Purification and properties of DNA polymerase II from Escherichia coli

Role of high-fidelity Escherichia coli DNA polymerase I in replication bypass of a deoxyadenosine DNA-peptide cross-link

Reaction of bifunctional electrophiles with DNA in the presence of peptides can result in DNA-peptide cross-links. In particular, the linkage can be formed in the major groove of DNA via the exocyclic amino group of adenine (N⁶-dA). We previously demonstrated that an A family human polymerase, Pol ν, can efficiently and accurately synthesize DNA past N⁶-dA-linked peptides. Based on these results, we hypothesized that another member of that family, Escherichia coli polymerase I (Pol I), may also be able to bypass these large major groove DNA lesions. To test this, oligodeoxynucleotides containing a site-specific N⁶-dA dodecylpeptide cross-link were created and utilized for in vitro DNA replication assays using E. coli DNA polymerases. The results showed that Pol I and Pol II could efficiently and accurately bypass this adduct, while Pol III replicase, Pol IV, and Pol V were strongly inhibited. In addition, cellular studies were conducted using E. coli strains that were either wild type or deficient in all three DNA damage-inducible polymerases, i.e., Pol II, Pol IV, and Pol V. When single-stranded DNA vectors containing a site-specific N⁶-dA dodecylpeptide cross-link were replicated in these strains, the efficiencies of replication were comparable, and in both strains, intracellular bypass of the lesion occurred in an error-free manner. Collectively, these findings demonstrate that despite its constrained active site, Pol I can catalyze DNA synthesis past N⁶-dA-linked peptide cross-links and is likely to play an essential role in cellular bypass of large major groove DNA lesions.

Replication bypass of the acrolein-mediated deoxyguanine DNA-peptide cross-links by DNA polymerases of the DinB family

DNA-protein cross-links (adducts) are formed in cellular DNA under a variety of conditions, particularly following exposure to an alpha,beta-unsaturated aldehyde, acrolein. DNA-protein cross-links are subject to repair or damage-tolerance processes. These adducts serve as substrates for proteolytic degradation, yielding DNA-peptide lesions that have been shown to be actively repaired by the nucleotide excision repair complex. Alternatively, DNA-peptide cross-links can be subjected to replication bypass. We present new evidence about the capabilities of DNA polymerases to synthesize DNA past such cross-links. DNAs were constructed with site-specific cross-links, in which either a tetrapeptide or a dodecylpeptide was covalently attached at the N (2) position of guanine via an acrolein adduct, and replication bypass assays were carried out with members of the DinB family of polymerases, human polymerase (pol) kappa, Escherichia coli pol IV, and various E. coli polymerases that do not belong to the DinB family. Pol kappa was able to catalyze both the incorporation and the extension steps with an efficiency that was qualitatively indistinguishable from control (undamaged) substrates. Fidelity was comparable on all of these substrates, suggesting that pol kappa would have a role in the low mutation frequency associated with replication of these adducts in mammalian cells. When the E. coli orthologue of pol kappa, damage-inducible DNA polymerase, pol IV, was analyzed on the same substrates, pause sites were detected opposite and three nucleotides beyond the site of the lesion, with incorporation opposite the lesion being accurate. In contrast, neither E. coli replicative polymerase, pol III, nor E. coli damage-inducible polymerases, pol II and pol V, could efficiently incorporate a nucleotide opposite the DNA-peptide cross-links. Consistent with a role for pol IV in tolerance of these lesions, the replication efficiency of DNAs containing DNA-peptide cross-links was greatly reduced in pol IV-deficient cells. Collectively, these data indicate an important role for the DinB family of polymerases in tolerance mechanisms of N (2)-guanine-linked DNA-peptide cross-links.

Replication bypass of interstrand cross-link intermediates by Escherichia coli DNA polymerase IV

Repair of interstrand DNA cross-links (ICLs) in Escherichia coli can occur through a combination of nucleotide excision repair (NER) and homologous recombination. However, an alternative mechanism has been proposed in which repair is initiated by NER followed by translesion DNA synthesis (TLS) and completed through another round of NER. Using site-specifically modified oligodeoxynucleotides that serve as a model for potential repair intermediates following incision by E. coli NER proteins, the ability of E. coli DNA polymerases (pol) II and IV to catalyze TLS past N(2)-N(2)-guanine ICLs was determined. No biochemical evidence was found suggesting that pol II could bypass these lesions. In contrast, pol IV could catalyze TLS when the nucleotides that are 5' to the cross-link were removed. The efficiency of TLS was further increased when the nucleotides 3' to the cross-linked site were also removed. The correct nucleotide, C, was preferentially incorporated opposite the lesion. When E. coli cells were transformed with a vector carrying a site-specific N(2)-N(2)-guanine ICL, the transformation efficiency of a pol II-deficient strain was indistinguishable from that of the wild type. However, the ability to replicate the modified vector DNA was nearly abolished in a pol IV-deficient strain. These data strongly suggest that pol IV is responsible for TLS past N(2)-N(2)-guanine ICLs.

