The gapped duplex DNA approach to oligonucleotide-directed mutation construction.

A simple and efficient method is described to introduce structurally pre-determined mutations into recombinant genomes of filamentous phage M13. The method rests on gapped duplex DNA (gdDNA) molecules of the phage M13 genome as the key intermediate. In this gdDNA, the (+) and the (shorter) (-) strand carry different genetic markers in such a way, that a rigorous selection can be applied for phage carrying the markers of the (-) strand. For introduction of the mutation, a synthetic oligonucleotide with partial homology to a target site within the single stranded DNA region is annealed to the gdDNA. The oligonucleotide subsequently becomes part of the (-) strand by enzymatic DNA gap filling and sealing. This physical linkage is preserved at the genetic level after transfection of a recipient E.coli strain deficient in DNA mismatch correction, so that the synthetic marker can be selected from the phage progeny independent from its potential phenotype. It is demonstrated that by this method mutants can be constructed with marker yields in excess of 70%.     

Bacteriophage T4 gene 41 protein, required for the synthesis of RNA primers, is also a DNA helicase

Bacteriophage T4 gene 41 protein is one of the two phage proteins previously shown to be required for the synthesis of the pentaribonucleotide primers which initiate the synthesis of new chains in the T4 DNA replication system. We now show that a DNA helicase activity which can unwind short fragments annealed to complementary single-stranded DNA copurifies with the gene 41 priming protein. T4 gene 41 is essential for both the priming and helicase activities, since both are absent after infection by T4 phage with an amber mutation in gene 41. A complete gene 41 product is also required for two other activities previously found in purified preparations of the priming activity: a single-stranded DNA-dependent GTPase (ATPase) and an activity which stimulates strand displacement synthesis catalyzed by T4 DNA polymerase, the T4 gene 44/62 and 45 polymerase accessory proteins, and the T4 gene 32 helix-destabilizing protein (five-protein reaction). The 41 protein helicase requires a single-stranded DNA region adjoining the duplex region and begins unwinding at the 3' terminus of the fragment. There is a sigmoidal dependence on both nucleotide (rGTP, rATP) and protein concentration for this reaction. 41 Protein helicase activity is stimulated by our purest preparation of the T4 gene 61 priming protein, and by the T4 gene 44/62 and 45 polymerase accessory proteins. The direction of unwinding is consistent with the idea that 41 protein facilitates DNA synthesis on duplex templates by destabilizing the helix as it moves 5' to 3' on the displaced strand.     

Selective cloning of a DNA single-strand initiation determinant from phi X174 replicative-form DNA.

An M13 phage deletion mutant, M13 delta E101, developed as a vector for selecting DNA sequences that direct DNA strand initiation on a single-stranded template, has been used for cloning restriction enzyme digests of phi X174 replicative-form DNA. Initiation determinants, detected on the basis of clear-plaque formation by the chimeric phage, were found only in restriction fragments containing the unique effector site in phi X174 DNA for the Escherichia coli protein n' dATPase (ATPase). Furthermore, these sequences were functional only when cloned in the orientation in which the phi X174 viral strand was joined to the M13 viral strand. A 181-nucleotide viral strand fragment containing this initiation determinant confers a phi X174-type complementary-strand replication mechanism on M13 chimeras. The chimeric phage is converted to the parental replicative form in vivo by a mechanism resistant to rifampin, a specific inhibitor of the normal RNA polymerase-dependent mechanism of M13. In vitro, the chimeric single-stranded DNA promotes the assembly of a functional multiprotein priming complex, or primosome, identical to that utilized by intact phi X174 viral strand DNA. Chimeric phage containing the sequence complementary to the 181-nucleotide viral strand sequence shows no initiation capability, either in vivo or in vitro.     

Mechanism of protein priming DNA replication of B.subtilis phage M2.

B.subtilis phage M2 uses a protein, instead of RNA, as the primer of its DNA replication. Hence this protein encoded in the phage genome is called as the primer protein (PP). At the initiation of DNA replication, a hetero dimer complex with its own DNA polymerase and the PP supposed to interact with the terminal protein (TP), which is covalently bound to the template DNA (TP-DNA). PP contained an important adhesive amino acid sequence, Arg-Gly-Asp (RGD), near the carboxyl terminal. We have recently showed that the synthetic RGD peptide inhibited the transfection of phage M2. By site-directed mutagenesis, we introduced different amino acid into the RGD site of PP. These altered PP decreased obviously the priming activity in vitro.     

