A fully active DNA polymerase I from Escherichia coli lacking stoichiometric zinc

Divalent ions attenuate DNA synthesis by human DNA polymerase α by changing the structure of the template/primer or by perturbing the polymerase reaction

DNA polymerases (pols) are sophisticated protein machines operating in the replication, repair and recombination of genetic material in the complex environment of the cell. DNA pol reactions require at least two divalent metal ions for the phosphodiester bond formation. We explore two understudied roles of metals in pol transactions with emphasis on polα, a crucial enzyme in the initiation of DNA synthesis. We present evidence that the combination of many factors, including the structure of the template/primer, the identity of the metal, the metal turnover in the pol active site, and the influence of the concentration of nucleoside triphosphates, affect DNA pol synthesis. On the poly-dT70 template, the increase of Mg(2+) concentration within the range typically used for pol reactions led to the severe loss of the ability of pol to extend DNA primers and led to a decline in DNA product sizes when extending RNA primers, simulating the effect of "counting" of the number of nucleotides in nascent primers by polα. We suggest that a high Mg(2+) concentration promotes the dynamic formation of unconventional DNA structure(s), thus limiting the apparent processivity of the enzyme. Next, we found that Zn(2+) supported robust polα reactions when the concentration of nucleotides was above the concentration of ions; however, there was only one nucleotide incorporation by the Klenow fragment of DNA pol I. Zn(2+) drastically inhibited polα, but had no effect on Klenow, when Mg(2+) was also present. It is possible that Zn(2+) perturbs metal-mediated transactions in pol active site, for example affecting the step of pyrophosphate removal at the end of each pol cycle necessary for continuation of polymerization.

Transition Metal Homeostasis

This chapter focuses on transition metals. All transition metal cations are toxic-those that are essential for Escherichia coli and belong to the first transition period of the periodic system of the element and also the "toxic-only" metals with higher atomic numbers. Common themes are visible in the metabolism of these ions. First, there is transport. High-rate but low-affinity uptake systems provide a variety of cations and anions to the cells. Control of the respective systems seems to be mainly through regulation of transport activity (flux control), with control of gene expression playing only a minor role. If these systems do not provide sufficient amounts of a needed ion to the cell, genes for ATP-hydrolyzing high-affinity but low-rate uptake systems are induced, e.g., ABC transport systems or P-type ATPases. On the other hand, if the amount of an ion is in surplus, genes for efflux systems are induced. By combining different kinds of uptake and efflux systems with regulation at the levels of gene expression and transport activity, the concentration of a single ion in the cytoplasm and the composition of the cellular ion "bouquet" can be rapidly adjusted and carefully controlled. The toxicity threshold of an ion is defined by its ability to produce radicals (copper, iron, chromate), to bind to sulfide and thiol groups (copper, zinc, all cations of the second and third transition period), or to interfere with the metabolism of other ions. Iron poses an exceptional metabolic problem due its metabolic importance and the low solubility of Fe(III) compounds, combined with the ability to cause dangerous Fenton reactions. This dilemma for the cells led to the evolution of sophisticated multi-channel iron uptake and storage pathways to prevent the occurrence of unbound iron in the cytoplasm. Toxic metals like Cd2+ bind to thiols and sulfide, preventing assembly of iron complexes and releasing the metal from iron-sulfur clusters. In the unique case of mercury, the cation can be reduced to the volatile metallic form. Interference of nickel and cobalt with iron is prevented by the low abundance of these metals in the cytoplasm and their sequestration by metal chaperones, in the case of nickel, or by B12 and its derivatives, in the case of cobalt. The most dangerous metal, copper, catalyzes Fenton-like reactions, binds to thiol groups, and interferes with iron metabolism. E. coli solves this problem probably by preventing copper uptake, combined with rapid efflux if the metal happens to enter the cytoplasm.

Structural and functional differences between the two intrinsic zinc ions of Escherichia coli RNA polymerase

DNA-dependent RNA polymerase (RPase) from Escherichia coli contains 2 mol of intrinsic Zn(II)/mol of core enzyme (alpha 2 beta beta'). In techniques analogous to those employed with the Zn(II) metalloenzyme aspartate transcarbamoylase [Hunt, J. B., Neece, S. H., Schachman, H. K., & Ginsberg, A. (1984) J. Biol. Chem. 259, 14793-14803], we show that titration of core or holoRPase with 10 or 16 equiv, respectively, of the sulfhydryl reagent p-(hydroxymercuri)benzenesulfonate (PMPS) results in the facile release of 1 mol of Zn(II) [B-site Zn(II)] in a reaction totally reversible with the addition of excess thiol provided no metal chelator is present. If ethylenediaminetetraacetic acid (EDTA) is present, reversal of the PMPS-enzyme complex results in formation of a Zn1 RPase [A-site Zn(II)]. This enzyme retains full transcriptional activity relative to Zn2 RPase on both calf thymus (nonspecific) and T7 (sigma-dependent, specific) DNA templates. If the core enzyme-PMPS complex is incubated with a large excess of another metal such as Cd(II) followed by thiol treatment, a hybrid ZnACdB RPase is formed. Direct treatment of the enzyme with excess Cd(II) also gives rise to a hybrid ZnACdB RPase. Transcription by these enzymes is also comparable to that of the starting Zn2 enzyme. Isolation of in vivo synthesized Co2 RPase and Cd2 RPase and treatment of either enzyme with PMPS/EDTA results in formation of a CoA and CdA enzyme, respectively. Co(II)A and Cd(II)A enzymes show 123 and 76%, respectively, of the elongation rates on T7 DNA observed for the Zn(II) enzyme. Visible absorption spectroscopy of the Co2 enzyme exhibits four d-d transition bands positioned at 760 (epsilon = 800), 710 (epsilon = 900), 602 (epsilon = 1500), and 484 (epsilon = 4000) nm. In addition, two charge-transfer bands are found at 350 (epsilon = 9600) and 370 (epsilon = 9500) nm. Only the Co(II) ion bound at site A is associated with this unique set of intense d-d transitions. The positions and intensities of both the visible and charge-transfer bands of Co(II)A RPase approximate those shown by Co(II)-substituted metalloenzyme sites where the ligands are four S rather than mixed S,N or S,O sites.

