Cleavage of double-stranded DNA by the intrinsic 3'-5' exonuclease activity of DNA polymerase B1 from the hyperthermophilic archaeon Sulfolobus solfataricus at high temperature

Characterization and application of a family B DNA polymerase from the hyperthermophilic and radioresistant euryarchaeon Thermococcus gammatolerans

Thermococcus gammatolerans is anaerobic euryarchaeon which grows optimally at 88 °C and its genome encodes a family B DNA polymerase (Tga PolB). Herein, we cloned the gene of Tga PolB, expressed and purified the gene product, and characterized the enzyme biochemically. The recombinant Tga PolB can efficiently synthesize DNA at high temperature, and retain 93% activity after heated at 95 °C for 1.0 h, suggesting that the enzyme is thermostable. Furthermore, the optimal pH for the enzyme activity was measured to be 7.0-9.0. Tga PolB activity is dependent on a divalent cation, among which magnesium ion is optimal. NaCl at low concentration stimulates the enzyme activity but at high concentration inhibits enzyme activity. Interestingly, Tga PolB is able to efficiently bypass uracil in DNA, which is distinct from other archaeal family B DNA pols. By contrast, Tga PolB is halted by an AP site in DNA, as observed in other archaeal family B DNA polymerases. Furthermore, Tga PolB extends the mismatched ends with reduced efficiencies. The enzyme possesses 3'-5' exonuclease activity and this activity is inhibited by dNTPs. The DNA binding assays showed that Tga PolB can efficiently bind to ssDNA and primed DNA, and have a marked preference for primed DNA. Last, Tga PolB can be used in routine PCR.

Sulfolobus replication factor C stimulates the activity of DNA polymerase B1

Replication factor C (RFC) is known to function in loading proliferating cell nuclear antigen (PCNA) onto primed DNA, allowing PCNA to tether DNA polymerase for highly processive DNA synthesis in eukaryotic and archaeal replication. In this report, we show that an RFC complex from the hyperthermophilic archaea of the genus Sulfolobus physically interacts with DNA polymerase B1 (PolB1) and enhances both the polymerase and 3'-5' exonuclease activities of PolB1 in an ATP-independent manner. Stimulation of the PolB1 activity by RFC is independent of the ability of RFC to bind DNA but is consistent with the ability of RFC to facilitate DNA binding by PolB1 through protein-protein interaction. These results suggest that Sulfolobus RFC may play a role in recruiting DNA polymerase for efficient primer extension, in addition to clamp loading, during DNA replication.

Sulfolobus chromatin proteins modulate strand displacement by DNA polymerase B1

Strand displacement by a DNA polymerase serves a key role in Okazaki fragment maturation, which involves displacement of the RNA primer of the preexisting Okazaki fragment into a flap structure, and subsequent flap removal and fragment ligation. We investigated the role of Sulfolobus chromatin proteins Sso7d and Cren7 in strand displacement by DNA polymerase B1 (PolB1) from the hyperthermophilic archaeon Sulfolobus solfataricus. PolB1 showed a robust strand displacement activity and was capable of synthesizing thousands of nucleotides on a DNA-primed 72-nt single-stranded circular DNA template. This activity was inhibited by both Sso7d and Cren7, which limited the flap length to 3–4 nt at saturating concentrations. However, neither protein inhibited RNA displacement on an RNA-primed single-stranded DNA minicircle by PolB1. Strand displacement remained sensitive to modulation by the chromatin proteins when PolB1 was in association with proliferating cell nuclear antigen. Inhibition of DNA instead of RNA strand displacement by the chromatin proteins is consistent with the finding that double-stranded DNA was more efficiently bound and stabilized than an RNA:DNA duplex by these proteins. Our results suggest that Sulfolobus chromatin proteins modulate strand displacement by PolB1, permitting efficient removal of the RNA primer while inhibiting excessive displacement of the newly synthesized DNA strand during Okazaki fragment maturation.

