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.     

Unique primed start of phage phi X174 DNA replication and mobility of the primosome in a direction opposite chain synthesis.

A specific fragment of the phi X174 viral circle sustains the primed start of complementary DNA strand synthesis in vitro, even though the intact circle permits primed starts at many sites. The 300-nucleotide fragment from restriction nuclease digestion contains the recognition site for protein n', a DNA-dependent ATPase essential for priming phi X174 DNA replication. This n' recognition site contains within it a 44-nucleotide sequence with a potential hairpin structure and may be regarded as the starting signal for replication [Shlomai, J. & Kornberg, A. (1980) Proc. Natl. Acad. Sci. USA 77, 799-803]. After initiation on the 3' side of this sequence, the priming system (primosome) repeatedly generates primers by moving processively on the DNA template in a direction opposite to chain elongation. This primosome mobility is an attractive model for the discontinuous phase of Escherichia coli chromosome replication, in which processive primosome movement with the replicating fork is proposed for repeated initiations of nascent replication fragments.     

Conservation of the primosome in successive stages of phi X174 DNA replication.

Synthesis of a complementary strand to match the single-stranded, circular, viral (+) DNA strand of phage phi X174 creates a parental duplex circle (replicative form, RF). This synthesis is initiated by the assembly and action of a priming system, called the primosome [Arai, K. & Kornberg, A (1981) Proc. Natl. Acad. Sci. USA 78, 69-73; Arai, K., Low, R. L. & Kornberg, A. (1981) Proc. Natl. Acad. Sci. USA 78, 707-711]. Of the seven proteins that participate in the assembly and function of the primosome, most all of the components remain even after the DNA duplex is completed and covalently sealed. Remarkably, the primosome in the isolated RF obviates the need for supercoiling of RF by DNA gyrase, an action previously considered essential for the site-specific cleavage by gene A protein that starts viral strand synthesis in the second stage of phi X174 DNA replication. Finally, priming of the synthesis of complementary strands on the nascent viral strands to produce many copies of progeny RF utilizes the same primosome, requiring the addition only of prepriming protein i. thus a single primosome, which becomes associated with the incoming viral DNA in the initial stage of replication, may function repeatedly in the initiation of complementary strands at the subsequent stage of RF multiplication. These patterns of phi X174 DNA replication suggest that a conserved primosome also functions in the progress of the replicating fork of the Escherichia coli chromosome, particularly in initiating the synthesis of nascent (Okazaki) fragments.     

Functional division and reconstruction of a plasmid replication origin: molecular dissection of the oriV of the broad-host-range plasmid RSF1010.

Two single-stranded DNA initiation signals (designated ssi) present in the origin of vegetative DNA replication (oriV) of the broad-host-range plasmid RSF1010 are essential for the priming of replication of each complementary DNA strand of this plasmid in Escherichia coli. Each of the RSF1010 ssi signals, ssiA and ssiB, could be replaced by a primosome assembly site from plasmid pACY184 or from bacteriophage phi X174. In these chimeric origins, replication of the strand complementary to that containing the primosome assembly site was no longer dependent on the RSF1010 primase, protein RepB', but required the E. coli primase, DnaG. If both ssiA and ssiB sites of RSF1010 were replaced by primosome assembly sites, protein RepB' was no longer essential for the replication at this origin, whereas proteins RepA and RepC of RSF1010 were still required. These results strongly suggest that the two ssi sites and the RepB' protein actually direct the priming of DNA synthesis in the replication of RSF1010, and the proteins RepA and RepC are involved in the prepriming events--i.e., the opening of the DNA duplex at oriV. It is evident that the origin of RSF1010 can be separated into three functional domains and reconstructed by replacing the ssi sites with heterologous elements.     

Molecular cloning and DNA sequence analysis of Escherichia coli priA, the gene encoding the primosomal protein replication factor Y.

Escherichia coli replication factor Y (protein n') functions in the assembly of a mobile multiprotein replication-priming complex called the primosome. Although the role of factor Y in primosome assembly during replication in vitro of bacteriophage phi X174 and plasmid pBR322 DNA is clear, its role in E. coli chromosomal replication is not. To address this issue, the gene for factor Y has been cloned molecularly and its DNA sequence has been determined. The cloned fragment of DNA contained an open reading frame capable of encoding a polypeptide of 81.7 kDa. This open reading frame contains amino acid sequences identical to 13 N-terminal amino acids of purified factor Y, as well as to a 10-amino acid internal sequence (from a cyanogen bromide fragment) as determined by gas-phase microsequencing. Expression of the polypeptide encoded by this open reading frame using a bacteriophage T7 transient expression system resulted in the accumulation of a polypeptide with an apparent molecular mass of 78 kDa that comigrated with bona fide factor Y during SDS/polyacrylamide gel electrophoresis. Soluble extracts made from cells overexpressing the product of the putative factor Y open reading frame showed a 2000-fold increase in factor Y activity during bacteriophage phi X174 complementary-strand DNA synthesis in vitro when compared to control extracts. The gene encoding factor Y, which maps to 88.5 min on the E. coli chromosome, has been designated primosome A (priA).     

