On the processivity of polymerases

A novel strategy to engineer DNA polymerases for enhanced processivity and improved performance in vitro

Mechanisms that allow replicative DNA polymerases to attain high processivity are often specific to a given polymerase and cannot be generalized to others. Here we report a protein engineering-based approach to significantly improve the processivity of DNA polymerases by covalently linking the polymerase domain to a sequence non-specific dsDNA binding protein. Using Sso7d from Sulfolobus solfataricus as the DNA binding protein, we demonstrate that the processivity of both family A and family B polymerases can be significantly enhanced. By introducing point mutations in Sso7d, we show that the dsDNA binding property of Sso7d is essential for the enhancement. We present evidence supporting two novel conclusions. First, the fusion of a heterologous dsDNA binding protein to a polymerase can increase processivity without compromising catalytic activity and enzyme stability. Second, polymerase processivity is limiting for the efficiency of PCR, such that the fusion enzymes exhibit profound advantages over unmodified enzymes in PCR applications. This technology has the potential to broadly improve the performance of nucleic acid modifying enzymes.

Processive phosphorylation of alternative splicing factor/splicing factor 2

SR proteins, named for their multiple arginine/serine (RS) dipeptide repeats, are critical components of the spliceosome, influencing both constitutive and alternative splicing of pre-mRNA. SR protein function is regulated through phosphorylation of their RS domains by multiple kinases, including a family of evolutionarily conserved SR protein-specific kinases (SRPKs). The SRPK family of kinases is unique in that they are capable of phosphorylating repetitive RS domains with remarkable specificity and efficiency. Here, we carried out kinetic experiments specially developed to investigate how SRPK1 phosphorylates the model human SR protein, ASF/SF2. By using the start-trap strategy, we monitored the progress curve for ASF/SF2 phosphorylation in the absence and presence of an inhibitor peptide directed at the active site of SRPK1. ASF/SF2 modification is not altered when the inhibitor peptide (trap) is added with ATP (start). However, when the trap is added first and allowed to incubate for a specific delay time, the decrease in phosphate content of the enzyme-substrate complex follows a simple exponential decline corresponding to the release rate of SRPK1. These data demonstrate that SRPK1 phosphorylates a specific region within the RS domain of ASF/SF2 by using a fully processive catalytic mechanism, in which the splicing factor remains "locked" onto SRPK1 during RS domain modification.

Expression and characterization of a recombinant novel reverse transcriptase of a porcine endogenous retrovirus

The study of porcine endogenous retroviruses (PERVs) becomes increasingly important due to the potential use of pig cells, tissues, and organs as a source for xenogenic cell therapy and xenotransplantation into humans. Consequently, we have constructed a plasmid that induces in bacteria the synthesis of a soluble and highly active reverse transcriptase (RT) of PERV-B. The purified PERV RT was studied biochemically in comparison with the RT of murine leukemia virus (MLV), because of the high-sequence homology between these two RTs. The data show that in several properties the two enzymes are similar, particularly regarding the monomeric subunit composition of the proteins in solution, the high resistance to deoxynucleoside analogues, and the pattern of RNA cleavage by the ribonuclease H activity (RNase H) of the RTs. However, in several cases there are apparent differences between the two RTs, most notable the divalent cation preference (Mn(+2) versus Mg(+2)) in the DNA polymerase reactions. As already shown for viral PERV RT, the novel recombinant PERV RT exhibits a relatively high resistance to several deoxynucleoside analogue inhibitors, suggesting that they might not be very efficient in inhibiting the replication of PERV virions. Therefore, the availability of large amounts of the recombinant RT can be useful for a wide screening of novel drugs against infectious PERV.

