Structural and functional insights provided by crystal structures of DNA polymerases and their substrate complexes

Structure of Saccharomyces cerevisiae DNA polymerase epsilon by cryo-electron microscopy

The structure of the multisubunit yeast DNA polymerase epsilon (Pol epsilon) was determined to 20-A resolution using cryo-EM and single-particle image analysis. A globular domain comprising the catalytic Pol2 subunit is flexibly connected to an extended structure formed by subunits Dpb2, Dpb3 and Dpb4. Consistent with the reported involvement of the latter in interaction with nucleic acids, the Dpb portion of the structure directly faces a single cleft in the Pol2 subunit that seems wide enough to accommodate double-stranded DNA. Primer-extension experiments reveal that Pol epsilon processivity requires a minimum length of primer-template duplex that corresponds to the dimensions of the extended Dpb structure. Together, these observations suggest a mechanism for interaction of Pol epsilon with DNA that might explain how the structure of the enzyme contributes to its intrinsic processivity.

Acid-base and metal-ion-binding properties of 9-[2-(2-phosphonoethoxy)ethyl]adenine (PEEA), a relative of the antiviral nucleotide analogue 9-[2-(phosphonomethoxy)ethyl]adenine (PMEA). An exercise on the quantification of isomeric complex equilibria in solution

The acidity constants of 3-fold protonated 9-[2-(2-phosphonoethoxy)ethyl]adenine, H3(PEEA)+, and of 2-fold protonated (2-phosphonoethoxy)ethane, H2(PEE), and the stability constants of the M(H;PEEA)+, M(PEEA), and M(PEE) complexes with M2+ = Mg2+, Ca2+, Sr2+, Ba2+, Mn2+, Co2+, Ni2+, Cu2+, Zn2+, or Cd2+ have been determined (potentiometric pH titrations; aqueous solution; 25 degrees C; I = 0.1 M, NaNO3). It is concluded that in the M(H;PEEA)+ species, the proton is at the phosphonate group and the metal ion at the adenine residue. The application of previously determined straight-line plots of log K(M(R-PO3))M versus pK(H(R-PO3))H for simple phosph(on)ate ligands, R-PO3(2-), where R represents a residue that does not affect metal-ion binding, proves that the M(PEEA) complexes of Co2+, Ni2+, Cu2+, Zn2+, and Cd2+ as well as the M(PEE) complexes of Co2+, Cu2+, and Zn2+ have larger stabilities than is expected for a sole phosphonate coordination of M2+. For the M2+ complexes without an enhanced stability (e.g., Mg2+ or Mn2+), it is concluded that M2+ binds in a monodentate fashion to the phosphonate group of the two ligands. Combination of all of the results allows the following conclusions: (i) The increased stability of the Co(PEE), Cu(PEE), Zn(PEE), and Co(PEEA) complexes is due to the formation of six-membered chelates involving the ether-oxygen atom of the aliphatic residue (-CH2-O-CH2CH2-PO3(2-)) of the ligands with formation degrees of about 15-30%. (ii) Cd(PEEA) forms a macrochelate with N7 of the adenine residue (formation degree about 30%); Ni(PEEA) has similar properties. (iii) With Zn(PEEA), both mentioned types of chelates are observed, that is, Zn(PEEA)(cl/O) and Zn(PEEA)(cl/N7), with formation degrees of about 13 and 41%, respectively; the remaining 46% is due to the "open" isomer Zn(PEEA)(op) in which the metal ion binds only to the PO3(2-) group. (iv) Most remarkable is Cu(PEEA) because a fourth isomer, Cu(PEEA)(cl/O/N3), is formed that contains a six-membered ring involving the ether oxygen next to the phosphonate group and also a seven-membered ring involving N3 of the adenine residue with a very significant formation degree of about 50%. Hence, PEEA(2-) is a truly ambivalent ligand, its properties being strongly dependent on the kind of metal ion involved. Comparisons with M2+ complexes formed by the dianions of 9-[2-(phosphonomethoxy)ethyl]adenine (PMEA) and related ligands reveal that five-membered chelates involving an ether-oxygen atom are considerably more stable than the corresponding six-membered ones. This observation offers an explanation of why PMEA is a nucleotide analogue with excellent antiviral properties and PEEA is not.

Accommodation of a 1S-(-)-benzo[c]phenanthrenyl-N6-dA adduct in the Y-family Dpo4 DNA polymerase active site: structural insights through molecular dynamics simulations

Molecular modeling and molecular dynamics simulations have been performed to elucidate feasible structures in the Y-family Dpo4 DNA polymerase for the 1S-(-)-trans-anti-B[c]Ph-N6-dA adduct, derived from the fjord region polycyclic aromatic hydrocarbon (PAH) benzo[c]phenanthrene. Three types of models were delineated as follows: an intercalation model, a model with the aromatic ring system in the polymerase major groove open pocket, and a -1 deletion major groove model. All four 2'-deoxyribonucleoside 5'-triphosphates (dNTPs) were considered in the first two cases, and a normal Watson-Crick partner positioned to have skipped the modified template was employed as the incoming dNTP in the -1 deletion case. The trajectories derived from the dynamics simulations were analyzed in detail to evaluate the extents of distortion for each system. Overall, our results suggest that the major groove model is the least distorted, followed by the -1 deletion model, while the intercalation model is perturbed the most. The syn-dGTP and syn-dATP mismatches opposite the lesion are well-accommodated in the major groove model, as is the normal Watson-Crick partner dTTP. The intercalation model appears most likely to impede the polymerase. More broadly, these models look reasonable for other PAH metabolite-derived adducts to adenine with similar 1S stereochemistry. Furthermore, these models suggest how error-prone translesion synthesis by Y-family polymerases might produce mutations that may play a role in the initiation of cancer.

A Dielectric-Sensitive Fluorescent DNA Probe for Monitoring Polarities on the Interior of a DNA-Binding Protein

We report a novel fluorescent nucleobase, (DNC)U, for the mapping of the local dielectric properties around DNA. Fluorescence spectra of the nucleoside d(DNC)U showed a significant shift depending on the solvent polarity. This property was used to determine the dielectric constants of the interior of DNA-binding proteins, such as DNA polymerases. We were able to demonstrate that the DNA-binding region of the Klenow fragment is a lower polarity site, as shown by the blue shift of the fluorescence peak originating from (DNC)U.