Initiation signals for complementary strand DNA synthesis on single-stranded plasmid DNA.

The bacteriophage 0X174 origin for (+) strand DNA synthesis, when inserted in a plasmid, is in vivo a substrate for the initiator A protein, that is produced by infecting phages. The result of this interaction is the packaging of single-stranded plasmid DNA into preformed phage coats. These plasmid particles can transduce 0X-sensitive cells; however, the transduction efficiency depends strongly on the presence in the packaged DNA strand of an initiation signal for complementary strand DNA synthesis. A plasmid with the complementary (-) strand origin of 0X inserted in the same strand as the viral (+) origin transduces 50-100 times more efficient than the same plasmid without the (-) origin of 0X. The transduction efficiency of such a particle is comparable to the infection efficiency of the phage particle. It is shown that in this system the 0X (-) origin can be replaced by the complementary strand origins of the bacteriophages G4 and M13. We have used this system to isolate sequences, from E. coli plasmids (pACYC177, CloDF13, miniF and OriC) and from the E. coli chromosome that can function as initiation signals for the conversion of single-stranded plasmid DNA to double-stranded DNA. All isolated origins were found to be dependent for their activity on the dnaB, dnaC and dnaG proteins. We conclude that these signals were all primosome-dependent origins and that primosome priming is the major mechanism for initiation of the lagging strand DNA synthesis in E. coli. The assembly of the primosome depends on the sequence-specific interaction of the n' protein with single-stranded DNA. We have used the isolated sequences to deduce a consensus recognition sequence for the n' protein. The role of a possible secondary structure in this sequence is discussed.     

Electron microscopic analysis of DNA forks generated by Escherichia coli DNA helicase II

T7 phage DNA eroded with lambda exonuclease (to create 3'-protruding strands) or exonuclease III (to create 5'-protruding strands) was treated under unwinding assay conditions with DNA helicase II. Single-stranded DNA-binding protein (of Escherichia coli or phage T4) was added to disentangle the denatured DNA and the complexes were examined in the electron microscope. DNA helicase II complexes filtered through a gel column before assay retain the ability to generate forks suggesting that DNA helicase II unwinds in a preformed complex by translocating along the bound DNA strand. The enzyme initiates preferentially at the ends of the lambda-exonuclease-treated duplexes and is found at a fork on the initially protruding strand. It also initiates at the ends of the exonuclease-III-treated duplexes where, as with approximately 5% of the forks traceable back to a single-stranded gap, it is found on the initially recessed strand. The results are consistent with the view that DNA helicase II unwinds in the 3'-5' direction relative to the bound strand. They also confirm that the enzyme can initiate at the end of a fully base-paired strand. At a fork, DNA helicase II is bound as a tract of molecules of approximately 110 nm in length. Tracts of enzyme assemble from non-cooperatively bound molecules in the presence of ATP. During unwinding, DNA helicase II apparently can translocate to the displaced strand which conceivably can deplete the leading strand of the enzyme. Continued adsorption of enzyme to DNA might replenish forks arrested by strand switch of the unwinding enzyme.     

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.     

Formation of rolling-circle molecules during phi X174 complementary strand DNA replication

The primosome is a mobile multiprotein priming apparatus that requires seven Escherichia coli proteins for assembly (the products of the dnaB, dnaC and dnaG genes; replication factor Y (protein n'); and proteins i, n, and n"). While the primosome is analagous to the phage T7 gene 4 protein and phage T4 gene 41/61 proteins in its DNA G-catalyzed priming function, its ability to act similarly also as a DNA helicase has remained equivocal. The role of the primosome in unwinding duplex DNA strands was investigated in the coliphage phi X174 SS(c)----replicative form DNA replication reaction in vitro, which requires the E. coli single-stranded DNA binding protein, the primosomal proteins, and the DNA polymerase III holoenzyme. Multigenome-length, linear, double-stranded DNA molecules were generated in this reaction, presumably via a rolling circle-type mechanism. Synthesis of these products required the presence of a helicase-catalyzed strand-displacement activity to permit multiple cycles of continuous complementary (-) strand synthesis. The participation of the primosome in this helicase activity was supported by demonstrating that other SS(c) DNA templates (G4 and alpha-3), which lack primosome assembly sites, failed to support significant linear multimer production and that replication of phi X174 with the general priming system (the DNA B and DNA G proteins and DNA polymerase III holoenzyme) resulted in a 13-fold lower rate of linear multimer synthesis.     

