Conversion of ?X174 and fd Single-Stranded DNA to Replicative Forms in Extracts of Escherichia coli

varphiX174 and M13 (fd) single-stranded circular DNAs are converted to their replicative forms by extracts of E. coli pol A1 cells. We find that the varphiX174 DNA-dependent reaction requires Mg(++), ATP, and all four deoxynucleoside triphosphates, but not CTP, UTP, or GTP. This reaction also involves the products of the dnaC, dnaD, dnaE (DNA polymerase III), and dnaG genes, but not that of dnaF (ribonucleotide reductase). The in vitro conversion of fd single-stranded DNA to the replicative form requires all four ribonucleoside triphosphates, Mg(++), and all four deoxynucleoside triphosphates. The reaction involves the product of gene dnaE but not those of genes dnaC, dnaD, dnaF, or dnaG. The reaction with fd DNA is inhibited by rifampicin or antibody to RNA polymerase, while the reaction with varphiX174 DNA is not affected by either. With the varphiX174 DNA-dependent reaction, activities have been detected that specifically complement extracts of dnaA, dnaB, dnaC, dnaD, or dnaG mutants.     

Association of phiX174 DNA-dependent ATPase activity with an Escherichia coli protein, replication factor Y, required for in vitro synthesis of phiX174 DNA.

phiX174 DNA-dependent DNA synthesis is catalyzed in vitro by the combination of at least 11 purified protein fractions: dnaB, dnaC(D), and dnaG gene products, DNA polymerase III, DNA elongation factors I and II, DNA binding protein, and replication factors W, X, Y, and Z. The reaction requires ATP, 4 dNTPs, and Mg+2 and is specific for phiX174 (or phiXahb) DNA. Purified replication factor Y contains phiX174 (or phiXahb) DNA-dependent ATPase (or dATPase) activity. The ATPase activity is poorly stimulated by other single-stranded DNA, by double-stranded DNA, or by RNA. The products of the phiX174 DNA-dependent ATPase activity of factor Y are Pi and ADP (or dADP). The association of phiX174 DNA-dependent ATPase activity with factor Y was shown in the following ways: (a) the two activities copurified with a constant ratio; (b) they comigrated on native polyacrylamide gel electrophoresis; (c) both activities were heat-inactivated at the same rate; and (d) both showed identical patterns of N-ethylmaleimide sensitivity.     

Escherichia coli factor Y sites of plasmid pBR322 can function as origins of DNA replication.

The Escherichia coli replication factor Y, in conjunction with other genetically undefined E. coli replication factors and the gene products of the E. coli dnaB, dnaC, and dnaG loci, is involved in de novo primer formation on the phi X174 (+) single-strand circular DNA template [(+) ss(c)DNA]. The participation of factor Y in this series of reactions is correlated with its phi X174 (+) ss(c)-specific DNA-dependent ATPase activity. Recently two factor Y effector DNA segments of the plasmid pBR322 have been identified in close proximity to the plasmid origin of DNA replication. We report here that insertion of these factor Y sites into the filamentous phage f1R229 (+) ss(c)DNA confers upon it the ability to be converted to RF DNA in vitro through a rifampicin-resistant dnaB, dnaC, and dnaG gene product-dependent pathway. Our data suggest that factor Y effector sites can function as origins of DNA replication.     

Escherichia coli replication factor Y, a component of the primosome, can act as a DNA helicase.

The primosome is a mobile multienzyme DNA replication-priming complex that requires seven Escherichia coli proteins for assembly (the products of the dnaB, dnaC, dnaG, and dnaT genes as well as proteins n and n" and replication factor Y). It has been shown previously that the primosome, in combination with the E. coli DNA polymerase III holoenzyme, can form replication forks in vitro that move at rates similar to those measured in vivo and that the primosome and one of the components of the primosome, the DNA B protein, have DNA helicase activity. Evidence is presented here that another component of the primosome, replication factor Y, possesses DNA helicase activity as well. Factor Y helicase activity requires the presence of E. coli single-stranded DNA binding protein, Mg2+, and hydrolyzable ATP or dATP. Helicase activity is stimulated 15-fold when the enzyme is actively loaded onto single-stranded DNA through a primosome assembly site, and duplex DNA is unwound unidirectionally, 3'----5', along the DNA strand to which the protein is bound.     

DNA synthesis in vitro dependent upon phiX174 replicative form I DNA.