Nucleoside 5'-triphosphates: self-association, acid-base, and metal ion-binding properties in solution

Adenosine 5'-triphosphate (ATP(4-)) and related nucleoside 5'-triphosphates (NTP(4-)) serve as substrates in the form of metal ion complexes in enzymic reactions taking part thus in central metabolic processes. With this in mind, the coordination chemistry of NTPs is critically reviewed and the conditions are defined for studies aiming to describe the properties of monomeric complexes because at higher concentrations (>1 mM) self-stacking may take place. The metal ion (M(2+)) complexes of purine-NTPs are more stable than those of pyrimidine-NTPs; this stability enhancement is attributed, in accord with NMR studies, to macrochelate formation of the phosphate-coordinated M(2+) with N7 of the purine residue and the formation degrees of the resulting isomeric complexes are listed. Furthermore, the formation of mixed-ligand complexes (including also those with buffer molecules), the effect of a reduced solvent polarity on complex stability and structure (giving rise to selectivity), the use of nucleotide analogues as antiviral agents, and the effect of metal ions on group transfer reactions are summarized.

Incorporation of non-nucleoside triphosphate analogues opposite to an abasic site by human DNA polymerases beta and lambda

A novel class of non-nucleoside triphosphate analogues, bearing hydrophobic groups sterically similar to nucleosides linked to the alpha-phosphate but lacking the chemical functional groups of nucleic acids, were tested against six different DNA polymerases (polymerases). Human polymerases alpha, beta and lambda, and Saccharomyces cerevisiae polymerase IV, were inhibited with different potencies by these analogues. On the contrary, Escherichia coli polymerase I and HIV-1 reverse transcriptase were not. Polymerase beta incorporated these derivatives in a strictly Mn++-dependent manner. On the other hand, polymerase lambda could incorporate some alkyltriphosphate derivatives with both Mg++ and Mn++, but only opposite to an abasic site on the template strand. The active site mutant polymerase lambda Y505A showed an increased ability to incorporate the analogues. These results show for the first time that neither the base nor the sugar moieties of nucleotides are required for incorporation by family X DNA polymerases.

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.

Model of full-length HIV-1 integrase complexed with viral DNA as template for anti-HIV drug design

We report structural models of the full-length integrase enzyme (IN) of the human immunodeficiency virus type 1 (HIV-1) and its complex with viral and human DNA. These were developed by means of molecular modeling techniques using all available experimental evidence, including X-ray crystallographic and NMR structures of portions of the full-length protein. Special emphasis was placed on obtaining a model of the enzyme's active site with the viral DNA apposed to it, based on the hypothesis that such a model would allow structure-based design of inhibitors that retain activity in vivo. This was because bound DNA might be present in vivo after 3'-processing but before strand transfer. These structural models were used to study the potential binding modes of various diketo-acid HIV-1 IN inhibitors (many of them preferentially inhibiting strand transfer) for which no experimentally derived complexed structures are available. The results indicate that the diketo-acid IN inhibitors probably chelate the metal ion in the catalytic site and also prevent the exposure of the 3'-processed end of the viral DNA to human DNA.

Directed evolution of novel polymerases

DNA and RNA polymerases evolved to function in specific environments with specific substrates to propagate genetic information in all living organisms. The commercial availability of these polymerases has revolutionized the biotechnology industry, but for many applications native polymerases are limited by their stability or substrate recognition. Thus, there is great interest in the directed evolution of DNA and RNA polymerases to generate enzymes with novel, desired properties, such as thermal stability, resistance to inhibitors, and altered substrate specificity. Several screening and selection approaches have been developed, both in vivo and in vitro, and have been used to evolve polymerases with a variety of important activities. Both the techniques and the evolved polymerases are reviewed here, along with a comparison of the in vivo and in vitro approaches.

The error threshold

Basic principles underlying the population dynamics of bacteria and viruses are presented, with emphasis on RNA viruses. Concepts reviewed here include fitness, mutant generation, competition, selection, sequence space and the theoretical origins of quasispecies. A "wild-type" virus is no longer viewed as the fittest type, but as the center of gravity of a population landscape. A consequence of quasispecies is the existence of an error threshold for selective competence. The error threshold has a justification in quasispecies theory and lends itself to exploration of strategies to drive viral populations over the error threshold, the central theme of this volume.

Infidelity out in the open

The crystal structures of DNA polymerase beta in complex with two different mispairs (A-C and T-C) reveal that the two bases stack partially, rather than engage in hydrogen bonding with each other (Krahn et al., this issue of Structure). The N-domain of the polymerase, which is closed when the correct nucleotide pairs with the template base, adopts a partially open conformation suboptimal for catalysis.

Attenuation of DNA Replication by HIV-1 Reverse Transcriptase near the Central Termination Sequence

Previous pre-steady-state kinetic studies of equine infectious anemia virus-1 (EIAV) reverse transcriptase (RT) showed two effects of DNA substrates containing the central termination sequence (CTS) on the polymerization reaction: reduction of burst amplitude in single nucleotide addition experiments and accumulation of termination products during processive DNA synthesis [Berdis, A. J., Stetor, S. R., Le Grice, S. F. J., and Barkley, M. D. (2001) Biochemistry 40, 12140-12149]. The present study of HIV RT uses pre-steady-state kinetic techniques to evaluate the molecular mechanisms of the lower burst amplitudes using both random sequence and CTS-containing DNA substrates. The effects of various factors, including primer/template length, binding orientation, and protein concentration, on the burst amplitude were determined using random sequence DNA substrates. The percent active RT increases with total RT concentration, indicating that reversible dissociation of RT dimer is responsible for substoichiometric burst amplitudes with normal substrates. This finding was confirmed by gel mobility shift assays. Like EIAV RT, HIV RT showed lower burst amplitudes on CTS-containing DNA substrates compared to random sequences. The dissociation kinetics of RT-DNA complexes were monitored by enzyme activity and fluorescence. Biphasic kinetics were observed for both random sequence and CTS-containing DNA complexes, revealing two forms of the RT-DNA complex. A mechanism is proposed to account for reduction in burst amplitude of CTS-containing DNA that is consistent with the results of both single nucleotide addition and dissociation experiments. The two forms of the RT-DNA complex may represent partitioning of primer/template between the P- and N-sites on RT for the nucleic acid substrate.

Dependence of DNA polymerase replication rate on external forces: a model based on molecular dynamics simulations

Molecular dynamics simulations are presented for a Thermus aquaticus (Taq) DNA polymerase I complex (consisting of the protein, the primer-template DNA strands, and the incoming nucleotide) subjected to external forces. The results obtained with a force applied to the DNA template strand provide insights into the effect of the tension on the activity of the enzyme. At forces below 30 pN a local model based on the parameters determined from the simulations, including the restricted motion of the DNA bases at the active site, yields a replication rate dependence on force in agreement with experiment. Simulations above 40 pN reveal large conformational changes in the enzyme-bound DNA that may have a role in the force-induced exonucleolysis observed experimentally.