Expression of a DNA strand initiation sequence of ColE1 plasmid in a single-stranded DNA phage.

In order to investigate initiation of H-strand (lagging strand) replication of the plasmid ColE1, the origin region fragment (Hae II-E) of ColE1 was inserted into the intergenic region of filamentous DNA phage M13 and cloned. A site capable of promoting DNA strand initiation on a single-stranded DNA template has been detected on the L-strand (leading strand) of the cloned fragment. The site, named rri-1 rifampicin-resistant initiation), directs conversion of chimeric phage single-stranded DNA to parental replicative form in the presence of rifampicin, which blocks the function of the complementary strand origin of M13. The function of rri-1 is dependent on both the dnaG and dnaB gene products. It is postulated that rri-1 might be an initiation site for synthesis of the lagging DNA strand during unidirectional replication of ColE1 DNA.     

Initiation of DNA replication on single-stranded DNA templates catalyzed by purified replication proteins of bacteriophage lambda and Escherichia coli.

Initiation of bacteriophage lambda DNA replication at the chromosomal origin depends on the lambda O and P replication proteins. These two viral initiators, together with an Escherichia coli protein fraction, promote the replication in vitro of single-stranded circular DNA chromosomes such as that of bacteriophage M13. This nonspecific strand initiation reaction, which we have termed the "lambda single-strand replication reaction," has now been established with eight purified proteins, each of which is also required for replication of the phage lambda chromosome in vivo. An early rate-limiting step in the overall reaction is the ATP-dependent assembly of an activated nucleoprotein prepriming complex. In this step the lambda O and P initiators cooperate with the E. coli dnaJ and dnaK proteins to transfer the bacterial dnaB protein onto M13 DNA that is coated with the single-stranded DNA-binding protein. Multiple RNA primers are synthesized on each DNA circle when isolated prepriming complex is incubated with primase and rNTPs. In the complete system, DNA polymerase III holoenzyme extends the first primer synthesized into full-length complementary strands. Because the properties of this system are closely analogous to those found for the replication of phi X174 viral DNA by E. coli proteins, we infer that a mobile prepriming or priming complex (primosome) operates in the lambda single-strand replication reaction.     

Replication deficiencies in priA mutants of Escherichia coli lacking the primosomal replication n'' protein.

The priA gene of Escherichia coli encodes the protein that initiates assembly of the promosome, the entity essential for the replication of phage phi X174 and ColE1-like plasmids in vitro. We have prepared a null priA mutant to assess its role in vivo in replication of phages, plasmids, and the host chromosome. Extracts of this mutant are inert in the initial conversion of the phi X174 viral strand to the duplex form, confirming the absence of the PriA activity. In vivo, the priA mutant fails to produce phi X174 phage and, remarkably, is unable to maintain plasmids that depend on the E. coli chromosome origin as well as those of ColE1. Deficiencies in cell growth and cell division are also manifest.     

Movement and site selection for priming by the primosome in phage phi X174 DNA replication.

The Escherichia coli priming system used for initiation of DNA chains on phage phi X174 single-stranded DNA is a multiprotein unit called the primosome [Arai, K. & Kornberg. A. (1981) Proc. Natl. Acad. Sci. USA 78, 69-73]. Assembled with participation of seven prepriming proteins and primase at a unique place on the phi X174 DNA template, the primosome is bound tightly to the DNA, yet moves rapidly and unidirectionally opposite to primer and DNA chain synthesis. Contributions of protein n' and dnaB protein, two components of the primosome, to movement and site selection for priming are considered in this report. Figuratively, the primosome can be likened to a locomotive that depends on protein n' as its engine and dnaB protein as the engineer. Protein n', a DNA-dependent ATPase (dATPase) appears to use the energy of hydrolysis of the nucleoside triphosphate for processive translocation of the primosome. dnaB protein, A DNA-dependent ribonucleosidetriphosphatase, depends on allosteric effects of a nucleoside triphosphate to induce changes in the structure of the single-stranded DNA at preferred sequences that enable primase to synthesize a short primer for initiation of DNA synthesis (unpublished data). These primosome properties have important implications for the progress of the replication fork of the E. coli chromosome.     

