A new membrane-associated DNA replication protein, the gene 69 product of bacteriophage T4, shares a patch of homology with the Escherichia coli dnaA protein

A new phage T4 DNA replication protein, gp69, is found to be associated with membrane fractions, as predicted by the translated base sequence of gene 69. In addition, gp69 shares a patch of homology with a segment of the Escherichia coli dnaA initiation protein. The patchy homology of dnaA protein and gp69 suggests that they may serve some similar functions, such as interactions with the same E. coli components in bacterial and viral DNA replication. We have shown before that gene 69 spans an origin of T4 DNA replication, and that this origin is preferentially associated with membrane fractions. We suggest the possibility that gp69 is involved in the attachment of this origin to the bacterial envelope.     

Regulation of Expression of Cloned Bacteriophage T4 Late Gene 23

The parameters governing the activity of the cloned T4 gene 23, which codes for the major T4 head protein, were analyzed. Suppressor-negative bacteria carrying wild-type T4 gene 23 cloned into plasmid pCR1 or pBR322 were infected with T4 gene 23 amber phage also carrying mutations in the following genes: (i) denA and denB (to prevent breakdown of plasmid DNA after infection) and (ii) denA, denB, and, in addition, 56 (to generate newly replicated DNA containing dCMP) and alc/unf (because mutations in this last gene allow late genes to be expressed in cytosine-containing T4 DNA). Bacteria infected with these phage were labeled with (14)C-amino acids at various times after infection, and the labeled proteins were separated by one-dimensional gel electrophoresis so that the synthesis of plasmid-coded gp23 could be compared with the synthesis of other, chromosome-coded T4 late proteins. We analyzed the effects of additional mutations that inactivate DNA replication proteins (genes 32 and 43), an RNA polymerase-binding protein (gene 55), type II topoisomerase (gene 52), and an exonuclease function involved in recombination (gene 46) on the synthesis of plasmid-coded gp23 in relation to chromosome-coded T4 late proteins. In the denA:denB:56:alc/unf genetic background, the phage chromosome-borne late genes followed the same regulatory rules (with respect to DNA replication and gp55 action) as in the denA:denB genetic background. The plasmid-carried gene 23 was also under gp55 control, but was less sensitive than the chromosomal late genes to perturbations of DNA replication. Synthesis of plasmid-coded gp23 was greatly inhibited when both the type II T4 topoisomerase and the host's DNA gyrase are inactivated. Synthesis of gp23 was also substantially affected by a mutation in gene 46, but less strongly than in the denA:denB genetic background. These observations are interpreted as follows. The plasmid-borne T4 gene 23 is primarily expressed from a late promoter. Expression of gene 23 from this late promoter responds to an activation event which involves some structural alteration of DNA. In these respects, the requirements for expressing the plasmid-borne gene 23 and chromosomal late genes are very similar (although in the denA:denB:56:alc/unf genetic background, there are significant quantitative differences). For the plasmid-borne gene 23, activation involves the T4 gp46, a protein which is required for DNA recombination. However, for the reasons presented in the accompanying paper (Jacobs et al., J. Virol. 39:31-45, 1981), we conclude that the activation of gene 23 does not require a complete breakage-reunion event which transposes that gene to a later promoter on the phage chromosome. Ways in which gp46 may actually be involved in late promoter activation on the plasmid are discussed.     

Effect of single-stranded DNA-binding proteins on the helicase and primase activities of the bacteriophage T7 gene 4 protein