Archaeal CCA-adding Enzymes

The CCA-adding enzyme (tRNA nucleotidyltransferase) builds and repairs the 3' end of tRNA. A single active site adds both CTP and ATP, but the enzyme has no nucleic acid template, and tRNA does not translocate or rotate during C75 and A76 addition. We modeled the structure of the class I archaeal Sulfolobus shibatae CCA-adding enzyme on eukaryotic poly(A) polymerase and mutated residues in the vicinity of the active site. We found mutations that specifically affected C74, C75, or A76 addition, as well as mutations that progressively impaired addition of CCA. Many of these mutations clustered in an evolutionarily versatile beta-turn located between strands 3 and 4 of the nucleotidyltransferase domain. Our mutational analysis confirms and extends recent crystallographic studies of the highly homologous Archaeoglobus fulgidus enzyme. We suggest that the unusual phenotypes of the beta-turn mutants reflect the consecutive conformations assumed by the beta-turn as it presents the discriminator base N73, then C74, and finally C75 to the active site without translocation or rotation of the tRNA acceptor stem. We also suggest that beta-turn mutants can affect nucleotide selection because the growing 3' end of tRNA must be properly positioned to serve as part of the ribonucleoprotein template that selects the incoming nucleotide.

Calcium-independent calmodulin binding and two-metal-ion catalytic mechanism of anthrax edema factor

Edema factor (EF), a key anthrax exotoxin, has an anthrax protective antigen-binding domain (PABD) and a calmodulin (CaM)-activated adenylyl cyclase domain. Here, we report the crystal structures of CaM-bound EF, revealing the architecture of EF PABD. CaM has N- and C-terminal domains and each domain can bind two calcium ions. Calcium binding induces the conformational change of CaM from closed to open. Structures of the EF-CaM complex show how EF locks the N-terminal domain of CaM into a closed conformation regardless of its calcium-loading state. This represents a mechanism of how CaM effector alters the calcium affinity of CaM and uncouples the conformational change of CaM from calcium loading. Furthermore, structures of EF-CaM complexed with nucleotides show that EF uses two-metal-ion catalysis, a prevalent mechanism in DNA and RNA polymerases. A histidine (H351) further facilitates the catalysis of EF by activating a water to deprotonate 3'OH of ATP. Mammalian adenylyl cyclases share no structural similarity with EF and they also use two-metal-ion catalysis, suggesting the catalytic mechanism-driven convergent evolution of two structurally diverse adenylyl cyclases.

Transposition of hAT elements links transposable elements and V(D)J recombination

Transposons are DNA sequences that encode functions that promote their movement to new locations in the genome. If unregulated, such movement could potentially insert additional DNA into genes, thereby disrupting gene expression and compromising an organism's viability. Transposable elements are classified by their transposition mechanisms and by the transposases that mediate their movement. The mechanism of movement of the eukaryotic hAT superfamily elements was previously unknown, but the divergent sequence of hAT transposases from other elements suggested that these elements might use a distinct mechanism. Here we have analysed transposition of the insect hAT element Hermes in vitro. Like other transposons, Hermes excises from DNA via double-strand breaks between the donor-site DNA and the transposon ends, and the newly exposed transposon ends join to the target DNA. Interestingly, the ends of the donor double-strand breaks form hairpin intermediates, as observed during V(D)J recombination, the process which underlies the combinatorial formation of antigen receptor genes. Significant similarities exist in the catalytic amino acids of Hermes transposase, the V(D)J recombinase RAG, and retroviral integrase superfamily transposases, thereby linking the movement of transposable elements and V(D)J recombination.

A closed conformation for the Pol lambda catalytic cycle

Pol lambda is a family X member believed to fill short gaps during DNA repair. Here we report crystal structures of Pol lambda representing three steps in filling a single-nucleotide gap. These structures indicate that, unlike other DNA polymerases, Pol lambda does not undergo large subdomain movements during catalysis, and they provide a clear characterization of the geometry and stereochemistry of the in-line nucleotidyl transfer reaction.

Low-fidelity Pyrococcus furiosus DNA polymerase mutants useful in error-prone PCR

Random mutagenesis constitutes an important approach for identifying critical regions of proteins, studying structure-function relations and developing novel proteins with desired properties. Perhaps, the most popular method is the error-prone PCR, in which mistakes are introduced into a gene, and hence a protein, during DNA polymerase-catalysed amplification cycles. Unfortunately, the relatively high fidelities of the thermostable DNA polymerases commonly used for PCR result in too few mistakes in the amplified DNA for efficient mutagenesis. In this paper, we describe mutants of the family B DNA polymerase from Pyrococcus furiosus (Pfu-Pol), with superb performance in error-prone PCR. The key amino acid changes occur in a short loop linking two long alpha-helices that comprise the 'fingers' sub-domain of the protein. This region is responsible for binding the incoming dNTPs and ensuring that only correct bases are inserted opposite the complementary base in the template strand. Mutations in the short loop, when combined with an additional mutation that abolishes the 3'-5' proof-reading exonuclease activity, convert the extremely accurate wild-type polymerase into a variant with low fidelity. The mutant Pfu-Pols can be applied in error-prone PCR, under exactly the same conditions used for standard, high-fidelity PCR with the wild-type enzyme. Large quantities of amplified product, with a high frequency of nearly indiscriminate mutations, are produced. It is anticipated that the Pfu-Pol variants will be extremely useful for the randomization of gene, and hence protein, sequences.

Closing of the Fingers Domain Generates Motor Forces in the HIV Reverse Transcriptase

Using the force sensor of an atomic force microscope, motor forces of the human immunodeficiency virus-1 reverse transcriptase were measured during active replication of a short DNA transcript. At low load forces the polymerase is mechanically slowed, whereas at high force (approximately 15 piconewton) it stalls. From recordings of estimated polymerase turnover velocity versus load force, an approximate force-velocity curve has been constructed. The shape of the curve suggests that load force strongly inhibits the rate-limiting step of the polymerase turnover cycle and that the combined effect of load on all steps involves an effective motion of about 1.6 nm. Earlier results from pre-steady-state kinetics experiments have identified the rate-limiting step as the closing of the fingers domain to form a tight catalytic complex. Together these findings indicate that the closing of the fingers domain is a major force-generating step for human immunodeficiency virus reverse transcriptase and, by extension, for all DNA polymerase machines.

