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.     

The algorithm of estimation of the Km values for primers of various structure and length in the polymerization reaction catalyzed by Klenow fragment of DNA polymerase I from E. coli

DNA synthesis at primers d(pT)n, d(pA)n, d(pC)n, and d(pG)n in the presence of corresponding complementary templates and at hetero-oligoprimers complementary to M13 phage DNA was investigated. The values of both -log Km and log Vmax increased linearly if homo-oligoprimers contained less than 10 nucleotides. The lengthening of d(pT)n and d(pA)n primers by one mononucleotide unit (n = 1-10) resulted in the 1.82-fold decrease of the Km values. The incremental decreases of Km for d(pC)n and d(pG)n were equal to about 2.46. The enhancement of the homo- and hetero-oligonucleotide primers' affinity to the enzyme due to one Watson-Crick hydrogen bond between complementary template and primer is about 1.35 times. This allows to calculate the Km values for primers of various structure and length up to 10 units. The objective laws of the Km and Vmax values changes for primers containing more than 10 nucleotides were analyzed.     

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.     

Structure-function analysis of mononucleotides and short oligonucleotides in the priming of enzymatic DNA synthesis

The reversed-phase chromatography technique was employed in the measurement of DNA synthesis at the primers d(pT)n, r(pU)n, d(pA)n, and r(pA)n (n = 1-16) in the presence of template poly(dA) or poly(dT). DNA synthesis was catalyzed by Escherichia coli DNA polymerase I Klenow fragment, Physarum polycephalum DNA polymerase beta-like, P. polycephalum DNA polymerase alpha, and human placenta DNA polymerase alpha. Values of Km and Vmax were measured as functions of the primer chain lengths. It was found that all mononucleotides and small oligonucleotides served as primers of DNA synthesis. Values of the logarithm of both Km and Vmax increased linearly until primers had attained a chain length of 9-12 nucleotides, where a break was observed. The incremental as well as the absolute values of Km were interpreted in terms of free binding energies. These together with other data indicate that the 3'-ultimate nucleotide of the primer contributes a decisive amount of free energy of binding to DNA polymerase both from the nucleoside and from the phosphate moiety. The incremental increase is due to a complementary interaction between bases of primer and template buried in the binding cleft of the polymerase. It is also the ultimate nucleotide that determines whether the ribonucleotide or the deoxyribonucleotide is an efficient primer. It is of interest that the major results seem preserved for all four DNA polymerases. An energetic model for the binding of the template-primer was proposed and compared with available crystallographic data.     

RNA-dependent DNA-polymerase from avian myeloblastosis virus: effectiveness of interaction with oligothymidylate primers of various length]

Optimal conditions for the reaction of polymerization catalyzed by RNA-dependent DNA-polymerase from AMV on poly(A)- and poly(dA)-templates with d(pT)n-primers were established. Optimal concentrations of the components and pH of the reaction mixtures were found out to differ significantly. dTTP was shown to be both a nucleotide substrate and a minimal primer of the polymerization. The Km values for d(pT)2-primer (Km = 0.11 mM and 0.54 for poly(A) and poly(dA)-templates, respectively) and longer oligothymidylates were estimated. The lengthening of d(pT)n (n = 2-10) by one mononucleotide unit led to a 3-fold and 2-fold decrease of Km value for poly(A) and poly(dA), respectively. Further lengthening of the primer (n = 10-25) did not affect Km for the primers. The maximal rates of polymerization did not depend on primer length. The activation reaction (Ea = 12 kcal/mol) of polymerization on poly(A) was considerably lower than that on poly(dA) (Ea = 50 kcal/mol). In both cases a highly processive polymerization was observed. It was suggested that the synthesis had been more effective on poly(A)-template due to a more effective formation of the complex enzyme primer template.     

The effect of bases noncomplementary to the template on the effectiveness of interaction between primers and avian myeloblastosis virus reverse transcriptase]

The comparison of the Km and vmax values for various primers was carried out. The primers were either completely complementary to the poly(A)-template or contained noncomplementary bases in different positions from the 3'-end. An increase of the Km and vmax values for primers containing noncomplementary bases was shown. The affinity of the AMV-revertase complex with poly(A)-template to d(pT)10 was shown to be higher by a factor of 93, 325, 338, 425, 95 and 15 than to d(pT)9(pC), d[(pT)2pC]3pT, d(pT)8pCpT, d(pT)7pC(pT)2, d(pT)4pC(pT)5 and d(pC)3(pT)7, respectively. The vmax values for the above primers were 1.2-1.5-fold higher than for d(pT)10. The decrease of the affinity of noncorrect primers to the enzyme was supposed to serve as a mechanism for mistakes correction when noncomplementary to the template mononucleotide units were added to the primer. More effective discrimination between right and wrong primers takes place if the noncomplementary base is in the second or third position from the 3'-end. The mistake correction is performed by dissociation of a wrong primer from the complexes with the enzyme and template. The data obtained for AMV-revertase are in accord with results for pro- and eukaryotic DNA polymerases and are in favour of a similar mechanism of mistake correction by all enzymes in the case of short primers.     

