Host cell DNA chain initiation protein requirements for replication of bacteriophage G4 replicative-form DNA.

Bacteriophages G4ev1 and G4bs1 are simple temperature-resistant derivatives of wild-type G4 as demonstrated by restriction endonuclease analyses. The rate of replication of the duplex replicative-form DNA of these phages was normal in dnaB and dnaC mutants of the host, whereas the rate was markedly reduced in a dnaG host mutant at the restrictive temperature. We conclude that G4 duplex DNA replication requires the host cell dnaG protein, but not the dnaB and dnaC proteins. The reasons for the differences between our conclusions and those based on previously published data are documented and discussed.     

DNA requirements at the bacteriophage G4 origin of complementary-strand DNA synthesis.

An in vivo assay was used to define the DNA requirements at the bacteriophage G4 origin of complementary-strand DNA synthesis (G4 origin). This assay made use of an origin-cloning vector, mRZ1000, a defective M13 recombinant phage deleted for its natural origin of complementary-strand DNA synthesis. The minimal DNA sequence of the G4 genome sufficient for the restoration of normal M13 growth parameters was determined to be 139 bases long, located between positions 3868 and 4007. This G4-M13 construct was also found to give rise to proper initiation of complementary-strand synthesis in vitro. The cloned DNA sequence contains all the regions of potential secondary structure which have been implicated in primase-dependent replication initiation as well as additional sequence information. To address the role of one region which potentially forms a DNA secondary structure, the DNA sequence internal to the G4 origin was altered by site-directed mutagenesis. A 3-base insertion at the AvaII site as well as a 17-base deletion between the AvaI and AvaII sites both resulted in loss of origin function. The 17-base deletion was also generated within the G4 genome and found to dramatically reduce the infectious growth rate of the resulting phage. These results are discussed with respect to the role of the G4 origin as the recognition site for primase-dependent replication initiation and its possible role in stage II replication.     

The origin of DNA genomes and DNA replication proteins

In recent years, it has became clear that most proteins involved in cellular DNA precursor synthesis or DNA replication have been 'invented' more than once, indicating that the transition from RNA to DNA genomes was more complex than previously thought. Several authors have suggested that DNA viruses, which often encode their own version of these proteins, played an important role in this process. The nature of the genome of the last universal cellular ancestor (LUCA) -- that is, RNA or DNA, prokaryotic-like or eukaryotic-like -- remains in dispute. A hyperthermophilic LUCA would have suggested a circular, double-stranded DNA genome; however, recent data favor a mesophilic or moderately thermophilic LUCA.     

Properties of bacteriophage T4 proteins deficient in replication repair

An epistasis group of mutations engendering increased sensitivity to diverse DNA-damaging agents was described previously in bacteriophage T4. These mutations are alleles of genes 32 and 41, which, respectively, encode a single-stranded DNA-binding protein (gp32) and the replicative DNA helicase (gp41). The mechanism by which the lethality of DNA damage is mitigated is unknown but seems not to involve the direct reversal of damage, excision repair, conventional recombination repair, or translesion synthesis. Here we explore the hypothesis that the mechanism involves a switch in DNA primer extension from the cognate template to an alternative template, the just-synthesized daughter strand of the other parental strand. The activities of the mutant proteins are reduced about 2-fold (for gp32) or 4-fold (for gp41) in replication complexes catalyzing coordinated synthesis of leading and lagging strands, in binding single-stranded DNA, promoting DNA annealing, and promoting branch migration. In striking contrast, the mutant proteins are strongly impaired in promoting template switching, thus supporting the hypothesis of survival by template switching.     

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.     