Extracts of Escherichia coli strains infected with bacteriophage phiX174 catalyze DNA synthesis dependent on double-stranded, circular phiX174 replicative form I (phiX RFI) by a semiconservative process. The reaction required Mg++, ATP, all four dNTP, and exogenous phiX RFI DNA as template and yielded phiX RFI and phiX RFII. The reaction was inhibited by nalidixic acid and novobiocin but not by rifampicin. DNA synthesis required the phiX174 gene A product and E. coli gene products dnaB, dnaC(D), dnaG, and rep.     

Isolation of an intermediate which precedes dnaG RNA polymerase participation in enzymatic replication of bacteriophage phi X174 DNA.

Conversion of phi X174 single-stranded DNA to the duplex replicative form (RF) in vitro requires at least 10 purified proteins. Three stages - strand initiation, elongation, and termination - comprise this conversion. We now identify a separate stage in strand initiation which precedes dnaG RNA polymerase participation. Incubation of five proteins - protein i, protein n, DNA unwinding protein, dnaB protein, and dnaC protein - with ATP and phi X174 DNA forms an intermediate which enables subsequent stages measured by DNA synthesis to proceed 20 times faster. The intermediate can be isolated in quantitative yield by gel filtration or by ultracentrifugation. Protein i and protein n are required in less than stoichiometric amounts and appear to be absent from the isolated intermediate. Whereas formation of the intermediate is sensitive to antibody to protein i and to N-ethylmaleimide (an inhibitor of protein n and dnaC protein), the intermediate itself is resistant to these reagents. DNA unwinding protein complexes the DNA in a ratio of 60 molecules per circle. Synthesis of the intermediate appears to require stoichiometric quantities of dnaB protein and dnaC PROTEin but their presence in the intermediate has not been established as yet.     

Migration of Escherichia coli dnaB protein on the template DNA strand as a mechanism in initiating DNA replication

The first step in conversion of varphiX174 singlestranded DNA to the duplex replicative form in vitro is the synthesis of a nucleoprotein intermediate [Weiner, J. H., McMacken, R. & Kornberg, A. (1976) Proc. Natl. Acad. Sci. USA 73, 752-756]. We now demonstrate that dnaB protein (approximately one molecule per DNA circle) is an essential component of the intermediate and retains its ATPase activity. Synthesis of RNA primers, dependent on dnaG protein (primase), occurred only on DNA that had been converted to the intermediate form. In a coupled RNA priming-DNA replication reaction the first primer synthesized was extended by DNA polymerase III holoenzyme into full-length complementary strand DNA. In RNA priming uncoupled from replication, multiple RNA primers were initiated on a varphiX174 circle. The single dnaB protein molecule present on each DNA circle participated in initiation of each of the RNA primers, which appear to be aligned at regular intervals along the template strand. We propose that dnaB protein, once bound to the template, migrates in a processive fashion along the DNA strand, perhaps utilizing energy released by hydrolysis of ATP for propulsion; in this scheme the actively moving dnaB protein acts as a "mobile promoter" signal for dnaG protein (primase) to produce many RNA primers. Schemes are proposed for participation of dnaB protein both in the initiation of replication at the origin of the Escherichia coli chromosome and in the initiation of primers for nascent (Okazaki) fragments at a replication fork.     

A general priming system employing only dnaB protein and primase for DNA replication.

Priming of phage phi X174 DNA synthesis is effected simply by dnaB protein and primase when the DNA is not coated by single-strand binding protein (SSB). The five prepriming proteins (n,n',n',i, and dnaC protein) required for priming a SSB-coated phi X174 DNA circle are dispensable. The dnaB protein-primase priming system is also active on uncoated phage G4 and M13 DNAs and on poly(dT). Multiple RNA primers, 10--60 nucleotides long, are transcribed with patterns distinctive for each DNA template. Formation of a stable dnaB protein.DNA complex in the presence of primase and ATP supports the hypothesis that dnaB protein provides a mobile replication promoter signal for primase.     

Interaction of Escherichia coli dnaB and dnaC(D) gene products in vitro.

Purified E. coli dnaB and dnaC(D) gene products interact physically and functionally in vitro. This interaction was demonstrated as follows: (a) A complex of dnaB and dnaC(D) gene products was isolated by gel filtration; ATP specifically was required for isolation of the complex. (b) The DNA-independent ribonucleoside triphosphatase activity associated with dnaB gene product was inhibited by dnaC(D) gene product. (c) The dnaC(D) gene product was protected from inactivation by N-ethyl-maleimide by the combination of dnaB gene product and ATP; this protection required ATP specifically.     

