uvrA and recA mutations inhibit a site-specific transition produced by a single O6-methylguanine in gene G of bacteriophage phi X174.

Using site-specific mutagenesis, we have examined the mutagenic activity in vivo of O6-methylguanine or O6-n-butylguanine located at a preselected site in gene G of bacteriophage phi X174. The experiments were designed so that the phage mutant produced by a targeted transition from either of these alkylated derivatives would be recognizable by a simple plaque assay. Spheroplasts derived from normal and repair-deficient cells were transfected, and the lysates were screened for mutant virus. In cells with normal repair, DNA carrying the methylguanine produced the expected transition in 15% of the total phage; DNA carrying the butylguanine produced the same mutation in 0.3% of the phage. In cells deficient in excision repair (uvrA) the transition frequency went up by a factor of 8 for O6-butylguanine and down by a factor of 40 for O6-methylguanine. In cells deficient in recombination (recA), the transition frequency increased 1.5-fold for butylguanine and decreased by a factor of 8 for methylguanine. The data show that both methyl- and butylguanine produce site-directed transitions in phi X174; the transition occurs in recA cells; the frequency of the transition is influenced by both recA and uvrA mutations; the recA and uvrA mutations alter the transition frequency for methylguanine and butylguanine in opposite directions.     

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 synthesis of bacteriophage phi X174 by purified components.

An in vitro system capable of synthesizing infectious phi X174 phage particles was reconstituted from purified components. The synthesis required phi X174 supercoiled replicative form DNA, phi X174-encoded proteins A, C, J, and prohead, Escherichia coli DNA polymerase III holoenzyme, rep protein, and deoxyuridinetriphosphatase (dUTPase, dUTP nucleotidohydrolase, EC 3.6.1.23) as well as MgCl2, four deoxyribonucleoside triphosphates, and ATP. Phage production was coupled to the synthesis of viral single-stranded DNA. More than 70% of the synthesized particles sedimented at the position of mature phage in a sucrose gradient and associated with the infectivity. The simple requirement of the host proteins suggests that the mechanism of viral strand synthesis in the phage-synthesizing reaction resembles that of viral strand synthesis during the replication of replicative form DNA.     

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.     

Escherichia coli host factor required specifically for the phi X174 stage III reaction: in vitro identification and partial purification.

A cell-free extract prepared from phi X174-infected Escherichia coli cells sustained in vitro synthesis of viral DNA (stage III reaction) when supplemented with fraction II from uninfected cells. The reaction was dependent upon deoxyribonucleoside triphosphate, ATP, added phi X174 replicative form I DNA template, and the fraction II from uninfected cells. This reaction differed from the stage II reaction (semiconservative replication of duplex replicative form DNA) by the production of stable viral protein-DNA complexes sensitive to anti-phi X174 antiserum. Three types of protein-DNA complexes were identified, 50S, 92S, and a 114S complex that cobanded in CsCl and cosedimented in neutral sucrose gradients with a phi X174 phage marker. The sensitivity of these complexes to anti-phi X174 antiserum and Staphylococcus aureus provided a relatively rapid biochemical assay for direct measurement of the amount of DNA synthesized by the stage III reaction. With this assay, an E. coli factor (SIII) required specifically for the synthesis of viral protein-DNA complexes was identified and purified 200-fold from uninfected E. coli cells. The partially purified SIII factor was required for the synthesis of DNA and viral protein-DNA complexes in the phi X174-infected cell extracts and could not be replaced by rep protein, single-strand binding protein, or DNA polymerase III holoenzyme.     

Mutagenesis of bacteriophage T7 in vitro by incorporation of O6-methylguanine during DNA synthesis.

An in vitro system in which bacteriophage T7 DNA is replicated and efficiently packaged into procapsids to form viable phage has been used to examine mutagenesis. The fidelity of replication was assayed both by measuring reversion of an amber mutation in an essential gene and by generation of temperature-sensitive mutants among the phage produced in vitro. Under standard reaction conditions, the fidelity of DNA replication is about equal to that normally found in vivo. However, when O6-methyldeoxyguanosine triphosphate is included in the reaction, O6-methylguanine is incorporated into newly synthesized DNA and the mutation frequencies increase 10- to 70-fold over the control. These experiments demonstrate in vitro mutagenesis with the T7 DNA replication-packaging system and provide more direct evidence for the premutagenic role of O6-methylguanine.     

Infidelity of DNA synthesis associated with bypass of apurinic sites.

