DNA sequences which support activities of the bacteriophage phi X174 gene A protein

The DNA sequence of 30 nucleotides which surrounds the origin of viral strand DNA replication is highly conserved amongst the icosahedral single-stranded DNA bacteriophages. The A gene of these phages encodes a protein which is required for initiation and termination of viral strand DNA synthesis and acts as a nicking-closing activity specifically within this 30-nucleotide sequence. A system of purified Escherichia coli host proteins and phi X174 gene A protein has been developed which specifically replicates in vitro the viral strand of phi X174 from RF (replicative form) I template DNA and yields single-stranded circular DNA products (RF leads to SS(c) DNA replication system). Recombinant plasmids carrying inserts derived from phage phi X174 or G4 DNA which range in length from 49 to 1175 base pairs and contain the 30-nucleotide conserved sequence have been shown to support phi X A protein-dependent DNA synthesis in vitro in this replication system. We report here that insertion of the 30-nucleotide sequence alone into pBR322 allows the resulting recombinant plasmids to support phi X A protein-dependent in vitro DNA synthesis as efficiently as phi X174 template DNA in the RF leads to SS(c) replication system. The 30-nucleotide sequence functions as a fully wild type DNA replication origin as determined by the rate of DNA synthesis and the structure of resulting DNA products. Furthermore, the DNA sequence requirements for nicking of RF I DNA by the phi X A protein and for supporting replication origin function have been partially separated. Homology to positions 1, 29, and 30 of the 30-nucleotide conserved sequence are not required for cleavage of RF I DNA by the A protein; homology to position 1 but not 29 or 30 is required for efficient DNA replication.     

Effect of SSB protein on cleavage of single-stranded DNA by phi X gene A protein and A* protein.

Gene A protein of bacteriophage phi X174 plays a role as a site-specific endonuclease in the initiation and termination of phi X rolling circle DNA replication. To clarify the sequence requirements of this protein we have studied the cleavage of single-stranded restriction fragments from phi X and G4 viral DNAs using purified gene A protein. The results show that in both viral DNAs cleavage occurs at the origin and at one additional site which shows striking sequence homology with the origin region. During rolling circle replication the single-stranded viral DNA tail is covered with single-stranded DNA binding (SSB) protein. Therefore, we have also studied the effect of SSB on phi X gene A protein cleavage. In these conditions only single-stranded fragments containing the complete or almost complete origin region of 30 bases are cleaved, whereas cleavage at the additional sites of phi X or G4 viral DNAs does not occur. A model for termination of rolling circle replication which is based on these findings is presented. Finally, we present evidence that the second product of gene A, the A* protein, cleaves phi X viral DNA at the additional cleavage site in the presence of SSB, not only in vitro but also in vivo. The functional significance of this cleavage in vivo is discussed.     

Cleavage of single-stranded DNA by the A and A* proteins of bacteriophage phi X174.

The purified A protein and A* protein of bacteriophage phi X174 have been tested for endonuclease activity on single stranded viral phi X174 DNA. The A protein (55.000 daltons) nicks single-stranded DNA in the same way and at the same place as it does superhelical RFI DNA, at the origin of DNA replication. The A* protein (37.000 daltons) can cleave the single-stranded viral DNA at many different sites. It has however a strong preference for the origin of replication. Both proteins generate 3'OH ends and blocked 5' termini at the nick site.     

Analysis of bacteriophage phi X174 gene A protein-mediated termination and reinitiation of phi X DNA synthesis. I. Characterization of the termination and reinitiation reactions

