A domain of the Klenow fragment of Escherichia coli DNA polymerase I has polymerase but no exonuclease activity

The Role of Natural Polymorphic Variants of DNA Polymerase β in DNA Repair

DNA polymerase β (Polβ) is considered the main repair DNA polymerase involved in the base excision repair (BER) pathway, which plays an important part in the repair of damaged DNA bases usually resulting from alkylation or oxidation. In general, BER involves consecutive actions of DNA glycosylases, AP endonucleases, DNA polymerases, and DNA ligases. It is known that protein-protein interactions of Polβ with enzymes from the BER pathway increase the efficiency of damaged base repair in DNA. However natural single-nucleotide polymorphisms can lead to a substitution of functionally significant amino acid residues and therefore affect the catalytic activity of the enzyme and the accuracy of Polβ action. Up-to-date databases contain information about more than 8000 SNPs in the gene of Polβ. This review summarizes data on the in silico prediction of the effects of Polβ SNPs on DNA repair efficacy; available data on cancers associated with SNPs of Polβ; and experimentally tested variants of Polβ. Analysis of the literature indicates that amino acid substitutions could be important for the maintenance of the native structure of Polβ and contacts with DNA; others affect the catalytic activity of the enzyme or play a part in the precise and correct attachment of the required nucleotide triphosphate. Moreover, the amino acid substitutions in Polβ can disturb interactions with enzymes involved in BER, while the enzymatic activity of the polymorphic variant may not differ significantly from that of the wild-type enzyme. Therefore, investigation regarding the effect of Polβ natural variants occurring in the human population on enzymatic activity and protein-protein interactions is an urgent scientific task.

E. coli DNA Polymerase I and the Klenow Fragment

Escherichia coli DNA Pol I can carry out three enzymatic reactions: It possesses 5' → 3' DNA polymerase activity and 3' → 5' and 5' → 3' exonuclease activity. Pol I can be cleaved by mild treatment with subtilisin into two fragments; the larger fragment is known as the Klenow fragment. The Klenow fragment retains the polymerizing activity and the 3' → 5' exonuclease of the holo-enzyme but lacks its powerful 5' → 3' exonuclease activity. These enzymes and their applications in molecular cloning are introduced here.

Structural and catalytic insights into HoLaMa, a derivative of Klenow DNA polymerase lacking the proofreading domain

We report here on the stability and catalytic properties of the HoLaMa DNA polymerase, a Klenow sub-fragment lacking the 3’-5’ exonuclease domain. HoLaMa was overexpressed in Escherichia coli, and the enzyme was purified by means of standard chromatographic techniques. High-resolution NMR experiments revealed that HoLaMa is properly folded at pH 8.0 and 20°C. In addition, urea induced a cooperative folding to unfolding transition of HoLaMa, possessing an overall thermodynamic stability and a transition midpoint featuring ΔG and C_M equal to (15.7 ± 1.9) kJ/mol and (3.5 ± 0.6) M, respectively. When the catalytic performances of HoLaMa were compared to those featured by the Klenow enzyme, we did observe a 10-fold lower catalytic efficiency by the HoLaMa enzyme. Surprisingly, HoLaMa and Klenow DNA polymerases possess markedly different sensitivities in competitive inhibition assays performed to test the effect of single dNTPs.

Replisome Dynamics during Chromosome Duplication

This review describes the components of the Escherichia coli replisome and the dynamic process in which they function and interact under normal conditions. It also briefly describes the behavior of the replisome during situations in which normal replication fork movement is disturbed, such as when the replication fork collides with sites of DNA damage. E. coli DNA Pol III was isolated first from a polA mutant E. coli strain that lacked the relatively abundant DNA Pol I activity. Further biochemical studies, and the use of double mutant strains, revealed Pol III to be the replicative DNA polymerase essential to cell viability. In a replisome, DnaG primase must interact with DnaB for activity, and this constraint ensures that new RNA primers localize to the replication fork. The leading strand polymerase continually synthesizes DNA in the direction of the replication fork, whereas the lagging-strand polymerase synthesizes short, discontinuous Okazaki fragments in the opposite direction. Discontinuous lagging-strand synthesis requires that the polymerase rapidly dissociate from each new completed Okazaki fragment in order to begin the extension of a new RNA primer. Lesion bypass can be thought of as a two-step reaction that starts with the incorporation of a nucleotide opposite the lesion, followed by the extension of the resulting distorted primer terminus. A remarkable property of E. coli, and many other eubacterial organisms, is the speed at which it propagates. Rapid cell division requires the presence of an extremely efficient replication machinery for the rapid and faithful duplication of the genome.

HoLaMa: A Klenow sub-fragment lacking the 3'-5' exonuclease domain

The design, construction, overexpression, and purification of a Klenow sub-fragment lacking the 3'-5' exonuclease domain is presented here. In particular, a synthetic gene coding for the residues 515-928 of Escherichia coli DNA polymerase I was constructed. To improve the solubility and stability of the corresponding protein, the synthetic gene was designed to contain 11 site-specific substitutions. The gene was inserted into the pBADHis expression vector, generating 2 identical Klenow sub-fragments, bearing or not a hexahistidine tag. Both these Klenow sub-fragments, denominated HoLaMa and HoLaMaHis, were purified, and their catalytic properties were compared to those of Klenow enzyme. When DNA polymerase activity was assayed under processive conditions, the Klenow enzyme performed much better than HoLaMa and HoLaMaHis. However, when DNA polymerase activity was assayed under distributive conditions, the initial velocity of the reaction catalyzed by HoLaMa was comparable to that observed in the presence of Klenow enzyme. In particular, under distributive conditions HoLaMa was found to strongly prefer dsDNAs bearing a short template overhang, to the length of which the Klenow enzyme was relatively insensitive. Overall, our observations indicate that the exonuclease domain of the Klenow enzyme, besides its proofreading activity, does significantly contribute to the catalytic efficiency of DNA elongation.

Automated structural comparisons clarify the phylogeny of the right-hand-shaped polymerases

Polymerases are essential for life, being responsible for replication, transcription, and the repair of nucleic acid molecules. Those that share a right-hand-shaped fold and catalytic site structurally similar to the DNA polymerase I of Escherichia coli may catalyze RNA- or DNA-dependent RNA polymerization, reverse transcription, or DNA replication in eukarya, archaea, bacteria, and their viruses. We have applied novel computational methods for structure-based clustering and phylogenetic analyses of this functionally diverse polymerase superfamily, which currently comprises six families. We identified a structural core common to all right-handed polymerases, composed of 57 amino acid residues, harboring two positionally and chemically conserved residues, the catalytic aspartates. The structural conservation within each of the six families is considerable, for example, the structural core shared by family Y DNA polymerases covers over 90% of the polymerase domain of the Sulfolobus solfataricus Dpo4. Our phylogenetic analyses propose an early separation of RNA-dependent polymerases that use primers from those that are primer-independent. Furthermore, the exchange of polymerase genes between viruses and their hosts is evident. Because of this horizontal gene transfer, the phylogeny of polymerases does not always reflect the evolutionary history of the corresponding organisms.

