Properties of initiation complexes formed between Escherichia coli DNA polymerase III holoenzyme and primed DNA in the absence of ATP

In the presence of ATP, the beta subunit of the Escherichia coli DNA polymerase III holoenzyme can induce a stable initiation complex with the other holoenzyme subunits and primed DNA that is capable of highly processive synthesis. We have recently demonstrated that the ATP requirement for processive synthesis can be bypassed by an excess of the beta subunit (Crute, J., LaDuca, R., Johanson, K., McHenry, C., and Bambara, R. (1983) J. Biol. Chem. 258, 11344-11349). To examine the complex formed with excess beta subunit, and the lengths of the products of processive synthesis, we have designed a uniquely primed DNA template. Poly(dA)4000 was tailed with dCTP by terminal deoxynucleotidyl transferase and the resulting template annealed to oligo(dG)12-18. In the presence of excess beta, the lengths of processively extended primers nearly equaled the full-length of the DNA template. Similar length synthesis occurred in the presence or absence of spermidine or single-stranded DNA-binding protein. When the beta subunit was present at normal holoenzyme stoichiometry it could induce highly processive synthesis without ATP, although inefficiently. Both ATP and excess beta increased the amount of initiation complex formation, but complexes produced with excess beta did so without the time delay observed with ATP, suggesting different mechanisms for formation. Almost 50% of initiation complexes formed without ATP survived a 30-min incubation with anti-beta IgG, reflecting a stability similar to those formed with ATP. The ability to form initiation complexes in the absence of ATP permitted the demonstration that cycling of the holoenzyme to a new primer, after chain termination with a dideoxynucleotide, is not affected by the presence of ATP.     

Complete replication of templates by Escherichia coli DNA polymerase III holoenzyme

DNA polymerase III holoenzyme (holoenzyme) processively and rapidly replicates a primed single-stranded DNA circle to produce a duplex with an interruption in the synthetic strand. The precise nature of this discontinuity in the replicative form (RF II) and the influence of the 5' termini of the DNA and RNA primers were analyzed in this study. Virtually all (90%) of the RF II products primed by DNA were nicked structures sealable by Escherichia coli DNA ligase; in 10% of the products, replication proceeded one nucleotide beyond the 5' DNA terminus displacing (but not removing) the 5' terminal nucleotide. With RNA primers, replication generally went beyond the available single-stranded template. The 5' RNA terminus was displaced by 1-5 nucleotides in 85% of the products; a minority of products was nicked (9%) or had short gaps (6%). Termination of synthesis on a linear DNA template was usually (85%) one base shy of completion. Thus, replication by holoenzyme utilizes all, or nearly all, of the available template and shows no significant 5'----3' exonuclease action as observed in primer removal by the "nick-translation" activity of DNA polymerase I.     

Effects of T antigen and replication protein A on the initiation of DNA synthesis by DNA polymerase alpha-primase.

Studies of simian virus 40 (SV40) DNA replication in a reconstituted cell-free system have established that T antigen and two cellular replication proteins, replication protein A (RP-A) and DNA polymerase alpha-primase complex, are necessary and sufficient for initiation of DNA synthesis on duplex templates containing the SV40 origin of DNA replication. To better understand the mechanism of initiation of DNA synthesis, we analyzed the functional interactions of T antigen, RP-A, and DNA polymerase alpha-primase on model single-stranded DNA templates. Purified DNA polymerase alpha-primase was capable of initiating DNA synthesis de novo on unprimed single-stranded DNA templates. This reaction involved the synthesis of a short oligoribonucleotide primer which was then extended into a DNA chain. We observed that the synthesis of ribonucleotide primers by DNA polymerase alpha-primase is dramatically stimulated by SV40 T antigen. The presence of T antigen also increased the average length of the DNA product synthesized on primed and unprimed single-stranded DNA templates. These stimulatory effects of T antigen required direct contact with DNA polymerase alpha-primase complex and were most marked at low template and polymerase concentrations. We also observed that the single-stranded DNA binding protein, RP-A, strongly inhibits the primase activity of DNA polymerase alpha-primase, probably by blocking access of the enzyme to the template. T antigen partially reversed the inhibition caused by RP-A. Our data support a model in which DNA priming is mediated by a complex between T antigen and DNA polymerase alpha-primase with the template, while RP-A acts to suppress nonspecific priming events.     