Structure of a high fidelity DNA polymerase bound to a benzo[a]pyrene adduct that blocks replication

Of the carcinogens to which humans are most frequently exposed, the polycyclic aromatic hydrocarbon benzo[a]pyrene (BP) is one of the most ubiquitous. BP is a byproduct of grilled foods and tobacco and fuel combustion and has long been linked to various human cancers, particularly lung and skin. BP is metabolized to diol epoxides that covalently modify DNA bases to form bulky adducts that block DNA synthesis by replicative or high fidelity DNA polymerases. Here we present the structure of a high fidelity polymerase from a thermostable strain of Bacillus stearothermophilus (Bacillus fragment) bound to the most common BP-derived N2-guanine adduct base-paired with cytosine. The BP adduct adopts a conformation that places the polycyclic BP moiety in the nascent DNA minor groove and is the first structure of a minor groove adduct bound to a polymerase. Orientation of the BP moiety into the nascent DNA minor groove results in extensive disruption to the interactions between the adducted DNA duplex and the polymerase. The disruptions revealed by the structure of Bacillus fragment bound to a BP adduct provide a molecular basis for rationalizing the potent blocking effect on replication exerted by BP adducts.

DNA polymerase lambda can elongate on DNA substrates mimicking non-homologous end joining and interact with XRCC4-ligase IV complex

Non-homologous end joining (NHEJ) is one of two pathways responsible for the repair of double-strand breaks in eukaryotic cells. The mechanism involves the alignment of broken DNA ends with minimal homology, fill in of short gaps by DNA polymerase(s), and ligation by XRCC4-DNA ligase IV complex. The gap-filling polymerase has not yet been positively identified, but recent biochemical studies have implicated DNA polymerase lambda (pol lambda), a novel DNA polymerase that has been assigned to the pol X family, in this process. Here we demonstrate that purified pol lambda can efficiently catalyze gap-filling synthesis on DNA substrates mimicking NHEJ. By designing two truncated forms of pol lambda, we also show that the unique proline-rich region in pol lambda plays a role in limiting strand displacement synthesis, a feature that may help its participation in in vivo NHEJ. Moreover, pol lambda interacts with XRCC4-DNA ligase IV via its N-terminal BRCT domain and the interaction stimulates the DNA synthesis activity of pol lambda. Taken together, these data strongly support that pol lambda functions in DNA polymerization events during NHEJ.

Nucleotide-dependent isomerization of Escherichia coli RNA polymerase

During promoter engagement, RNA polymerase must change conformation or isomerize to its active form. These data show that high concentrations of nucleotides assist this isomerization. When binding to fork junction DNA probes is monitored, isomerization can occur without the need for the DNA that overlaps the transcription start site. When the start site is present, nucleoside triphosphates cause polymerase to change conformation in a way that drives cross-linking to the +1 position on the template strand. Preincubation of transcription complexes with 2 mM initiating nucleotide can drive formation of heparin-resistant complexes under conditions in which isomerization is limiting. It is proposed that complete polymerase isomerization can require nucleotide binding, which can assist formation of the active site that engages the transcription start site.

Observing Translesion Synthesis of an Aromatic Amine DNA Adduct by a High-fidelity DNA Polymerase

Aromatic amines have been studied for more than a half-century as model carcinogens representing a class of chemicals that form bulky adducts to the C8 position of guanine in DNA. Among these guanine adducts, the N-(2'-deoxyguanosin-8-yl)-aminofluorene (G-AF) and N-2-(2'-deoxyguanosin-8-yl)-acetylaminofluorene (G-AAF) derivatives are the best studied. Although G-AF and G-AAF differ by only an acetyl group, they exert different effects on DNA replication by replicative and high-fidelity DNA polymerases. Translesion synthesis of G-AF is achieved with high-fidelity polymerases, whereas replication of G-AAF requires specialized bypass polymerases. Here we have presented structures of G-AF as it undergoes one round of accurate replication by a high-fidelity DNA polymerase. Nucleotide incorporation opposite G-AF is achieved in solution and in the crystal, revealing how the polymerase accommodates and replicates past G-AF, but not G-AAF. Like an unmodified guanine, G-AF adopts a conformation that allows it to form Watson-Crick hydrogen bonds with an opposing cytosine that results in protrusion of the bulky fluorene moiety into the major groove. Although incorporation opposite G-AF is observed, the C:G-AF base pair induces distortions to the polymerase active site that slow translesion synthesis.

Quantification of isomeric equilibria formed by metal ion complexes of 8-[2-(phosphonomethoxy)ethyl]-8-azaadenine (8,8aPMEA) and 9-[2-(phosphonomethoxy)ethyl]-8-azaadenine (9,8aPMEA). Derivatives of the antiviral nucleotide analogue 9-[2-(phosphonomethoxy)ethyl]adenine (PMEA)

The acidity constants of the two-fold protonated acyclic 9-[2-(phosphonomethoxy)ethyl]-8-azaadenine, H2(9,8aPMEA)(+)(-), and its 8-isomer, 8-[2-(phosphonomethoxy)ethyl]-8-azaadenine, H2(8,8aPMEA)(+)(-), both abbreviated as H2(PA)(+)(-), as well as the stability constants of their M(H;PA)+ and M(PA) complexes with the metal ions M2+=Mg2+, Ca2+, Sr2+, Ba2+, Mn2+, Co2+, Ni2+, Cu2+, Zn2+ or Cd2+, have been determined by potentiometric pH titrations in aqueous solution at I=0.1 M (NaNO3) and 25 degrees C. Application of previously determined straight-line plots of log K(M)M(R-PO3) versus pK(H)H(R-PO3)for simple phosph(on)ate ligands, R-PO3(2-), where R represents a residue without an affinity for metal ions, proves that for all M(PA) complexes a larger stability is observed than is expected for a sole phosphonate coordination of the metal ion. This increased stability is attributed to the formation of five-membered chelates involving the ether oxygen present in the aliphatic residue (-CH2-O-CH2-PO3(2-)) of the ligands. The formation degrees of these chelates were calculated; they vary between about 13% for Ca(8,8aPMEA) and 71% for Cu(8,8aPMEA). The adenine residue has no influence on complex stability except in the Cu(9,8aPMEA) and Zn(9,8aPMEA) systems, where an additional stability increase attributable to the adenine residue is observed and equilibria between four different isomers exist. This means (1) an open isomer with a sole phosphonate coordination, M(PA)op, where PA(2-)=9,8aPMEA2-, (2) an isomer with a five-membered chelate involving the ether oxygen, M(PA)cl/O, (3) an isomer which contains five- and seven-membered chelates formed by coordination of the phosphonate group, the ether oxygen and the N3 site of the adenine residue, M(PA)cl/O/N3, and finally (4) a macrochelated isomer involving N7, M(PA)cl/N7. For Cu(9,8aPMEA) the formation degrees are 15, 30, 48 and 7% for Cu(PA)op, Cu(PA)cl/O, Cu(PA)cl/O/N3 and Cu(PA)cl/N7, respectively; this proves that the macrochelate involving N7 is a minority species. The situation for the Cu(PMEA) system, where PMEA2- represents the parent compound, i.e. the dianion of 9-[2-(phosphonomethoxy)ethyl]adenine, is quite similar. The relationship between the antiviral activity of acyclic nucleoside phosphonates and the structures of the various complexes is discussed and an explanation is offered why 9,8aPMEA is biologically active but 8,8aPMEA is not.

