary primers, respectively, Km values of the latters being unchanged. Km values for d[(pT)10pC] is about 146-fold greater than that for d[(pT)11]. Km values for d[(pT)7pC(pT)2] (20 microM) and d[[(pT)2pC]3pT] (20 microM); d[(pT)4pC(pT)5] (5.0 microM); d[(pC)(pT)7] (1.3 microM) and d[(pT)2pC(pT)7] (1.2 microM) are comparable with those for d[(pT)2] (22 microM), d[(pT)5] (4.1 microM) and d[(pT)7] (1.2 microM), respectively, but not with the decathymidylate d[(pT)10] (0.2 microM). We suggest that it is not the length of the primers but the number of bases in the fragment beginning with the first nucleotide from the 3'-end and ending in the non-complementary base, that determines the efficiency of interaction of the primers containing non-complementary bases with the enzyme. The addition of one link to d(pT)n (n less than or equal to 10) resulted in a 1.8-fold increase in the affinity. When 11 less than n less than 25 the affinity is decreased so that d(pT)22-23 have minimal affinity to the enzyme. The primers containing more than 50 units were found to have about the same affinity (calculated on base concentration) as d(pT)10-11.     

Nuclease resistance of oligonucleotides containing the tricyclic cytosine analogues phenoxazine and 9-(2-aminoethoxy)-phenoxazine ("G-clamp") and origins of their nuclease resistance properties.

The tricyclic cytosine analogues phenoxazine and 9-(2-aminoethoxy)-phenoxazine ("G-clamp") are known to significantly enhance the binding affinity of oligonucleotides to their complementary target DNA or RNA strands. To investigate their effect on the nuclease resistance, they were incorporated into model oligomers with a natural phosphodiester backbone, and enzymatic degradation was monitored in an in vitro assay with snake venom phosphodiesterase as the hydrolytic enzyme. In both cases, a single incorporation at the 3'-terminus completely protected the oligonucleotides against 3'-exonuclease attack. Further investigations indicate that the observed high nuclease resistance is not due to the lack of binding affinity to the enzyme's active site, since these modified oligonucleotides were able to inhibit degradation of a natural DNA fragment by bovine intestinal mucosal phosphodiesterase in a dose-dependent manner.     

Oligothymidylate analogues having stereoregular, alternating methylphosphonate/phosphodiester backbones as primers for DNA polymerase

Oligothymidylate analogues having stereoregular, alternating methylphosphonate/phosphodiester backbones, d-Tp(TpTp)4T isomers I and II and d-Tp(TpTp)3T(pT)1-5 isomers I and II, were prepared by methods analogous to the phosphotriester synthetic technique. The designations isomer I nd isomer II refer to the configuration of the methylphosphonate linkage, which is the same through each isomer. Analogues with the type I methylphosphonate configuration form very stable duplexes with poly(dA) while those with the type II configuration form either 2T:1A triplexes or 1T:1A duplexes with poly(dA) of considerably lower stabilities. The oligothymidylate analogues were tested for their ability to initiate polymerizations catalyzed by Escherichia coli DNA polymerase I or calf thymus DNA polymerase alpha on a poly(dA) template. Neither d-Tp(TpTp)4T nor d-Tp(T]Tp)3TpT served as initiators of polymerization while d-Tp(TpTp)3T(pT)2-5 showed increasing priming ability as the length of the 3'-oligothymidylate tail increased. Analogues with type I methylphosphonate configuration were more effective initiators than the type II analogues at 37 degrees C. The apparent activation energies of polymerizations initiated by d-Tp(TpTp)3T-(pT)4 and 5 isomer I were greater than those for reactions initiated by isomer II or d-(Tp)11T. The results suggest that DNA polymerase interacts with the charged phosphodiester groups of the primer molecule and may help stabilize primer/template interaction. At least two contiguous phosphodiester groups are required at the 3' end of the analogue primers in order for polymerization to occur. Interactions between the polymerase and primer also appear to occur with phosphodiester groups located at sites remote from the 3'-OH polymerization site and may be influenced by the configuration of the methylphosphonate group.     

The effects of the ring fragmentation product of thymidine C5-hydrate on phosphodiesterases and klenow (exo-) fragment.