An auxiliary protein for DNA polymerase-delta from fetal calf thymus

An auxiliary protein which affects the ability of calf thymus DNA polymerase-delta to utilize template/primers containing long stretches of single-stranded template has been purified to homogeneity from the same tissue. The auxiliary protein coelutes with DNA polymerase-delta on DEAE-cellulose and phenyl-agarose chromatography but is separated from the polymerase on phosphocellulose chromatography. The physical and functional properties of the auxiliary protein strongly resemble those of the beta subunit of Escherichia coli DNA polymerase III holoenzyme. A molecular weight of 75,000 has been calculated from a sedimentation coefficient of 5.0 s and a Stokes radius of 36.5 A. A single band of 37,000 daltons is seen on sodium dodecyl sulfate gel electrophoresis, suggesting that the protein exists as a dimer of identical subunits. The purified protein has no detectable DNA polymerase, primase, ATPase, or nuclease activity. The ability of DNA polymerase-delta to replicate gapped duplex DNA is relatively unaffected by the presence of the auxiliary protein, however, it is required to replicate templates with low primer/template ratios, e.g. poly(dA)/oligo(dT) (20:1), primed M13 DNA, and denatured calf thymus DNA. The auxiliary protein is specific for DNA polymerase-delta; it has no effect on the activity of calf thymus DNA polymerase-alpha or the Klenow fragment of E. coli DNA polymerase I with primed homopolymer templates. Although the auxiliary protein does not bind to either single-stranded or double-stranded DNA, it does increase the binding of DNA polymerase-delta to poly(dA)/oligo(dT), suggesting that the auxiliary protein interacts with the polymerase in the presence of template/primer, stabilizing the polymerase-template/primer complex.     

Role of bacteriophage T7 DNA primase in the initiation of DNA strand synthesis.

Bacteriophage T7 DNA primase (gene-4 protein, 66,000 daltons) enables T7 DNA polymerase to initiate the synthesis of DNA chains on single-stranded templates. An initial step in the process of chain initiation is the formation of an oligoribonucleotide primer by T7 primase. The enzyme, in the presence of natural SS DNA, Mg++ (or Mn++), ATP and CTP (or a mixture of all 4 rNTPs), catalyzes the synthesis of di-, tri-, and tetraribonucleotides all starting at the 5' terminus with pppA. In a subsequent step requiring both T7 DNA polymerase and primase, the short oligoribonucleotides (predominantly pppA-C-C-AOH) are extended by covalent addition of deoxyribonucleotides. With the aid of primase, T7 DNA polymerase can also utilize efficiently a variety of synthetic tri-, tetra-, or pentanucleotides as chain initiators. T7 primase apparently plays an active role in primer extension by stabilizing the short primer segments in a duplex state on the template DNA.     

Initiation of RNA-primed DNA synthesis in vitro by DNA polymerase alpha-primase.

The initiation of new DNA strands at origins of replication in animal cells requires de novo synthesis of RNA primers by primase and subsequent elongation from RNA primers by DNA polymerase alpha. To study the specificity of primer site selection by the DNA polymerase alpha-primase complex (pol alpha-primase), a natural DNA template containing a site for replication initiation was constructed. Two single-stranded DNA (ssDNA) molecules were hybridized to each other generating a duplex DNA molecule with an open helix replication 'bubble' to serve as an initiation zone. Pol alpha-primase recognizes the open helix region and initiates RNA-primed DNA synthesis at four specific sites that are rich in pyrimidine nucleotides. The priming site positioned nearest the ssDNA-dsDNA junction in the replication 'bubble' template is the preferred site for initiation. Using a 40 base oligonucleotide template containing the sequence of the preferred priming site, primase synthesizes RNA primers of 9 and 10 nt in length with the sequence 5'-(G)GAAGAAAGC-3'. These studies demonstrate that pol alpha-primase selects specific nucleotide sequences for RNA primer formation and suggest that the open helix structure of the replication 'bubble' directs pol alpha-primase to initiate RNA primer synthesis near the ssDNA-dsDNA junction.     