The role of phenylalanine-119 of the reverse transcriptase of mouse mammary tumour virus in DNA synthesis, ribose selection and drug resistance

Phe-119 in the reverse transcriptase (RT) of mouse mammary tumour virus (MMTV) is homologous with Tyr-115 in HIV type 1 (HIV-1) RT and to Phe-155 in murine leukaemia virus (MLV) RT. By mutating these residues in HIV-1 and MLV RTs (which are strict DNA polymerases) the enzymes were shown to function also as RNA polymerases. Owing to the uniqueness of MMTV as a type B retrovirus, we have generated a Phe-119-Val mutant of MMTV RT to study the involvement of this residue in affecting the catalytic features of this RT. The data presented here show that the mutant MMTV RT can incorporate both deoxyribonucleosides and ribonucleosides while copying either RNA or DNA. In addition, this mutant RT shows resistance to nucleoside analogues and an enhanced fidelity of DNA synthesis; all relative to the wild-type enzyme. The Phe-119-Val mutant is also different from the wild-type enzyme in its preference for most template primers tested and in its ability to synthesize DNA under non-processive and processive conditions. Overall, it is likely that the aromatic side chain of Phe-119 is located at the dNTP-binding site of MMTV RT and thus might be part of a putative "steric gate" that prevents the incorporation of nucleoside triphosphates. Since the only three-dimensional structures of RTs published so far are those of HIV-1 and MLV, it is likely that MMTV RT folds quite similarly to these RTs.

Helix-hairpin-helix motifs confer salt resistance and processivity on chimeric DNA polymerases

Helix-hairpin-helix (HhH) is a widespread motif involved in sequence-nonspecific DNA binding. The majority of HhH motifs function as DNA-binding modules with typical occurrence of one HhH motif or one or two (HhH)(2) domains in proteins. We recently identified 24 HhH motifs in DNA topoisomerase V (Topo V). Although these motifs are dispensable for the topoisomerase activity of Topo V, their removal narrows the salt concentration range for topoisomerase activity tenfold. Here, we demonstrate the utility of Topo V's HhH motifs for modulating DNA-binding properties of the Stoffel fragment of TaqDNA polymerase and Pfu DNA polymerase. Different HhH cassettes fused with either NH(2) terminus or COOH terminus of DNA polymerases broaden the salt concentration range of the polymerase activity significantly (up to 0.5 M NaCl or 1.8 M potassium glutamate). We found that anions play a major role in the inhibition of DNA polymerase activity. The resistance of initial extension rates and the processivity of chimeric polymerases to salts depend on the structure of added HhH motifs. Regardless of the type of the construct, the thermal stability of chimeric Taq polymerases increases under the optimal ionic conditions, as compared with that of TaqDNA polymerase or its Stoffel fragment. Our approach to raise the salt tolerance, processivity, and thermostability of Taq and Pfu DNA polymerases may be applied to all pol1- and polB-type polymerases, as well as to other DNA processing enzymes.

High processivity of the reverse transcriptase from a non-long terminal repeat retrotransposon

R2 is a retrotransposable element that specifically inserts into the 28 S rRNA genes of arthropods. The element encodes a single protein with endonuclease activity that cleaves the 28 S gene target site and reverse transcriptase (RT) activity that uses the cleaved DNA to prime reverse transcription. Here we compare various properties of the R2 RT activity with those of the well characterized retroviral RT, avian myeloblastosis virus (AMV). In processivity assays using heterogeneous RNA templates, R2 RT can synthesize cDNA over twice the length of that synthesized by AMV RT and can synthesize cDNA over 4 times longer than AMV RT in assays with poly(rA) templates. The higher processivity of R2 RT compared with retroviral RTs is a result of the slower rate of dissociation of the enzyme from RNA templates. The elongation rates of the two enzymes are similar. Finally, a highly distinct property of the R2 RT, compared with retroviral enzymes, is its ability to displace RNA strands annealed to RNA templates during cDNA synthesis. We suggest that both the higher processivity and displacement properties of R2 RT compared with retroviral RT result from the greater affinity of the R2 protein for the RNA template upstream of its active site.

The isomerization of the UvrB-DNA preincision complex couples the UvrB and UvrC activities

In Escherichia coli nucleotide excision repair, the UvrB-DNA preincision complex plays a key role, linking adduct recognition to incision. We previously showed that the efficiency of the incision is inversely related to the stability of the preincision complex. We postulated that an isomerization reaction converts [UvrB-DNA], stable but incompetent for incision, into the [UvrB-DNA]' complex, unstable and competent for incision. Here, we identify two parameters, negative supercoiling and presence of a nick at the fifth phosphodiester bond 3' to the lesion, that accelerate the isomerization leading to an increasing incision efficiency. We also show that the [UvrB-DNA] complex is more resistant to a salt concentration increase than the [UvrB-DNA]' complex. Finally, we report that the [UvrB-DNA]' is recognized by UvrC. These data suggest that the isomerization reaction leads to an exposure of single-stranded DNA around the lesion. This newly exposed single-stranded DNA serves as a binding site and substrate for the UvrC endonuclease. We propose that the isomerization reaction is responsible for coupling UvrB and UvrC activities and that this reaction corresponds to the binding of ATP.