The mutagenic potential of apurinic sites in vivo has been studied by transfection of depurinated phi X174 DNA containing amber mutations into SOS-induced Escherichia coli spheroplasts. Mutagenicity is abolished by treatment of the depurinated DNA with an apurinic endonuclease from Hela cells, establishing the apurinic site as the mutagenic lesion. The frequency of copying apurinic sites in vitro was analyzed by measuring the extent of DNA synthesis using E. coli DNA polymerase I and avian myeloblastosis DNA polymerase. The inhibition of DNA synthesis by apurinic sites was less with avian myeloblastosis DNA polymerase, suggesting that this error-prone enzyme copies apurinic sites with greater frequency. Consistent with this conclusion is the observation that, upon transfection into (normal) spheroplasts, the reversion frequency of depurinated phi X174 am3 DNA copied with avian myeloblastosis virus DNA polymerase is much greater than that of the same DNA copied with E. coli DNA polymerase I. Sequence analysis of the DNA of 33 revertant phage produced by depurination indicates a preference for incorporation of deoxyadenosine opposite putative apurinic sites. The combined results indicate that mutagenesis resulting from apurinic sites is associated with bypass of these noncoding lesions during DNA synthesis.     

Replication of duplex DNA of phage phi X174 reconstituted with purified enzymes.

Replication of the covalently closed duplex replicative form (RF) of phage phi X174 DNA has been achieved by coupling two known enzyme systems: (i) synthesis of viral strand circles (SS) from RF, and (ii) conversion of SS to nearly complete RF (RF II). In this coupled system, activated RF (gene A . RF II complex) was a more efficient template and generated as many as 10 RF II molecules per RF input, at a rate commensurate with SS synthesis. The 11 proteins required for the two component systems were all needed in the coupled RF duplication system; no new factors were required. Single-stranded DNA binding protein was needed for RF duplication at only 4% the level needed in its stoichiometric participation in SS synthesis. In addition to RF II, more complex replicative forms appeared late in the reaction, and their possible origin is discussed.     

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.     

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.     

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.     

Clonal inheritance of the pattern of DNA methylation in mouse cells.

DNA-mediated gene transfer was used to investigate the mode of inheritance of 5-methylcytosine in mouse L cells. Unmethylated phi X174 replicative form DNA remains unmethylated after its introduction and integration into these cells. On the other hand, phi X174 replicative form DNA that was methylated in vitro at its C-C-G-G residues retains these methylations as shown by restriction enzyme analysis with Hpa II and Msp I to detect methylation at this specific site. Although these unselected methylated vectors are prone to lose 30-40% of their methyl moieties upon transfection, this demethylation appears to be random. Once established, the resulting methylation pattern is stable for at least 100 cell generations. In order to examine the specificity of methylation inheritance, fully hemimethylated duplex phi X174 DNA was synthesized in vitro from primed single-strand phi X174 DNA by using 5-methyl deoxycytidine 5'-triphosphate. This molecule was inserted into mouse L cells by cotransformation and subsequently was analyzed by a series of restriction enzymes. Only methylations located at C-G residues were conserved after many generations of cell growth. The results suggest that the inheritance of the cellular DNA methylation pattern is based on a C-G-specific methylase that operates on newly replicated hemimethylated DNA.     

In vivo mutagenesis by O6-methylguanine built into a unique site in a viral genome.

The mutagenicity of O6-methylguanine (O6MeGua), a chemical carcinogen-DNA adduct, has been studied in vivo by using a single-stranded M13mp8 genome in which a single O6MeGua residue was positioned in the unique recognition site for the restriction endonuclease Pst I. Transformation of Escherichia coli MM294A cells with this vector gave progeny phage, of which 0.4% were mutated in their Pst I site. In a separate experiment, cellular levels of O6MeGua-DNA methyltransferase (an O6MeGua-repair protein) were depleted by treatment with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) prior to viral DNA uptake. In these cells, the mutation frequency due to O6MeGua increased with increasing MNNG dose (the highest mutation frequency observed was 20%). DNA sequence analysis of 60 mutant genomes revealed that O6MeGua induced exclusively G-to-A transitions.     

A mechanism of duplex DNA replication revealed by enzymatic studies of phage phi X174: catalytic strand separation in advance of replication.