Further characterization of the interaction between the Epstein-Barr virus DNA polymerase catalytic subunit and its accessory subunit with regard to the 3'-to-5' exonucleolytic activity and stability of initiation complex at primer terminus.

The Epstein-Barr virus (EBV) DNA polymerase catalytic subunit, BALF5 gene product, possesses an intrinsic 3'-to 5' proofreading exonuclease activity in addition to 5'-to-3' DNA polymerase activity (T. Tsurumi, A. Kobayashi, K. Tamai, T. Daikoku, R. Kurachi, and Y. Nishiyama, J. Virol. 67:4651-4658, 1993). The exonuclease hydrolyzed both double-and single-stranded DNA substrates with 3'-to-5' directionality, releasing deoxyribonucleoside 5'-monophosphates. The double-strand exonucleolytic activity catalyzed by the BALF5 polymerase catalytic subunit was very sensitive to high ionic strength, whereas the single-strand exonucleolytic activity was moderately resistant. The addition of the BMRF1 polymerase accessory subunit to the reaction enhanced the double-strand exonucleolytic activity in the presence of high concentrations of ammonium sulfate (fourfold stimulation at 75 mM ammonium sulfate). Optimal stimulation was obtained when the molar ratio of BMRF1 protein to BALF5 protein was 2 and higher, identical to the values required for reconstituting the optimum DNA polymerizing activity (T. Tsurumi, T. Daikoku, R. Kurachi, and Y. Nishiyama, J. Virol. 67:7648-7653, 1993). Furthermore, product size analyses revealed that the polymerase catalytic subunit alone excised a few nucleotides from the 3' termini of the primer hybridized to template DNA and that the addition of the BMFR1 polymerase accessory subunit stimulated the nucleotide excision several times. In contrast, the hydrolysis of single-stranded DNA by the BALF5 protein was not affected by the addition of the BMRF1 polymerase accessory subunit at all. These observations suggest that the BMRF1 polymerase accessory subunit forms a complex with the BALF5 polymerase catalytic subunit to stabilize the interaction of the holoenzyme complex with the 3'-OH end of the primer on the template DNA during exonucleolysis. On the other hand, challenger DNA experiments revealed that the BALF5 polymerase catalytic subunit alone stably binds to the primer terminus in a stationary state, whereas the reconstituted polymerase holoenzyme is unstable. The instability of the initiation complex of the EBV DNA polymerase would allow the rapid removal of the EBV DNA polymerase holoenzyme from the lagging strand after it has replicated up to the previous Okazaki fragment. This feature of the EBV DNA polymerase holoenzyme in a stationary state is in marked contrast to the moving holoenzyme complex tightly bound to the primer end during polymerization and exonucleolysis.     

Coordinated leading- and lagging-strand synthesis at the Escherichia coli DNA replication fork. II. Frequency of primer synthesis and efficiency of primer utilization control Okazaki fragment size.