An Escherichia coli replication protein that recognizes a unique sequence within a hairpin region in phi X174 DNA.

Protein n', a prepriming DNA replication enzyme of Escherichia coli, is a phi X174 DNA-dependent ATPase. Restriction of phi X174 DNA have led to the identification of a 55-nucleotide fragment that carries the protein n' recognition sequence. Molecular hybridization and sequence analysis have located this sequence within the untranslated region between genes F and G, a map location analogous to that of the unique complementary strand origin of phage G4 DNA. Within the 55-nucleotide fragment is a sequence of 44 nucleotides that forms a stable hairpin structure. This duplex may be the signal for protein n' to initiate the prepriming events that led to the start of phi X174 complementary DNA strand replication.     

Viable deletions of the M13 complementary strand origin

The single-stranded DNA of bacteriophage M13 is converted to a duplex replicative form by a mechanism involving RNA-primed initiation at a single unique site on the viral DNA. The DNA sequence that specifies the RNA primer is contained largely within one of two adjacent hairpin structures protected from DNase degradation by RNA polymerase. We have used in vitro techniques to construct a series of M13 mutants having deletions in the region of the complementary strand origin. Deletions of the duplex replicative form DNA range in size from 54 to 201 base pairs. The largest deletions remove both of the RNA polymerase-protected hairpins and the entire sequence specifying the primer RNA. Mutants lacking one or both hairpins form faint plaques, give reduced phage yields, and show a lag in phage production of >30 min. The rate of conversion of the single-stranded viral DNA to the parental replicative form is reduced both in vivo and in vitro. These results indicate that both the RNA polymerase-protected hairpins and the RNA primer-coding sequence are important, but not essential, for replication. Other sequences within the origin region, or possibly elsewhere in the genome, may play a role in complementary strand initiation in these mutant phages. The M13 viral strand is initiated by extension of the 3′ terminus generated by site-specific nicking of the viral strand of the replicative form DNA by the M13 gene II protein. This specific nicking site is retained in all of the M13 deletion mutants. Deletion end points do not extend into a 13-nucleotide sequence preceding the viral strand nicking site. We propose that a sequence including these 13 nucleotides is required for gene II protein action at this site.     

Morphogenesis of phi X174: in vitro synthesis of infectious phage from purified viral components.

An in vitro system that synthesizes infectious phage phi X174 was developed. The synthesis depended on phi X174 supercoiled replicative form DNA, purified phi X174 gene A protein, gene C protein, gene J protein, prohead (phage head precursor composed of gene F, G, H, B, and D proteins), and uninfected host crude extract. The infectious phage synthesis was coupled with DNA synthesis. De novo initiation, elongation, and termination of phi X174 single-stranded DNA was observed. The phage synthesized in vitro cosedimented with in vivo phage in sucrose gradients and had the same buoyant density as in vivo phage in a CsCl gradient. Our results indicate that the in vitro system mimics the in vivo phi X174 assembly process.     

In vitro DNA replication of recombinant plasmid DNAs containing the origin of progeny replicative form DNA synthesis of phage phi X174.

The origin of phage phi X174 progeny replicative form (RF) DNA synthesis has been inserted into the plasmid vector pBR322 and cloned. In direct contrast to pBR322, the recombinant superhelical plasmids can substitute for phi X174 RFI DNA as template in phi X174-specific reactions in vitro. We have shown that the recombinant plasmids: (i) are cleaved by the phi X174 A protein; (ii) support net synthesis of unit-length single-stranded circular DNA in the presence of the phi X174 A protein and Escherichia coli rep protein, DNA-binding protein, and DNA polymerase III elongation system; (iii) support replication of duplexes catalyzed by the phi X174 A protein and extracts of E. coli.     

The priA gene encoding the primosomal replicative n'' protein of Escherichia coli.

The Escherichia coli gene encoding protein n' has been isolated and named priA for primosomal protein A. Protein n' is absolutely required for the conversion of single-stranded phi X174 DNA to the duplex replicative form in an in vitro-reconstituted system. The gene maps to 88.7 minutes on the chromosome adjacent to the cytR locus. Soluble protein extracts from cells harboring the priA gene on a multicopy plasmid contained 45-fold more n' replication activity than wild-type extracts. Enhanced overproduction of greater than 1000-fold was achieved by replacing the natural Shine-Dalgarno sequence with that of the phage T7 phi 10 gene and placing this priA under the control of the T7 phage promoter and RNA polymerase. The priA sequence reveals a 732-amino acid open reading frame and a nucleotide-binding consensus site consistent with the size and ATPase activity of the purified protein. The gene for protein n has been named priB and the putative gene for protein n", priC.     