RNA polymerase fidelity and transcriptional proofreading

Whereas mechanisms underlying the fidelity of DNA polymerases (DNAPs) have been investigated in detail, RNA polymerase (RNAP) fidelity mechanisms remained poorly understood. New functional and structural studies now suggest how RNAPs select the correct nucleoside triphosphate (NTP) substrate to prevent transcription errors, and how the enzymes detect and remove a misincorporated nucleotide during proofreading. Proofreading begins with fraying of the misincorporated nucleotide away from the DNA template, which pauses transcription. Subsequent backtracking of RNAP by one position enables nucleolytic cleavage of an RNA dinucleotide that contains the misincorporated nucleotide. Since cleavage occurs at the same active site that is used for polymerization, the RNAP proofreading mechanism differs from that used by DNAPs, which contain a distinct nuclease specific active site.

Synthetic lethality with the dut defect in Escherichia coli reveals layers of DNA damage of increasing complexity due to uracil incorporation

Synthetic lethality is inviability of a double-mutant combination of two fully viable single mutants, commonly interpreted as redundancy at an essential metabolic step. The dut-1 defect in Escherichia coli inactivates dUTPase, causing increased uracil incorporation in DNA and known synthetic lethalities [SL(dut) mutations]. According to the redundancy logic, most of these SL(dut) mutations should affect nucleotide metabolism. After a systematic search for SL(dut) mutants, we did identify a single defect in the DNA precursor metabolism, inactivating thymidine kinase (tdk), that confirmed the redundancy explanation of synthetic lethality. However, we found that the bulk of mutations interacting genetically with dut are in DNA repair, revealing layers of damage of increasing complexity that uracil-DNA incorporation sends through the chromosomal metabolism. Thus, we isolated mutants in functions involved in (i) uracil-DNA excision (ung, polA, and xthA); (ii) double-strand DNA break repair (recA, recBC, and ruvABC); and (iii) chromosomal-dimer resolution (xerC, xerD, and ftsK). These mutants in various DNA repair transactions cannot be redundant with dUTPase and instead reveal "defect-damage-repair" cycles linking unrelated metabolic pathways. In addition, two SL(dut) inserts (phoU and degP) identify functions that could act to support the weakened activity of the Dut-1 mutant enzyme, suggesting the "compensation" explanation for this synthetic lethality. We conclude that genetic interactions with dut can be explained by redundancy, by defect-damage-repair cycles, or as compensation.

Mitochondrial genome of the moon jelly Aurelia aurita (Cnidaria, Scyphozoa): A linear DNA molecule encoding a putative DNA-dependent DNA polymerase

The 16,937-nuceotide sequence of the linear mitochondrial DNA (mt-DNA) molecule of the moon jelly Aurelia aurita (Cnidaria, Scyphozoa) - the first mtDNA sequence from the class Scypozoa and the first sequence of a linear mtDNA from Metazoa - has been determined. This sequence contains genes for 13 energy pathway proteins, small and large subunit rRNAs, and methionine and tryptophan tRNAs. In addition, two open reading frames of 324 and 969 base pairs in length have been found. The deduced amino-acid sequence of one of them, ORF969, displays extensive sequence similarity with the polymerase [but not the exonuclease] domain of family B DNA polymerases, and this ORF has been tentatively identified as dnab. This is the first report of dnab in animal mtDNA. The genes in A. aurita mtDNA are arranged in two clusters with opposite transcriptional polarities; transcription proceeding toward the ends of the molecule. The determined sequences at the ends of the molecule are nearly identical but inverted and lack any obvious potential secondary structures or telomere-like repeat elements. The acquisition of mitochondrial genomic data for the second class of Cnidaria allows us to reconstruct characteristic features of mitochondrial evolution in this animal phylum.

The thermodynamics of template-directed DNA synthesis: base insertion and extension enthalpies

We used stopped-flow calorimetry to measure the overall enthalpy change associated with template-directed nucleotide insertion and DNA extension. Specifically, we used families of hairpin self-priming templates in conjunction with an exonuclease-free DNA polymerase to study primer extension by one or more dA or dT residues. Our results reveal exothermic heats between -9.8 and -16.0 kcal/bp for template-directed enzymatic polymerization. These extension enthalpies depend on the identity of the inserting base, the primer terminus, and/or the preceding base. Despite the complexity of the overall process, the sign, magnitude, and sequence dependence of these insertion and extension enthalpies are consistent with nearest-neighbor data derived from DNA melting studies. We recognize that the overall process studied here involves contributions from a multitude of events, including dNTP to dNMP hydrolysis, phosphodiester bond formation, and enzyme conformational changes. It is therefore noteworthy that the overall enthalpic driving force per base pair is of a magnitude similar to that expected for addition of one base pair or base stack per insertion event, rather than that associated with the rupture and/or formation of covalent bonds, as occurs during this catalytic process. Our data suggest a constant sequence-independent background of compensating enthalpic contributions to the overall process of DNA synthesis, with discrimination expressed by differences in noncovalent interactions at the template-primer level. Such enthalpic discrimination underscores a model in which complex biological events are regulated by relatively modest energy balances involving weak interactions, thereby allowing subtle mechanisms of regulation.

Human DNA polymerase lambda possesses terminal deoxyribonucleotidyl transferase activity and can elongate RNA primers: implications for novel functions

DNA polymerase lambda is a novel enzyme of the family X of DNA polymerases. The recent demonstration of an intrinsic 5'-deoxyribose-5'-phosphate lyase activity, a template/primer dependent polymerase activity, a distributive manner of DNA synthesis and sequence similarity to DNA polymerase beta suggested a novel beta-like enzyme. All these properties support a role of DNA polymerase lambda in base excision repair. On the other hand, the biochemical properties of the polymerisation activity of DNA polymerase lambda are still largely unknown. Here we give evidence that human DNA polymerase lambda has an intrinsic terminal deoxyribonucleotidyl transferase activity that preferentially adds pyrimidines onto 3'OH ends of DNA oligonucleotides. Furthermore, human DNA polymerase lambda efficiently elongates an RNA primer hybridized to a DNA template. These two novel properties of human DNA polymerase lambda might suggest additional roles for this enzyme in DNA replication and repair processes.

DNA replication fidelity

DNA replication fidelity is a key determinant of genome stability and is central to the evolution of species and to the origins of human diseases. Here we review our current understanding of replication fidelity, with emphasis on structural and biochemical studies of DNA polymerases that provide new insights into the importance of hydrogen bonding, base pair geometry, and substrate-induced conformational changes to fidelity. These studies also reveal polymerase interactions with the DNA minor groove at and upstream of the active site that influence nucleotide selectivity, the efficiency of exonucleolytic proofreading, and the rate of forming errors via strand misalignments. We highlight common features that are relevant to the fidelity of any DNA synthesis reaction, and consider why fidelity varies depending on the enzymes, the error, and the local sequence environment.