To investigate the role of the priming apparatus at the replication fork in determining Okazaki fragment size, the products of primer synthesis generated in vitro during rolling-circle DNA replication catalyzed by the DNA polymerase III holoenzyme, the single-stranded DNA binding protein, and the primosome on a tailed form II DNA template were isolated and characterized. The abundance of oligoribonucleotide primers and the incidence of covalent DNA chain extension of the primer population was measured under different reaction conditions known to affect the size of the products of lagging-strand DNA synthesis. These analyses demonstrated that the factors affecting Okazaki fragment length could be distinguished by either their effect on the frequency of primer synthesis or by their influence on the efficiency of initiation of DNA synthesis from primer termini. Primase and the ribonucleoside triphosphates were found to stimulate primer synthesis. The observed trend toward smaller fragment size as the concentration of these effectors was raised was apparently a direct consequence of the increased frequency of primer synthesis. The beta subunit of the DNA polymerase III holoenzyme and the deoxyribonucleoside triphosphates did not alter the priming frequency; instead, the concentration of these factors influenced the ability of the lagging-strand DNA polymerase to efficiently utilize primers to initiate DNA synthesis. Maximum utilization of the available primers correlated with the lowest mean value of Okazaki fragment length. These data were used to draw general conclusions concerning the temporal order of enzymatic steps that operate during a cycle of Okazaki fragment synthesis on the lagging-strand DNA template.     

Primer-mediated inhibition of the hydrolysis of template DNA by T5-induced DNA polymerase.

Bacteriophage T5-induced DNA polymerase has an associated 3′→5′ exonuclease activity for which both single-stranded and duplex DNA serve as substrate (1). In this report, we demonstrate that hydrolysis of single-stranded DNA homopolymers (template) is inhibited in the presence of complementary (Watson-Crick sense) oligonucleotides (primer). Almost complete inhibition is observed at a primer/template ratio of ? 0.1. Formation of “H-bonded” primer-template complex seems to be necessary for the inhibition of template hydrolysis because (a) similar amounts of noncomplementary oligonucleotides have no detectable effect on the rate of template hydrolysis, and (b) complementary oligonucleotides lose their inhibitory potential at temperatures where the H-bonded primer-template complex is expected to be unstable. From our data, it appears that the inhibition of template hydrolysis in the presence of primer molecules is due to the preferential binding of the enzyme at the 3′-OH terminus of the primer in the primer-template complex.     

The ABC-primosome. A novel priming system employing dnaA, dnaB, dnaC, and primase on a hairpin containing a dnaA box sequence

A priming mechanism requiring dnaA, dnaB, and dnaC proteins operates on a single-stranded DNA coated with single-stranded DNA-binding protein. This novel priming, referred to as "ABC-priming," requires a specific hairpin structure whose stem carries a dnaA protein recognition sequence (dnaA box). In conjunction with primase and DNA polymerase III holoenzyme, ABC-priming can efficiently convert single-stranded DNA into the duplex replicative form. dnaA protein specifically recognizes and binds the single-stranded hairpin and permits the loading of dnaB protein to form a prepriming protein complex containing dnaA and dnaB proteins which can be physically isolated. ABC-priming can replace phi X174 type priming on the lagging strand template of pBR322 in vitro, suggesting a possible function of ABC-priming for the lagging strand synthesis and duplex unwinding. Similar to the phi X174 type priming, a mobile nature of ABC-priming was indicated by helicase activity in the presence of ATP of a prepriming protein complex formed at the hairpin. The implications of this novel priming in initiation of replication at the chromosomal origin, oriC, and in its contribution to the replication fork are discussed.     

Bypass of a nick by the replisome of bacteriophage T7

DNA polymerase and DNA helicase are essential components of DNA replication. The helicase unwinds duplex DNA to provide single-stranded templates for DNA synthesis by the DNA polymerase. In bacteriophage T7, movement of either the DNA helicase or the DNA polymerase alone terminates upon encountering a nick in duplex DNA. Using a minicircular DNA, we show that the helicase · polymerase complex can bypass a nick, albeit at reduced efficiency of 7%, on the non-template strand to continue rolling circle DNA synthesis. A gap in the non-template strand cannot be bypassed. The efficiency of bypass synthesis depends on the DNA sequence downstream of the nick. A nick on the template strand cannot be bypassed. Addition of T7 single-stranded DNA-binding protein to the complex stimulates nick bypass 2-fold. We propose that the association of helicase with the polymerase prevents dissociation of the helicase upon encountering a nick, allowing the helicase to continue unwinding of the duplex downstream of the nick.     

A mammalian DNA polymerase alpha holoenzyme functioning on defined in vivo-like templates.