Biochemical and structural insights into substrate binding and catalytic mechanism of mammalian poly(A) polymerase

Polyadenylation of messenger RNA precursors is an essential process in eukaryotes. Poly(A) polymerase (PAP), a member of the nucleotidyltransferase family that includes DNA polymerase beta, incorporates ATP at the 3' end of mRNAs in a template-independent manner. Although the structures of mammalian and yeast PAPs are known, their mechanism of ATP selection has remained elusive. In a recent bovine PAP structure complexed with an analog of ATP and Mn2+, strictly conserved residues interact selectively with the adenine base, but the nucleotide was found in a "non-productive" conformation. Here we report a second bovine crystal structure, obtained in the presence of Mg2+, where 3'-dATP adopts a "productive" conformation similar to that seen in yeast PAP or DNA polymerase beta. Mutational analysis and activity assays with ATP analogs suggest a role in catalysis for one of the two adenine-binding sites revealed by our structural data. The other site might function to prevent futile hydrolysis of ATP. In order to investigate the role of metals in catalysis we performed steady state kinetics experiments under distributive polymerization conditions. These tests suggest a sequential random mechanism in vitro in the presence of ATP and RNA, without preference for a particular order of binding of the two substrates. In vivo, however, where polyadenylation is processive and the primer does not dissociate from the enzyme, an ordered mechanism with the primer as the leading substrate is more likely.

Coordination of divalent metal ions in the active site of poly(A)-specific ribonuclease

Poly(A)-specific ribonuclease (PARN) is a highly poly(A)-specific 3'-exoribonuclease that efficiently degrades mRNA poly(A) tails. PARN belongs to the DEDD family of nucleases, and four conserved residues are essential for PARN activity, i.e. Asp-28, Glu-30, Asp-292, and Asp-382. Here we have investigated how catalytically important divalent metal ions are coordinated in the active site of PARN. Each of the conserved amino acid residues was substituted with cysteines, and it was found that all four mutants were inactive in the presence of Mg2+. However, in the presence of Mn2+, Zn2+, Co2+, or Cd2+, PARN activity was rescued from the PARN(D28C), PARN(D292C), and PARN(D382C) variants, suggesting that these three amino acids interact with catalytically essential metal ions. It was found that the shortest sufficient substrate for PARN activity was adenosine trinucleotide (A3) in the presence of Mg2+ or Cd2+. Interestingly, adenosine dinucleotide (A) was efficiently hydrolyzed in the presence of Mn2+, Zn2+, or Co2+, suggesting that the substrate length requirement for PARN can be modulated by the identity of the divalent metal ion. Finally, introduction of phosphorothioate modifications into the A substrate demonstrated that the scissile bond non-bridging phosphate oxygen in the pro-R position plays an important role during cleavage, most likely by coordinating a catalytically important divalent metal ion. Based on our data we discuss binding and coordination of divalent metal ions in the active site of PARN.

Poliovirus RNA-dependent RNA polymerase (3Dpol): pre-steady-state kinetic analysis of ribonucleotide incorporation in the presence of Mn2+

The use of Mn(2+) as the divalent cation cofactor in polymerase-catalyzed reactions instead of Mg(2+) often diminishes the stringency of substrate selection and incorporation fidelity. We have solved the complete kinetic mechanism for single nucleotide incorporation catalyzed by the RNA-dependent RNA polymerase from poliovirus (3D(pol)) in the presence of Mn(2+). The steps employed during a single cycle of nucleotide incorporation are identical to those employed in the presence of Mg(2+) and include a conformational-change step after nucleotide binding to achieve catalytic competence of the polymerase-primer/template-nucleotide complex. In the presence of Mn(2+), the conformational-change step is the primary determinant of enzyme specificity, phosphoryl transfer appears as the sole rate-limiting step for nucleotide incorporation, and the rate of phosphoryl transfer is the same for all nucleotides: correct and incorrect. Because phosphoryl transfer is the rate-limiting step in the presence of Mn(2+), it was possible to determine that the maximal phosphorothioate effect in this system is in the range of 8-11. This information permitted further interrogation of the nucleotide-selection process in the presence of Mg(2+), highlighting the capacity of this cation to permit the enzyme to use the phosphoryl-transfer step for nucleotide selection. The inability of Mn(2+) to support a reduction in the efficiency of phosphoryl transfer when incorrect substrates are employed is the primary explanation for the loss of fidelity observed in the presence of this cofactor. We propose that the conformational change involves reorientation of the triphosphate moiety of the bound nucleotide into a conformation that permits binding of the second metal ion required for catalysis. In the presence of Mg(2+), this conformation requires interactions with the enzyme that permit a reduction in catalytic efficiency to occur during an attempt to incorporate an incorrect nucleotide. Adventitious interactions in the cofactor-binding site with bound Mn(2+) may diminish fidelity by compensating for interaction losses used to modulate catalytic efficiency when incorrect nucleotides are bound in the presence of Mg(2+).

Structural basis for template-independent RNA polymerization

The 3'-terminal CCA nucleotide sequence (positions 74-76) of transfer RNA is essential for amino acid attachment and interaction with the ribosome during protein synthesis. The CCA sequence is synthesized de novo and/or repaired by a template-independent RNA polymerase, 'CCA-adding enzyme', using CTP and ATP as substrates. Despite structural and biochemical studies, the mechanism by which the CCA-adding enzyme synthesizes the defined sequence without a nucleic acid template remains elusive. Here we present the crystal structure of Aquifex aeolicus CCA-adding enzyme, bound to a primer tRNA lacking the terminal adenosine and an incoming ATP analogue, at 2.8 A resolution. The enzyme enfolds the acceptor T helix of the tRNA molecule. In the catalytic pocket, C75 is adjacent to ATP, and their base moieties are stacked. The complementary pocket for recognizing C74-C75 of tRNA forms a 'protein template' for the penultimate two nucleotides, mimicking the nucleotide template used by template-dependent polymerases. These results are supported by systematic analyses of mutants. Our structure represents the 'pre-insertion' stage of selecting the incoming nucleotide and provides the structural basis for the mechanism underlying template-independent RNA polymerization.