Analysis of O29 DNA polymerase by partial proteolysis: binding of terminal protein in the double-stranded DNA channel

ø29 DNA polymerase, which belongs to the family of the eukaryotic type DNA polymerases, is able to use two kinds of primers to initiate DNA replication: DNA and terminal protein (TP). By partial proteolysis we have studied the regions of ø29 DNA polymerase involved in primer binding. With proteinase K, no change in the proteolytic pattern was observed upon DNA binding, suggesting that it does not induce a global conformational change in ø29 DNA polymerase. Conversely, two of the three main cleavage sites obtained by partial digestion of free ø29 DNA polymerase with endoproteinase LysC were protected upon DNA binding, indicating that the DNA could be occluding these cleavage sites to the protease either directly by itself and/or indirectly by induction of local conformational changes affecting their exposure. Partial proteolysis with endoproteinase LysC of ø29 DNA polymerase/TP heterodimer resulted in a protection and digestion pattern similar to that obtained with DNA, suggesting that both primers, DNA and TP, fit in the same double-stranded DNA-binding channel and protect the same regions of ø29 DNA polymerase.

DNA binding properties and processive proofreading of herpes simplex virus type 1 DNA polymerase

The DNA binding properties of herpes simplex virus type 1 DNA polymerase (HSV pol), an alpha-like DNA polymerase, were investigated using an optimized band-shift assay. With linear double-stranded DNA (dsDNA), HSV pol formed two complexes. The favored DNA template was dsDNA with protruding 5'-phosphoryl termini. Stable binding of HSV pol was observed with a DNA hairpin containing a primer region of 9 bp of dsDNA, a 6-base loop and a 12-base 5'-terminal single-stranded extension. For the polymerization activity of HSV pol on poly(dT) an optimal primer length of 8 to 10 nucleotides was determined. The DNA binding event could be clearly separated from the enzymatic activities by its unique response to divalent cations and salt. Under ionic strength conditions where HSV pol exerts optimal polymerization activity in vitro, novel polymerase-DNA complexes were detected by band-shift analysis. These new complexes were similar while either in DNA polymerase or 3',5' exonuclease mode. Using a polymerase trap method and high-resolution polyacrylamide gel electrophoresis, HSV pol demonstrated internal switching from 3',5' exonuclease to polymerase-active mode during one DNA binding event. These results support the role of HSV pol as a true replicase, which proofreads without dissociating from the DNA template.

Phi 29 DNA polymerase requires the N-terminal domain to bind terminal protein and DNA primer substrates

A 44 kDa C-terminal fragment of phi 29 DNA polymerase has been separately expressed and purified from Escherichia coli cells. As expected, the truncated protein lacked the 3'-5' exonuclease activity and strand-displacement capacity, previously mapped in the N-terminal domain of phi 29 DNA polymerase. On the other hand, the 44 kDa C-terminal fragment retained polymerase activity when using Mn2+ as metal activator, although the catalytic efficiency was greatly reduced with respect to that of the complete enzyme. Moreover, and in contrast to the high processivity exhibited by phi 29 DNA polymerase (> 70 kb), polymerization by its C-terminal domain was completely distributive. All these polymerization defects were related to a strong impairment of DNA binding, suggesting that additional contacts present in the N-terminal domain are important for an optimal stabilization and translocation of the DNA during polymerization. Moreover, the C-terminal domain showed a very reduced capacity to initiate terminal protein (TP)-primed DNA replication, as a consequence of a weakened interaction with the TP primer, and a lack of activation by protein p6, the initiator of phi 29 DNA replication. We conclude that the C-terminal portion of phi 29 DNA polymerase (residues 188 to 575), although having a structural entity as the domain responsible for the synthetic activities, requires the N-terminal domain to provide important contacts for the two different substrates, DNA and TP, that prime DNA synthesis. These results support the hypothesis of a modular organization of enzymatic activities in DNA-dependent DNA polymerases, but emphasize the functional coordination required for coupling DNA synthesis and proofreading, and for the more specific functions (TP-priming, high processivity and strand-displacement) inherent to phi 29 DNA polymerase.

Evolution of viral DNA-dependent DNA polymerases

DNA viruses as their host cells require a DNA-dependent DNA polymerase (Pol) to faithfully replicate their genomic information. Large eukaryotic DNA viruses as well as bacterial viruses encode a specific Pol equipped with a proofreading 3'-5'-exonuclease, and other replication proteins. All known viral Pol belong to family A and family B Pol. Common to all viral Pol is the conservation of the 3'-5'-exonuclease domain manifested by the three sequence motifs Exo I, Exo II, and Exo III. The polymerase domain of family A and B Pol is clearly distinguishable. Family A Pol share 9 distinct consensus sequences, only two of them are convincingly homologous to sequence motif B of family B Pol. The putative sequence motifs A, B, and C of the polymerase domain are located near the C-terminus in family A Pol and more central in family B Pol. Thus, family A Pol show a significant greater spacing between the Exo III motif and the Pol motif A that is especially extended in the case of the mitochondrial Pol gamma. From each host and virus family whenever possible the consensus sequences of two distantly related polymerase species were aligned for assessment of phylogenetic trees, using both maximum parsimony and distance methods, and evaluated by bootstrap analysis. Three alternative methods yielded trees with identical major groupings. A subdivision of viral family B Pol was achieved resulting in a branch with Pol carrying out a protein-primed mechanism of DNA replication, including adenoviruses, bacteriophages and linear plasmids of plant and fungal origin. Archaebacterial Pol and cellular Pol epsilon were consistently found at the base of this branch. Another major branch comprised alpha- and delta-like viral Pol from mammalian herpesviruses, fish lymphocystis disease virus, insect ascovirus, and chlorella virus. Due to a lower branch integrity Pol of T-even bacteriophages, poxviruses, African swine fever virus, fish herpesvirus, and baculoviruses were not clearly resolved and placed in alternate groupings. A composite and rooted tree of family A and B Pol shows that viral Pol with a protein-priming requirement represent the oldest viral Pol species suggesting that the protein-primed mechanism is one of the earliest modes of viral DNA replication.