The functional origin of bacteriophage f1 DNA replication. Its signals and domains

The origin of DNA replication of bacteriophage f1 functions as a signal, not only for initiation of viral strand synthesis, but also for its termination. Viral (plus) strand synthesis initiates and terminates at a specific site (plus origin) that is recognized and nicked by the viral gene II protein. Mutational analysis of the 5' side (upstream) of the origin of plus strand replication of phage f1 led us to postulate the existence of a set of overlapping functional domains. These included ones for strand nicking, and initiation and termination of DNA synthesis. Mutational analysis of the 3' side (downstream) of the origin has verified the existence of these domains and determined their extent. The results indicate that the f1 "functional origin" can be divided into two domains: (1) a "core region", about 40 nucleotides long, that is absolutely required for plus strand synthesis and contains three distinct but partially overlapping signals, (a) the gene II protein recognition sequence, which is necessary both for plus strand initiation and termination, (b) the termination signal, which extends for eight more nucleotides on the 5' side of the gene II protein recognition sequence, (c) the initiation signal that extends for about ten more nucleotides on the 3' side of the gene II protein recognition sequence; (2) a "secondary region", 100 nucleotides long, required exclusively for plus strand initiation. Disruption of the secondary region does not completely abolish the functionality of the f1 origin but does drastically reduce it (1% residual biological activity). We discuss a possible explanation of the fact that this region can be interrupted (e.g. f1, M13 cloning vectors) by large insertions of foreign DNA without significantly affecting replication.     

Plasmid models for bacteriophage T4 DNA replication: requirements for fork proteins.

Bacteriophage T4 DNA replication initiates from origins at early times of infection and from recombinational intermediates as the infection progresses. Plasmids containing cloned T4 origins replicate during T4 infection, providing a model system for studying origin-dependent replication. In addition, recombination-dependent replication can be analyzed by using cloned nonorigin fragments of T4 DNA, which direct plasmid replication that requires phage-encoded recombination proteins. We have tested in vivo requirements for both plasmid replication model systems by infecting plasmid-containing cells with mutant phage. Replication of origin and nonorigin plasmids strictly required components of the T4 DNA polymerase holoenzyme complex. Recombination-dependent plasmid replication also strictly required the T4 single-stranded DNA-binding protein (gene product 32 [gp32]), and replication of origin-containing plasmids was greatly reduced by 32 amber mutations. gp32 is therefore important in both modes of replication. An amber mutation in gene 41, which encodes the replicative helicase of T4, reduced but did not eliminate both recombination- and origin-dependent plasmid replication. Therefore, gp41 may normally be utilized for replication of both plasmids but is apparently not required for either. An amber mutation in gene 61, which encodes the T4 RNA primase, did not eliminate either recombination- or origin-dependent plasmid replication. However, plasmid replication was severely delayed by the 61 amber mutation, suggesting that the protein may normally play an important, though nonessential, role in replication. We deleted gene 61 from the T4 genome to test whether the observed replication was due to residual gp61 in the amber mutant infection. The replication phenotype of the deletion mutant was identical to that of the amber mutant. Therefore, gp61 is not required for in vivo T4 replication. Furthermore, the deletion mutant is viable, demonstrating that the gp61 primase is not an essential T4 protein.     

Initiation of DNA synthesis on the isolated strands of bacteriophage f1 replicative-form DNA.

Viral and complementary strand circular DNA molecules were isolated from intracellular bacteriophage f1 replicative-form DNA. Soluble protein extracts of Escherichia coli were used to examine the initiation of DNA synthesis on these DNA templates. The initiation of DNA synthesis on f1 viral strand DNA was catalyzed by E. coli DNA-dependent RNA polymerase, as was initiation of f1 viral strand DNA isolated from mature phage particles. The site of initiation was the same as that used in vivo. In contrast, no de novo initiation of DNA synthesis was detected on f1 complementary strand DNA. Control experiments demonstrated that the E. coli dnaB, dnaC, and dnaG initiation proteins were active under the conditions employed. The results suggest that the viral strand of the f1 replicative-form DNA molecule carries the same DNA synthesis initiation site as the viral strand packaged in mature phage, whereas the complementary strand of the replicative-form DNA molecule carries no site for de novo primer synthesis. These in vitro observations are consistent with the simple rolling circle model for f1 DNA replication in vivo proposed by Horiuchi and Zinder.     

DNA replication and head assembly in bacteriophage T4.