In analogy to the Escherichia coli replicative DNA polymerase III we define two forms of DNA polymerase alpha: the core enzyme and the holoenzyme. The core enzyme is not able to elongate efficiently primed single-stranded DNA templates, in contrast to the holoenzyme which functions well on in vivo-like template. Using these criteria, we have identified and partially purified DNA polymerase alpha holoenzyme from calf thymus and have compared it to the corresponding homogeneous DNA polymerase alpha (defined as the core enzyme) from the same tissue. The holoenzyme is able to use single-stranded parvoviral DNA and M13 DNA with a single RNA primer as template. The core enzyme, on the other hand, although active on DNAs treated with deoxyribonuclease to create random gaps, is unable to act on these two long, single-stranded DNAs. E. coli DNA polymerase III holoenzyme also copies the two in vivo-like templates, while the core enzyme is virtually inactive. The homologous single-stranded DNA-binding proteins from calf thymus and from E. coli stimulate the respective holoenzymes and inhibit the core enzymes. These results suggest a cooperation between a DNA polymerase holoenzyme and its homologous single-stranded DNA-binding protein. The prokaryotic and the mammalian holoenzyme behave similarly in several chromatographic systems.     

ATP activation of DNA polymerase III holoenzyme from Escherichia coli. II. Initiation complex: stoichiometry and reactivity

DNA polymerase III holoenzyme (holenzyme) has an ATPase activity elicited only by a primed DNA template. Reaction of preformed ATP.holoenzyme complex with a primed template results in hydrolysis of the ATP bound to the holoenzyme, release of ADP and Pi, and formation of an initiation complex between holoenzyme and the primed template. Approximately two ATP molecules are hydrolyzed for each initiation complex formed, a value in keeping with the number bound in the ATP.holoenzyme complex. The possibility that the latter and the initiation complex contain two holoenzyme molecules is supported by the presence of two beta monomers in the initiation complex. Holoenzyme action in the absence of ATP resembles that of pol III (the holoenzyme core) or DNA polymerase III (holoenzyme lacking the beta subunit), with or without ATP, in sensitivity to salt and in processivity of elongation. The initiation complex formed by ATP-activated holoenzyme resists a level of KCl (150 mM) that completely inhibits nonactivated holoenzyme and the incomplete forms of the holoenzyme, and displays a processivity at least 20 times greater. Upon completing replication of available template, holoenzyme can dissociate and form an initiation complex with another primed template, provided ATP is available to reactivate the holoenzyme. By inference, no essential subunits are lost in the cycle of initiation, elongation and dissociation.     

Saccharomyces cerevisiae replication factor C. II. Formation and activity of complexes with the proliferating cell nuclear antigen and with DNA polymerases delta and epsilon.

Lag times in DNA synthesis by DNA polymerase delta holoenzyme were due to ATP-mediated formation of an initiation complex on the primed DNA by the polymerase with the proliferating cell nuclear antigen (PCNA) and replication factor C (RF-C). Lag time analysis showed that high affinity binding of RF-C to the primer terminus required PCNA and that this complex was recognized by the polymerase. The formation of stable complexes was investigated through their isolation by Bio-Gel A-5m filtration. A stable complex of RF-C and PCNA on primed single-stranded mp18 DNA was isolated when these factors were preincubated with the DNA and with ATP, or, less efficiently with ATP gamma S. These and additional experiments suggest that ATP binding promotes the formation of a labile complex of RF-C with PCNA at the primer terminus, whereas its hydrolysis is required to form a stable complex. Subsequently, DNA polymerase delta binds to either complex in a replication competent fashion without further energy requirement. DNA polymerase epsilon did not associate stably with RF-C and PCNA onto the DNA, but its transient participation with these cofactors into a holoenzyme-like initiation complex was inferred from its kinetic properties and replication product analysis. The kinetics of the elongation phase at 30 degrees, 110 nucleotides/s by DNA polymerase delta holoenzyme and 50 nucleotides/s by DNA polymerase epsilon holoenzyme, are in agreement with in vivo rates of replication fork movement in yeast. A model for the eukaryotic replication fork involving both DNA polymerase delta and epsilon is proposed.     