The activity of selected RB69 DNA polymerase mutants can be restored by manganese ions: the existence of alternative metal ion ligands used during the polymerization cycle

Site specific mutants in the pol active center of RB69 DNA polymerase have been produced and studied using rapid chemical-quench techniques. Pre-steady-state kinetic analysis carried out with Mg(2+) and Mn(2+) has enabled us to divide the mutants into two groups. One group had greatly reduced k(pols) values in the presence of Mg(2+) but responded to Mn(2+) which restored the k(pol) values for the nucleotidyl transfer reaction to near wild-type levels. The other group of mutants also had lower k(pol) values, relative to that of the wild-type polymerase, but could not be rescued by Mn(2+). The behavior of these mutants was interpreted in terms of the crystal structures of the available RB69 pol complexes. Our results on the metal ion dependence of the D621A and E686A mutants, together with knowledge of the position of their side chains in two different RB69 pol conformations, suggest that these acidic residues serve as alternative ligands for the metal ions destined to occupy the A and B catalytic sites. We infer that this occurs prior to the conformational change that produces the ternary RB69 pol complex in which the A and B metal ions are ligated by D623 and D411 as the enzyme is poised for phosphoryl transfer.

Structural basis for the dual coding potential of 8-oxoguanosine by a high-fidelity DNA polymerase

Accurate DNA replication involves polymerases with high nucleotide selectivity and proofreading activity. We show here why both fidelity mechanisms fail when normally accurate T7 DNA polymerase bypasses the common oxidative lesion 8-oxo-7, 8-dihydro-2'-deoxyguanosine (8oG). The crystal structure of the polymerase with 8oG templating dC insertion shows that the O8 oxygen is tolerated by strong kinking of the DNA template. A model of a corresponding structure with dATP predicts steric and electrostatic clashes that would reduce but not eliminate insertion of dA. The structure of a postinsertional complex shows 8oG(syn).dA (anti) in a Hoogsteen-like base pair at the 3' terminus, and polymerase interactions with the minor groove surface of the mismatch that mimic those with undamaged, matched base pairs. This explains why translesion synthesis is permitted without proofreading of an 8oG.dA mismatch, thus providing insight into the high mutagenic potential of 8oG.

Structure of foot-and-mouth disease virus RNA-dependent RNA polymerase and its complex with a template-primer RNA

Genome replication in picornaviruses is catalyzed by a virally encoded RNA-dependent RNA polymerase, termed 3D. The enzyme performs this operation, together with other viral and probably host proteins, in the cytoplasm of their host cells. The crystal structure of the 3D polymerase of foot-and-mouth disease virus, one of the most important animal pathogens, has been determined unliganded and bound to a template-primer RNA decanucleotide. The enzyme folds in the characteristic fingers, palm and thumb subdomains, with the presence of an NH2-terminal segment that encircles the active site. In the complex, several conserved amino acid side chains bind to the template-primer, likely mediating the initiation of RNA synthesis. The structure provides essential information for studies on RNA replication and the design of antiviral compounds.

Pre-steady-state kinetics of RB69 DNA polymerase and its exo domain mutants: effect of pH and thiophosphoryl linkages on 3'-5' exonuclease activity

DNA polymerases from the A and B families with 3'-5' exonucleolytic activity have exonuclease domains with similar three-dimensional structures that require two divalent metal ions for catalysis. B family DNA polymerases that are part of a replicase generally have a more potent 3'-5' exonuclease (exo) activity than A family DNA polymerases that mainly function in DNA repair. To investigate the basis for these differences, we determined pH-activity profiles for the exonuclease reactions of T4, RB69, and phi29 DNA polymerases as representatives of B family replicative DNA polymerases and the Klenow fragment (KF) as an example of a repair DNA polymerase in the A family. We performed exo assays under single-turnover conditions and found that excision rates exhibited by the B family DNA polymerases were essentially independent of pH between pH 6.5 and 8.5, whereas the exo activity of KF increased 10-fold for each unit increase in pH. Three exo domain mutants of RB69 polymerase had much lower exo activities than the wild-type enzyme and exhibited pH-activity profiles similar to that of KF. On the basis of pH versus activity data and elemental effects obtained using short double-stranded DNA substrates terminating in phosphorothioate linkages, we suggest that the rate of the chemical step is reduced to the point where it becomes limiting with RB69 pol mutants K302A, Y323F, and E116A, in contrast to the wild-type enzyme where chemistry is faster than the rate-determining step that precedes it.

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.

Efficient 3D Database Screening for Novel HIV-1 IN Inhibitors

We describe the use of pharmacophore modeling as an efficient tool in the discovery of novel HIV-1 integrase (IN) inhibitors. A three-dimensional hypothetical model for the binding of diketo acid analogues to the enzyme was built by means of the Catalyst program. Using these models as a query for virtual screening, we found several compounds that contain the specified 3D patterns of chemical functions. Biological testing shows that our strategy was successful in searching for new structural leads as HIV-1 IN inhibitors.

Accuracy, lesion bypass, strand displacement and translocation by DNA polymerases

The structures of DNA polymerases from different families show common features and significant differences that shed light on the ability of these enzymes to accurately copy DNA and translocate. The structure of a B family DNA polymerase from phage RB69 exhibits an active-site closing conformational change in the fingers domain upon forming a ternary complex with primer template in deoxynucleoside triphosphate. The rotation of the fingers domain alpha-helices by 60 degrees upon dNTP binding is analogous to the changes seen in other families of polymerases. When the 3' terminus is bound to the editing 3' exonuclease active site, the orientation of the DNA helix axis changes by 40 degrees and the thumb domain re-orients with the DNA. Structures of substrate and product complexes of T7 RNA polymerase, a structural homologue of T7 DNA polymerase, show that family polymerases use the rotation conformational change of the fingers domain to translocate down the DNA. The fingers opening rotation that results in translocation is powered by the release of the product pyrophosphate and also enables the Pol I family polymerases to function as a helicase in displacing the downstream non-template strand from the template strand.