The processivity and fidelity of DNA synthesis exhibited by the reverse transcriptase of bovine leukemia virus

We have recently expressed in bacteria the enzymatically active reverse transcriptase (RT) of bovine leukemia virus (BLV) [Perach, M. & Hizi, A. (1999) Virology 259, 176-189]. In the present study, we have studied in vitro two features of the DNA polymerase activity of BLV RT, the processivity of DNA synthesis and the fidelity of DNA synthesis. These properties were compared with those of the well-studied RTs of human immunodeficiency virus type 1 (HIV-1) and murine leukaemia virus (MLV). Both the elongation of the DNA template and the processivity of DNA synthesis exhibited by BLV RT are impaired relative to the other two RTs studied. Two parameters of fidelity were studied, the capacity to incorporate incorrect nucleotides at the 3' end of the nascent DNA strand and the ability to extend these 3' end mispairs. BLV RT shows a fidelity of misinsertion higher than that of HIV-1 RT and lower than that of MLV RT. The pattern of mispair elongation by BLV RT suggests that the in vitro error proneness of BLV RT is closer to that of HIV-1 RT. These fidelity properties are discussed in the context of the various retroviral RTs studied so far.

Fidelity and damage bypass ability of Schizosaccharomyces pombe Eso1 protein, comprised of DNA polymerase eta and sister chromatid cohesion protein Ctf7

DNA polymerase eta (Poleta) functions in error-free bypass of ultraviolet light-induced DNA lesions, and mutational inactivation of Poleta in humans causes the cancer prone syndrome, the variant form of xeroderma pigmentosum (XPV). Both Saccharomyces cerevisiae and human Poleta efficiently insert two adenines opposite the two thymines of a cyclobutane pyrimidine dimer. Interestingly, in the fission yeast Schizosaccharomyces pombe, the eso1(+) encoded protein is comprised of two domains, wherein the NH(2) terminus is highly homologous to Poleta, and the COOH terminus is highly homologous to the S. cerevisiae Ctf7 protein which is essential for the establishment of sister chromatid cohesion during S phase. Here we characterize the DNA polymerase activity of S. pombe GST-Eso1 fusion protein and a truncated version containing only the Poleta domain. Both proteins exhibit a similar DNA polymerase activity with a low processivity, and steady-state kinetic analyses show that on undamaged DNA, both proteins misincorporate nucleotides with frequencies of approximately 10(-2) to 10(-3). We also examine the two proteins for their ability to replicate a cyclobutane pyrimidine dimer-containing DNA template and find that both proteins replicate through the lesion equally well. Thus, fusion with Ctf7 has no significant effect on the DNA replication or damage bypass properties of Poleta. The possible role of Ctf7 fusion with Poleta in the replication of Cohesin-bound DNA sequences is discussed.

Role of the C-terminal residue of the DNA polymerase of bacteriophage T7

The crystal structure of the DNA polymerase encoded by gene 5 of bacteriophage T7, in a complex with its processivity factor, Escherichia coli thioredoxin, a primer-template, and an incoming deoxynucleoside triphosphate reveals a putative hydrogen bond between the C-terminal residue, histidine 704 of gene 5 protein, and an oxygen atom on the penultimate phosphate diester of the primer strand. Elimination of this electrostatic interaction by replacing His(704) with alanine renders the phage nonviable, and no DNA synthesis is observed in vivo. Polymerase activity of the genetically altered enzyme on primed M13 DNA is only 12% of the wild-type enzyme, and its processivity is drastically reduced. Kinetic parameters for binding a primer-template (K(D)(app)), nucleotide binding (K(m)), and k(off) for dissociation of the altered polymerase from a primer-template are not significantly different from that of wild-type T7 DNA polymerase. However, the decrease in polymerase activity is concomitant with increased hydrolytic activity, judging from the turnover of nucleoside triphosphate into the corresponding nucleoside monophosphate (percentage of turnover, 65%) during DNA synthesis. Biochemical data along with structural observations imply that the terminal amino acid residue of T7 DNA polymerase plays a critical role in partitioning DNA between the polymerase and exonuclease sites.