The enzyme system for duplicating the duplex, circular DNA of phage phi X174 (replicative form) in stage II of the replicative life cycle was shown to proceed in two steps: synthesis of the viral (+) strand ]stage II(+)], followed by synthesis of the complementary (-) strand ]stage II(-)] [Eisenberg et al. (1976) Proc. Natl. Acad. Sci. USA 73, 3151-3155]. Novel features of the mechanism of the stage II(+) reaction have now been observed. The product, synthesized in extensive net quantities, is a covalently closed, circular, single-stranded DNA. The supercoiled replicative form I template and three of the four required proteins--the phage-induced cistron A protein (cis A), the host rep protein (rep), and the DNA polymerase III holoenzyme (holoenzyme)--act catalytically; the Escherichia coli DNA unwinding (or binding) protein binds the product stoichiometrically. In a reaction uncoupled from replication, cis A, rep, DNA binding protein, ATP, and Mg2+ separate the supercoiled replicative form I into its component single strands coated with DNA binding protein. In the presence of Mg2+, cis A, nicks the replicative form I; rep, ATP, and Mg2+ achieve strand separation with a concurrent cleavage of ATP and binding of DNA binding protein to the single strands. rep exhibits a single-stranded DNA-dependent ATPase activity. These observations suggest that the rep enzymatically melts the duplex at the replicating fork, using energy provided by ATP; this mechanism may apply to the replication of the E. coli chromosome as well.     

Enzymatic techniques for the isolation of random single-base substitutions in vitro at high frequency.

A general and efficient method has been developed to generate large numbers of single-base substitution mutations simply and rapidly. A unique f1 phage recombinant DNA cloning vector is described, which contains the phi X174 origin of viral strand DNA synthesis and allows one to direct mutagenesis to any specific segment of DNA. Gapped circular DNA is constructed by annealing viral single-stranded circular DNA [ss(c) DNA] with a mixture of linear duplex DNAs that have had their 3'-OH termini processively digested with Escherichia coli exonuclease III under conditions in which the resulting, newly generated 3'-OH termini present in the various hybrid molecules span the region of interest. Base changes are induced by misincorporation of an alpha-thiodeoxynucleoside triphosphate analog onto this primer-template, followed by DNA repair synthesis. The asymmetric segregation of mutants from wild-type sequences is accomplished by double-stranded replicative form DNA----ss(c) DNA synthesis in vitro, initiated from the phi X174 viral strand origin sequence present on the vector DNA. Mutated ss(c) DNA is screened by the dideoxy chain termination method. In one mutagenesis experiment, 21 independent single-base substitutions were isolated in a 72-nucleotide-long target region. DNA sequence analysis showed that all possible base transversions and transitions were represented.     

Repair of O6-methylguanine in adapted Escherichia coli.

Cells exposed to sublethal concentrations of simple alkylating agents develop resistance to their mutagenic effects. This results from the induction of a system that we have called the adaptive response. During exposure to N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), Escherichia coli cells induced for the adaptive response accumulate substantially less O6-methylguanine in their DNA than control cells. If O6-methylguanine does form, adapted cells possess a repair system for removing it from their DNA. The capacity of this system is limited and the system ceases to function when too much alkylation has occurred. From this point onwards O6-methylguanine starts to accumulate, and the cells begin to develop mutations at a rate directly proportional to their rate of O6-methylguanine accumulation. Our data support the idea that the O6 methylation of guanine accounts for most MNNG-induced mutagenesis.     

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.     

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.     

On the molecular mechanisms of transposition

We present a model for transposition that allows a choice between cointegrate formation (replicon fusion) and direct transposition. We propose that initiation of the process occurs by invasion of the target DNA by a single-stranded end of the transposable element. This leads to nicking of one of the DNA strands of the target molecule and ligation of this strand to that of the invading transposon. Transposition then occurs in a processive way by replication of the element from the invading end into the target site in a looped rolling-circle mode similar to replication of phage phi X174 replicative form to viral strand. The choice between cointegrate formation and direct transposition occurs at the nick-ligation step, which terminates the process. We suggest that the choice is determined by the topology of the transposition enzymes and could be related to whether the element generates five- or nine-base-pair repeats in the target DNA on insertion.     

A Coat Protein of the Bacteriophage M13 Virion Participates in Membrane-Oriented Synthesis of DNA

Several molecules of a protein specified by gene 3 of M13 comprise a minor fraction of the phage coat and have been assigned a role in adsorption to the bacterial cell. We find that the gene-3 protein molecules of the virion are fully conserved in phage that have attached irreversibly to the host cell, and they form a complex with the phage DNA when it has been converted to a duplex replicative form. In cells infected at a restrictive temperature with a thermosensitive mutant in gene 3, there is no conversion of the phage DNA to the replicative form. Both the adsorbed phage and the complex of replicative form DNA with the gene-3 protein were isolated with the inner membrane fraction of the cell. We suggest that the gene-3 protein may perform an essential function in the synthesis of replicative form by linking the phage DNA to a cellular replicative system in or on the inner cell membrane.