N-(2-Deoxy-beta-D-erythro-pentofuranosyl)-N-3-(2R-hydroxyisobutyric acid)urea (alpha-R-hydroxy-beta-ureidoisobutyric acid, 8) was site specifically incorporated into a series of oligonucleotides via the ammonolysis of biopolymers containing 5R-thymidine C5-hydrate (3). alpha-R-hydroxy-beta-ureidoisobutyric acid (8) inhibits snake venom phosphodiesterase, lambda exonuclease and Klenow (exo-) fragment. Kinetic measurements for insertion of nucleotides opposite 8 by Klenow (exo-) fragment indicate that this lesion is instructive.     

Comparison of the effectiveness of the interaction of ribo- and deoxyriboprimers with DNA-polymerase from the human placenta

The Km and Vmax values for primers d(pA)n, d(pT)n, r(pA)n, r(pU)n where n = 1-16, were compared. The Km values for minimal primers dTMP, dAMP, rUMP, rAMP were found to be 48, 71, 602 and 602 microM, respectively. The Vmax value for any NMP made up approximately 7% of that for (pN)10. The lengthening of any primer per one mononucleotide unit for n from 1 to 10 resulted in the decrease of the Km value 1.8-fold and the increase of the Vmax value 1.35-fold. The ratios of the Km values for primers r(pA)n-d(pA)n and r(pU)n-d(pT)n were 7.5 and 12.5, respectively, for any n. The Km value for [d[pT)8]r(pU) primer was the same as for r(pU)9, but not for d(pT)9. Decanucleotide [d(Tp)9]ddT interacted with the polymerase competitively to the template, but not to the primer. The primer's 3'-OH group was supposed to form the hydrogen bond with the enzyme. The absence of 3'-hydroxygroup in [d(Tp)9]ddT resulted in its inability to compete effectively with the primer. The difference of the affinity of ribo- and deoxyriboprimers is due, apparently, to the existence of the different conformation of the furanose rings in the ribose and deoxyribose.     

Reactivity of oligonucleotide derivatives, containing a methylphosphate group. Affinity modification of target DNA by 4-N-(methyl-N-2-chlorethylamino)benzyl 3'- and 5'-phosphamide derivatives of octathymidylate containing methylphosphonate residues

Modification of 5'-32P-labelled octadecadeoxyribonucleotide d(pC5A8C5) (III) with octathymidylate methylphosphonate derivatives bearing both 3'- and 5'-terminal alkylating 4-(N-2-chloroethyl-N-methylamino)benzylphosphoamide residue has been investigated. Yield in the modification depends on configuration of methylphosphonate fragment, in case of Rp-isomer it may amount to 90%. Specificity of alkylation of nucleic acide target (III) by reagents based on the oligonucleotide methylphosphonates is almost the same as by reagents based on the oligonucleotides having phosphodiester internucleotide bonds.     

Ligand interactions of the cation-dependent mannose 6-phosphate receptor. Comparison with the cation-independent mannose 6-phosphate receptor

The interactions of the bovine cation-dependent mannose 6-phosphate receptor with monovalent and divalent ligands have been studied by equilibrium dialysis. This receptor appears to be a homodimer or a tetramer. Each mole of receptor monomer bound 1.2 mol of the monovalent ligands, mannose 6-phosphate and pentamannose phosphate with Kd values of 8 X 10(-6) M and 6 X 10(-6) M, respectively and 0.5 mol of the divalent ligand, a high mannose oligosaccharide with two phosphomonoesters, with a Kd of 2 X 10(-7) M. When Mn2+ was replaced by EDTA in the dialysis buffer, the Kd for pentamannose phosphate was 2.5 X 10(-5) M. By measuring the affinity of the cation-dependent and cation-independent mannose 6-phosphate receptors for a variety of mannose 6-phosphate analogs, we conclude that the 6-phosphate and the 2-hydroxyl of mannose 6-phosphate each contribute approximately 4-5 kcal/mol of Gibb's free energy to the binding reaction. Neither receptor appears to interact substantially with the anomeric oxygen of mannose 6-phosphate. The receptors differ in that the cation-dependent receptor displays no detectable affinity for N-acetylglucosamine 1'-(alpha-D-methylmannopyranose 6-monophosphate) whereas this ligand binds to the cation-independent receptor with a poor, but readily measurable Kd of about 0.1 mM. The spacing of the mannose 6-phosphate-binding sites relative to each other may also differ for the two receptors.