A unified kinetic mechanism applicable to multiple DNA polymerases

After extensive studies spanning over half a century, there is little consensus on the kinetic mechanism of DNA polymerases. Using stopped-flow fluorescence assays for mammalian DNA polymerase beta (Pol beta), we have previously identified a fast fluorescence transition corresponding to conformational closing, and a slow fluorescence transition matching the rate of single-nucleotide incorporation. Here, by varying pH and buffer viscosity, we have decoupled the rate of single-nucleotide incorporation from the rate of the slow fluorescence transition, thus confirming our previous hypothesis that this transition represents a conformational event after chemistry, likely subdomain reopening. Analysis of an R258A mutant indicates that rotation of the Arg258 side chain is not rate-limiting in the overall kinetic pathway of Pol beta, yet is kinetically significant in subdomain reopening. We have extended our kinetic analyses to a high-fidelity polymerase, Klenow fragment (KF), and a low-fidelity polymerase, African swine fever virus DNA polymerase X (Pol X), and showed that they follow the same kinetic mechanism as Pol beta, while differing in relative rates of single-nucleotide incorporation and the putative conformational reopening. Our data suggest that the kinetic mechanism of Pol beta is not an exception among polymerases, and furthermore, its delineated kinetic mechanism lends itself as a platform for comparison of the kinetic properties of different DNA polymerases and their mutants.

The role of specific amino acid residues in the active site of Escherichia coli DNA polymerase I on translesion DNA synthesis across from and past an N-2-aminofluorene adduct

Understanding how carcinogenic DNA adducts compromise accurate DNA replication is an important goal in cancer research. A central part of these studies is to determine the molecular mechanism that allows a DNA polymerase to incorporate a nucleotide across from and past a bulky adduct in a DNA template. To address the importance of polymerase architecture on replication across from this type of bulky DNA adduct, three active-site mutants of Escherichia coli DNA polymerase I (Klenow fragment) were used to study DNA synthesis on DNA modified with the carcinogen N-2-aminofluorene (AF). Running-start synthesis studies showed that full-length synthesis past the AF adduct was inhibited for all of the mutants, but that this inhibition was substantially less for the F762A mutant. Single nucleotide extension and steady-state kinetic experiments showed that the Y766S mutant displayed higher rates of insertion of each incorrect nucleotide relative to WT across from the dG-AF adduct. This effect was not observed for F762A or E710A mutants. Similar experiments that measured synthesis one nucleotide past the dG-AF adduct revealed an enhanced preference by the F762A mutant for dG opposite the T at this position. Finally, synthesis at the +1 and +2 positions was inhibited to a greater extent for the Y766S and E710A mutants compared with both the WT and F762A mutants. Taken together, this work is consistent with the model that polymerase geometry plays a crucial role in both the insertion and extension steps during replication across from bulky DNA lesions.

DNA polymerase catalysis in the absence of Watson-Crick hydrogen bonds: analysis by single-turnover kinetics

We report the first pre-steady-state kinetic studies of DNA replication in the absence of hydrogen bonds. We have used nonpolar nucleotide analogues that mimic the shape of a Watson-Crick base pair to investigate the kinetic consequences of a lack of hydrogen bonds in the polymerase reaction catalyzed by the Klenow fragment of DNA polymerase I from Escherichia coli. With a thymine isostere lacking hydrogen-bonding ability in the nascent pair, the efficiency (k(pol)/Kd) of the polymerase reaction is decreased by 30-fold, affecting the ground state (Kd) and transition state (k(pol)) approximately equally. When both thymine and adenine analogues in the nascent pair lack hydrogen-bonding ability, the efficiency of the polymerase reaction is decreased by about 1000-fold, with most of the decrease attributable to the transition state. Reactions using nonpolar analogues at the primer-terminal base pair demonstrated the requirement for a hydrogen bond between the polymerase and the minor groove of the primer-terminal base. The R668A mutation of Klenow fragment abolished this requirement, identifying R668 as the probable hydrogen-bond donor. Detailed examination of the kinetic data suggested that Klenow fragment has an extremely low tolerance of even minor deviations of the analogue base pairs from ideal Watson-Crick geometry. Consistent with this idea, some analogue pairings were better tolerated by Klenow fragment mutants having more spacious active sites. In contrast, the Y-family polymerase Dbh was much less sensitive to changes in base pair dimensions and more dependent upon hydrogen bonding between base-paired partners.