Bacteriophage f1 DNA replication genes. II. The roles of gene V protein and gene II protein in complementary strand synthesis

Filamentous phage gene V, which encodes a single-stranded DNA binding protein, has been cloned and placed under control of the lac promoter. Cells bearing the clone are refractory to filamentous phage infection if the expression of the gene is induced with isopropyl-1-thio-beta-D-galactoside. The inhibition of infection is shown to occur at an early stage, and can be reversed if the cells express gene II in addition to gene V protein. These observations support the hypothesis that gene II protein, in addition to its role in nicking and facilitating the synthesis of phage viral (+) strand DNA, functions to prevent the gene V-mediated inhibition of complementary (-) strand synthesis. We proposed a model in which the absolute and relative concentrations of the products of genes II, X and V determine whether a single strand is to be exported as phage or incorporated into double-stranded replicative form DNA.     

Regulation of bacteriophage f1 DNA replication. I. New functions for genes II and X

Gene II protein is required for all phases of filamentous phage DNA synthesis other than the conversion of the infecting single strand to the parental double-stranded molecule. It introduces a specific nick into the double-stranded replicative form DNA, is required for the initiation of (+) strand synthesis and is responsible for termination and ring closure of the (+) strand product. Here we show that the gene II protein also promotes minus strand synthesis later in infection. Over-expression of gene II protein can induce the conversion of all nascent single-stranded phage DNA to the double-stranded form, even in the presence of the single-stranded DNA-binding gene V protein that would normally sequester the newly synthesized single strands. We also present evidence that the gene X protein (separately translated from an initiator codon within gene II, and identical to the C-terminal one-third of the gene II protein) is a powerful inhibitor of phage-specific DNA synthesis in vivo.     

Effects of UV irradiation on the fate of 5-bromodeoxyuridine-substituted bacteriophage T4 DNA.

We have carried out a series of experiments designed to characterize the impact of UV irradiation (260 nm) on 5-bromodeoxyuridine-labeled (heavy) T4 bacteriophage, both before and after infection of Escherichia coli. In many respects, these effects differ greatly from those previously described for non-density-labeled (light) phage. Moreover, our results have led us to propose a model for a novel mechanism of host-mediated repair synthesis, in which excision of UV-damaged areas is followed by initiation of replication, strand displacement, and a considerable amount of DNA replication. UV irradiation of 5-bromodeoxyuridine-labeled phage results in single-stranded breaks in a linear, dose-dependent manner (1.3 to 1.5 breaks per genomic strand per lethal hit). This damage does not interfere with injection of the phage genome, but some of the UV-irradiated heavy phage DNA undergoes additional intracellular breakdown (also dose dependent). However, a minority (25%) of the injected parental DNA is protected, maintaining its preinjection size. This protected moiety is associated with a replicative complex of DNA and proteins, and is more efficiently replicated than is the parental DNA not so associated. Most of the progeny DNA is also found with the replicative complex. The 5-bromodeoxyuridine of heavy phage DNA is debrominated by UV irradiation, resulting in uracil which is removed by host uracil glycosylase. Unlike the simple gap-filling repair synthesis after infection with UV-irradiated light phage, the repair replication of UV-irradiated heavy phage is extensive as determined by density shift of the parental label in CsC1 gradients. The newly synthesized segments are covalently attached to the parental fragments. The repair replication takes place even in the presence of chloramphenicol, a protein synthesis inhibitor, suggesting it is host mediated. Furthermore, the extent of the repair replication is greater at higher doses of UV irradiation applied to the heavy phage. This abundant synthesis results ultimately in dispersion of the parental sequences as short stretches in the midst of long segments of newly synthesized progeny DNA. Together, the extensive replication and the resulting distribution pattern of parental sequences, without significant solubilization of parental label, are most consistent with a model of repair synthesis in which the leading strand displaces, rather than ligates to, the encountered 5' end.     