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.     

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.     

Klenow fragment of DNA-polymerase I from E. coli. III. The role of internucleotide phosphate groups of the matrix in its binding with the enzyme

The modification of Klenow fragment of DNA polymerase I E. coli was investigated by the affinity reagents d(Tp)2C[Pt2+(NH3)2OH](pT)7 and d(pT)2pC[Pt2+(NH3)2OH](pT)7. The template binding site of the enzyme was modified by these reagents in the presence of NaF (5 mM), which inhibits selectively the 3'----5'-exonuclease activity of the enzyme and therefore prevents the reagent from degradation. NaCN destroyed covalent bonds between reagents and enzyme, restoring activity of the Klenow fragment. The affinity of different ligands (inorganic phosphate, nucleoside monophosphates, oligonucleotides) to the template binding site of Klenow fragment was estimated. Minimal ligands capable to bind with the template site were shown to be triethylphosphate (Kd 290 microM) and phosphate (Kd 26 microM). Ligand affinity increases by the factor 1.76 per an added (monomer unit from phosphate to d(pT) and then for oligonucleotides d(Tp)nT (n 1 to 19-20). At n greater than 19-20, the ligand affinity remained constant. The complete ethylation of phosphodiester groups lowers affinity of the oligothymidylates to the enzyme by approximately 10 times, and comparable decrease of Pt2+-oligonucleotide affinity to polymerase is caused by the absence of Mn2+-ions. The data obtained led to suggestion that one Me2+-dependent electrostatic contact of the template phosphodiester group with the enzyme takes place (delta G = -1.45...-1.75 kcal/mole). Formation of a hydrogen bond with the oxygen atom of P = O group of the same template phosphate is also assumed (delta G = -4.8...-4.9 kcal/mole). Other template internucleotide phosphates do not interact with the enzyme but the bases of oligonucleotides take part in hydrophobic interactions with the template binding site. Gibbs energy changes by -0.34 kcal/mole when the template is lengthened by one unit.     

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.     

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.     

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.     

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.     

Comparison of initiating abilities of primers of different length in polymerization reactions catalyzed by DNA polymerases from thermoacidophilic archaebacteria

Optimal conditions for polymerization reaction catalyzed on poly(dA) and poly(dT) templates by DNA polymerases from thermoacidophilic archaebacteria--DNA polymerase A from Sulfolobus acidocaldarius and DNA polymerase B from Thermoplasma acidophilum--have been established. Values of Km and Vmax (60 degrees C) for a set of primers d(pA)n and d(pT)n have been estimated. Minimal primers for both enzymes are dNMP. Lengthening of primers by each mononucleotide increases their affinity about 2.16-fold. Linear dependence of log Km and of log vmax on the number of mononucleotide links in primers (n) has breaking point at n = 10. The value of Vmax is about 20% of that for decanucleotide. The affinity of the primer d(pA)9p(rib*) with a deoxyribosylurea residue at the 3'-end does not differ essentially from that of d(pA)9. Substitution of the 3'-terminal nucleotide of a complementary primer for a noncomplementary nucleotide, e.g., substitution of 3'-terminal A for C in d(pA)10 in the reaction catalyzed on poly(dT), decreases the affinity of a primer by one order of magnitude.     

Mnemonic aspects of Escherichia coli DNA polymerase I. Interaction with one template influences the next interaction with another template

When Escherichia coli DNA polymerase I (Pol I) replicates a homopolymer, the excision/polymerization (exo/pol) ratio varies with enzyme and initiator concentration. The study of this effect in the case of poly(dA).oligo(dT) replication led us to propose a mnemonic model for Pol I, in which the 3' to 5' excision activity warms up when the enzyme is actively polymerizing, and cools down when it dissociates from the template. The model predicts that the exo/pol ratio must increase with processivity length and initiator concentration and decrease with enzyme concentration. It predicts also that contact of the enzyme with one template alters its excision efficiency towards another template. The exo/pol ratio and processivities of Pol I and its Klenow fragment were studied on four templates: poly(dA).(dT)10, poly(dT).(dA)10, poly(dC).(dG)10 and poly(dI).(dC)10. We show that the Klenow fragment is usually much less processive than Pol I and when this is the case it has a much lower exo/pol ratio. At equal processivity, the exo/pol ratios are nearly equal. Furthermore, many factors that influence processivity length (e.g. manganese versus magnesium, inorganic pyrophosphate, ionic strength) influence the exo/pol ratio in the same direction. The study of deaminated poly(dC) replication, where we followed incorporation and excision of both G and A residues, allowed us to assign the origin of the dNMP variations to changes in the 3' to 5' proof-reading activity of Pol I. Similarly, the lower dNMP turnover of the Klenow fragment observed with deaminated poly(dC) was specifically assigned to a decreased 3' to 5' exonuclease activity. The exo/pol ratio generally increased with initiator and decreased with enzyme concentration, in agreement with the model, except for poly(dI).oligo(dC), where it decreased with initiator concentration. However, by terminating chain elongation with dideoxy CTP, we showed directly that, even in this system, excision is relatively inefficient at the beginning of synthesis. Interaction of Pol I with poly(dA).(dT) or with poly(dC).(dG) modifies its exo/pol characteristics in the replication of poly(dI).(dC) and poly(dA).(dT), respectively. The Klenow enzyme is not sensitive to such influences and this correlates with its reduced processivity on the influencing templates. Our results reveal the existence of differences between Pol I and its Klenow fragment that are more profound than has been thought previously.(ABSTRACT TRUNCATED AT 400 WORDS)     

Adenine base unstacking dominates the observed enthalpy and heat capacity changes for the Escherichia coli SSB tetramer binding to single-stranded oligoadenylates.