Identification of two Escherichia coli factor Y effector sites near the origins of replication of the plasmids (ColE1 and pBR322.

The Escherichia coli replication factor Y has been characterized as a phi X174 (+) strand specific DNA-dependent phosphohydrolase. In conjunction with other E. coli replication proteins, factor Y is involved in the formation of heterogeneous primers that are elongated by the E. coli DNA polymerase III elongation machinery. We report here that the heat-denatured DNAs of plasmids pBR322 and ColE1 serve as effectors for the hydrolysis of ATP by factor Y. The DNA sequences of pBR322 responsible for factor Y effector activity have been localized. Two separate regions of the pBR322 chromosome support Y ATPase activity. These sequences are near the replication origin and are located on opposite DNA strands.     

Association of DNA-dependent and -independent Ribonucleoside Triphosphatase Activities with dnaB Gene Product of Escherichia coli

Preparations of E. coli dnaB gene product contain ribonucleoside triphosphatase activity that is stimulated 10-fold by DNA. The products of the triphosphatase activity are nucleoside diphosphates and P(i). The dnaB complementing activity in the varphiX174 DNA-dependent system and these triphosphatase activities copurify over the last 20-fold of an extensive (about 40,000-fold) purification procedure. Acrylamide gel electrophoresis of the purified material shows a single band of protein coincident with eluted dnaB complementing and DNA-dependent and -independent nucleoside triphosphatase activities.     

Studies on In Vitro DNA Synthesis Purification of dna C Gene Product Containing dna D Activity from Escherichia coli

The conversion of varphiX174 single-stranded DNA to duplex DNA by extracts of E. coli requires products of the E. coli DNA replication genes. By use of this complementation system, the dna C gene product has been purified from wild-type E. coli as well as from a dna C temperature-sensitive mutant. The latter preparations are temperature sensitive when compared to the wild-type gene product. The dna C and dna D gene products copurify, have similar characteristics, are both temperature sensitive in preparations from dna C temperature-sensitive cells, and are both undetectable in preparations from dna D temperature-sensitive cells.     

Enzymatic replication of viral and complementary strands of duplex DNA of phage phiX174 proceeds by seprate mechanisms.

Multiplication of the duplex, circular, phage phiX174DNA (replicative form, RF) in stage II of the replicative life cycle has been observed with a crude enzyme preparation [Eisenberg et al. (1976) Proc, Natl. Acad, Sci. USA 73, 1594-1597]. This stage has now been partially reconstituted with purified proteins and subdivided into two stages: II(+) and II(-). In stage II(+), viral (+) strand synthesis is carried out by four proteins: the phage-induced, cistron A-dependent protein, rep-dependent protein, DNA unwinding protein, and DNA polymerase III holenzyme. In stage II(-), complementary (-) strand synthesis utilizes the product of stage II(+) as template and the multiprotein system previously identified in the stage I synthesis of a complementary strand on the viral DNA template to produce RF. The multiprotein system includes DNA unwinding protein, proteins i and n, dnaB protein, dnaC protein, dnaG protein, and DNA polymerase III holoenzyme. A discussion of these two separate mechanism for synthesis of (+) and (-) strands suggests that they may account for essentially all the replicative stages in the life cycle of phiX174.     

Studies on In Vitro DNA Synthesis Isolation of dna B Gene Product from Escherichia coli

Formation of duplex DNA from varphiX174 single-stranded DNA by extracts of E. coli was previously shown to require the gene product of dna B. Using as an assay the stimulation of varphiX174 DNA-dependent synthesis in inactivated extracts of dna B temperature-sensitive cells, we purified the dna B gene product from wild-type E. coli as well as from a dna B temperature-sensitive mutant. The dna B temperature-sensitive gene product is more thermolabile than its wild-type counterpart.     

Involvement of escherichia coli dnaZ gene product in DNA elongation in vitro.

E. coli dnaZ gene product is required for conversion of phiX174, fd, and ST-1 single-stranded phage DNAs to duplex DNAs in vitro. This protein has been purified about 5000-fold. It functions in the elongation of RNA- or DNA-primed single-stranded DNA that is catalyzed by DNA polymerase III(DNA nucleotidyltransferase; deoxynucleosidetriphosphate: DNA deoxynucleotidyltransferase; EC 2.7.7.7) in conjunctions with two other E. coli protein preparations referred to as DNA elongation factors I and III. It also functions in similar reactions catalyzed by DNA polymerase II in combination with E. coli DNA binding protein and DNA elongation factors I and III.     