Template recognition sequence for RNA primer synthesis by gene 4 protein of bacteriophage T7

The gene 4 protein of bacteriophage T7 recognizes specific sequences on single-stranded DNA and then catalyzes the synthesis of tetraribonucleotide primers complementary to the template. With phi X174 DNA as a template, the gene 4 protein enables T7 DNA polymerase (deoxynucleosidetriphosphate:DNA deoxynucleotidyltransferase, EC 2.7.7.7) to initiate DNA synthesis at 13 major sites. DNA sequence analysis of the 5' termini of the newly synthesized DNA shows the predominant recognition sequences for the gene 4 protein to be 3'-C-T-G-G-G-5' or 3'-C-T-G-G-T-5'; the products of synthesis at these sites are RNA primers having the sequences pppA-C-C-C or pppA-C-C-A. The gene 4 protein can also synthesize primers at the sequences 3'-C-T-G-G-AC-5' and 3'-C-T-G-T-N-5', although these sites are used less than 10% as frequently as the predominant sites. Comparison of the utilization of primer sites suggests that the gene 4 protein binds randomly to single-stranded DNA and then translocates along the DNA in a unidirectional 5'-to-3' direction with regard to the DNA strand in search of recognition sequences. Models are presented for the role of the gene 4 protein in the initiation of lagging-strand synthesis and in the initiation of DNA replication at the origin.     

Polar branch migration promoted by recA protein: effect of mismatched base pairs.

Escherichia coli recA protein makes joint molecules from single-stranded circular phage DNA (viral or plus strand) and homologous linear duplex DNA by a polar reaction that displaces the 5' end of the plus strand from the duplex molecule [Kahn, R., Cunningham, R. P., DasGupta, C. & Radding, C. M. (1981) Proc. Natl. Acad. Sci. USA 78, 4786-4790]. Growth of the heteroduplex joint, which results from strand exchange or branch migration, stopped at the borders of regions of nonhomologous DNA that were variously located 145, 630, or 1202 nucleotides from the end. Accumulation of migrating branches at heterologous borders demonstrates that their migration is not the result of random diffusion but is actively driven by recA protein. Growth of the heteroduplex joint was blocked even when a heterologous insertion was located in the single-stranded DNA, a case in which the flexible single-stranded region might conceivably fold out of the way under some condition. The recA protein did not make joint molecules from phage phi X174 and G4DNAs, which are 70% homologous, but did join phage fd and M13DNAs, which are 97% homologous. In the latter case, heteroduplex joints extended through regions containing isolated mismatched base pairs but stopped in a region where the fd and M13 sequences differ by an average of 1 base pair in 10. These results suggest that in genetic recombination the discrimination of perfect or near-perfect homology from a high degree of relatedness may be attributable in part to the mechanism by which recA protein promotes strand transfer.     

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.     

Transposition of the Escherichia coli insertion element gamma generates a five-base-pair repeat.

We have determined DNA sequences surrounding the termini of the Escherichia coli insertion element gamma delta, both at its normal locus on the F (fertility) factor and at three different sites of insertion into the plasmid pBR322. After transposition, a five-base-pair pBR322 sequence is duplicated and appears in direct orientation adjacent to each end of the element. No such duplication flanks the ends of gamma delta in F, and there is no apparent homology between the sequences surrounding gamma delta in F and the five-base-pair duplications generated by insertion. These findings suggest that the duplications are not essential for transposition and that they do not act to direct gamma delta to a homologous site in the target chromosome. In addition, we find that the 35-base-pair inverted repeat that comprises the termini of gamma delta is strikingly similar in sequence to the ends of both the ampicillin-resistance transposon Tn3 and a 200-nucleotide-long sequence on the plasmid pSC101 which has been shown to mediate recombination with phage f1 replicative form. Within the terminal region, there is a specific heptanucleotide sequence common to each of the above elements and to bacteriophage Mu, all of which generate five-base-pair repeats upon insertion.     

Heteroduplex formation by recA protein: polarity of strand exchanges.

Purified recA protein promotes strand exchanges between linear duplex DNA and homologous circular single-stranded phage phi X174 DNA that carries a short hybridized fragment [West, S. C., Cassuto, E. & Howard-Flanders, P. (1981) Proc. Natl. Acad. Sci. USA 78, 2100-2104]. In this paper we investigate the mechanism of this strand exchange reaction. We show that recA protein initiates strand exchanges by pairing the free end of the duplex fragment with the single-stranded DNA. In addition, we find that strand exchanges are polar, stable heteroduplex molecules being formed by the directional transfer transfer of the (-) strands starting at 3' termini.