Phage DNA was accumulated in cells of E. coli B, infected with the phage T4DtsLB3 (gene 42), without the synthesis of late proteins (in the presence of chloramphenicol). Then (stage II), chloramphenicol was removed and further replication of the phage DNA suppressed with hydroxyurea and by simultaneously raising the temperature to 40 degrees. The media M9 or M9 with 1% amino acid were used; the times of addition of chloramphenicol and the hydroxyurea concentration were also varied. It was also shown that in medium M9, at stage II, chiefly early proteins were synthesized. In the medium containing amino acids, at stage II the following was observed: 1) DNA synthesis was entirely suppressed and a degradation of DNA occurred; 2) both early and late proteins were synthesized, with a predominance of the latter; 3) an assembly of the elements of the phage tails and capsids occurred without the neck and flagellum, and a small number of phage particles were also found; 4) the capsids, isolated in a sucrose density gradient after lysis with chloroform, contained the proteins Palt, P20, P23, P24, several unidentified proteins, and did not contain Pwac, P23, and P22, 5) the yield of viable phage varied from 0.05 to 15% per cell. Thus, the entire morphogenesis of T4 phage can occur without accompanying replication of phage DNA.     

The Bacillus subtilis bacteriophage SPP1 G39P delivers and activates the G40P DNA helicase upon interacting with the G38P-bound replication origin.

Initiation of Bacillus subtilis bacteriophage SPP1 replication requires the phage-encoded genes 38, 39 and 40 products (G38P, G39P and G40P). G39P, which does not bind DNA, interacts with the replisome organiser, G38P, in the absence of ATP and with the ATP-activated hexameric replication fork helicase, G40P. G38P, which specifically interacts with the phage replication origin (oriL) DNA, does not seem to form a stable complex with G40P in solution. G39P when complexed with G40P-ATP inactivates the single-stranded DNA binding, ATPase and unwinding activities of G40P, and such effects are reversed by increasing amounts of G38P. Unwinding of a forked substrate by G40P-ATP is increased about tenfold by the addition of G38P and G39P to the reaction mixture. The specific protein-protein interactions between oriL-bound G38P and the G39P-G40P-ATPgammaS complex are necessary for helicase delivery to the SPP1 replication origin. Formation of G38P-G39P heterodimers releases G40P-ATPgammaS from the unstable oriL-G38P-G39P-G40P-ATPgammaS intermediate. G40P-ATPgammaS binds to the origin region, the uncomplexed G38P fraction remains bound to oriL, and the G38P-G39P heterodimer is lost from the complex. We demonstrate that G39P is a component of an oligomeric nucleoprotein complex which plays an important role in the initiation of SPP1 replication.     

Unique hairpin structures occurring at the replication origin of phage G4 DNA

Recently we reported that a DNA fragment, GCCAAAGC, forms an extraordinarily stable hairpin structure with two G-C pairs at the terminus and A-A-A stacked structure. The sequence is present at the replication origin of bacteriophage G4 ssDNA, and so on. Several kinds of possible hairpin structures, corresponding to the replication origin of phage G4, were synthesized and their secondary structures were examined. It was found that the fragments are able to form interconvertible hairpin structures depending on the length of the base-paired regions. The hairpin structure consisting of GCGAAAGC was not digested by the exonuclease activity of T4 DNA polymerase and it was stable enough to be only minimally bound by a single-stranded DNA binding protein.     

DNA helicase requirements for DNA replication during bacteriophage T4 infection.

The lytic bacteriophage T4 uses multiple mechanisms to initiate the replication of its DNA. Initiation occurs predominantly at replication origins at early times of infection, but there is a switch to genetic recombination-dependent initiation at late times of infection. The T4 insertion-substitution system was used to create a deletion in the T4 dda gene, which encodes a 5'-3' DNA helicase that stimulates both DNA replication and recombination reactions in vitro. The deletion caused a delay in T4 DNA synthesis at early times of infection, suggesting that the Dda protein is involved in the initiation of origin-dependent DNA synthesis. However, DNA synthesis eventually reached nearly wild-type levels, and the final number of phages produced per bacterium was similar to that of the wild type. When the dda mutant phage also contained a mutation in T4 gene 59 (a gene normally required only for recombination-dependent DNA replication), essentially no DNA was synthesized. Recent in vitro studies have shown that the gene 59 protein loads a component of the primosome, the T4 gene 41 DNA helicase, onto DNA. A molecular model for replication initiation is presented that is based on our genetic data.     