Mechanism for N-acetyl-2-aminofluorene-induced frameshift mutagenesis by Escherichia coli DNA polymerase I (Klenow fragment)

N-Acetyl-2-aminofluorene (AAF) is a chemical carcinogen that reacts with guanines at the C8 position in DNA to form a structure that interferes with DNA replication. In bacteria, the NarI restriction enzyme recognition sequence (G1G2CG3CC) is a very strong mutational hot spot when an AAF adduct is positioned at G3 of this sequence, causing predominantly a -2 frameshift GC dinucleotide deletion mutation. In this study, templates were constructed that contained an AAF adduct at this position, and primers of different lengths were prepared such that the primer ended one nucleotide before or opposite or one nucleotide after the adduct site. Primer extension and gel shift binding assays were used to study the mechanism of bypass by the Escherichia coli DNA polymerase I (Klenow fragment) in the presence of these templates. Primer extension in the presence of all four dNTPs produced a fully extended product using the unmodified template, while with the AAF-modified template synthesis initially stalled at the adduct site and subsequent synthesis resulted in a product that contained the GC dinucleotide deletion. Extension product and gel shift binding analyses were consistent with the formation of a two-nucleotide bulge structure upstream of the active site of the polymerase after a nucleotide is incorporated across from the adduct. These data support a model in which the AAF adduct in the NarI sequence specifically induces a structure upstream of the polymerase active site that leads to the GC frameshift mutation and that it is this structure that allows synthesis past the adduct to occur.

Loss of DNA minor groove interactions by exonuclease-deficient Klenow polymerase inhibits O6-methylguanine and abasic site translesion synthesis

The importance of DNA polymerase-DNA minor groove interactions on translesion synthesis (TLS) was examined in vitro using variants of exonuclease-deficient Klenow polymerase and site-specifically modified DNA oligonucleotides. Polymerase variant R668A lacks primer strand interactions, while variant Q849A lacks template strand interactions. O(6)-Methylguanine (m6G) and abasic site TLS was examined in three stages: dNTP insertion opposite the lesion, extension from a terminal lesion-containing base pair, and the dissociation equilibrium of the polymerase from the lesion-containing template. Less than 5% TLS was observed at the insertion step for either variant on the lesion-containing templates. While extensive TLS was observed for WT polymerase on the m6G template, only incorporation opposite the lesion was observed for the R668A variant. Loss of the template strand interaction, Q849A, resulted in the inability to insert dNTPs opposite either the m6G or abasic lesion. For both variants, extension of purine-containing m6G primer-templates was increased relative to WT polymerase. We observed similar extension efficiencies for all variants, relative to WT, using abasic template-primers. Polymerase dissociation/reassociation was studied through the use of a competitor primer/template complex. Dissociation for WT polymerase increased 2-fold and 3-fold, respectively, for m6G and abasic lesion-containing templates, relative to the natural template. Variants lacking DNA minor groove interactions displayed increased dissociation from DNA templates, relative to WT polymerase, but do not display an increased level of lesion-induced polymerase dissociation. Our results indicate that the primer and template strand interactions of the Klenow polymerase with the DNA minor groove are critical for maintaining the DNA-polymerase complex during translesion synthesis.

Increased dNTP binding affinity reveals a nonprocessive role for Escherichia coli beta clamp with DNA polymerase IV

Replication forks often stall at undamaged or damaged template sites in Escherichia coli. Subsequent resumption of DNA synthesis occurs by replacing DNA polymerase III, which is bound to DNA by the beta-sliding clamp, with one of three damage-induced DNA polymerases II, IV, or V. The principal role of the beta clamp is to tether the normally weakly bound polmerases to DNA thereby increasing their processivities. DNA polymerase IV binds dNTP substrates with about 10-fold lower affinity compared with the other E. coli polymerases, which if left unchecked could hinder its ability to synthesize DNA in vivo. Here we report a new property for the beta clamp, which when bound to DNA polymerase IV results in a large increase in dNTP binding affinity that concomitantly increases the efficiency of nucleotide incorporation at normal and transiently slipped mispaired primer/template ends. Primer-template DNA slippage resulting in single nucleotide deletions is a biological hallmark of DNA polymerase IV infidelity responsible for enhancing cell fitness in response to stress. We show that the increased DNA polymerase IV-dNTP binding affinity is an intrinsic property of the DNA polymerase IV-beta clamp interaction and not an indirect consequence of an increased binding of DNA polymerase IV to DNA.