Structures of mismatch replication errors observed in a DNA polymerase

Accurate DNA replication is essential for genomic stability. One mechanism by which high-fidelity DNA polymerases maintain replication accuracy involves stalling of the polymerase in response to covalent incorporation of mismatched base pairs, thereby favoring subsequent mismatch excision. Some polymerases retain a "short-term memory" of replication errors, responding to mismatches up to four base pairs in from the primer terminus. Here we a present a structural characterization of all 12 possible mismatches captured at the growing primer terminus in the active site of a polymerase. Our observations suggest four mechanisms that lead to mismatch-induced stalling of the polymerase. Furthermore, we have observed the effects of extending a mismatch up to six base pairs from the primer terminus and find that long-range distortions in the DNA transmit the presence of the mismatch back to the enzyme active site, suggesting the structural basis for the short-term memory of replication errors.

Effect of equatorial ligands of dirhodium(II,II) complexes on the efficiency and mechanism of transcription inhibition in vitro

The nature of the equatorial ligands spanning the dirhodium core was shown to affect the ability and mechanism of various lantern-type complexes to inhibit transcription in vitro. The inhibition of transcription by Rh(2)(mu-O(2)CCF(3))(4), Rh(2)(mu-HNCOCF(3))(4), and [Rh(2)(mu-O(2)CCH(3))(2)(CH(3)CN)(6)](2+) appears to proceed predominantly via binding of the complexes to T7-RNA polymerase (T7-RNAP) and is dependent on the concentration of enzyme and Mg(2+) ions in solution. The concentrations of the aforementioned complexes required to inhibit 50% of the transcription, C(inh)(50), are similar to that measured for activated cisplatin, whereas a significantly higher concentration of Rh(2)(mu-HNCOCH(3))(4) is required to effect similar inhibition; the inhibition induced by Rh(2)(mu-HNCOCH(3))(4) does not involve binding to T7-RNAP. The spectral changes observed for each complex upon addition of enzyme are consistent with Rh(2)(mu-O(2)CCF(3))(4), Rh(2)(mu-HNCOCF(3))(4), and [Rh(2)(mu-O(2)CCH(3))(2)(CH(3)CN)(6)](2+) binding to the enzyme and may involve partial displacement of the equatorial (eq) groups by the Lewis basic sites of T7-RNAP. In contrast, addition of enzyme to solutions of Rh(2)(mu-HNCOCH(3))(4) does not result in significant spectral changes, a finding consistent with lack of enzyme dependence in the transcription inhibition. These differences in reactivity and transcription inhibition mechanism among complexes with different bridging ligands are explained by variations of the Lewis acidity of the axial (ax) sites in the series of complexes Rh(2)(mu-O(2)CCF(3))(4), Rh(2)(mu-HNCOCF(3))(4), and Rh(2)(mu-HNCOCH(3))(4). The Lewis acidity of the ax sites is expected to affect the initial interaction of the complexes with the biomolecules, followed by their rearrangement to eq positions if the bridging ligands are labile.

Crystallographic snapshots of a replicative DNA polymerase encountering an abasic site

Abasic sites are common DNA lesions, which are strong blocks to replicative polymerases and are potentially mutagenic when bypassed. We report here the 2.8 A structure of the bacteriophage RB69 replicative DNA polymerase attempting to process an abasic site analog. Four different complexes were captured in the crystal asymmetric unit: two have DNA in the polymerase active site whereas the other two molecules are in the exonuclease mode. When compared to complexes with undamaged DNA, the DNA surrounding the abasic site reveals distinct changes suggesting why the lesion is so poorly bypassed: the DNA in the polymerase active site has not translocated and is therefore stalled, precluding extension. All four molecules exhibit conformations that differ from the previously published structures. The polymerase incorporates dAMP across the lesion under crystallization conditions, indicating that the different conformations observed in the crystal may be part of the active site switching reaction pathway.

RNA-dependent RNA polymerases of dsRNA bacteriophages

Genome replication and transcription of riboviruses are catalyzed by an RNA-dependent RNA polymerase (RdRP). RdRPs are normally associated with other virus- or/and host-encoded proteins that modulate RNA polymerization activity and template specificity. The polymerase complex of double-stranded dsRNA viruses is a large icosahedral particle (inner core) containing RdRP as a minor constituent. In phi6 and other dsRNA bacteriophages from the Cystoviridae family, the inner core is composed of four virus-specific proteins. Of these, protein P2, or Pol subunit, has been tentatively identified as RdRP by sequence comparisons, but the role of this protein in viral RNA synthesis has not been studied until recently. Here, we overview the work on the Pol subunits of phi6 and related viruses from the standpoints of function, structure and evolution.

Two positively charged residues of phi29 DNA polymerase, conserved in protein-primed DNA polymerases, are involved in stabilisation of the incoming nucleotide

In DNA polymerases from families A and B in the closed conformation, several positively charged residues, located in pre-motif B and motif B, have been shown to interact with the phosphate groups of the incoming nucleotide at the polymerisation active site: the invariant Lys of motif B and the nearly invariant Lys of pre-motif B (family B) correspond to a His in family A DNA polymerases. In phi29 DNA polymerase, belonging to the family B DNA polymerases able to start replication by protein-priming, the corresponding residues, Lys383 and Lys371, have been shown to be dNTP-ligands. Since in several DNA polymerases a third residue has been involved in dNTP binding, we have addressed here the question if in the DNA polymerases of the protein-primed subfamily, and especially in phi29 DNA polymerase, there are more than these two residues involved in nucleotide binding. By site-directed mutagenesis in phi29 DNA polymerase the functional role of the remaining two conserved positively charged amino acid residues of pre-motif B and motif B (besides Lys371 and Lys383) has been studied. The results indicate that residue Lys379 of motif B is also involved in dNTP binding, possibly through interaction with the triphosphate moiety of the incoming nucleotide, since the affinity for nucleotides of mutant DNA polymerase K379T was reduced in DNA and TP-primed reactions. On the other hand, we propose that, when the terminal protein (TP) is present at the polymerisation active site, residue Lys366 of pre-motif B is involved in stabilising the incoming nucleotide in an appropriate position for efficient TP-deoxynucleotidylation. Although mutant DNA polymerase K366T showed a wild-type like phenotype in DNA-primed polymerisation in the presence of DNA as template, in TP-primed reactions as initiation and transition it was impaired, especially in the presence of the phi29 DBP, protein p6.

