Affinity labeling of Escherichia coli DNA polymerase I by 5'-fluorosulfonylbenzoyladenosine. Identification of the domain essential for polymerization and Arg-682 as the site of reactivity

Affinity labeling of hepatitis C virus replicase with a nucleotide analogue: identification of binding site

We have used an ATP analogue 5'-[p-(fluorosulfonyl)benzoyl]adenosine (FSBA) to modify HCV replicase in order to identify the ATP binding site in the enzyme. FSBA inactivates HCV replicase activity in a concentration-dependent manner with a binding stoichiometry of 2 moles of FSBA per mole of enzyme. The enzyme activity is protected from FSBA in the presence of rNTP substrates or double-stranded RNA template primers that do not support ATP as the incoming nucleotide but not in the presence of polyrU.rA(26). HPLC analysis of tryptic peptides of FSBA-modified enzyme revealed the presence of two distinct peptides eluted at 23 and 36 min; these were absent in the control. Further we noted that both peptides were protected from FSBA modification in the presence of Mg·ATP. The LC/MS/MS analysis of the affinity-labeled tryptic peptides purified from HPLC, identified two major modification sites at positions 382 (Tyr), and 491 (Lys) and a minor site at position 38 (Tyr). To validate the functional significance of Tyr38, Tyr382, and Lys491 in catalysis, we individually substituted these residues by alanine and examined their ability to catalyze RdRp activity. We found that both Y382A and K491A mutants were significantly affected in their ability to catalyze RdRp activity while Y38A remained unaffected. We further observed that both Y382A and K491A mutants were not affected in their ability to bind template primer but were significantly affected in their ability to photo-cross-link ATP in the absence or presence of template primer.

Inhibition of multidrug resistance-linked P-glycoprotein (ABCB1) function by 5'-fluorosulfonylbenzoyl 5'-adenosine: evidence for an ATP analogue that interacts with both drug-substrate-and nucleotide-binding sites

5'-Fluorosulfonylbenzonyl 5'-adenosine (FSBA) is an ATP analogue that covalently modifies several residues in the nucleotide-binding domains (NBDs) of several ATPases, kinases, and other proteins. P-glycoprotein (P-gp, ABCB1) is a member of the ATP-binding cassette (ABC) transporter superfamily that utilizes energy from ATP hydrolysis for the efflux of amphipathic anticancer agents from cancer cells. We investigated the interactions of FSBA with P-gp to study the catalytic cycle of ATP hydrolysis. Incubation of P-gp with FSBA inhibited ATP hydrolysis (IC(50 )= 0.21 mM) and the binding of 8-azido[α-(32)P]ATP (IC(50) = 0.68 mM). In addition, (14)C-FSBA cross-links to P-gp, suggesting that FSBA-mediated inhibition of ATP hydrolysis is irreversible due to covalent modification of P-gp. However, when the NBDs were occupied with a saturating concentration of ATP prior to treatment, FSBA stimulated ATP hydrolysis by P-gp. Furthermore, FSBA inhibited the photo-cross-linking of P-gp with [(125)I]iodoarylazidoprazosin (IAAP; IC(50) = 0.17 mM). As IAAP is a transport substrate for P-gp, this suggests that FSBA affects not only the NBDs but also the transport-substrate site in the transmembrane domains. Consistent with these results, FSBA blocked efflux of rhodamine 123 from P-gp-expressing cells. Additionally, mass spectrometric analysis identified FSBA cross-links to residues within or nearby the NBDs but not in the transmembrane domains, and docking of FSBA in a homology model of human P-gp NBDs supports the biochemical studies. Thus, FSBA is an ATP analogue that interacts with both the drug-binding and ATP-binding sites of P-gp, but fluorosulfonyl-mediated cross-linking is observed only at the NBDs.

Crystal structures of the Klenow fragment of Thermus aquaticus DNA polymerase I complexed with deoxyribonucleoside triphosphates

The crystal structures of the Klenow fragment of the Thermus aquaticus DNA polymerase I (Klentaq1) complexed with four deoxyribonucleoside triphosphates (dNTP) have been determined to 2.5 A resolution. The dNTPs bind adjacent to the O helix of Klentaq1. The triphosphate moieties are at nearly identical positions in all four complexes and are anchored by three positively charged residues, Arg659, Lys663, and Arg587, and by two polar residues, His639 and Gln613. The configuration of the base moieties in the Klentaq1/dNTP complexes demonstrates variability suggesting that dNTP binding is primarily determined by recognition and binding of the phosphate moiety. However, when superimposed on the Taq polymerase/blunt end DNA complex structure (Eom et al., 1996), two of the dNTP/Klentaq1 structures demonstrate appropriate stacking of the nucleotide base with the 3' end of the DNA primer strand, suggesting that at least in these two binary complexes, the observed dNTP conformations are functionally relevant.

Isolation and characterization of a multienzyme complex containing DNA replicative enzymes from mitochondria of S. cerevisiae. Multienzyme complex from yeast mitochondria

A 40 S multienzyme complex containing mtDNA polymerase was isolated from mitochondria of S. cerevisiae by density gradient centrifugation and by gel filtration chromatography. Besides DNA polymerase, RNA polymerase, primase, 3'-->5' exonuclease and an ATPase activities were found to be associated with it. The presence of some of these enzymes were confirmed by Western blot. This high molecular weight multienzyme complex containing DNA has most of the attributes of a putative replisome.