A structural basis for processivity

The structures of a number of processive enzymes have been determined recently. These proteins remain attached to their polymeric substrates and may perform thousands of rounds of catalysis before dissociating. Based on the degree of enclosure of the substrate, the structures fall into two broad categories. In one group, the substrate is partially enclosed, while in the other class, enclosure is complete. In the latter case, enclosure is achieved by way of an asymmetric structure for some enzymes while others use a symmetrical toroid. In those cases where the protein completely encloses its polymeric substrate, the two are topologically linked and an immediate explanation for processivity is provided. In cases where there is only partial enclosure, the structural basis for processivity is less obvious. There are, for example, pairs of proteins that have quite similar structures but differ substantially in their processivity. It does appear, however, that the enzymes that are processive tend to be those that more completely enclose their substrates. In general terms, proteins that do not use topological restraint appear to achieve processivity by using a large interaction surface. This allows the enzyme to bind with moderate affinity at a multitude of adjacent sites distributed along its polymeric substrate. At the same time, the use of a large interaction surface minimizes the possibility that the enzyme might bind at a small number of sites with much higher affinity, which would interfere with sliding. Proteins that can both slide along a polymeric substrate, and, as well, recognize highly specific sites (e.g., some site-specific DNA-binding proteins) appear to undergo a conformational change between the cognate and noncognate-binding modes.

The effect of increased processivity on overall fidelity of human immunodeficiency virus type 1 reverse transcriptase

We previously reported that two insertions of 15 amino acids in the beta3-beta4 hairpin loop of fingers subdomain of HIV-1(NL4-3) RT confer an increased polymerase processivity. The processivity of human immunodeficiency virus (HIV) reverse transcriptase (RT) is thought to influence the fidelity of HIV-1 RT, which tends to create errors at template sites with high termination probability. Employing the two insertion variants of HIV-1 RT (FE20 and FE103), we examined the relationship between processivity, overall fidelity and error specificity. Although the overall mutation rate was unaffected by increased processivity, one of the mutants, FE103, generated significantly fewer frameshift errors. The other mutant, FE20, generated errors at hotspots not previously observed for HIV-1 RT. Our results indicate that an increase in the polymerase processivity of HIV-1 RT does not necessarily result in a decreased mutation rate and confirm that changes in processivity alter the sequence context in which the errors are made. Furthermore, our results also reveal that the mutation frequency obtained via in vitro gap-filling reactions with wild-type HIV-1(NL4-3) RT is only 2-fold higher than that obtained via a single cycle infection assay using the same, wild-type HIV-1(NL4-3) RT sequence as part of the helper pol function [Mansky and Temin: J Virol 69:5087-5094;1995].

Characterization of human herpesvirus 8 ORF59 protein (PF-8) and mapping of the processivity and viral DNA polymerase-interacting domains