Identification of ColE1 DNA sequences that direct single strand-to-double strand conversion by a phi X174 type mechanism.

A DNA single-strand initiation sequence, named rriA (called rri-1 previously), was detected in the origin region (Hae II fragment E) of the ColE1 plasmid [Nomura, N. & Ray, D. S. (1980) Proc. Natl. Acad. Sci. USA 77, 6566-6570]. Another site, called rriB, has been found on the opposite strand of Hae II fragment C. Both rriA and rriB (i) direct conversion of chimeric M13 phage single-stranded DNA to parental replicative form DNA in vivo by a rifampicin-resistant mechanism that is dependent on the dnaG and dnaB gene products, (ii) provide effector sites of dATP hydrolysis by primosomal protein n', and (iii) require the same primosomal proteins as phi X174 DNA for directing the in vitro conversion that rriA is the DNA sequence that determines the mechanism of lagging strand synthesis of ColE1 DNA and that the mechanism of discontinuous synthesis involves the primosomal proteins utilized in the in vitro conversion of phi X174 single strands to the double-stranded replicative form.     

Initiation of DNA replication by the Escherichia coli dnaG protein: evidence that tertiary structure is involved.

The dnaG protein of Escherichia coli initiates DNA replication by synthesizing primer oligonucleotides for elongation by DNA polymerae. The experiments reported here probe the nature of the nucleic acid element recognized by the dnaG protein. Three well-separated groups of nucleotides within the negative-strand origin of the single-stranded phage phi K are protected by the dnaG protein against nuclease digestion. DNA as far as 115 bases from the start site of primer synthesis is involved in binding of the dnaG protein to the replication origin. One molecule of dnaG protein could protect all of these nucleotides if the DNA were folded into a higher-order tertiary structure. Protection of the phi K origin by dnaG protein requires DNA binding protein, and it does not occur if the group of protected nucleotides most distant from the start site is removed from the template. There is no binding of dnaG protein to the complementary strand of the phi K origin-region DNA. The observed protection of the positive strand is due to a functional nucleic acid-protein complex.     

DNA or RNA priming of bacteriophage G4 DNA synthesis by Escherichia coli dnaG protein.

Escherichia coli dnaG protein is involved in the initiation of DNA synthesis dependent on G4 or ST-1 single-stranded phage DNAs [Bouche, J.-P., Zechel, K & Kornberg, A. (1975) J. Biol. Chem. 250, 5995-6001]. The reaction occurs by the following mechanism: dnaG protein binds to specific sites on the DNA in a reaction requiring E. coli DNA binding protein. An oligonucleotide is synthesized in a reaction involving dnaG protein, DNA binding protein, and DNA. With G4 DNA this reaction requires ADP, dTTP (or UTP), and dGTP (or GTP). Elongation of the oligonucleotide can be catalyzed by DNA polymerase II or III in combination with dnaZ protein and DNA elongation factors I and III, presumably by the mechanism previously reported [Wickner, S. (1976) Proc. Natl. Acad. Sci. USA 73, 3511-3515] or by DNA polymerase I.     

Mechanism of DNA elongation catalyzed by Escherichia coli DNA polymerase III, dnaZ protein, and DNA elongation factors I and III.

Elongation of a primed single-stranded DNA template catalyzed by E. coli DNA polymerase III (DNA nucleotidyltransferase, deoxynucleosidetriphosphate:DNA deoxynucleotidyltransferase, EC 2.7.7.7) requires dnaZ protein and two other protein factors, DNA elongation factors I and III. The reaction occurs by the following mechanism: (i) dnaZ protein and DNA elongation factor III together catalyze the transfer of DNA elongation factor I to a primed DNA template. This transfer reaction requires ATP or dATP in addition to dnaZ protein, DNA elongation factors I and III, and primed template; it does not require DNA polymerase III. (ii) DNA polymerase III binds to the complex of DNA elongation factor I with primed template; it does not bind to primed template which is not complexed with DNA elongation factor I. This binding reaction proceeds in the absence of ATP or dATP as cofactor, dnaZ protein, and DNA elongation factor III and without additional DNA elongation factor I. (iii) The complex of DNA polymerase III, DNA elongation factor I, and primed template catalyzes DNA synthesis upon the addition of dNTPs.