Evaluating the contribution of base stacking during translesion DNA replication

Despite the nontemplating nature of the abasic site, dAMP is often preferentially inserted opposite the lesion, a phenomenon commonly referred to as the "A-rule". We have evaluated the molecular mechanism accounting for this unique behavior using a thorough kinetic approach to evaluate polymerization efficiency during translesion DNA replication. Using the bacteriophage T4 DNA polymerase, we have measured the insertion of a series of modified nucleotides and have demonstrated that increasing the size of the nucleobase does not correlate with increased insertion efficiency opposite an abasic site. One analogue, 5-nitroindolyl-2'-deoxyriboside triphosphate, was unique as it was inserted opposite the lesion with approximately 1000-fold greater efficiency compared to that for dAMP insertion. Pre-steady-state kinetic measurements yield a kpol value of 126 s(-1) and a Kd value of 18 microM for the insertion of 5-nitroindolyl-2'-deoxyriboside triphosphate opposite the abasic site. These values rival those associated with the enzymatic formation of a natural Watson-Crick base pair. These results not only reiterate that hydrogen bonding is not necessary for nucleotide insertion but also indicate that the base-stacking and/or desolvation capabilities of the incoming nucleobase may indeed play the predominant role in generating efficient DNA polymerization. A model accounting for the increase in catalytic efficiency of this unique nucleobase is provided and invokes pi-pi stacking interactions of the aromatic moiety of the incoming nucleobase with aromatic amino acids present in the polymerase's active site. Finally, differences in the rate of 5-nitroindolyl-2'-deoxyriboside triphosphate insertion opposite an abasic site are measured between the bacteriophage T4 DNA polymerase and the Klenow fragment. These kinetic differences are interpreted with regard to the differences in various structural components between the two enzymes and are consistent with the proposed model for DNA polymerization.

Use of 2-aminopurine fluorescence to examine conformational changes during nucleotide incorporation by DNA polymerase I (Klenow fragment)

We have investigated conformational transitions in the Klenow fragment polymerase reaction by stopped-flow fluorescence using DNA substrates containing the fluorescent reporter 2-aminopurine (2-AP) on the template strand, either at the templating position opposite the incoming nucleotide (designated the 0 position) or 5' to the templating base (the +1 position). By using both deoxy- and dideoxy-terminated primers, we were able to distinguish steps that accompany ternary complex formation from those that occur during nucleotide incorporation. The fluorescence changes revealed two extremely rapid steps that occur early in the pathway for correct nucleotide incorporation. The first, detectable with the 2-AP reporter at the 0 position, occurs within the first few milliseconds and is associated with dNTP binding. This is followed by a rapid step involving relative movement of the +1 base, detectable when the 2-AP reporter is at the +1 position. Finally, when the primer had a 3'-OH, a fluorescence decrease with a rate equal to the rate of nucleotide incorporation was observed with both 0 and +1 position reporters. When the primer was dideoxy-terminated, the only change observed at the rate expected for nucleotide incorporation had a very small amplitude, suggesting that the rate-limiting conformational change does not produce a large fluorescence change, and is therefore unlikely to involve a significant change in the environment of the fluorophore. Fluorescence changes observed during misincorporation were substantially different from those observed during correct nucleotide incorporation, implying that the conformations adopted during correct and incorrect nucleotide incorporation are distinct.

Mechanistic insights into replication across from bulky DNA adducts: a mutant polymerase I allows an N-acetyl-2-aminofluorene adduct to be accommodated during DNA synthesis

The molecular mechanism that allows a polymerase to incorporate a nucleotide opposite a DNA lesion is not well-understood. One way to study this process is to characterize the altered molecular interactions that occur between the polymerase and a damaged template. Prior studies have determined the polymerase-template dissociation constants and used kinetic analyses and a protease digestion assay to measure the effect of various DNA adducts positioned in the active site of Klenow fragment (KF). Here, a mutator polymerase was used in which the tyrosine at position 766 of the KF has been replaced with a serine. This position is located at the junction of the fingers and palm domain and is thought to be involved in maintaining the active site geometry. The primer-template was modified with N-acetyl-2-aminofluorene (AAF), a well-studied carcinogenic adduct. The mutant polymerase displayed a significant increase in the rate of incorporation of the correct nucleotide opposite the adduct but was much less prone to incorporate an incorrect nucleotide relative to the wild-type polymerase. Both the wild-type and the mutant polymerase bound much more tightly to the AAF-modified primer-template; however, unlike the wild-type polymerase, the binding strength of the mutant was influenced by the presence of a dNTP. Moreover, the mutant polymerase was able to undergo a dNTP-induced conformational change when the AAF adduct was positioned in the active site, while the wild-type enzyme could not. A model is proposed in which the looser active site of the mutant is able to better accommodate the AAF adduct.