Inhibition of Euglena gracilis and wheat germ zinc RNA polymerases II by 1,10-phenanthroline acting as a chelating agent

Copper complexes of 1,10-phenanthroline (OP-Cu) hydrolyze DNA [D'Aurora, V., Stern, A. M., & Sigman, D. S. (1978) Biochem. Biophys. Res. Commun. 80, 1025-1032; Marshall Pope, L., Reich, K. A., Graham, D. R., & Sigman, D. S. (1982) J. Biol. Chem. 257, 12121-12128]. This reaction has been studied to determine whether the 1,10-phenanthroline (OP) inhibition of the activity of RNA and DNA polymerases is the result of template hydrolysis or the chelation of a metal associated with and essential to the function of these enzymes. Addition of 4',6-diamino-2-phenylindole dihydrochloride (DAPI) to DNA generates a fluorescence signal with a linear increase of the intensity over a broad range of DNA concentrations from 0 to 100 micrograms/mL. The progress of hydrolysis of DNA by DNase I or OP (2 mM) is monitored by the time-dependent decrease in DAPI-induced fluorescence. In the presence of OP, the rate of hydrolysis increases as the Cu2+ concentration in the reaction mixture rises from 10(-8) to 10(-5) M. The rate differs for each nucleic acid template used; hydrolysis of poly(dA-dT) greater than denatured DNA greater than double-stranded DNA. However, millimolar amounts of OP do not hydrolyze the template even in the presence of Cu2+ (10(-6) M) when DNA is complexed with either Escherichia coli DNA polymerase I or Euglena gracilis or wheat germ RNA polymerase II. Under the same conditions, OP inhibits the activity of both varieties of RNA polymerase II with pKi's of 3.4 and 3.0, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure of large fragment of Escherichia coli DNA polymerase I complexed with dTMP

The 3.3-A resolution crystal structure of the large proteolytic fragment of Escherichia coli DNA polymerase I complexed with deoxythymidine monophosphate consists of two domains, the smaller of which binds zinc-deoxythymidine monophosphate. The most striking feature of the larger domain is a deep crevice of the appropriate size and shape for binding double-stranded B-DNA. A flexible subdomain may allow the enzyme to surround completely the DNA substrate, thereby allowing processive nucleotide polymerization without enzyme dissociation.

T7 DNA polymerase is not a zinc-metalloenzyme and the polymerase and exonuclease activities are inhibited by zinc ions

Phage T7 DNA polymerase purified to homogeneity by an antithioredoxin immunoadsorbent technique was resolved into its active subunits the gene 5 protein and Escherichia coli thioredoxin by a novel technique involving chromatography on Sephadex G-50 at pH 11.5. Analysis of the metal content of the holoenzyme by atomic absorption spectroscopy showed that it did not contain stoichiometric amounts of zinc. Determination of polymerase and exonuclease activities of the holoenzyme and the gene 5 protein in assay mixtures containing enzyme concentrations in excess of the Zn2+ concentration showed full activity. Addition of Zn2+ resulted in no stimulation and the activities were completely inhibited by 0.1 mM Zn2+. These results demonstrate that the essential T7 DNA polymerase is not a zinc-metalloenzyme and suggest that DNA polymerases show no functional requirement for Zn2+.

Poly(ADP-ribose) polymerase is a zinc metalloenzyme

Purified poly(ADP-ribose) polymerase was inhibited by 1,10-phenanthroline at pH less than 8. This inhibition and the inhibition by other chelating agents suggested that this enzyme was a metalloprotein. Atomic absorption spectroscopy showed the presence of one atom of zinc per protein molecule. Dialysis of the enzyme against buffers containing 1,10-phenanthroline resulted in the loss of activity and the removal of zinc from the enzyme. Initial rate kinetics showed that 1,10-phenanthroline was non-competitive with NAD+ and competitive with DNA. The binding of DNA to the enzyme was unaffected by the inhibitor. These results suggest that a metal-containing site is involved as part of the interaction of DNA and poly(ADP-ribose) polymerase.

Mechanism of o-phenanthroline mediated inhibition of E. coli DNA polymerase I : formation of template-primer-metal-phenanthroline complexes with resultant loss of catalytic activity

Inhibition of E. coli DNA polymerase I activity by 1,10 phenanthroline in the absence of reducing agents requires a high concentration of inhibitor (1-10 mM) depending upon the template primer used to direct the synthesis. We find that o-phenanthroline, unlike its non-chelating analogue, forms a divalent cation mediated complex with template-primers. Enzyme bound to such complexes is unable to catalyse either polymerization or nuclease functions.

Metal content of DNA polymerase I purified from overproducing and wild type Escherichia coli

DNA polymerase I purified from both E. coli strain B, and from an overproducing E. coli stain lysogenized with a lambda pol A phage were analyzed for metal content. After gel filtration to remove loosely bound metals, DNA polymerase I from both strains contained less than or equal to 0.2 gm atoms Zn2+/mole enzyme and 0.09 to 0.7 Mg2+/mole enzyme. Substoichiometric amounts of Fe, Co, Ni (less than or equal to 0.2 gm atoms), and Mn (less than or equal to 0.1 gm atoms) were detected. Since the metal content does not correlate with enzymatic activity, we conclude that DNA polymerase I is not a metalloenzyme.