The phi X174 (phi X) gene A protein-mediated termination and reinitiation of single-stranded circular (SS(c] phi X viral DNA synthesis in vitro were directly and independently analyzed. Following incubation together with purified DNA replication enzymes from Escherichia coli, ATP, [alpha-32P]dNTPs, and either the phi X A protein and phi X replicative form I (RF I) DNA, or the purified RF II X A complex, the phi X A protein was detected covalently linked to newly synthesized 32P-labeled DNA. Formation of the phi X A protein-[32P]DNA covalent complex required all the factors necessary for phi X (+) SS(c) DNA synthesis in vitro. Thus, it was a product of the reinitiation reaction and an intermediate of the replication cycle. Identification of this complex provided direct evidence that reinitiation of phi X (+) strand DNA synthesis involved regeneration of the RF II X A complex. Substitution of 2',3'-dideoxyguanosine triphosphate (ddGTP) for dGTP in reaction mixtures resulted in the formation of covalent phi X A protein 32P-oligonucleotide complexes; these complexes were trapped analogues of the regenerated RF II X A complex. They could not act catalytically due to the presence of ddGMP residues at the 3'-termini of the oligonucleotide moieties. Reaction mixtures containing ddGTP also yielded nonradioactive (+) SS(c) DNA products derived from circularization of the displaced (+) strand of the input parental template DNA. The formation of the phi X A protein-32P-oligonucleotide complexes and nonradioactive (+) SS(c) DNA were used to assay both reinitiation and termination reactions, respectively. Both reactions required DNA synthesis from the 3'-hydroxyl primer at nucleotide residue 4305 which was formed by cleavage of phi X RF I DNA by the phi X A protein. Elongation of this primer by 18, but not 11 nucleotides was sufficient to support each reaction. Reinitiation reactions proceeded rapidly and were essentially complete after 90 s. In contrast, when ddGTP was replaced with dGTP in reaction mixtures, DNA synthesis proceeded with linear kinetics for up to 10 min. These results suggested that in the presence of all four dNTPs, active templates supported more than 40 rounds of DNA synthesis.     

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

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

Regions of incompatibility in single-stranded DNA bacteriophages phi X174 and G4.

The intracellular presence of a recombinant plasmid containing the intercistronic region between the genes H and A of bacteriophage phi X174 strongly inhibits the conversion of infecting single-stranded phi X DNA to parental replicative-form DNA. Also, transfection with single-stranded or double-stranded phi X174 DNA of spheroplasts from a strain containing such a "reduction" plasmid shows a strong decrease in phage yield. This phenomenon, the phi X reduction effect, was studied in more detail by using the phi X174 packaging system, by which plasmid DNA strands that contain the phi X(+) origin of replication were packaged as single-stranded DNA into phi X phage coats. These "plasmid particles" can transduce phi X-sensitive host cells to the antibiotic resistance coded for by the vector part of the plasmid. The phi X reduction sequence in the resident plasmid strongly affected the efficiency of the transduction process, but only when the transducing plasmid depended on primosome-mediated initiation of DNA synthesis for its conversion to double-stranded DNA. The combination of these results led to a model for the reduction effect in which the phi X reduction sequence interacted with an intracellular component that was present in limiting amounts and that specified the site at which phi X174 replicative-form DNA replication takes place. The phi X reduction sequence functioned as a viral incompatibility element in a way similar to the membrane attachment site model for plasmid incompatibility. In the DNA of bacteriophage G4, a sequence with a similar biological effect on infecting phages was identified. This reduction sequence not only inhibited phage G4 propagation, but also phi X174 infection.     

Initiation and termination of the bacteriophage phi X174 rolling circle DNA replication in vivo: packaging of plasmid single-stranded DNA into bacteriophage phi X174 coats.

The bacteriophage phi X174 viral (+) origin when inserted in a plasmid can interact in vivo with the A protein produced by infecting phi X174 phages. A consequence of this interaction is packaging of single-stranded plasmid DNA into preformed phage coats resulting in infective particles (1). This property was used to study morphogenesis and to analyse the signals for initiation and termination of the rolling circle DNA replication in vivo. It is shown that the size of the DNA had a strong effect on the encapsidation by the phage coats and the infectivity of the particle. Termination was analysed by using plasmids with two phi X (+) origins either in the same orientation or in opposite orientation. Both origins were used with equal frequency. Initiation at one origin resulted in very efficient termination (greater than 96%) at the second origin in the case of two origins in the same orientation. When the two (+) origins have opposite orientations, no correct termination was observed. The second origin in the opposite strand effectively inhibits (greater than 98%) the normal DNA synthesis; i.e. the covalently bound A protein present in the replication fork interacts with the (+) origin sequence in the opposite strand.     