Interaction of DNA polymerase I (Klenow fragment) with the single-stranded template beyond the site of synthesis

Cocrystal structures of DNA polymerases from the Pol I (or A) family have provided only limited information about the location of the single-stranded template beyond the site of nucleotide incorporation, revealing contacts with the templating position and its immediate 5' neighbor. No structural information exists for template residues more remote from the polymerase active site. Using a competition binding assay, we have established that Klenow fragment contacts at least the first four unpaired template nucleotides, though the quantitative contribution of any single contact is relatively small. Photochemical cross-linking indicated that the first unpaired template base beyond the primer terminus is close to Y766, as expected, and the two following template bases are close to F771 on the surface of the fingers subdomain. We have constructed point mutations in the region of the fingers subdomain implicated by these experiments. Cocrystal structures of family A DNA polymerases predict contacts between the template strand and S769, F771, and R841, and our DNA binding assays provide evidence for the functional importance of these contacts. Overall, the data are most consistent with the template strand following a path over the fingers subdomain, close to the side chain of R836 and a neighboring cluster of positively charged residues.

Error-prone repair DNA polymerases in prokaryotes and eukaryotes

DNA repair is crucial to the well-being of all organisms from unicellular life forms to humans. A rich tapestry of mechanistic studies on DNA repair has emerged thanks to the recent discovery of Y-family DNA polymerases. Many Y-family members carry out aberrant DNA synthesis-poor replication accuracy, the favored formation of non-Watson-Crick base pairs, efficient mismatch extension, and most importantly, an ability to replicate through DNA damage. This review is devoted primarily to a discussion of Y-family polymerase members that exhibit error-prone behavior. Roles for these remarkable enzymes occur in widely disparate DNA repair pathways, such as UV-induced mutagenesis, adaptive mutation, avoidance of skin cancer, and induction of somatic cell hypermutation of immunoglobulin genes. Individual polymerases engaged in multiple repair pathways pose challenging questions about their roles in targeting and trafficking. Macromolecular assemblies of replication-repair "factories" could enable a cell to handle the complex logistics governing the rapid migration and exchange of polymerases.

3'-5' exonuclease of Klenow fragment: role of amino acid residues within the single-stranded DNA binding region in exonucleolysis and duplex DNA melting

The mechanism of the 3'-5' exonuclease activity of the Klenow fragment of DNA polymerase I has been investigated with a combination of biochemical and spectroscopic techniques. Site-directed mutagenesis was used to make alanine substitutions of side chains that interact with the DNA substrate on the 5' side of the scissile phosphodiester bond. Kinetic parameters for 3'-5' exonuclease cleavage of single- and double-stranded DNA substrates were determined for each mutant protein in order to probe the role of the selected side chains in the exonuclease reaction. The results indicate that side chains that interact with the penultimate nucleotide (Q419, N420, and Y423) are important for anchoring the DNA substrate at the active site or ensuring proper geometry of the scissile phosphate. In contrast, side chains that interact with the third nucleotide from the DNA terminus (K422 and R455) do not participate directly in exonuclease cleavage of single-stranded DNA. Alanine substitutions of Q419, Y423, and R455 have markedly different effects on the cleavage of single- and double-stranded DNA, causing a much greater loss of activity in the case of a duplex substrate. Time-resolved fluorescence anisotropy decay measurements with a dansyl-labeled primer/template indicate that the Q419A, Y423A, and R455A mutations disrupted the ability of the Klenow fragment to melt duplex DNA and bind the frayed terminus at the exonuclease site. In contrast, the N420A mutation stabilized binding of a duplex terminus to the exonuclease site, suggesting that the N420 side chain facilitates the 3'-5' exonuclease reaction by introducing strain into the bound DNA substrate. Together, these results demonstrate that protein side chains that interact with the second or third nucleotides from the terminus can participate in both the chemical step of the exonuclease reaction, by anchoring the substrate in the active site or by ensuring proper geometry of the scissile phosphate, and in the prechemical steps of double-stranded DNA hydrolysis, by facilitating duplex melting.