How E. coli DNA polymerase I (Klenow fragment) distinguishes between deoxy- and dideoxynucleotides

Deoxy- and dideoxynucleotides differ only in whether they have a hydroxyl substituent at C-3' of the ribose moiety, and yet the Klenow fragment DNA polymerase prefers the natural (dNTP) substrate by several thousandfold. We have used this preference in order to investigate how Klenow fragment interacts with the sugar portion of an incoming dNTP. We screened mutant derivatives of Klenow fragment so as to identify those amino acid residues that play important roles in distinguishing between dNTPs and ddNTPs. Substitution of Phe762 with Ala or Tyr caused a dramatic decrease in the discrimination against ddNTPs, while mutations in Tyr766 and Glu710 had a smaller effect, suggesting that these two side-chains play secondary roles in the selection of dNTPs over ddNTPs. In order to understand the interactions in the enzyme-DNA-dNTP ternary complex, pre-steady-state kinetic parameters for the incorporation of dNTPs and ddNTPs were determined for wild-type Klenow fragment and for mutant derivatives that showed changes in dNTP/ddNTP discrimination. From elemental effect measurements we infer that selection against dideoxynucleotides takes place in the transition state for the conformational change that precedes phosphoryl transfer. The crucial role of the Phe762 side-chain appears to be to constrain the dNTP molecule so that the 3'-OH can make an interaction with another group within the ternary complex. When Tyr is substituted at position 762, the same interactions can take place to position the dNTP, but specificity against the ddNTP is lost because the phenolic OH can compensate for the missing 3'-OH of the nucleotide. Substitution of the smaller Ala side-chain results in a loss in specificity because the dNTP is no longer appropriately constrained. Measurement of reaction rates as a function of magnesium ion concentration suggests that the interaction made with the dNTP 3'-OH may involve a metal ion and the Glu710 side-chain, the simplest scenario being that both the 3'-OH and the carboxylate of Glu710 are ligands to the same metal ion.

Kinetics of DNA polymerase I (Klenow fragment exo-) activity on damaged DNA templates: effect of proximal and distal template damage on DNA synthesis

Mutagenic DNA adducts have been analyzed with respect to the rate of nucleotide insertion opposite the modified base, extension from that "mispair", and nucleotide insertion preference. To complement and extend these studies we have investigated the long-range effects of DNA adducts on DNA polymerase activity. To address this question, primer extension reactions were performed using DNA polymerase I, Klenow fragment exo-. Templates containing 7,8-dihydro-8-oxoguanine, dG-C8-aminofluorene, dG-C8-(acetylamino)fluorene, and the model abasic site, tetrahydrofuran, were used for these studies, and the steady-state kinetics of correct nucleotide insertion were determined at positions (-2), (-1), (+1), (+2), (+3), and (+5) with respect to the template lesion. The kinetics of primer extension by Klenow fragment exo- at template positions 3' to the lesion showed only a small inhibitory effect, <3-fold, even for the strongly blocking lesion, dG-C8-(acetylamino)fluorene, indicating that Klenow fragment exo- activity is not greatly affected by lesions in the single-stranded portion of the template-primer. In contrast, a dramatic decrease in the frequency of primer extension was observed at template sites 5' to the site of adduction. Inhibition of polymerase activity decreased as the distance from the lesion increased; however, a relatively large effect was seen at the (+2) and (+3) positions for dG-C8-(acetylamino)fluorene and tetrahydrofuran. For these blocking lesions, the effect on extension 5 bases from the lesion was greatly reduced. We conclude from these studies that DNA damage at positions remote from the site of the lesion affects DNA polymerase function.

Functional consequences and exonuclease kinetic parameters of point mutations in bacteriophage T4 DNA polymerase

Three groups of T4 DNA polymerase mutants were prepared and characterized. In the first group, Ala and Asn were substituted for four acidic residues in the exonuclease domain that were chosen on the basis of their sequence alignment with the Klenow fragment from Escherichia coli DNA polymerase I. Two divalent metal ions required for catalyzing the 3'-5' exonuclease reaction are ligated by carboxyl groups from these conserved Asp and Glu residues. The Ala and Asn replacements have a profound effect on the exonuclease activity of T4 DNA polymerase and also have a significant, but less pronounced influence on its polymerase activity which is located in a domain distal to the exonuclease region. The kcat values for the exonuclease reaction were reduced by 3-4 orders of magnitude by these replacements, but the values of Km(app) did not differ greatly from the wild-type enzyme. The second group consists of replacements of other residues, that are conserved in the exonuclease domain of eukaryotic DNA polymerases, but do not contribute to divalent metal ion coordination. Many of these alterations resulted in decreased exonuclease and/or polymerase activity. Mutants in the third group have substitutions of conserved residues in the polymerase domain which diminished polymerase and altered exonuclease activities. Our results, combined with structural data on crystals of protein N388, a truncated form of T4 DNA polymerase (Wang et al., 1996), show that: (i) the reduction in the relative specific exonuclease activities of mutants in the first group was significantly less than that of mutants in the Klenow fragment, despite the nearly identical geometric arrangement of the metal liganding groups in two proteins; (ii) altered residues, that affect exonuclease and/or polymerase activities in mutants of the second group, cluster within a small area of the exonuclease domain, suggesting that this area may be directly or indirectly involved in polymerase activity; (iii) mutations in the third group, which affect polymerase and exonuclease activities, may participate in DNA and dNTP binding. Our results point to the functional interdependence of the polymerase and exonuclease domains in T4 DNA polymerase, a property not observed with the Klenow fragment.

Herpes simplex virus type 1 DNA polymerase. Mutational analysis of the 3'-5'-exonuclease domain

Like true DNA replicases, herpes simplex virus type 1 DNA polymerase is equipped with a proofreading 3'-5'-exonuclease. In order to assess the functional significance of conserved residues in the putative exonuclease domain, we introduced point mutations as well as deletions within and near the conserved motifs' exonuclease (Exo) I, II, and III of the DNA polymerase gene from a phosphonoacetic acid-resistant derivative of herpes simplex virus-1 strain ANG. We examined the catalytic activities of the partially purified enzymes after overexpression by recombinant baculovirus. Mutations of the motifs' Exo I (D368A, E370A) and Exo III (Y577F, D581A) yielded enzymes without detectable and severely impaired 3'-5'-exonuclease activities, respectively. Except for the Exo I mutations, all other Exo mutations examined affected both exonuclease and polymerization activities. Mutant enzymes D368A, E370A, Y557S, and D581A showed a significant ability to extend mispaired primer termini. Mutation Y557S resulted in a strong reduction of the 3'-5'-exonuclease activity and in a polymerase activity that was hyperresistant to phosphonoacetic acid. The results of the mutational analysis provide evidence for a tight linkage of polymerase and 3'-5'-exonuclease activity in the herpesviral enzyme.

Structural and functional organization of the DNA polymerase of bacteriophage T7

The 80-kDa gene 5 protein encoded by bacteriophage T7 shares significant amino acid homology with the large fragment of Escherichia coli DNA polymerase I (Klenow fragment). Like the Klenow fragment, T7 gene 5 protein has both DNA polymerase and 3' to 5' exonuclease activities. However, unlike the Klenow fragment, T7 gene 5 protein binds tightly to E. coli thioredoxin to form a complex that has a high processivity of nucleotide polymerization. In order to identify the domains of gene 5 protein responsible for polymerization, hydrolysis, and binding of thioredoxin, we have analyzed proteolytic fragments of gene 5 protein. Cleavage of the protein within one protease-sensitive region (residue 250-300) yields two molecular weight species of peptides of 32-37 and 43-51 kDa derived from the N-terminal and C-terminal region, respectively. DNA polymerase activity is found within the C-terminal fragments and exonuclease activity within the N-terminal fragments. Thioredoxin stimulates the DNA polymerase activity of the C-terminal fragments. All fragments bind to DNA. In addition to delineating the polymerase and exonuclease domains, the protease-sensitive region appears to interact with E. coli thioredoxin. Thioredoxin protects this region from proteolysis, and alteration of this region reduces the ability of thioredoxin to stimulate polymerase activity.