Identification and characterization of a highly conserved crenarchaeal protein lysine methyltransferase with broad substrate specificity

Protein lysine methylation occurs extensively in the Crenarchaeota, a major kingdom in the Archaea. However, the enzymes responsible for this type of posttranslational modification have not been found. Here we report the identification and characterization of the first crenarchaeal protein lysine methyltransferase, designated aKMT, from the hyperthermophilic crenarchaeon Sulfolobus islandicus. The enzyme was capable of transferring methyl groups to selected lysine residues in a substrate protein using S-adenosyl-l-methionine (SAM) as the methyl donor. aKMT, a non-SET domain protein, is highly conserved among crenarchaea, and distantly related homologs also exist in Bacteria and Eukarya. aKMT was active over a wide range of temperatures, from ~25 to 90 °C, with an optimal temperature at ~60 to 70 °C. Amino acid residues Y9 and T12 at the N terminus appear to be the key residues in the putative active site of aKMT, as indicated by sequence conservation and site-directed mutagenesis. Although aKMT was identified based on its methylating activity on Cren7, the crenarchaeal chromatin protein, it exhibited broad substrate specificity and was capable of methylating a number of recombinant Sulfolobus proteins overproduced in Escherichia coli. The finding of aKMT will help elucidate mechanisms underlining extensive protein lysine methylation and the functional significance of posttranslational protein methylation in crenarchaea.

Characterization of EndoTT, a novel single-stranded DNA-specific endonuclease from Thermoanaerobacter tengcongensis

EndoTT encoded by tte0829 of Thermoanaerobacter tengcongensis binds and cleaves single-stranded (ss) and damaged double-stranded (ds) DNA in vitro as well as binding dsDNA. In the presence of a low concentration of NaCl, EndoTT cleaved ss regions of damaged dsDNA efficiently but did not cleave DNA that was entirely ss or ds. At high concentrations of NaCl or MgCl(2) or ATP, there was also specific cleavage of ssDNA. This suggested a preference for ss/ds junctions to stimulate cleavage of the DNA substrates. EndoTT has six specific sites (a-f) in the oriC region (1-70 nt) of T. tengcongensis. Substitutions of nucleotides around site c prevented cleavage by EndoTT of both sites c and d, implying that the cleavage specificity may depend on both the nucleotide sequence and the secondary structure of the ssDNA. A C-terminal sub-fragment of EndoTT (residues 107-216) had both endonucleolytic and DNA-binding activity, whereas an N-terminal sub-fragment (residues 1-110) displayed only ssDNA-binding activity. Site-directed mutations showed that G(170), R(172) and G(177) are required for the endonuclease activity of EndoTT, but not for DNA-binding, whereas D(171), R(178) and G(189) are partially required for the DNA-binding activity.

A trimeric DNA polymerase complex increases the native replication processivity

DNA polymerases are essential enzymes in all domains of life for both DNA replication and repair. The primary DNA replication polymerase from Sulfolobus solfataricus (SsoDpo1) has been shown previously to provide the necessary polymerization speed and exonuclease activity to replicate the genome accurately. We find that this polymerase is able to physically associate with itself to form a trimer and that this complex is stabilized in the presence of DNA. Analytical gel filtration and electrophoretic mobility shift assays establish that initially a single DNA polymerase binds to DNA followed by the cooperative binding of two additional molecules of the polymerase at higher concentrations of the enzyme. Protein chemical crosslinking experiments show that these are specific polymerase–polymerase interactions and not just separate binding events along DNA. Isothermal titration calorimetry and fluorescence anisotropy experiments corroborate these findings and show a stoichiometry where three polymerases are bound to a single DNA substrate. The trimeric polymerase complex significantly increases both the DNA synthesis rate and the processivity of SsoDpo1. Taken together, these results suggest the presence of a trimeric DNA polymerase complex that is able to synthesize long DNA strands more efficiently than the monomeric form.