Resolving a fidelity paradox: why Escherichia coli DNA polymerase II makes more base substitution errors in AT- compared with GC-rich DNA

The activity of DNA polymerase-associated proofreading 3'-exonucleases is generally enhanced in less stable DNA regions leading to a reduction in base substitution error frequencies in AT- versus GC-rich sequences. Unexpectedly, however, the opposite result was found for Escherichia coli DNA polymerase II (pol II). Nucleotide misincorporation frequencies for pol II were found to be 3-5-fold higher in AT- compared with GC-rich DNA, both in the presence and absence of polymerase processivity subunits, beta dimer and gamma complex. In contrast, E. coli pol III holoenzyme, behaving "as expected," exhibited 3-5-fold lower misincorporation frequencies in AT-rich DNA. A reduction in fidelity in AT-rich regions occurred for pol II despite having an associated 3'-exonuclease proofreading activity that preferentially degrades AT-rich compared with GC-rich DNA primer-template in the absence of DNA synthesis. Concomitant with a reduction in fidelity, pol II polymerization efficiencies were 2-6-fold higher in AT-rich DNA, depending on sequence context. Pol II paradoxical fidelity behavior can be accounted for by the enzyme's preference for forward polymerization in AT-rich sequences. The more efficient polymerization suppresses proofreading thereby causing a significant increase in base substitution error rates in AT-rich regions.

Determinants of DNA mismatch recognition within the polymerase domain of the Klenow fragment

The Klenow fragment of Escherichia coli DNA polymerase I catalyzes template-directed synthesis of DNA and uses a separate 3'-5' exonuclease activity to edit misincorporated bases. The polymerase and exonuclease activities are contained in separate structural domains. In this study, nine Klenow fragment derivatives containing mutations within the polymerase domain were examined for their interaction with model primer-template duplexes. The partitioning of the DNA primer terminus between the polymerase and 3'-5' exonuclease active sites of the mutant proteins was assessed by time-resolved fluorescence anisotropy, utilizing a dansyl fluorophore attached to the DNA. Mutation of N845 or R668 disrupted favorable interactions between the Klenow fragment and a duplex containing a matched terminal base pair but had little effect when the terminus was mismatched. Thus, N845 and R668 are required for recognition of correct terminal base pairs in the DNA substrate. Mutation of N675, R835, R836, or R841 resulted in tighter polymerase site binding of DNA, suggesting that the side chains of these residues induce strain in the DNA and/or protein backbone. A double mutant (N675A/R841A) showed an even greater polymerase site partitioning than was displayed by either single mutation, indicating that such strain is additive. In both groups of mutant proteins, the ability to discriminate between duplexes containing matched or mismatched base pairs was impaired. In contrast, mutation of K758 or Q849 had no effect on partitioning relative to wild type, regardless of DNA mismatch character. These results demonstrate that DNA mismatch recognition is dependent on specific amino acid residues within the polymerase domain and is not governed solely by thermodynamic differences between correct and mismatched base pairs. Moreover, this study suggests a mechanism whereby the Klenow fragment is able to recognize polymerase errors following a misincorporation event, leading to their eventual removal by the 3'-5' exonuclease activity.

Affinity purification of DNA-binding proteins

The focus of this review is on DNA affinity chromatography, which is the most powerful tool for purification of DNA binding proteins. The use of nonspecific-, sequence specific- and single stranded-DNA affinity columns in purification of various DNA binding proteins is discussed. The purification strategies for transcription factors, restriction enzymes, telomerases, DNA and RNA polymerase and DNA binding antibodies are described. Different applications of DNA affinity chromatography are presented.

Molecular mechanism of sequence-specific termination of lentiviral replication

The central termination sequence (CTS) terminates (+) strand DNA synthesis in certain lentiviruses. The molecular mechanism underlying this event, catalyzed by equine infectious anemia virus reverse transcriptase (EIAV RT), was evaluated by pre-steady-state kinetic techniques. Time courses in nucleotide incorporation using several DNA substrates were biphasic, consistent with release of enzyme from extended DNA being the rate-limiting step for turnover. While the burst amplitude reflecting the amount of functional RT-DNA complex was sequence-dependent, rate constants for initial product formation were not. Filter binding assays indicate the K(d) for CTS-containing substrate is only 2-fold higher than a random DNA and cannot account entirely for the large diminution in burst amplitudes. Measurements of processive DNA replication on a millisecond time scale indicate that the rate of polymerization is unaffected by the T(6)-tract within the CTS. However, termination products accumulate due to a substantial increase in the rate of nonproductive enzyme-nucleic acid complex formation after incorporation of four to five adenosines of a T(6)-tract within the CTS. During strand displacement synthesis through the CTS, products accumulate after incorporation of three to four adenosines. The rate of polymerization during strand displacement synthesis decreases 2-fold while the rate of nonproductive enzyme-nucleic acid complex formation is identical in the absence or presence of the displacement strand. These results have allowed us to develop a model for CTS-induced termination of (+) strand synthesis.