Isothermal titration calorimetry (ITC) was used to test the hypothesis that the relatively small enthalpy change (DeltaHobs) and large negative heat capacity change (DeltaCp,obs) observed for the binding of the Escherichia coli SSB protein to single-stranded (ss) oligodeoxyadenylates result from the temperature-dependent adenine base unstacking equilibrium that is thermodynamically coupled to binding. We have determined DeltaH1,obs for the binding of 1 mole of each of dT(pT)34, dC(pC)34, and dA(pA)34 to the SSB tetramer (20 mM NaCl at pH 8.1). For dT(pT)34 and dC(pC)34, we found large, negative values for DeltaH1,obs of -75 +/- 1 and -85 +/- 2 kcal/mol at 25 degrees C, with DeltaCp,obs values of -540 +/- 20 and -570 +/- 30 cal mol-1 K-1 (7-50 degrees C), respectively. However, for SSB-dA(pA)34 binding, DeltaH1,obs is considerably less negative (-14 +/- 1 kcal/mol at 25 degrees C), even becoming positive at temperatures below 13 degrees C, and DeltaCp,obs is nearly twice as large in magnitude (-1180 +/- 40 cal mol-1 K-1). These very different thermodynamic properties for SSB-dA(pA)34 binding appear to result from the fact that the bases in dA(pA)34 are more stacked at any temperature than are the bases in dC(pC)34 or dT(pT)34 and that the bases become unstacked within the SSB-ssDNA complexes. Therefore, the DeltaCp,obs for SSB-ssDNA binding has multiple contributions, a major one being the coupling to binding of a temperature-dependent conformational change in the ssDNA, although SSB binding to unstacked ssDNA still has an "intrinsic" negative DeltaCp,0. In general, such temperature-dependent changes in the conformational "end states" of interacting macromolecules can contribute significantly to both DeltaCp,obs and DeltaHobs.     

NaF and mononucleotides as inhibitors of 3'-5'-exonuclease activity and stimulators of polymerase activity of E. coli DNA polymerase I Klenow fragment

It has been shown that, in the absence of dATP in the poly(dT).oligo(dA) template-primer complex, the rate of primer cleavage by the E. coli DNA polymerase I Klenow fragment equals 4% of polymerization rate, while in the presence of dATP it equals as much as 50-60%. NaF and NMP taken separately inhibit exonuclease cleavage of oligo(dA) both with and without dATP. The addition of NaF (5-10 mM) or NMP (5-20 mM) increases the absolute increment of polymerization rate 5-9-fold relative to the absolute decrement of the rate of nuclease hydrolysis of primer. This proves the assumption that not more than 10-20% of primer molecules, interacting with the exonuclease center of polymerase, are cleaved by the enzyme. Presumably, NaF and nucleotides disturb the coupling of the 3'-end of oligonucleotide primer to the exonuclease center of the enzyme. As the primers mostly form complexes with the polymerizing center, the reaction of polymerization is activated.     

The effect of antibiotics on the T4 polynucleotide ligase catalyzed template dependent polymerization of oligodeoxythymidylates.

The poly(dA) dependent T4 polynucleotide ligase catalyzed polymerization of oligodeoxythymidylates is dependent upon duplex stability. The antibiotics ethidium bromide, netropsin and Hoechst 33258 stabilize the duplex poly(dA) . P(dT)n (n = 6-10) to thermal denaturation. Ethidium bromide to DNA ratio of 1.25 and netropsin or Hoechst 33258 to DNA ratio of 0.1 the Tm of d(pT) 10 . poly (dA) was increased by 10 degrees and 25 degrees C respectively. The T4 polynucleotide ligase activity was not inhibited under these conditions and temperature optimum of joining of d(pT) 10 . poly(dA) was increased 5 degrees to 10 degrees by the binding of the antibiotics. Duplexes containing shorter oligodeoxythymidylates required lower concentrations of the antibiotics netropsin or Hoechst 33258 to show no inhibition of T4 polynucleotide ligase. The temperature optima of joining the duplexes d(pT)6 . POLY(DA) and d(pT) 8 . poly(dA) were increased by 5 degrees C upon binding of the antibiotics. Polyacrylamide gel analysis of the T4 polynucleotide ligase catalyzed joining of the oligodeoxythymidylates showed that the presence of antibiotics affected the product distribution of the polymerized oligomers.