Gene 4 protein (gp4) of bacteriophage T7 provides two essential functions at the T7 replication fork, primase and helicase activities. Previous studies have shown that the single-stranded DNA-binding protein of T7, encoded by gene 2.5, interacts with gp4 and modulates its multiple functions. To further characterize the interactions between gp4 and gene 2.5 protein (gp2.5), we have examined the effect of wild-type and altered gene 2.5 proteins as well as Escherichia coli single-stranded DNA-binding (SSB) protein on the ability of gp4 to synthesize primers, hydrolyze dTTP, and unwind duplex DNA. Wild-type gp2.5 and E. coli SSB protein stimulate primer synthesis and DNA-unwinding activities of gp4 at low concentrations but do not significantly affect single-stranded DNA-dependent hydrolysis of dTTP. Neither protein inhibits the binding of gp4 to single-stranded DNA. The variant gene 2.5 proteins, gp2.5-F232L and gp2.5-Delta26C, inhibit primase, dTTPase, and helicase activities proportional to their increased affinities for DNA. Interestingly, wild-type gp2.5 stimulates the unwinding activity of gp4 except at very high concentrations, whereas E. coli SSB protein is highly inhibitory at relative low concentrations.     

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.     

Nucleotide sequence from the genetic left end of bacteriophage T7 DNA to the beginning of gene 4

The nucleotide sequence running from the genetic left end of bacteriophage T7 DNA to within the coding sequence of gene 4 is given, except for the internal coding sequence for the gene 1 protein, which has been determined elsewhere. The sequence presented contains nucleotides 1 to 3342 and 5654 to 12,100 of the approximately 40,000 base-pairs of T7 DNA. This sequence includes: the three strong early promoters and the termination site for Escherichia coli RNA polymerase: eight promoter sites for T7 RNA polymerase; six RNAase III cleavage sites; the primary origin of replication of T7 DNA; the complete coding sequences for 13 previously known T7 proteins, including the anti-restriction protein, protein kinase, DNA ligase, the gene 2 inhibitor of E. coli RNA polymerase, single-strand DNA binding protein, the gene 3 endonuclease, and lysozyme (which is actually an N-acetylmuramyl-l-alanine amidase); the complete coding sequences for eight potential new T7-coded proteins; and two apparently independent initiation sites that produce overlapping polypeptide chains of gene 4 primase. More than 86% of the first 12,100 base-pairs of T7 DNA appear to be devoted to specifying amino acid sequences for T7 proteins, and the arrangement of coding sequences and other genetic elements is very efficient. There is little overlap between coding sequences for different proteins, but junctions between adjacent coding sequences are typically close, the termination codon for one protein often overlapping the initiation codon for the next. For almost half of the potential T7 proteins, the sequence in the messenger RNA that can interact with 16 S ribosomal RNA in initiation of protein synthesis is part of the coding sequence for the preceding protein. The longest non-coding region, about 900 base-pairs, is at the left end of the DNA. The right half of this region contains the strong early promoters for E. coli RNA polymerase and the first RNAase III cleavage site. The left end contains the terminal repetition (nucleotides 1 to 160), followed by a striking array of repeated sequences (nucleotides 175 to 340) that might have some role in packaging the DNA into phage particles, and an A · T-rich region (nucleotides 356 to 492) that contains a promoter for T7 RNA polymerase, and which might function as a replication origin.     

Initiation of DNA replication at cloned origins of bacteriophage T7

Bacteriophage T7 DNA replication is initiated at a site 15% of the distance from the genetic left end of the chromosome. This primary origin contains two tandem T7 RNA polymerase promoters (phi 1.1A and phi 1.1B) followed by an A + T-rich region. When the primary origin region is deleted replication initiates at secondary origins. We have analyzed the ability of plasmids containing cloned fragments of T7 to replicate after infection of Escherichia coli with bacteriophage T7. All cloned T7 fragments that support plasmid replication contain a T7 promoter but a T7 promoter alone is not sufficient for replication. Replication of plasmids containing the primary origin is dependent on T7 DNA polymerase and gene 4 protein (helicase/primase) and a portion of the A + T-rich region. The other T7 fragments that support plasmid replication after T7 infection are promoter regions phi OR, phi 13 and phi 6.5 (secondary origins). When both the primary and secondary origins are present simultaneously on compatible plasmids, replication of each is temporally regulated. Such regulation may play a role during T7 DNA replication.     