Characterization of the active site of DNA polymerase beta by molecular dynamics and quantum chemical calculation

It is well established that the fully formed polymerase active site of the DNA repair enzyme, polymerase beta (pol beta), including two bound Mg2+ cations and the nucleoside triphosphate (dNTP) substrate, exists at only one point in the catalytic cycle just prior to the chemical nucleotidyl transfer step. The structure of the active conformation has been the subject of much interest as it relates to the mechanism of the chemical step and also to the question of fidelity assurance. Although crystal structures of ternary pol beta-(primer-template) DNA-dNTP complexes have provided the main structural features of the active site, they are necessarily incomplete due to intentional alterations (e.g., removal of the 3'OH groups from primer and substrate) needed to obtain a structure from midcycle. Working from the crystal structure closest to the fully formed active site [Protein Data Bank (PDB) code: 1bpy], two molecular dynamics (MD) simulations of the solvated ternary complex were performed: one with the missing 3'OHs restored, via modeling, to the primer and substrate, and the other without restoration of the 3'OHs. The results of the simulations, together with ab initio optimizations on simplified active-site models, indicate that the missing primer 3'OH in the crystal structure is responsible for a significant perturbation in the coordination sphere of the catalytic cation and allow us to suggest several corrections and additions to the active-site structure as observed by crystallography. In addition, the calculations help to resolve questions raised regarding the protonation states of coordinating ligands.

Why are there four letters in the genetic alphabet?

We list, without thinking, the four base types that make up DNA as adenine, guanine, cytosine and thymine. But why are there four? This question is now all the more relevant as organic chemists have synthesized new base pairs that can be incorporated into nucleic acids. Here, I argue that there are theoretical, experimental and computational reasons to believe that having four base types is a frozen relic from the RNA world, when RNA was genetic as well as enzymatic material.

Function of the C-terminus of phi29 DNA polymerase in DNA and terminal protein binding

The thumb subdomain, located in various family B DNA polymerases in the C-terminal region, has been shown in their crystal structures to move upon binding of DNA, changing its conformation to nearly completely wrap around the DNA. It has therefore been involved in DNA binding. In agreement with this, partial proteolysis studies of phi29 DNA polymerase have shown that the accessibility of the cleavage sites located in their C-terminal region is reduced in the presence of DNA or terminal protein (TP), indicating that a conformational change occurs in this region upon substrate binding and suggesting that this region might be involved in DNA and TP binding. Therefore, we have studied the role of the C-terminus of phi29 DNA polymerase by deletion of the last 13 residues of this enzyme. This fragment includes a previously defined region conserved in family B DNA polymerases. The resulting DNA polymerase Delta13 was strongly affected in DNA binding, resulting in a distributive replication activity. Additionally, the capacity of the truncated polymerase to interact with TP was strongly reduced and its initiation activity was very low. On the other hand, its nucleotide binding affinity and its fidelity were not affected. We propose that the C-terminal 13 amino acids of phi29 DNA polymerase are involved in DNA binding and in a stable interaction with the initiator protein TP, playing an important role in the intrinsic processivity of this enzyme during polymerization.

Divergent evolutions of trinucleotide polymerization revealed by an archaeal CCA-adding enzyme structure

CCA-adding enzyme [ATP(CTP):tRNA nucleotidyltransferase], a template-independent RNA polymerase, adds the defined 'cytidine-cytidine-adenosine' sequence onto the 3' end of tRNA. The archaeal CCA-adding enzyme (class I) and eubacterial/eukaryotic CCA-adding enzyme (class II) show little amino acid sequence homology, but catalyze the same reaction in a defined fashion. Here, we present the crystal structures of the class I archaeal CCA-adding enzyme from Archaeoglobus fulgidus, and its complexes with CTP and ATP at 2.0, 2.0 and 2.7 A resolutions, respectively. The geometry of the catalytic carboxylates and the relative positions of CTP and ATP to a single catalytic site are well conserved in both classes of CCA-adding enzymes, whereas the overall architectures, except for the catalytic core, of the class I and class II CCA-adding enzymes are fundamentally different. Furthermore, the recognition mechanisms of substrate nucleotides and tRNA molecules are distinct between these two classes, suggesting that the catalytic domains of class I and class II enzymes share a common origin, and distinct substrate recognition domains have been appended to form the two presently divergent classes.

Covalent trapping of protein-DNA complexes

High-resolution structural studies of protein-DNA complexes have proven to be an invaluable means of understanding the diverse functions of proteins that manage the genome. Most of the structures determined to date represent proteins bound noncovalently to various DNA sequences or structures. Although noncovalent complexation is often adequate to study the structures of proteins that have robust, specific interactions with DNA, it is poorly suited to the study of transient intermediates in enzyme-catalyzed DNA processing reactions or of complexes that exist in multiple equilibrating forms. In recent years, strategies developed for the covalent trapping of protein-DNA complexes have begun to show promise as a window into an otherwise inaccessible world of structure.

Terminal deoxynucleotidyl transferases from elasmobranchs reveal structural conservation within vertebrates

The DNA polymerase (pol) X family is an ancient group of enzymes that function in DNA replication and repair (pol beta), translesion synthesis (pol lambda and pol micro) and terminal addition of non-templated nucleotides. This latter terminal deoxynucleotidyl transferase (TdT) activity performs the unique function of providing diversity at coding joins of immunoglobulin and T-cell receptor genes. The first isolated full-length TdT genes from shark and skate are reported here. Comparisons with the three-dimensional structure of mouse TdT indicate structural similarity with elasmobranch orthologues that supports both a template-independent mode of replication and a lack of strong nucleotide bias. The vertebrate TdTs appear more closely related to pol micro and fungal polymerases than to pol lambda and pol beta. Thus, unlike other molecules of adaptive immunity, TdT is a member of an ancient gene family with a clear gene phylogeny and a high degree of similarity, which implies the existence of TdT ancestors in jawless fishes and invertebrates.

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.

DNA Polymerase Template Interactions Probed by Degenerate Isosteric Nucleobase Analogs

The development of novel artificial nucleobases and detailed X-ray crystal structures for primer/template/DNA polymerase complexes provide opportunities to assess DNA-protein interactions that dictate specificity. Recent results have shown that base pair shape recognition in the context of DNA polymerase must be considered a significant component. The isosteric azole carboxamide nucleobases (compounds 1-5; ) differ only in the number and placement of nitrogen atoms within a common shape and therefore present unique electronic distributions that are shown to dictate the selectivity of template-directed nucleotide incorporation by DNA polymerases. The results demonstrate how nucleoside triphosphate substrate selection by DNA polymerase is a complex phenomenon involving electrostatic interactions in addition to hydrogen bonding and shape recognition. These azole nucleobase analogs offer unique molecular tools for probing nonbonded interactions dictating substrate selection and fidelity of DNA polymerases.