3'-5' Exonucleolytic activity of DNA polymerases: structural features that allow kinetic discrimination between ribo- and deoxyribonucleotide residues

We have determined rates for the excision of nucleotides from the 3' termini of chimeric DNA-RNA oligonucleotides using the Klenow fragment (KF) and two other DNA polymerases, from phages T4 and T7. For these studies, we synthesized DNA-RNA chimeric oligonucleotides with RNA residues in defined positions. When a ribonucleotide residue was placed at the 3' terminus, all three DNA polymerases removed it at the same rate as they did for substrates composed solely of deoxynucleotide residues. There was a decrease in the excision rate, however, when a ribonucleotide residue was located at the second or third position from the 3' terminus. When both the second and third positions were occupied by ribonucleotide residues, the excision rate for the 3' terminal nucleotide was reduced even further and was almost identical to the rate observed when the DNA polymerases encountered single-stranded RNA. The magnitude of the effect of ribonucleotide residues on the excision rate was lower when Mn(2+) replaced Mg(2+) as the essential divalent cation. Two KF mutations, Y423A and N420A, selectively affected the excision rates for the chimeric substrates. Specifically, Y423A totally abolished the rate reduction when there was a single ribonucleotide residue immediately preceding the 3' terminus, whereas N420A diminished, but did not eliminate, the rate reduction relative to that of wild-type KF when the single ribonucleotide residue occupied either the second or third position from the 3' terminus. These results are consistent with the structure of a KF-ss DNA complex from which it can be deduced, by modeling, that a 2' OH group on the second sugar from the 3' terminus would sterically clash with the Tyr 423 side chain, and a 2' OH group on the third sugar would clash with the side chain of Asn 420. The corresponding mutations in T4 DNA polymerase did not affect the rate of hydrolysis of the chimeric oligonucleotides. Thus, there appears to be a major difference in the kinetic behavior of KF and T4 DNA polymerase with respect to the exonuclease reaction. These results are discussed with respect to their possible biological relevance to DNA replication.

Use of fluorescence resonance energy transfer to investigate the conformation of DNA substrates bound to the Klenow fragment

Fluorescence resonance energy transfer (FRET) has been used to investigate the conformation of the single stranded region for a series of fluorescent DNA template-primers bound to the Klenow fragment (KF) of Escherichia coli DNA polymerase I. Fluorescent derivatives of template-primer DNA, modified with tetramethylrhodamine (TMR), served as energy transfer acceptors to the donor fluorescein fluorophore used to modify cysteine 751 in the double mutant KF (S751C, C907S). Design of the template-primer allowed the probe's position within the DNA-protein complex to be varied by stepwise extension of the primer strand upon addition of the appropriate deoxynucleoside triphosphates (dNTP). The TMR acceptor probe occupied seven different positions in the template-primers, five in the single stranded region and two in the double stranded region. The efficiency of energy transfer was determined at each position by calculating the integrated area of the fluorescein emission peak in the presence and absence of acceptor. Results indicate that the FRET efficiency varied in a sinusoidal fashion with a periodicity of approximately 10 base pairs and that the data could be fitted to an equation derived from a simple model formulated on the basis of helical structure. The data support the conclusion that the single stranded template portion of a DNA template-primer adopts a helical conformation when bound to the KF. The results of this study further support FRET as a useful method for the determination of structure and conformation in protein-DNA complexes.