Elucidation of the metal-binding properties of the Klenow fragment of Escherichia coli polymerase I and bacteriophage T4 DNA polymerase by lanthanide(III) luminescence spectroscopy

BACKGROUND

The exonuclease active site of the Klenow fragment (KF) of Escherichia coli DNA polymerase I has a double binding site for the two essential divalent metal ions in the presence of the nucleotide monophosphate dTMP.

RESULTS

The luminescence spectroscopy observed upon binding of Eu3+ to the exonuclease active site of T4 DNA polymerase was interpreted relative to the binding of Eu3+ or Tb3+ observed with KF. Both wild-type enzymes tightly bind a single Ln3+ ion but in two isomeric forms. The single mutants of KF (D424A) and T4 (D219A) also bind a single Eu3+ ion tightly, but the alignment of the coordinating ligands is altered. The KF double mutant (D355A, E357A) exhibits a markedly altered and weakened binding site (Kd = 20-26 microM). Eu3+ serves as a competitive inhibitor of Mg2+-induced polymerase and exonuclease activity, validating its use as a probe for these active sites.

CONCLUSIONS

Ln3+ luminescence spectroscopy is established as a sensitive way to determine the consequences of exonuclease binding-site mutations and to examine binding site similarities and differences among DNA polymerases from different sources. The binding sites of KF and T4 DNA polymerase are shown to be quite similar.

Subunit structure of mitochondrial DNA polymerase from Drosophila embryos. Physical and immunological studies

The subunit structure of mitochondrial DNA polymerase from Drosophila embryos has been examined by a combination of physical and immunological methods. A highly specific rabbit antiserum directed against the native enzyme was developed and found to recognize specifically its two subunits in immunoblot and immunoprecipitation analyses. That and the potent inhibition by the rabbit antiserum of the DNA polymerase and 3'-->5' exonuclease activities of the nearly homogeneous mitochondrial DNA polymerase provide strong evidence for the physical association of the 3'-->5' exonuclease with the two subunit enzyme. An immunoprecipitation analysis of crude enzyme fractions showed that the two subunits of Drosophila mitochondrial DNA polymerase are intact, and an in situ gel proteolysis analysis showed that they are structurally distinct. Template-primer DNA binding studies demonstrated formation of a stable and discrete enzyme-DNA complex in the absence of accessory proteins. Photochemical cross-linking of the complexes by UV light indicated that the alpha but not the beta subunit of mitochondrial DNA polymerase makes close contact with DNA, and limited digestion of the native enzyme with trypsin showed that an approximately 65-kDa proteolytic fragment of the alpha subunit retains the DNA binding function.

The 3'-5' exonuclease site of DNA polymerase III from gram-positive bacteria: definition of a novel motif structure

The primary structure of the 3'-5' exonuclease (Exo) site of the Gram+ bacterial DNA polymerase III (Pol III) was examined by site-directed mutagenesis of Bacillus subtilis Pol III (BsPol III). It was found to differ significantly from the conventional three-motif substructure established for the Exo site of DNA polymerase I of Escherichia coli (EcPol I) and the majority of other DNA polymerase-exonucleases. Motifs I and II were conventionally organized and anchored functionally by the predicted carboxylate residues. However, the conventional downstream motif, motif III, was replaced by motif III epsilon, a novel 55-amino-acid (aa) segment incorporating three essential aa (His565, Asp533 and Asp570) which are strictly conserved in three Gram+ Pol III and in the Ec Exo epsilon (epsilon). Despite its unique substructure, the Gram+ Pol III-specific Exo site was conventionally independent of Pol, the site of 2'-deoxyribonucleoside 5-triphosphate (dNTP) binding and polymerization. The entire Exo site, including motif III epsilon, could be deleted without profoundly affecting the enzyme's capacity to polymerize dNTPs. Conversely, Pol and all other sequences downstream of the Exo site could be deleted with little apparent effect on Exo activity. Whether the three essential aa within the unique motif III epsilon substructure participate in the conventional two-metal-ion mechanism elucidated for the model Exo site of EcPol I, remains to be established.

Deoxynucleoside triphosphate and pyrophosphate binding sites in the catalytically competent ternary complex for the polymerase reaction catalyzed by DNA polymerase I (Klenow fragment)

We have employed site-directed mutagenesis to identify those amino acid residues that interact with the deoxynucleoside triphosphate (dNTP) and pyrophosphate in the Klenow fragment-DNA-dNTP ternary complex. Earlier structural, mutagenesis, and labeling studies have suggested that the incoming dNTP molecule contacts a region on one side of the polymerase cleft, primarily involving residues within the so-called "fingers" subdomain. We have made mutations in residues seen to be close to the dNTP in the crystal structure of the Klenow fragment-dNTP binary complex and have examined their kinetic parameters, particularly Km(dNTP). The results are consistent with the notion that there are significant differences between the dNTP interactions in the binary and ternary complexes, although some contacts may be present in both. When dTTP is the incoming nucleotide, the side chains of Arg754 and Phe762 make the largest contributions to binding; measurement of Km(PPi) suggests that Arg754 contacts the beta- or gamma-phosphate of the dNTP. With dGTP, the contribution of Arg754 remains the same, but the additional interactions are provided by both Lys758 and Phe762, suggesting that the binding of the incoming dNTP is not identical under all circumstances. Mutations in Arg754 and Lys758 also cause a substantial decrease in the rate of polymerase-catalyzed incorporation, and sulfur elemental effect measurements indicate that loss of Arg754 (and perhaps also Lys758) slows the rate of the chemical step of the reaction. Mutations of Arg682, His734, and Tyr766 affect the binding of DNA, suggesting that these mutations, whose effect on dNTP binding is small, may influence dNTP binding indirectly via the positioning of the DNA template-primer.