Improved oligonucleotide site-directed mutagenesis using M13 vectors.

An improved method is described for the construction of mutations in M13 vectors using synthetic oligonucleotides. The DNA is first cloned into a novel M13 vector (based upon M13mp18 or M13mp19), which carries a genetic marker that can be selected against, such as an EcoK or EcoB site, or an amber mutation in an essential phage gene. In this "coupled priming" technique, one primer is used to construct the silent mutation of interest, and a second primer is used to eliminate the selectable marker on the minus strand. After primer extension and ligation, the heteroduplex DNA is transfected into a strain of E. coli which is repair deficient and selects against the plus strand marker. Over 50 mutants have been constructed with this approach, and the yields can be excellent (up to 70%). For the stepwise construction of mutations using separate rounds of mutagenesis, the EcoK and EcoB markers offer a particular advantage over the amber marker. They permit selection in each round, as it is possible to cycle between the two markers. However for construction of multiple mutations over a short region, long synthetic oligonucleotides with multiple mismatches to the template can offer an alternative strategy.     

Replication of bacteriophage M13. 8. Differential effects of rifampicin and nalidixic acid on the synthesis of the two strands of M13 duplex DNA

Replication of bacteriophage M13 replicative forms is inhibited by rifampicin, an antibiotic that specifically inhibits the Escherichia coli RNA polymerase, and by nalidixic acid, an inhibitor of phage and bacterial DNA replication. Synthesis of the M13 complementary strand during RF³ replication was at least tenfold more sensitive to inhibition by rifampicin and by nalidixic acid than was that of the viral strand. Since M13 complementary strand synthesis is relatively insensitive to chloramphenicol, an inhibitor of protein synthesis, its inhibition by rifampicin suggests that complementary strands are initiated during RF replication by an RNA priming mechanism similar to that involved in parental RF formation. The nalidixic acid-sensitivity of complementary strand synthesis during RF replication clearly distinguishes this process from the nalidixic acid-resistant formation of the parental complementary strand in the conversion of the infecting single strand to RF.Production of progeny viral strands is indirectly affected by rifampiein in two ways. It prevents the conversion of supercoiled RF (RFI) to the open form (RFII), an essential step both in RF replication and in single-strand synthesis. In addition, rifampiein interferes with the expression of gene 5, an M13 gene function required for the accumulation of progeny viral strands.     

Insights into strand displacement and processivity from the crystal structure of the protein-primed DNA polymerase of bacteriophage phi29

The DNA polymerase from phage phi29 is a B family polymerase that initiates replication using a protein as a primer, attaching the first nucleotide of the phage genome to the hydroxyl of a specific serine of the priming protein. The crystal structure of phi29 DNA polymerase determined at 2.2 A resolution provides explanations for its extraordinary processivity and strand displacement activities. Homology modeling suggests that downstream template DNA passes through a tunnel prior to entering the polymerase active site. This tunnel is too small to accommodate double-stranded DNA and requires the separation of template and nontemplate strands. Members of the B family of DNA polymerases that use protein primers contain two sequence insertions: one forms a domain not previously observed in polymerases, while the second resembles the specificity loop of T7 RNA polymerase. The high processivity of phi29 DNA polymerase may be explained by its topological encirclement of both the downstream template and the upstream duplex DNA.     

Dissociative properties of the proteins within the bacteriophage T4 replisome

DNA replication is a highly processive and efficient process that involves the coordination of at least eight proteins to form the replisome in bacteriophage T4. Replication of DNA occurs in the 5' to 3' direction resulting in continuous replication on the leading strand and discontinuous replication on the lagging strand. A key question is how a continuous and discontinuous replication process is coordinated. One solution is to avoid having the completion of one Okazaki fragment to signal the start of the next but instead to have a key step such as priming proceed in parallel to lagging strand replication. Such a mechanism requires protein elements of the replisome to readily dissociate during the replication process. Protein trapping experiments were performed to test for dissociation of the clamp loader and primase from an active replisome in vitro whose template was both a small synthetic DNA minicircle and a larger DNA substrate. The primase, clamp, and clamp loader are found to dissociate from the replisome and are continuously recruited from solution. The effect of varying protein concentrations (dilution) on the size of Okazaki fragments supported the protein trapping results. These findings are in accord with previous results for the accessory proteins but, importantly now, identify the primase as dissociating from an active replisome. The recruitment of the primase from solution during DNA synthesis has also been found for Escherichia coli but not bacteriophage T7. The implications of these results for RNA priming and extension during the repetitive synthesis of Okazaki fragments are discussed.     