Properties of tyrosine 766-->serine mutant of Escherichia coli DNA polymerase I: template-specific effects

In order to determine the role of Tyr 766 of Escherichia coli DNA polymerase I in the catalysis of DNA synthesis, we investigated the properties of a Tyr 766-->Ser (Y766S) mutant of the Klenow fragment of E. coli DNA polymerase I. We found that the rates of incorporation of only dTTP but not the other dNTP substrates were affected in the reactions catalyzed by the mutant enzyme, when homopolymeric template-primers were used. The mutant enzyme exhibited a reduced rate of synthesis only with poly(rA)- or poly(dA)-directed reactions. Examination of the ability of the mutant and the wild-type enzymes to bind to dGTP and dTTP, as judged by UV-mediated cross-linking, indicated nearly identical binding efficiencies of both nucleotides. However, the ability of the mutant enzyme to bind to poly(rA).(dT)15 and poly(dA).(dT)15 was found to be significantly reduced as compared to the binding to heteropolymeric DNA. In order to further define the nature of template-mediated restriction on the catalytic activity of the mutant enzyme, its ability to copy DNA templates containing a stretch of AAAAA and ACACA sequences was compared. The results show that DNA synthesis catalyzed by the mutant enzyme is significantly retarded when it encounters the AAAAA region of the template but not the ACACA region. Product analysis of the reaction directed by the two template-primers showed that the mutant enzyme stalls/terminates synthesis upon encountering an AAAAA sequence in the template.(ABSTRACT TRUNCATED AT 250 WORDS)

Crystal structure of bacteriophage T7 RNA polymerase at 3.3 A resolution

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

Site directed mutagenesis of DNA polymerase I (Klenow) from Escherichia coli. The significance of Arg682 in catalysis

We have reported that a domain containing Arg682 in the Klenow fragment of Escherichia coli DNA polymerase I (pol I) is important for the template-dependent dNTP-binding function [Pandey, V.N., Kaushik, N. A., Pradhan, D. S. & Modak, M. J. (1990) J. Biol. Chem. 265, 3679-3884]. In order to further define the role of Arg682 in the catalytic process, we have performed site-directed mutagenesis of this residue. For this purpose the Klenow-coding region of the DNA-pol-I gene was selectively amplified from the genomic DNA of E. coli and was cloned in an expression vector, pET-3a. This clone under appropriate conditions overproduces the Klenow fragment in E. coli. Using this clone (pET-3a-K) as the template, two mutant polymerase clones were constructed in which arginine has been replaced with either alanine, [R682A] pol I, or lysine [R682K] pol I. Both mutant enzymes showed significantly lower specific activity as compared to the wild-type enzyme. The kinetic analyses of the mutant enzymes indicated a 3-4-fold increase in the Km for the substrate dNTP, a 20-25-fold decrease in the Vmax and an overall decrease in the processive nature of DNA synthesis in both the mutant enzymes. The reverse mutation of Ala682 to the wild-type form Arg682 fully restored the processive nature and the polymerase activity of the enzyme. These observations suggest that the positively charged guanidino group in the side chain of Arg682 is catalytically important but not absolutely essential for synthesis of DNA. Furthermore it appears to maintain high processivity of the DNA synthesis catalyzed by the enzyme.

Binding of DNA to large fragment of DNA polymerase I: identification of strong and weak electrostatic forces and their biological implications

Examination of the electrostatic potential of a modeled complex, consisting of the Klenow fragment of E. coli DNA polymerase I and DNA template-primer, suggested the presence of two distinct interacting regions. The one displaying a strong electropositive potential field is generated by side chains of basic amino acid pairs and is directed towards the major groove site in DNA. The second electrostatic potential field around DNA is somewhat weaker and appears to be exerted by a pair of vicinal side chains of acidic and basic amino acids. The distribution of charges in this manner appears well suited for the binding of enzyme to the template-primer required in the enzymatic synthesis of DNA.

Crystal structure at 3.5 A resolution of HIV-1 reverse transcriptase complexed with an inhibitor

A 3.5 angstrom resolution electron density map of the HIV-1 reverse transcriptase heterodimer complexed with nevirapine, a drug with potential for treatment of AIDS, reveals an asymmetric dimer. The polymerase (pol) domain of the 66-kilodalton subunit has a large cleft analogous to that of the Klenow fragment of Escherichia coli DNA polymerase I. However, the 51-kilodalton subunit of identical sequence has no such cleft because the four subdomains of the pol domain occupy completely different relative positions. Two of the four pol subdomains appear to be structurally related to subdomains of the Klenow fragment, including one containing the catalytic site. The subdomain that appears likely to bind the template strand at the pol active site has a different structure in the two polymerases. Duplex A-form RNA-DNA hybrid can be model-built into the cleft that runs between the ribonuclease H and pol active sites. Nevirapine is almost completely buried in a pocket near but not overlapping with the pol active site. Residues whose mutation results in drug resistance have been approximately located.