Human herpesvirus 8 (HHV-8) or Kaposi's sarcoma-associated herpesvirus (KSHV) ORF59 protein (PF-8) is a processivity factor for HHV-8 DNA polymerase (Pol-8) and is homologous to processivity factors expressed by other herpesviruses, such as herpes simplex virus type 1 UL42 and Epstein-Barr virus BMRF1. The interaction of UL42 and BMRF1 with their corresponding DNA polymerases is essential for viral DNA replication and the subsequent production of infectious virus. Using HHV-8-specific monoclonal antibody 11D1, we have previously identified the cDNA encoding PF-8 and showed that it is an early-late gene product localized to HHV-8-infected cell nuclei (S. R. Chan, C. Bloomer, and B. Chandran, Virology 240:118-126, 1998). Here, we have further characterized PF-8. This viral protein was phosphorylated both in vitro and in vivo. PF-8 bound double-stranded DNA (dsDNA) and single-stranded DNA independent of DNA sequence; however, the affinity for dsDNA was approximately fivefold higher. In coimmunoprecipitation reactions, PF-8 also interacted with Pol-8. In in vitro processivity assays with excess poly(dA):oligo(dT) as a template, PF-8 stimulated the production of elongated DNA products by Pol-8 in a dose-dependent manner. Functional domains of PF-8 were determined using PF-8 truncation mutants. The carboxyl-terminal 95 amino acids (aa) of PF-8 were dispensable for all three functions of PF-8: enhancing processivity of Pol-8, binding dsDNA, and binding Pol-8. Residues 10 to 27 and 279 to 301 were identified as regions critical for the processivity function of PF-8. Interestingly, aa 10 to 27 were also essential for binding Pol-8, whereas aa 1 to 62 and aa 279 to 301 were involved in binding dsDNA, suggesting that the processivity function of PF-8 is correlated with both the Pol-8-binding and the dsDNA-binding activities of PF-8.

Accuracy of thymine-thymine dimer bypass by Saccharomyces cerevisiae DNA polymerase

The Saccharomyces cerevisiae RAD30 gene functions in error-free replication of UV-damaged DNA. RAD30 encodes a DNA polymerase, Pol eta, which inserts two adenines opposite the two thymines of a cis-syn thymine-thymine (T-T) dimer. Here we use steady-state kinetics to determine the accuracy of DNA synthesis opposite the T-T dimer. Surprisingly, the accuracy of DNA synthesis opposite the damaged DNA is nearly indistinguishable from that opposite nondamaged DNA, with frequencies of misincorporation of about 10(-2) to 10(-3). These studies support the hypothesis that unlike most DNA polymerases, Pol eta is able to tolerate distortions in DNA resulting from damage, which then enables the polymerase to utilize the intrinsic base pairing ability of the T-T dimer.

Accuracy of thymine-thymine dimer bypass by Saccharomyces cerevisiae DNA polymerase eta

The Saccharomyces cerevisiae RAD30 gene functions in error-free replication of UV-damaged DNA. RAD30 encodes a DNA polymerase, Pol eta, which inserts two adenines opposite the two thymines of a cis-syn thymine-thymine (T-T) dimer. Here we use steady-state kinetics to determine the accuracy of DNA synthesis opposite the T-T dimer. Surprisingly, the accuracy of DNA synthesis opposite the damaged DNA is nearly indistinguishable from that opposite nondamaged DNA, with frequencies of misincorporation of about 10(-2) to 10(-3). These studies support the hypothesis that unlike most DNA polymerases, Pol eta is able to tolerate distortions in DNA resulting from damage, which then enables the polymerase to utilize the intrinsic base pairing ability of the T-T dimer.

Fidelity and processivity of Saccharomyces cerevisiae DNA polymerase eta

The yeast RAD30 gene functions in error-free replication of UV-damaged DNA, and RAD30 encodes a DNA polymerase, pol eta, that has the ability to efficiently and correctly replicate past a cis-syn-thymine-thymine dimer in template DNA. To better understand the role of pol eta in damage bypass, we examined its fidelity and processivity on nondamaged DNA templates. Steady-state kinetic analyses of deoxynucleotide incorporation indicate that pol eta has a low fidelity, misincorporating deoxynucleotides with a frequency of about 10(-2) to 10(-3). Also pol eta has a low processivity, incorporating only a few nucleotides before dissociating. We suggest that pol eta's low fidelity reflects a flexibility in its active site rendering it more tolerant of DNA damage, while its low processivity limits its activity to reduce errors.