Early intermediates in bacteriophage T4 DNA replication and recombination.

We investigated, by density gradients and subsequent electron microscopy, vegetative T4 DNA after single or multiple infection of Escherichia coli with wild-type T4. Our results can be summarized as follows. (i) After single infection (i.e., when early intermolecular recombination could not occur), most, if not all, T4 DNA molecules initiated the first round of replication with a single loop. (ii) After multiple infection, recombinational intermediates containing label from both parents first appeared as early as 1 min after the onset of replication, long before all parental DNA molecules had finished their first round and before secondary replication was detectable. (iii) At the same time, in multiple infections only, complex, highly branched concatemeric T4 DNA first appeared. (iv) Molecules in which two loops or several branches were arranged in tandem were only found after multiple infections. (v) Secondary loops within primary loops were seen after both single and multiple infections, but they were rare and many appeared off center. Thus, recombination in wild-type T4-infected cells occurred very early, and the generation of multiple tandem loops or branches in vegetative T4 DNA depended on recombination. These results are consistent with the previous finding (A. Luder and G. Mosig, Proc. Natl. Acad. Sci. U.S.A. 79:1101-1105, 1982) that most secondary growing points of T4 are not initiated from origin sequences but from recombinational intermediates. By these and previous results, the various DNA molecules that we observed are most readily explained as intermediates in DNA replication and recombination according to a model proposed earlier to explain various other aspects of T4 DNA metabolism (Mosig et al., p. 277-295, in D. Ray, ed., The Initiation of DNA Replication, Academic Press, Inc., New York, 1981).     

Interconvertible hairpin structure found in the replication origin of phage G4 single-stranded DNA

We found a synthetic GCGAAAGC fragment with a mobility greater than that of other oligodeoxyribonucleotides in gel electrophoresis to take on a stable hairpin structure possessing two terminal G-C base pairs. The GCGAAAGC sequence is also found in the replication origin of phage G4 single-stranded DNA, but the hairpin structure originally proposed differs from that of the GCGAAAGC fragment we have studied. Possibility of rearrangement of the secondary structure in the replication origin of phage G4 was examined in relation to its replication initiation mechanism.     

The role of DNA polymerase I-associated 5'-exonuclease in replication of coliphage M13 replicative-form DNA.

The conversion of both parental- and progeny-nascent open circular M13 RF DNA into covalently closed RF I is drastically reduced in an $\text{E. coli}$ mutant deficient in the 5′ → 3′ exonuclease associated with DNA polymerase I. The nascent progeny RF DNA also contains a significant proportion of fragments of smaller than unit length.     

A hypothesis for DNA viruses as the origin of eukaryotic replication proteins

The eukaryotic replicative DNA polymerases are similar to those of large DNA viruses of eukaryotic and bacterial T4 phages but not to those of eubacteria. We develop and examine the hypothesis that DNA virus replication proteins gave rise to those of eukaryotes during evolution. We chose the DNA polymerase from phycodnavirus (which infects microalgae) as the basis of this analysis, as it represents a virus of a primitive eukaryote. We show that it has significant similarity with replicative DNA polymerases of eukaryotes and certain of their large DNA viruses. Sequence alignment confirms this similarity and establishes the presence of highly conserved domains in the polymerase amino terminus. Subsequent reconstruction of a phylogenetic tree indicates that these algal viral DNA polymerases are near the root of the clade containing all eukaryotic DNA polymerase delta members but that this clade does not contain the polymerases of other DNA viruses. We consider arguments for the polarity of this relationship and present the hypothesis that the replication genes of DNA viruses gave rise to those of eukaryotes and not the reverse direction.