Initiation of adenovirus DNA replication. II. Structural requirements using synthetic oligonucleotide adenovirus templates

Adenovirus (Ad) virions contain a 55-kDa terminal protein covalently linked to both 5'-ends of the linear duplex DNA genome. The origin of DNA replication is contained within the terminal 50 base pair of the inverted terminal repeats. In the accompanying paper (Kenny, M. K., Balogh, L. A., and Hurwitz, J. (1988) J. Biol. Chem. 263, 9801-9808), it was demonstrated that synthetic oligonucleotide templates which contain the Ad origin, but lack the 55-kDa terminal protein, can serve as templates for the initiation of Ad DNA replication. Partially duplex oligonucleotides that lacked up to 14 nucleotides from the 5'-end of the nontemplate (displaced) strand supported initiation as much as 20-fold more efficiently than fully duplex oligonucleotides. The removal of 18 nucleotides or more from the 5'-end of the displaced strand resulted in a sharp decrease in the ability of the DNA templates to support initiation. The poor template efficiency of certain DNAs could be explained by their inability to bind nuclear factor I. The initiation efficiency observed with other DNAs correlated with their ability to bind the preterminal protein-Ad DNA polymerase complex. At low concentrations of the Ad DNA-binding protein, protein-primed initiation was also observed on single-stranded DNAs. The single-stranded template strand of the Ad origin was at least 5-20-fold better at supporting initiation than other single-stranded DNAs. These findings suggest a model in which the 3'-end of the template strand is rendered single-stranded as a prerequisite for initiation of Ad DNA replication.     

Polymerase chain reaction amplification of single-stranded DNA containing a base analog, 2-chloradenine.

By utilization of polymerase chain reaction techniques, single-stranded DNA of defined length and sequence containing a purine analog, 2-chloroadenine, in place of adenine was synthesized. This was accomplished by a combination of standard polymerase chain amplification reactions with Thermus aquaticus DNA polymerase in the presence of four normal deoxynucleoside triphosphates, M13 duplex DNA as template, and two primers to generate double-stranded DNA 118 bases in length. An asymmetric polymerase chain reaction, which produced an excess of single-stranded 98-base DNA, was then conducted with 2-chloro-2'-deoxy-adenosine 5'-triphosphate in place of dATP and with only one primer that annealed internal to the original two primers. Standard polymerase chain reaction techniques alone conducted in the presence of the analog as the fourth nucleotide did not produce duplex DNA that was modified within both strands. This asymmetric technique allows the incorporation of an altered nucleotide at specific sites into large quantities of single-stranded DNA without using chemical phosphoramidite synthesis procedures and circumvents the apparent inability of DNA polymerase to synthesize fully substituted double-stranded DNA during standard amplification reactions. The described method will permit the study of the effects of modified bases in template DNA on a variety of protein-DNA interactions and enzymes.     

Adenosine 5'-O-(3-thiotriphosphate) can support the formation of an initiation complex between the DNA polymerase III holoenzyme and primed DNA

Adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S) will substitute for ATP in the formation of an initiation complex between the DNA polymerase III holoenzyme of Escherichia coli and primed DNA. The initiation complex formed in the presence of ATP gamma S between the DNA polymerase III holoenzyme and single-stranded DNA-binding protein-encoated primed M13 Gori DNA is stabile and isolable by gel filtration at room temperature. Upon addition of the four required deoxynucleoside triphosphates, this complex is rapidly converted to the duplex replicative form without dissociation of the polymerase. Initiation complexes formed in the presence of either ATP gamma S or ATP are indistinguishable by their resistance to antibody directed against the beta subunit of the holoenzyme and by their ability to elongate without further activation. A 2-fold difference was observed, however, in both the extent of initiation complex formation and in the dissociation of initiation complexes once formed. This difference is discussed in the light of previous proposals regarding a dimeric polymerase capable of replicating both strands at a replication fork concurrently.     