The interaction of Escherichia coli replication factor Y with complementary strand origins of DNA replication. Contact points revealed by DNase footprinting and protection from methylation

A defined region of the viral (+) strand of phi X174 and of each strand of pBR322 DNA serves as an effector for the ATPase activity of replication factor Y from Escherichia coli. These loci can also function as complementary strand origins of DNA replication in a single-stranded circular leads to replicative form pathway whose protein requirements are characteristic of phi X174 DNA. Despite this functional similarity, these three sites possess no extensive sequence homology. To uncover a possible common structural determinant, factor Y recognition sequences were treated with pancreatic DNase or dimethyl sulfate in the presence and absence of this replication protein. When factor Y was present, the action of the nuclease was altered in a similar manner on each of the three templates, indicating that factor Y was bound to the entire length of its effector site. Factor Y-mediated modification of the dimethyl sulfate methylation patterns gave evidence of specific, tight protein-DNA contacts. Protection maps, devised by plotting the results of the methylation and footprinting experiments on duplex structures, suggest that tertiary interactions are either involved in the formation of a factor Y effector site or are induced by the binding of the protein.     

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.     

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

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

Phi X 174 gene A protein does not cleave at a mouse mitochondrial DNA sequence homologous to the phi X and G4 cleavage site

The light strand origin of replication of mouse mitochondrial DNA contains a 30-nucleotide region which is 60% homologous to the 30-nucleotide conserved sequence in φX174 and G4 viral DNAs known to contain the viral gene A protein cleavage site. Gene A protein does not cleave closed circular mouse mitochondrial DNA under conditions in which φX174 closed circular DNA is cleaved.     

Mechanism of replication of bacteriophage phi X174. XXII. Site-specific mutagenesis of the A* gene reveals that A* protein is not essential for phi X174 DNA replication

The A and A* proteins of phage phi X174 are encoded in the same reading frame in the viral genome; the smaller A protein is the result of a translational start signal with the A gene. To differentiate their respective functions, oligonucleotide-directed site-specific mutagenesis was used to change the ATG start codon of the phi X 174 A* gene, previously cloned into pCQV2 under lambda repressor control, into a TAG stop codon. The altered A gene was then inserted back into phi X replicative form DNA to produce an amber mutant, phi XamA*. Two different Escherichia coli amber suppressor strains infected with this mutant produced viable progeny phage with only a slight reduction in yield. In Su+ cells infected with phi XamA*, phi X gene A protein, altered at one amino acid, was synthesized at normal levels; A* protein was not detectable. These observations indicate that the A* protein increases the replicative efficiency of the phage, perhaps by shutting down host DNA replication, but is not required for replication of phi X174 DNA or the packaging of the viral strand under the conditions tested.     

Replication of phage G4. A novel and simple system for the initiation of deoxyribonucleic acid synthesis.

Conversion in vitro of single-stranded circular DNA of phage G4 (related to phage phiX174) to the double-stranded replicative form (RF-II) depends on a novel and relatively simple group of three proteins: a priming protein of approximately 65,000 daltons, the DNA unwinding protein, and the DNA polymerase III holoenzyme. Stimulation by ATP and GTP suggests an RNA synthetic step in the priming of DNA synthesis. The synthetic strand in the RF-II contains a small gap at a unique position relative to the template strand; the 5' end of the gap is about 250 nucleotide residues (5% of the genome length) away from the single site of cleavage by a restriction endonuclease (Eco RI).     