Melting of a DNA helix terminus within the active site of a DNA polymerase

Accurate synthesis of DNA by polymerase is due in part to the selective removal of misincorporated nucleotides by a 3'-5' exonuclease activity (proofreading). Proofreading by an exonuclease domain containing a single-stranded DNA binding site may involve local melting of a duplex DNA substrate. Here we use time-resolved fluorescence spectroscopy to analyze the local melting of a DNA duplex terminus induced by the Klenow fragment of DNA polymerase I. Four oligodeoxynucleotide primer/templates were prepared, each containing the fluorescent adenine analog 2-aminopurine (A*) at the primer 3' terminus, and one of the common DNA bases opposite the A* residue. Fluorescence decays of the duplex DNAs and the single primer oligonucleotide were jointly analyzed using global analysis procedures. Four lifetime components were resolved in the duplex DNAs, representing distinct conformational states of the terminal A* residue: paired A* bases, partially stacked A* bases, and extended A* bases. The variation of the apparent fraction of paired A* bases with temperature was in accord with optical melting data, and the extent of base pairing observed in each duplex was consistent with the base-pairing preferences of A* established in other studies. These results establish that the fluorescence decay characteristics of A* can be used to examine base-pairing interactions at a DNA duplex terminus. Since the fluorescence of A* can be observed without interference from protein amino acid residues, unlike existing methods for monitoring DNA melting transitions, this method was used to examine the extent to which Klenow fragment could induce fraying at each duplex terminus.(ABSTRACT TRUNCATED AT 250 WORDS)

A DNA-polymerase-related reading frame (pol-r) in the mtDNA of Secale cereale

Mitochondrial (mt)DNA of Secale cereale contains an open reading frame (pol-r), the potential translation product of which shows significant homology to the type-B DNA polymerase encoded by the S1 plasmid of Zea mays; it contains the highly-conserved domains IIa to V of family B polymerases. The pol-r ORF is transcribed, as proven by RT-PCR, but the transcript is not edited. Upstream of the putative start codon a potential promoter motif was detected, fitting well into the postulated consensus sequence of the transcription initiation regions of Z. mays and Triticum aestivum. The pol-r ORF occurs in mtDNA of the fertile rye variety "Halo" and the cytoplasmic male-sterile (CMS) line "Pampa". Both ORFs are almost identical, apart from the 3' terminus; pol-r from Halo can code for 289 amino acids, pol-r from Pampa for 312 amino acids. Based on codon usage and the lack of editing, pol-r is considered to be a "young" gene, probably introduced in the mtDNA of rye by recombination with an mt plasmid.

Re-engineering the polymerase domain of Klenow fragment and evaluation of overproduction and purification strategies

We describe experiments to produce large quantities of the polymerase domain of E. coli DNA polymerase I for biochemical and biophysical studies. The polymerase domain derivative used in previous studies was insoluble when overproduced and tended to aggregate during purification. These problems were solved by a combination of two distinct strategies. By changing the expression system, we were able to obtain the overproduced protein in a soluble form, a necessary first step since attempts to purify the polymerase domain from the insoluble pellet were unsuccessful. The tendency of the polymerase domain to aggregate was eliminated by re-engineering the protein so as to remove both a solvent-exposed hydrophobic patch and a potentially unstructured region at the extreme N-terminus. Unlike the original construct, the re-engineered derivatives chromatographed as a single species and could be purified to homogeneity in good yield. Our experience in this study emphasizes the level of ignorance of the factors that influence protein overproduction and the need, in difficult cases, to evaluate many strategies in a semi-empirical manner.

Crystal structure of bacteriophage T7 RNA polymerase at 3.3 A resolution

The crystal structure of T7 RNA polymerase reveals a molecule organized around a cleft that can accommodate a double-stranded DNA template. A portion (approximately 45%) of the molecule displays extensive structural homology to the polymerase domain of Klenow fragment and more limited homology to the human immunodeficiency virus HIV-1 reverse transcriptase. A comparison of the structures and sequences of these polymerases identifies structural elements that may be responsible for discriminating between ribonucleotide and deoxyribonucleotide substrates, and RNA and DNA templates. The relative locations of the catalytic site and a specific promoter recognition residue allow the orientation of the polymerase on the template to be defined.

Multi-stage proofreading in DNA replication

The mechanisms by which DNA polymerases achieve their remarkable fidelity, including base selection and proofreading, are briefly reviewed. Nine proofreading models from the current literature are evaluated in the light of steady-state and transient kinetic studies of E. coli DNA polymerase I, the best-studied DNA polymerase. One model is demonstrated to predict quantitatively the response of DNA polymerase I to three mutagenic probes of proofreading: exogenous pyrophosphate, deoxynucleoside monophosphates, and the next correct deoxynucleoside triphosphate substrate, as well as the response to combinations of these probes. The theoretical analysis allows elimination of many possible proofreading mechanisms based on the kinetic data. A structural hypothesis links the kinetic analysis with crystallographic, NMR and genetic studies. It would appear that DNA polymerase I proofreads each potential error twice, at the same time undergoing two conformational changes within a catalytic cycle. Multi-stage proofreading is more efficient, and may be utilized in other biological systems as well. In fact, recent evidence suggests that fidelity of transfer RNA charging may be ensured by a similar mechanism.

Genetic characterization of the vaccinia virus DNA polymerase: cytosine arabinoside resistance requires a variable lesion conferring phosphonoacetate resistance in conjunction with an invariant mutation localized to the 3'-5' exonuclease domain

In this report, we describe the isolation, molecular genetic mapping, and phenotypic characterization of vaccinia virus mutants resistant to cytosine arabinoside (araC) and phosphonoacetic acid (PAA). At 37 degrees C, 8 microM araC was found to prevent macroscopic plaque formation by wild-type virus and to cause a 10(4)-fold reduction in viral yield. Mutants resistant to 8 microM araC were selected by serial passage of a chemically mutagenized viral stock in the presence of drug. Because recovery of mutants required that initial passages be performed under less stringent selective conditions, and because plaque-purified isolates were found to be cross-resistant to 200 micrograms of PAA per ml, it seemed likely that resistance to araC required more than one genetic lesion. This hypothesis was confirmed by genetic and physical mapping of the responsible mutations. PAAr was accorded by the acquisition of one of three G-A transitions in the DNA polymerase gene which individually alter cysteine 356 to tyrosine, glycine 372 to aspartic acid, or glycine 380 to serine. AraCr was found to require one of these substitutions plus an additional T-C transition within codon 171 of the DNA polymerase gene, a change which replaces the wild-type phenylalanine with serine. Congenic viral stocks carrying one of the three PAAr lesions, either alone or in conjunction with the upstream araCr lesion, in an otherwise wild-type background were generated. The PAAr mutations conferred nearly complete resistance to PAA, a slight degree of resistance to araC, hypersensitivity to aphidicolin, and decreased spontaneous mutation frequency. Addition of the mutation at codon 171 significantly augmented araC resistance and aphidicolin hypersensitivity but caused no further change in mutation frequency. Several lines of evidence suggest that the PAAr mutations primarily affect the deoxynucleoside triphosphate-binding site, whereas the codon 171 mutation, lying within a conserved motif associated with 3'-5' exonuclease function, is postulated to affect the proofreading exonuclease of the DNA polymerase.