Leading strand synthesis of R1 plasmid replication in vitro is primed by primase alone at a specific site downstream of oriR

By using an in vitro system for R1 plasmid replication dependent on a plasmid-encoded repA protein and host dnaA protein, 5' ends of the nascent leading strand were located at positions 1986-1992, some 380 base pair downstream of oriR. Analyses of early replication intermediates generated in vitro in the presence of dideoxy TTP also indicated that replication initiates about 400 base pair downstream of oriR and proceeds unidirectionally. When a 418-base single-stranded DNA from position 1778 to 2195, derived from the leading strand template, was cloned onto an M13 vector, the chimeric single-stranded phage could be replicated in vitro with only single-stranded DNA binding protein, primase (dnaG gene product), and DNA polymerase III holoenzyme. Furthermore, the priming occurred at a site identical to leading strand initiation. These results strongly suggest that the leading strand synthesis is primed by primase alone. The lagging strand synthesis is specifically terminated at position 1515 or 1516 within oriR, preventing further leftward fork movement. Based on these results, a scheme of R1 plasmid replication is presented.     

Fluorescence energy transfer between the primer and the beta subunit of the DNA polymerase III holoenzyme.

We report here our initial success in using fluorescence energy transfer to map the position of the subunits of the DNA polymerase III holoenzyme within initiation complexes formed on primed DNA. Using primers containing a fluorescent derivative 3 nucleotides from the 3'-terminus and acceptors of fluorescence energy transfer located on Cys333 of the beta subunit, a donor-acceptor distance of 65 A was measured. Coupling this distance with other information enabled us to propose a model for the positioning of beta within initiation complexes. Examination of the fluorescence properties of a labeled primer with the unlabeled beta subunit and other assemblies of DNA polymerase III holoenzyme subunits allowed us to distinguish all of the known intermediates of the holoenzyme-catalyzed reaction. Specific fluorescence changes could be assigned for primer annealing, Escherichia coli single-stranded DNA-binding protein binding, 3'----5' exonucleolytic hydrolysis of the primer, DNA polymerase III* binding, initiation complex formation upon the addition of beta in the presence of ATP, and DNA elongation. These fluorescence changes are sufficiently large to support future detailed kinetic studies. Particularly interesting was the difference in fluorescence changes accompanying initiation complex formation as compared to binding of DNA polymerase III holoenzyme subunit assemblies. Initiation complex formation resulted in a strong fluorescence enhancement. Binding of DNA polymerase III* led to a fluorescence quenching, and transfer of beta to primed DNA by the gamma delta complex did not change the fluorescence. This demonstrates a rearrangement of subunits accompanying initiation complex formation. Monitoring fluorescence changes with labeled beta, we have determined that beta binds with a stoichiometry of one monomer/primer terminus.     

The role of gene A protein and E. coli rep protein in the replication of phi X 174 replicative form DNA

The gene A protein of bacteriophage phi X 174 initiates replication of super-twisted RFI DNA by cleaving the viral (+) strand at the origin of replication and binding to the 5' end. Upon addition of E. coli rep protein (single-stranded DNA dependent ATPase), E. coli single-stranded DNA binding protein and ATP, complete unwinding of the two strands occurs. Electron microscopic analyses of intermediates in the reaction reveal that the unwinding occurs by movement of the 5' end into the duplex, displacing the viral strand in the form of a single-stranded loop. Since unwinding will not occur in the absence of either gene A protein or rep protein, it is presumed that the rep protein interacts to form a complex with the bound gene A protein. Single-stranded DNA binding protein facilitates the unwinding by binding to the exposed single-stranded DNA. Further addition of the four deoxyribotriphosphates and DNA polymerase III holoenzyme to the reaction results in synthesis of viral (+) single-stranded circles in amounts exceeding that of the input template. A model describing the role of gene A protein and rep protein in duplex DNA replication is presented and other properties of gene A protein discussed.