Interaction of Escherichia coli DNA polymerase I (Klenow fragment) with primer-templates containing N-acetyl-2-aminofluorene or N-2-aminofluorene adducts in the active site

DNA adducts formed by aromatic amines such as N-acetyl-2-aminofluorene (AAF) and N-2-aminofluorene (AF) are known to cause mutations by interfering with the process of DNA replication. To understand this phenomenon better, a gel retardation assay was used to measure the equilibrium dissociation constants for the binding of an exonuclease-deficient Escherichia coli DNA polymerase I (Klenow fragment) to DNA primer-templates modified with an AAF or AF adduct. The results indicate that the nature of the adduct as well as the presence and nature of an added dNTP have a significant influence on the strength of the binding of the polymerase to the DNA. More specifically, it was found that the binding is 5-10-fold stronger when an AAF adduct, but not an AF adduct, is positioned in the enzyme active site. In addition, the polymerase was found to bind the unmodified primer-template less strongly in the presence of a noncomplementary dNTP than in the presence of the correct nucleotide. The same trend holds true for the primer-template having an AF adduct, although the magnitude of this difference was lower. In the case of the AAF adduct, the interaction of the polymerase with the primer-template was stronger and almost independent of the nucleotide present.

Herpes simplex virus processivity factor UL42 imparts increased DNA-binding specificity to the viral DNA polymerase and decreased dissociation from primer-template without reducing the elongation rate

Herpes simplex virus DNA polymerase consists of a catalytic subunit, Pol, and a processivity subunit, UL42, that, unlike other established processivity factors, binds DNA directly. We used gel retardation and filter-binding assays to investigate how UL42 affects the polymerase-DNA interaction. The Pol/UL42 heterodimer bound more tightly to DNA in a primer-template configuration than to single-stranded DNA (ssDNA), while Pol alone bound more tightly to ssDNA than to DNA in a primer-template configuration. The affinity of Pol/UL42 for ssDNA was reduced severalfold relative to that of Pol, while the affinity of Pol/UL42 for primer-template DNA was increased approximately 15-fold relative to that of Pol. The affinity of Pol/UL42 for circular double-stranded DNA (dsDNA) was reduced drastically relative to that of UL42, but the affinity of Pol/UL42 for short primer-templates was increased modestly relative to that of UL42. Pol/UL42 associated with primer-template DNA approximately 2-fold faster than did Pol and dissociated approximately 10-fold more slowly, resulting in a half-life of 2 h and a subnanomolar Kd. Despite such stable binding, rapid-quench analysis revealed that the rates of elongation of Pol/UL42 and Pol were essentially the same, approximately 15 [corrected] nucleotides/s. Taken together, these studies indicate that (i) Pol/UL42 is more likely than its subunits to associate with DNA in a primer-template configuration rather than nonspecifically to either ssDNA or dsDNA, and (ii) UL42 reduces the rate of dissociation from primer-template DNA but not the rate of elongation. Two models of polymerase-DNA interactions during replication that may explain these findings are presented.

The processivity of DNA synthesis exhibited by drug-resistant variants of human immunodeficiency virus type-1 reverse transcriptase

The reverse transcriptase (RT) of human immunodeficiency virus (HIV) undergoes rapid mutagenesis due to selective pressure by RT inhibitors which renders the mutated RT variants resistant to these inhibitors. Resistance to nucleoside analogs during drug therapy results from point mutations that lead to specific variations in the RT sequences. It was recently shown that several well-defined drug-resistant variants of HIV-1 RT (i.e. Leu74Val, Glu89Gly, Tyr183Phe, Met184Lue, Met184Val and Met184Ile) show enhanced accuracy of DNA synthesis relative to wild-type HIV-1 RT (as evident from a reduction in the capacity to introduce mispairs and to elongate them). Since the last two Met184 variants were shown also to possess decreased processivity of DNA synthesis, it was recently suggested that there might be an inverse correlation between the apparent in vitro fidelity and processivity of DNA synthesis in drug-resistant HIV-1 RT mutants. In the present study we have conducted a comparative analysis of the processivity of DNA synthesis on both DNA and RNA templates of the Leu74Val, Glu89Gly, Tyr183Phe and Met184Leu drug-resistant mutants of HIV-1 RT in comparison with wild-type RT. Apart from the Met184 mutant, which shows reduced relative processivity (similar to the other mutants of residue 184 already studied), the other three variants have relative processivity at least as high as that of wild-type RT. This suggests that the inverse correlation between reduced processivity and increased fidelity is restricted only to mutants with modifications of Met184. The results presented may bear on potential mechanistic and structural differences in the involvement of the various mutated residues studied in processivity, fidelity and sensitivity to nucleoside analogs.