High-level expression, purification, and enzymatic characterization of full-length Thermus aquaticus DNA polymerase and a truncated form deficient in 5' to 3' exonuclease activity

The Thermus aquaticus DNA polymerase I (Taq Pol I) gene was cloned into a plasmid expression vector that utilizes the strong bacteriophage lambda PL promoter. A truncated form of Taq Pol I was also constructed. The two constructs made it possible to compare the full-length 832-amino-acid Taq Pol I and a deletion derivative encoding a 544-amino-acid translation product, the Stoffel fragment. Upon heat induction, the 832-amino-acid construct produced 1-2% of total protein as Taq Pol I. The induced 544-amino-acid construct produced 3% of total protein as Stoffel fragment. Enzyme purification included cell lysis, heat treatment followed by Polymin P precipitation of nucleic acids, phenyl sepharose column chromatography, and heparin-Sepharose column chromatography. For full-length 94-kD Taq Pol I, yield was 3.26 x 10(7) units of activity from 165 grams wet weight cell paste. For the 61-kD Taq Pol I Stoffel fragment, the yield was 1.03 x 10(6) units of activity from 15.6 grams wet weight cell paste. The two enzymes have maximal activity at 75 degrees C to 80 degrees C, 2-4 mM MgCl2 and 10-55 mM KCl. The nature of the substrate determines the precise conditions for maximal enzyme activity. For both proteins, MgCl2 is the preferred cofactor compared to MnCl2, CoCl2, and NiCl2. The full-length Taq Pol I has an activity half-life of 9 min at 97.5 degrees C. The Stoffel fragment has a half-life of 21 min at 97.5 degrees C. Taq Pol I contains a polymerization-dependent 5' to 3' exonuclease activity whereas the Stoffel fragment, deleted for the 5' to 3' exonuclease domain, does not possess that activity. A comparison is made among thermostable DNA polymerases that have been characterized; specific activities of 292,000 units/mg for Taq Pol I and 369,000 units/mg for the Stoffel fragment are the highest reported.

Conformational changes induced in herpes simplex virus DNA polymerase upon DNA binding

Herpesvirus DNA polymerases are prototypes for alpha-like DNA polymerases and important targets for antiherpesvirus drugs. We have investigated changes in the catalytic subunit of herpes simplex virus DNA polymerase following DNA binding by using the techniques of endogeneous fluorescence quenching and limited proteolysis. The fluorescence studies revealed a reduction in the rate of quenching by acrylamide in the presence of DNA without changes in the wavelength of the emission peak or in the lifetime of the fluorophore, consistent with the possibility of conformational changes. Strikingly, the proteolysis studies revealed that binding to a variety of natural and synthetic DNA and RNA molecules induced the appearance of a new cleavage site for trypsin near residue 1060 of the protein and increased cleavage by trypsin near the center of the protein. The extent of these cleavages correlated with the affinity of the polymerase for these ligands. These data provide strong evidence that binding to nucleic acid polymers induces substantial localized conformational changes in the polymerase. The locations of enhanced tryptic cleavage near sites implicated in substrate recognition and interaction with a processivity factor suggest that the conformational changes are important for catalysis and processivity of this prototype alpha-like DNA polymerase. Inhibition of these changes may provide a mechanism for antiherpesvirus drugs.

Streptococcus pneumoniae DNA polymerase I lacks 3'-to-5' exonuclease activity: localization of the 5'-to-3' exonucleolytic domain

The Streptococcus pneumoniae polA gene was altered at various positions by deletions and insertions. The polypeptides encoded by these mutant polA genes were identified in S. pneumoniae. Three of them were enzymatically active. One was a fused protein containing the first 11 amino acid residues of gene 10 from coliphage T7 and the carboxyl-terminal two-thirds of pneumococcal DNA polymerase I; it possessed only polymerase activity. The other two enzymatically active proteins, which contained 620 and 351 amino acid residues from the amino terminus, respectively, lacked polymerase activity and showed only exonuclease activity. These two polymerase-deficient proteins and the wild-type protein were hyperproduced in Escherichia coli and purified. In contrast to the DNA polymerase I of Escherichia coli but similar to the corresponding enzyme of Thermus aquaticus, the pneumococcal enzyme appeared to lack 3'-to-5' exonuclease activity. The 5'-to-3' exonuclease domain was located in the amino-terminal region of the wild-type pneumococcal protein. This exonuclease activity excised deoxyribonucleoside 5'-monophosphate from both double- and single-stranded DNAs. It degraded oligonucleotide substrates to a decameric final product.

The polymerase domain of Streptococcus pneumoniae DNA polymerase I. High expression, purification and characterization

The 3'-terminal two-thirds of the Streptococcus pneumoniae polA gene was cloned in an Escherichia coli genefusion vector with inducible expression. The resulting recombinant plasmid (pSM10) directs the hyperproduction of a polypeptide of 70.6 kDa corresponding to the C-terminal fragment of pneumococcal DNA polymerase I. Induced cells synthesized catalytically active protein to the extent of 7% of the total soluble protein in the cells. The polymerase fragment was purified to greater than 90% homogeneity with a yield of 1.5 mg pure protein/l culture. The protein has DNA polymerase activity, but no exonuclease activity. The enzyme requires a divalent cation (MgCl2 or MnCl2) for polymerization of DNA. Comparison of the mutant and wild-type pneumococcal polymerases shows that the construction did not affect the enzymatic affinity for the various substrates. The mutant protein, like its parent DNA polymerase I, exhibited an intermediate level of activity with primed single-stranded DNA. At high molar ratio of enzyme/DNA substrate, the polymerase fragment catalyzes strand displacement and switching after completing the replication of a primed single-stranded M13 DNA molecule.

Polymerization activity of an alpha-like DNA polymerase requires a conserved 3'-5' exonuclease active site

Most DNA polymerases are multifunctional proteins that possess both polymerizing and exonucleolytic activities. For Escherichia coli DNA polymerase I and its relatives, polymerase and exonuclease activities reside on distinct, separable domains of the same polypeptide. The catalytic subunits of the alpha-like DNA polymerase family share regions of sequence homology with the 3'-5' exonuclease active site of DNA polymerase I; in certain alpha-like DNA polymerases, these regions of homology have been shown to be important for exonuclease activity. This finding has led to the hypothesis that alpha-like DNA polymerases also contain a distinct 3'-5' exonuclease domain. We have introduced conservative substitutions into a 3'-5' exonuclease active site homology in the gene encoding herpes simplex virus DNA polymerase, an alpha-like polymerase. Two mutants were severely impaired for viral DNA replication and polymerase activity. The mutants were not detectably affected in the ability of the polymerase to interact with its accessory protein, UL42, or to colocalize in infected cell nuclei with the major viral DNA-binding protein, ICP8, suggesting that the mutation did not exert global effects on protein folding. The results raise the possibility that there is a fundamental difference between alpha-like DNA polymerases and E. coli DNA polymerase I, with less distinction between 3'-5' exonuclease and polymerase functions in alpha-like DNA polymerases.