Interaction of the bacteriophage T4 gene 59 helicase loading protein and gene 41 helicase with each other and with fork, flap, and cruciform DNA

Bacteriophage T4 gene 59 helicase loading protein accelerates the loading of T4 gene 41 DNA helicase and is required for recombination-dependent DNA replication late in T4 phage infection. The crystal structure of 59 protein revealed a two-domain alpha-helical protein, whose N-terminal domain has strong structural similarity to the DNA binding domain of high mobility group family proteins (Mueser, T. C., Jones, C. E., Nossal, N. G., and Hyde, C. C. (2000) J. Mol. Biol. 296, 597-612). We have previously shown that 59 protein binds preferentially to fork DNA. Here we show that 59 protein binds to completely duplex forks but cannot load the helicase unless there is a single-stranded gap of more than 5 nucleotides on the fork arm corresponding to the lagging strand template. Consistent with the roles of these proteins in recombination, we find that 59 protein binds to and stimulates 41 helicase activity on Holliday junction DNA, and on a substrate that resembles a strand invasion structure. 59 protein forms a stable complex with wild type 41 helicase and fork DNA in the presence of adenosine 5'-O-(thiotriphosphate). The unwinding activity of 41 helicase missing 20 C-terminal amino acids is not stimulated by 59 protein, and it does not form a complex with 59 protein on fork DNA.     

Initiation of DNA synthesis in the transfer origin region of RK2 by the plasmid-encoded primase: detection using defective M13 phage

The broad host range IncP (IncP1) plasmids of gram-negative bacteria encode DNA primases that are involved in conjugal DNA synthesis. The primase of RK2/RP4 is required for efficient DNA transfer to certain gram-negative bacteria, indicating that the enzyme primes complementary strand synthesis in the recipient. In vitro, the primase initiates synthesis of oligoribonucleotides at 3'-dGdT-5' dinucleotides on the template strand. In this report, replication-defective M13 phage are used to assay the ability of the RK2-encoded primase to initiate complementary strand synthesis in vivo on single-strand templates containing the RK2 origin of conjugal transfer (oriT) or the RK2 origin of vegetative replication (oriV). The results show that sequences from either strand of the oriT region serve as efficient substrates for the RK2 primase and can enhance the growth of the defective M13 vectors delta E101 and delta Elac to levels approaching wild-type. The primise-oriT interaction appeared specific, since neither the oriV sequence nor another RK2 region, trfB, significantly enhanced growth of the defective phage, either in the presence or in the absence of the primase. In contrast to ColEl and F, this study also shows that the oriV region of RK2 lacks sites that are recognized by the host-specified DNA priming systems. The results suggest that the oriT region contains sites on both DNA strands that are efficient substrates for the plasmid-encoded primase, facilitating initiation of complementary strand DNA synthesis in both donor and recipient during conjugation.     

Construction of viable and lethal mutations in the origin of bacteriophage 'phi' X174 using synthetic oligodeoxyribonucleotides