Effects of mutations on the partitioning of DNA substrates between the polymerase and 3'-5' exonuclease sites of DNA polymerase I (Klenow fragment)

Site-directed mutagenesis and time-resolved fluorescence spectroscopy were used to evaluate the contributions of individual amino acid side chains to the binding of DNA primer-templates to the 3'-5' exonuclease site of the large proteolytic fragment (Klenow fragment) of DNA polymerase I. Mutations were introduced into side chains that have been shown crystallographically to be in close proximity to a DNA 3' terminus bound at the 3'-5' exonuclease site. The wild-type residues were replaced by alanine in each case. To assess the effects of the mutations on DNA binding, time-resolved fluorescence anisotropy measurements were performed on dansyl-labeled primer-templates bound to the mutant enzymes. In contrast to techniques that simply monitor the overall binding of proteins to DNA, the time-resolved fluorescence anisotropy technique was used to determine the fractional occupancies of the polymerase and 3'-5' exonuclease active sites of Klenow fragment. Equilibrium constants describing the partitioning of DNA between the two active sites were obtained for nine different mutant enzymes bound to both matched and mismatched DNA sequences. Mutations of Leu361 and Phe473 caused the largest effects, significantly destabilizing the binding of mismatched DNA substrates to the 3'-5' exonuclease site relative to DNA bound at the polymerase site, consistent with structural data showing that the side chains of these residues are involved in intimate hydrophobic interactions with the 3' terminal and penultimate bases of the primer strand [Beese, L., and Steitz, T. A. (1991) EMBO J. 10, 25-33]. Mutations of the His660 and Glu357 side chains also resulted in significant effects on the binding of mismatched DNA to the 3'-5' exonuclease site. Surprisingly, mutation of Tyr497 increased the partitioning of mismatched DNA into the 3'-5' exonuclease site, suggesting that the tyrosine side chain in the wildtype enzyme destabilizes substrate binding, despite crystallographic data showing that Tyr497 is H-bonded to the DNA substrate. The effects of mutating the amino acid side chains that serve as ligands to two divalent metal ions bound at the 3'-5' exonuclease site, designated A and B, indicated that metal A also helps to bind DNA to the 3'-5' exonuclease site. These results demonstrate that the time-resolved fluorescence anisotropy technique can be used to quantify the energetic contributions associated with each of the crystallographically defined DNA-protein contacts at the 3'-5' exonuclease site.

The Escherichia coli polB locus is identical to dinA, the structural gene for DNA polymerase II. Characterization of Pol II purified from a polB mutant

Escherichia coli DNA polymerase II (Pol II) is a member of the group B, "alpha-like" family of DNA polymerases. Pol II is encoded by the damage-inducible dinA gene and exhibits SOS induction under the control of Lex A repressor. The polB gene was originally designated as the structural gene for Pol II based on the absence of detectable Pol II activity in cell lysates prepared from a strain containing the mutant polB100 allele. Because polB and dinA mapped at different chromosomal locations, it remained an open question whether polB, in addition to lexA, might be involved in regulating the expression of Pol II. We have cloned and sequenced the polB100 mutant allele, including adjacent surrounding sequences, and have expressed the mutant dinA gene from Pol B100 on a high copy number plasmid. Our sequence data reveal that polB and dinA represent the same gene and that the original transduction mapping of polB was inaccurate. We purified the mutant Pol B100 polymerase and show that it retains 5 to 10% of the wild-type level of polymerase activity. The Pol B100 mutation, Gly401 --> Asp401, is not located within any of the five conserved domains that define group B polymerases. Pol B100 retains a wild-type level of 3' --> 5' exonuclease activity. We suggest that the normal level of exonucleolytic proofreading associated with the mutant Pol B100 enzyme may explain the repeated failures, over the past two decades, to detect phenotypes in polB mutant strains.

Escherichia coli DNA polymerase II catalyzes chromosomal and episomal DNA synthesis in vivo

We have investigated a role for Escherichia coli DNA polymerase II (Pol II) in copying chromosomal and episomal DNA in dividing cells in vivo. Forward mutation frequencies and rates were measured at two chromosomal loci, rpoB and gyrA, and base substitution and frameshift mutation frequencies were measured on an F'(lacZ) episome. To amplify any differences in polymerase error rates, methyl-directed mismatch repair was inactivated. When wild-type Pol II (polB+) was replaced on the chromosome by a proofreading-defective Pol II exo- (polBex1), there was a significant increase in mutation frequencies to rifampicin resistance (RifR) (rpoB) and nalidixic acid resistance (NalR) (gyrA). This increased mutagenesis occurred in the presence of an antimutator allele of E. coli DNA polymerase III (Pol III) (dnaE915), but not in the presence of wild-type Pol III (dnaE+), suggesting that Pol II can compete effectively with DnaE915 but not with DnaE+. Sequencing the RifR mutants revealed a G --> A hot spot highly specific to Pol II exo-. Pol II exo- caused a significant increase in the frequency of base substitution and frameshift mutations on F' episomes, even in dnaE+ cells, suggesting that Pol II is able to compete with Pol III for DNA synthesis on F episomes.