Effect of phi X C protein on leading strand DNA synthesis in the phi X174 replication pathway

The influence of the bacteriophage phi X174 (phi X) C protein on the replication of bacteriophage phi X174 DNA has been examined. This small viral protein, which is required for the packaging of phi X DNA into proheads, inhibits leading strand DNA synthesis. The inhibitory effect of the phi X C protein requires a DNA template bearing an intact 30-base pair (bp) phi X origin of DNA replication that is the target site recognized by the phi X A protein. Removal of nucleotides from the 3' end of this 30-bp conserved origin sequence prevents the inhibitory effects of the phi X C protein. Leading strand replication of supercoiled DNA substrates containing the wild-type phi X replication origin results in the production of single-stranded circular DNA as well as the formation of small amounts of multimeric and sigma structures. These aberrant products are formed when the termination and reinitiation steps of the replication pathway reactions are skipped as the replication fork moves through the origin sequence. Replication carried out in the presence of the phi X C protein leads to a marked decrease in these aberrant structures. While the exact mechanism of action of the phi X C protein is not clear, the results presented here suggest that the phi X C protein slows the movement of the replication fork through the 30-bp origin sequence, thereby increasing the fidelity of the termination and reinitiation reactions. In keeping with the requirement for the phi X C protein for efficient packaging of progeny phi X DNA into proheads, the phi X C protein-mediated inhibition of leading strand synthesis is reversed by the addition of proteins essential for phi X bacteriophage formation. Incubation of plasmid DNA substrates bearing mutant 30 base pair phi X origin sequences in the complete packaging system results in the in vitro packaging and production of infectious particles in a manner consistent with the replication activity of the origin under study.     

The A* protein of phi X174 is an inhibitor of DNA replication

Extracts prepared from phi X174 infected E. coli cells inhibited in vitro RF replication The inhibition was dependent upon the presence of A* protein in the reaction and served as an assay to highly purify the A* protein. Purified A* protein bound tightly to duplex DNA as well as single-stranded DNA. The binding of the A* protein to duplex DNA inhibited (I) its single-stranded DNA specific endonucleolytic activity; (II) in vitro synthesis of viral (+) single stranded DNA on an A-RFII DNA complex template; (III) ATP hydrolysis by rep protein and unwinding of the strands of RF DNA. We propose that this inhibitory activity is responsible in vivo for the shut off of E. coli chromosome replication during phi X174 infection, and has a role in the transition from semiconservative RF DNA replication to single-stranded DNA synthesis in the life cycle of phi X174.     

Two juxtaposed tyrosyl-OH groups participate in phi X174 gene A protein catalysed cleavage and ligation of DNA.

Bacteriophage phi X174 encoded gene A protein is an enzyme required for initiation and termination of successive rounds of rolling circle phi X DNA replication. This enzyme catalyses cleavage and ligation of a phosphodiester bond between nucleotide residues G and A at the phi X origin. The cleavage reaction which occurs during initiation involves formation of a free GOH residue at one end and a covalent bond between tyrosine-OH of the gene A protein and 5' phosphate of the A residue, at the other end of the cleavage site. During termination the covalently bound gene A protein cleaves the phosphodiester bond between G and A at the regenerated origin and ligates the 3' and 5' ends of the displaced genome-length viral DNA to form a circle. Since tyrosyl-OH mediated rearrangements of phosphodiester bonds in DNA may also apply to other enzymes involved in replication or recombination such as topoisomerases we have studied this interesting mechanism in greater detail. Analysis of 32P-labelled gene A protein-DNA complex by tryptic digestion followed by sequencing of 32P-containing peptides showed that two tyrosyl residues in the repeating sequence tyr-val-ala-lys-tyr-val-asn-lys participate in phosphodiester bond cleavage. Either one of these tyrosyl residues can function as the acceptor of the DNA chain. In an alpha-helix the side chains of these tyrosyl residues are in juxtaposition. An enzymatic mechanism is proposed in which these two tyrosyl-OH groups participate in an alternating manner in successive cleavage and ligations which occur during phosphodiester bond rearrangements of DNA.     