Six different synthetic deoxyhexadecamers complementary to the origin of bacteriophage φX174, corresponding to nucleotides 4299 to 4314, except for one preselected nucleotide change were used as primers for DNA synthesis on wild-type φX² DNA as a template. DNA synthesis was performed with Escherichia coli DNA polymerase I (Klenow fragment) in the presence of DNA ligase. Heteroduplex RFIV DNA was isolated and, after limited digestion with DNAase I, complementary strands containing the mutant primers were isolated. The biological activity of these complementary strands was assayed in spheroplasts. Spheroplasts were made from E. coli K58 ung^? (uracil N-glycosylase) to prevent degradation of the complementary strands caused by uracil incorporation (Baas et al., 1980a).Using (5′-³²P) end-labeled primers, it was shown that all tested DNA polymerase preparations, including phage T4 DNA polymerase, contained variable amounts of 5′ → 3′ exonuclease activity. This nick translation activity may result in removal of the mutation in the primers, and therefore in isolation of wild-type complementary DNA instead of mutant complementary DNA.Restriction enzyme analysis of completed RFIV DNA showed that the primers can initiate DNA synthesis at more than one place on the φX174 genome. These complications result in a mixed population of complementary strand DNAs synthesized in vitro. Nevertheless, the desired mutants were picked up with high frequency using a selection test that is based on the difference in ultraviolet light sensitivity of homoduplex and heteroduplex φX174 RF DNA. Heteroduplex φX174 RF DNA is two to three times more sensitive to ultraviolet light irradiation than is homoduplex φX174 RF DNA (Baas &; Jansz, 1971,1972). Phage DNA derived from single plaque lysates of two of the six mutant complementary strand DNA preparations yielded, after annealing with wild-type complementary strand DNA, heteroduplex DNA with high frequency. DNA sequence analysis in the origin region of RF DNA obtained from these two phage preparations revealed the presence of the expected mutation. RFI DNA of these two origin mutants was nicked by φX174 gene A protein in the same way as wild-type φX174 RFI DNA.Phage DNA derived from single plaque lysates of the other four mutant complementary strand DNA preparations yielded exclusively homoduplex DNA after annealing with wild-type complementary strand DNA. It is concluded that priming with these deoxyhexadecamers resulted in the synthesis of complementary φX174 DNA with lethal mutations. The implications of these results, the construction of two silent, viable φX174 origin mutants and the failure to detect four others, for the initiation mechanism of φX174 RF DNA replication are discussed.     

Gene X of bacteriophage f1 is required for phage DNA synthesis. Mutagenesis of in-frame overlapping genes

The gene II protein of bacteriophage f1 is a site-specific endonuclease required for initiation of phage viral strand DNA synthesis. Within gene II is another gene, X, encoding a protein of unknown function identical to the C-terminal 27% of the gene II protein, and separately translated from codon 300 (AUG) of gene II. By oligonucleotide mutagenesis, we constructed phage mutants in which this codon has been changed to UAG (amber) or UUG (leucine), and propagated them on cells carrying a cloned copy of gene X on a plasmid. The amber mutant makes no gene X protein, and cannot grow in the absence of the complementing plasmid; the leucine-inserting mutant can make gene X protein, and grows normally without the plasmid. Without gene X protein, phage DNA synthesis (particularly viral strand synthesis) is impaired. We discuss this finding in the context of other known in-frame overlapping genes (particularly genes A and A* of phage phi X174), many of which are also involved in the specific initiation of DNA synthesis, and suggest applications for the mutagenic strategy we employed.     

Initiation of lagging-strand synthesis for pBR322 plasmid DNA replication in vitro is dependent on primosomal protein i encoded by dnaT

The role of the primosome assembly and protein n' recognition site in replication of pBR322 plasmid was examined. The following evidence indicates that the primosome is involved in lagging-strand synthesis of pBR322 plasmid replication in vitro. Early replicative intermediates with newly synthesized leading strand, approximately 1 kilobase pair long, immediately downstream of the replication origin accumulate in products synthesized in extracts from a dnaT strain that lacks primosomal protein i or in wild-type extracts supplemented with anti-protein i antibody. These intermediates are converted efficiently into full-length DNA by addition of purified protein i. Consistent with the previously proposed role of the primosome (Arai, K. and Kornberg, A. (1981) Proc. Natl. Acad. Sci. U. S. A. 78, 69-73), an n' site on the lagging strand, but not on the leading strand, is required for efficient replication of the plasmid in vitro. Plasmids lacking an n' site on the lagging strand replicate only to a limited extent in vitro and early replicative intermediates carrying nascent leading strands are accumulated, although a portion of the intermediates complete replication to yield full-length DNA. The latter reaction is completely inhibited by addition of anti-protein i antibody. Insertion of the n' site of phage phi X174 into pBR322 plasmids lacking lagging-strand n' sites restores the replicative ability of the mutant plasmid comparable to that of the wild-type plasmid. These results indicate that protein i is essential for lagging-strand synthesis of pBR322 plasmid in vitro and that it may play an important role in the priming events as a part of either an n' site-dependent primosome or an n' site-independent, as yet unidentified, priming complex.