Polymerization fidelity of a replicative DNA polymerase from the hyperthermophilic archaeon Sulfolobus solfataricus P2

Sulfolobus solfataricus P2 is an aerobic crenarchaeon which grows optimally at 80 degrees C and pH 2-4. This organism encodes a B-family DNA polymerase, DNA polymerase B1 (PolB1), which faithfully replicates its genome of 3 million base pairs. Using pre-steady-state kinetic methods, we estimated the fidelity of PolB1 to be in the range of 10(-6) to 10(-8), or one error per 10(6) to 10(8) nucleotide incorporations in vivo. To discern how the polymerase and 3' --> 5' exonuclease activities contribute to the high fidelity of PolB1, an exonuclease-deficient mutant of PolB1 was constructed by mutating three conserved residues at the exonuclease active site. The base substitution fidelity of this mutant was kinetically measured to be in the range of 10(-4) to 10(-6) at 37 degrees C and pH 7.5. PolB1 exhibited high fidelity due to large differences in both ground-state nucleotide binding affinity and nucleotide incorporation rates between correct and incorrect nucleotides. The kinetic partitioning between the slow mismatch extension catalyzed by the polymerase activity and the fast mismatch excision catalyzed by the 3' --> 5' exonuclease activity further lowers the error frequency of PolB1 by 14-fold. Furthermore, the base substitution error frequency of the exonuclease-deficient PolB1 increased by 5-fold as the reaction temperature increased. Interestingly, the fidelity of the exonuclease-deficient PolB1 mutant increased by 36-fold when the buffer pH was lowered from 8.5 to 6.0. A kinetic basis for these temperature and pH changes altering the fidelity of PolB1 was established. The faithful replication of genomic DNA catalyzed by PolB1 is discussed.

Elucidating the kinetic mechanism of DNA polymerization catalyzed by Sulfolobus solfataricus P2 DNA polymerase B1

Transient-state kinetic techniques were used to resolve the kinetic mechanism of DNA polymerization catalyzed by an exonuclease-deficient mutant of Sulfolobus solfataricus P2 DNA polymerase B1 (PolB1 exo-). Here, we report the kinetic parameters of several elementary steps for the forward polymerization reaction. PolB1 exo- binds tightly to DNA (K(d)(DNA) = 1.8 nM) and a correct incoming nucleotide (apparent K(d)(dTTP) = 11 microM). Moreover, several lines of kinetic evidence suggested that correct nucleotide incorporation catalyzed by PolB1 exo- was limited by a protein conformational change which precedes the chemistry step. The utilization of an "induced fit" mechanism by PolB1 exo- was supported by the following: a small, alpha-thio elemental effect of 1.5, varying DNA dissociation rates for the binary complex (0.043 s(-1)) as well as ternary complexes before (0.18 s(-1)) and after (0.0071 s(-1)) a conformational change, a greater amplitude for the pulse-chase than the pulse-quench reaction, and an activation energy barrier of 38 kcal/mol which is greater than the predicted values of phosphodiester bond formation both in solution and within a polymerase active site. Lastly, PolB1 exo- exhibited a low processivity value of 15, thereby suggesting a protein cofactor confers this replicative DNA polymerase with higher processivity in vivo.

The hyperthermophilic euryarchaeota Pyrococcus abyssi likely requires the two DNA polymerases D and B for DNA replication

DNA polymerases carry out DNA synthesis during DNA replication, DNA recombination and DNA repair. During the past five years, the number of DNA polymerases in both eukarya and bacteria has increased to at least 19 and multiple biological roles have been assigned to many DNA polymerases. Archaea, the third domain of life, on the other hand, have only a subset of the eukaryotic-like DNA polymerases. The diversity among the archaeal DNA polymerases poses the intriguing question of their functional tasks. Here, we focus on the two identified DNA polymerases, the family B DNA polymerase B (PabpolB) and the family D DNA polymerase D (PabpolD) from the hyperthermophilic euryarchaeota Pyrococcus abyssi. Our data can be summarized as follows: (i) both Pabpols are DNA polymerizing enzymes exclusively; (ii) their DNA binding properties as tested in gel shift competition assays indicated that PabpolD has a preference for a primed template; (iii) PabPolD is a primer-directed DNA polymerase independently of the primer composition whereas PabpolB behaves as an exclusively DNA primer-directed DNA polymerase; (iv) PabPCNA is required for PabpolD to perform efficient DNA synthesis but not PabpolB; (v) PabpolD, but not PabpolB, contains strand displacement activity; (vii) in the presence of PabPCNA, however, both Pabpols D and B show strand displacement activity; and (viii) we show that the direct interaction between PabpolD and PabPCNA is DNA-dependent. Our data imply that PabPolD might play an important role in DNA replication likely together with PabpolB, suggesting that archaea require two DNA polymerases at the replication fork.