Polymerization activity of an alpha-like DNA polymerase requires a conserved 3'-5' exonuclease active site

Most DNA polymerases are multifunctional proteins that possess both polymerizing and exonucleolytic activities. For Escherichia coli DNA polymerase I and its relatives, polymerase and exonuclease activities reside on distinct, separable domains of the same polypeptide. The catalytic subunits of the alpha-like DNA polymerase family share regions of sequence homology with the 3'-5' exonuclease active site of DNA polymerase I; in certain alpha-like DNA polymerases, these regions of homology have been shown to be important for exonuclease activity. This finding has led to the hypothesis that alpha-like DNA polymerases also contain a distinct 3'-5' exonuclease domain. We have introduced conservative substitutions into a 3'-5' exonuclease active site homology in the gene encoding herpes simplex virus DNA polymerase, an alpha-like polymerase. Two mutants were severely impaired for viral DNA replication and polymerase activity. The mutants were not detectably affected in the ability of the polymerase to interact with its accessory protein, UL42, or to colocalize in infected cell nuclei with the major viral DNA-binding protein, ICP8, suggesting that the mutation did not exert global effects on protein folding. The results raise the possibility that there is a fundamental difference between alpha-like DNA polymerases and E. coli DNA polymerase I, with less distinction between 3'-5' exonuclease and polymerase functions in alpha-like DNA polymerases.

Structural aspects of protein-DNA recognition

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Continuous microspectrophotometric measurement of DNA polymerase activity: application to the Klenow fragment of Escherichia coli DNA polymerase I and human immunodeficiency virus type 1 reverse transcriptase

Progress of DNA- and/or RNA-directed DNA polymerization reactions can be measured continuously using circular dichroism (CD) or ultraviolet (UV) spectroscopy. In the presence of the Klenow fragment of Escherichia coli DNA polymerase I, a CD change of -0.27 +/- 0.06 millidegree at 248 nm and a UV change of -2.7 +/- 0.3 milliabsorbance units at 275 nm occur upon incorporation of 120 pmol of dTMP in a reaction volume of 120 microliters (1 microM dTMP incorporation) into a synthetic template-primer, p(dA)40-60.p(dT)20. The transcription of poly(A).p(dT)12-18 by reverse transcriptases can also be monitored using these methods. Kinetic parameters for the polymerization reaction catalyzed by the Klenow fragment were determined from initial velocity measurements using CD or UV assays and were in close agreement with those measured by the standard single point radiochemical filtration assay. The generality of optical techniques for the measurement of DNA polymerase activity was shown by the use of a partially self-complementary hairpin-shaped oligonucleotide substrate for the Klenow fragment. Addition of a single nucleotide residue under steady-state conditions to this 35-mer at a concentration of 1.5-3 microM gave an easily measurable absorbance decrease at 275 nm, and the absorbance changes upon sequential addition of nucleotide units were additive.

Structural basis for the 3'-5' exonuclease activity of Escherichia coli DNA polymerase I: a two metal ion mechanism

The refined crystal structures of the large proteolytic fragment (Klenow fragment) of Escherichia coli DNA polymerase I and its complexes with a deoxynucleoside monophosphate product and a single-stranded DNA substrate offer a detailed picture of an editing 3'-5' exonuclease active site. The structures of these complexes have been refined to R-factors of 0.18 and 0.19 at 2.6 and 3.1 A resolution respectively. The complex with a thymidine tetranucleotide complex shows numerous hydrophobic and hydrogen-bonding interactions between the protein and an extended tetranucleotide that account for the ability of this enzyme to denature four nucleotides at the 3' end of duplex DNA. The structures of these complexes provide details that support and extend a proposed two metal ion mechanism for the 3'-5' editing exonuclease reaction that may be general for a large family of phosphoryltransfer enzymes. A nucleophilic attack on the phosphorous atom of the terminal nucleotide is postulated to be carried out by a hydroxide ion that is activated by one divalent metal, while the expected pentacoordinate transition state and the leaving oxyanion are stabilized by a second divalent metal ion that is 3.9 A from the first. Virtually all aspects of the pretransition state substrate complex are directly seen in the structures, and only very small changes in the positions of phosphate atoms are required to form the transition state.

Independent folding of individual components in hybrid proteins. Evidence that the carboxy-terminal 135 residues of the LexA repressor constitute a single autonomous domain

Inactivation of the Escherichia coli repressor protein, LexA, takes place through a cleavage reaction which hydrolyzes the Ala84-Gly85 peptide bond near the center of the molecule. The mechanism of cleavage has previously been shown to be an intramolecular reaction stimulated in vitro by elevated pH or by the addition of activated RecA protein. The entire self-cleavage activity of LexA has been found to lie within a 135-residue tryptic fragment extending from Leu68 to the end of the protein at Leu202. Since the activity of self-cleavage is dependent on the proper three-dimensional structure of the protein, we have used it as a probe to investigate the extend of folding autonomy and functional independence of this 135-residue carboxy-terminal domain of LexA by applying a protein fusion approach. A series of twelve different hybrid proteins, containing LexA sequences in a variety of predefined primary structural arrangements, were constructed and evaluated for whether or not self-cleavage activity has been retained. The results revealed that retention or loss of activity is independent of the nature or size of the foreign protein used. Loss of self-cleavage was found to be a function of amino- or carboxy-terminal deletions in the self-cleaving LexA component of the fusion proteins. The present findings, together with the observations of other artificial fusions proteins and the naturally occurring bifunctional and multifunctional proteins, along with the data on helix packing, provide further support for the notion of modular architecture of proteins and suggest that when these autonomous units are fused, they retain their tendency to fold independently of the remainder of the polypeptide to generate physically linked active domains, rather than to fold dependently and yield scrambled structures.

Structure-function studies of the herpes simplex virus type 1 DNA polymerase

The analysis of the deduced amino acid sequence of the herpes simplex virus type 1 (HSV-1) DNA polymerase reported here suggests that the polymerase structure consists of domains carrying separate biological functions. The HSV-1 enzyme is known to possess 5'-3'-exonuclease (RNase H), 3'-5'-exonuclease, and DNA polymerase catalytic activities. Sequence analysis suggests an arrangement of these activities into distinct domains resembling the organization of Escherichia coli polymerase I. In order to more precisely define the structure and C-terminal limits of a putative catalytic domain responsible for the DNA polymerization activity of the HSV-1 enzyme, we have undertaken in vitro mutagenesis and computer modeling studies of the HSV-1 DNA polymerase gene. Sequence analysis predicts that the major DNA polymerization domain of the HSV-1 enzyme will be contained between residues 690 and 1100, and we present a three-dimensional model of this region, on the basis of the X-ray crystallographic structure of the E. coli polymerase I. Consistent with these structural and modeling studies, deletion analysis by in vitro mutagenesis of the HSV-1 DNA polymerase gene expressed in Saccharomyces cerevisiae has confirmed that certain amino acids from the C terminus (residues 1073 to 1144 and 1177 to 1235) can be deleted without destroying HSV-1 DNA polymerase catalytic activity and that the extreme N-terminal 227 residues are also not required for this activity.