RNA priming of DNA replication by bacteriophage T4 proteins

Bacteriophage T4 DNA replication proteins have been shown previously to require ribonucleoside triphosphates to initiator new DNA chains on unprimed single-stranded DNA templates in vitro. This DNA synthesis requires a protein controlled by T4 gene 61, as well as the T4 gene 41, 43 (DNA polymerase), 44, 45, and 62 proteins, and is stimulated by the gene 32 (helix-destabilizing) protein. In this paper, the nature of the RNA primers involved in DNA synthesis by the T4 proteins has been determined, using phi X174 and f1 DNA as model templates. The T4 41 and "61" proteins synthesize pentanucleotides with the sequence pppA-C(N)3 where N in positions 3 and 4 can be G, U, C, or A. The same group of sequences is found in the RNA at the 5' terminus of the phi X174 DNA product made by the seven T4 proteins. The DNA product chains begin at multiple discrete positions on the phi X174 DNA template. The characteristics of the T4 41 and "61" protein priming reaction are thus appropriate for a reaction required to initiate the synthesis of discontinuous "Okazaki" pieces on the lagging strand during the replication of duplex DNA.     

φX174 gene A protein does not cleave at a mouse mitochondrial DNA sequence homologous to the φX and G4 cleavage site

The light strand origin of replication of mouse mitochondrial DNA contains a 30-nucleotide region which is 60% homologous to the 30-nucleotide conserved sequence in φX174 and G4 viral DNAs known to contain the viral gene A protein cleavage site. Gene A protein does not cleave closed circular mouse mitochondrial DNA under conditions in which φX174 closed circular DNA is cleaved.     

Studies of the recognition sequence of phi X174 gene A protein. Cleavage site of phi X gene A protein in St-1 RFI DNA.

It is already known that phi X gene A protein converts besides phi X RFI DNA also the RFI DNAs of the single-stranded bacteriophages G4, St-1, alpha 3 and phi K into RFII DNA. We have extended this observations for bacteriophages G14 and U3. Restriction enzyme analysis placed the phi X gene A protein cleavage site in St-1 RF DNA in the HinfI restriction DNA fragment F10 and in the overlapping HaeIII restriction DNA fragment Z7. The exact position and the nucleotide sequence at the 3'-OH end of the nick were determined by DNA sequence analysis of the single-stranded DNA subfragment of the nicked DNA fragment F10 obtained by gelelectrophoresis in denaturing conditions. A stretch of 85 nucleotides of St-1 DNA around the position of the phi X gene A protein cleavage site was established by DNA sequence analysis of the restriction DNA fragment Z7F1. Comparison of this nucleotide sequence with the previously determined nucleotide sequence around the cleavage site of phi X gene A protein in phi X174 RF DNA and G4 RF DNA revealed an identical sequence of only 10 nucleotides. The results suggest that the recognition sequence of the phi X174 gene A protein lies within these 10 nucleotides.     

Nucleotide sequences at the phi X gene A protein cleavage site in replicative form I DNAs of bacteriophages U3, G14, and alpha 3

Gene A protein, a bacteriophage phi X174-encoded endonuclease involved in phi X replicative form (RF) DNA replication, nicks not only phi X RFI DNA but also RFI DNAs of several other spherical single-stranded DNA bacteriophages. The position of the phi X gene A protein nick and the nucleotide sequence surrounding this site in RF DNAs of the bacteriophages U3, G14, and alpha 3 were determined. Comparison of the nucleotide sequences which surround the nick site of the gene A protein in RF DNAs of phi X174, G4, St-1, U3, G14, and alpha 3 revealed that a strongly conserved 30-nucleotide stretch occurred in RF DNAs of all six phages. However, perfect DNA sequence homology around this site was only 10 nucleotides, the decamer sequence CAACTTGATA. The present results support the hypothesis that, for nicking of double-stranded supercoiled DNA by the phi X gene A protein, the presence of the recognition sequence CAACTTGATA and a specific gene A protein binding sequence upstream from the recognition sequence are required. The sequence data obtained so far from phages U3, G14, St-1, and alpha 3 have been compared with the nucleotide sequences and amino acid sequences of both phi X and G4. According to this comparison, the evolutionary relationship between phages G4, U3, and G14 is very close, which also holds for phages alpha 3 and St-1. However, the two groups are only distantly related, both to each other and to phi X.