Protein determinants of RNA binding by DNA polymerase of the T4-related bacteriophage RB69

DNA polymerase (gp43) of phage T4 plays two biological roles, one as an essential DNA binding replication enzyme and the other as an mRNA-specific autogenous translational repressor. Binding of T4 gp43 to its mRNA target (translational operator RNA) interferes with gp43-DNA interactions, but it is unclear how the protein determinants for binding DNA are affected by the dynamics of gp43-mRNA interactions. We have used RB69 gp43, a natural variant of the T4 enzyme whose crystal structure has been determined to identify protein sites that respond to the interaction with specific RNA. We used protein phosphorylation markers, photocross-linking studies, protease sensitivity assays, and mutational analyses to examine the effects of operator RNA on the enzyme's five structural domains (N, exo, palm, fingers, and thumb). Our studies suggest that this RNA affects gp43-DNA interactions through global effects on protein structure that occlude DNA-binding sites but leave the enzyme accessible to interactions with the sliding clamp (RB69 gp45) and possibly other polymerase accessory proteins. We discuss the possible biological significance of putative RNA-binding motifs in the N and palm domains of RB69 gp43.     

Biochemical characterization of interactions between DNA polymerase and single-stranded DNA-binding protein in bacteriophage RB69

The organization and proper assembly of proteins to the primer-template junction during DNA replication is essential for accurate and processive DNA synthesis. DNA replication in RB69 (a T4-like bacteriophage) is similar to those of eukaryotes and archaea and has been a prototype for studies on DNA replication and assembly of the functional replisome. To examine protein-protein interactions at the DNA replication fork, we have established solution conditions for the formation of a discrete and homogeneous complex of RB69 DNA polymerase (gp43), primer-template DNA, and RB69 single-stranded DNA-binding protein (gp32) using equilibrium fluorescence and light scattering. We have characterized the interaction between DNA polymerase and single-stranded DNA-binding protein and measured a 60-fold increase in the overall affinity of RB69 single-stranded DNA-binding protein (SSB) for template strand DNA in the presence of DNA polymerase that is the result of specific protein-protein interactions. Our data further suggest that the cooperative binding of the RB69 DNA polymerase and SSB to the primer-template junction is a simple but functionally important means of regulatory assembly of replication proteins at the site of action. We have also shown that a functional domain of RB69 single-stranded DNA-binding protein suggested previously to be the site of RB69 DNA polymerase-SSB interactions is dispensable. The data from these studies have been used to model the RB69 DNA polymerase-SSB interaction at the primer-template junction.     

Bacteriophage T4 Gene 32 Participates in Excision Repair as Well as Recombinational Repair of Uv Damages

Gene 32 of phage T4 has been shown previously to be involved in recombinational repair of UV damages but, based on a mutant study, was thought not to be required for excision repair. However, a comparison of UV-inactivation curves of several gene 32 mutants grown under conditions permissive for progeny production in wild-type or polA- hosts demonstrates that gene 32 participates in both kinds of repair. Different gene 32 mutations differentially inactivate these repair functions. Under conditions permissive for DNA replication and progeny production, all gene 32 mutants investigated here are partially defective in recombinational repair, whereas only two of them, P7 and P401, are also defective in excision repair. P401 is the only mutant whose final slope of the inactivation curve is significantly steeper than that of wild-type T4. These results are discussed in terms of interactions of gp32, a single-stranded DNA-binding protein, with DNA and with other proteins.     

Autogenous translational operator recognized by bacteriophage T4 DNA polymerase

The synthesis of the DNA polymerase of bacteriophage T4 is autogenously regulated. This protein (gp43), the product of gene 43, binds to a segment of its mRNA that overlaps its ribosome binding site, and thereby blocks translation. We have determined the Kd of the gp43-operator interaction to be 1.0 x 10(-9) M. The minimum operator sequence to which gp43 binds consists of 36 nucleotides that include a hairpin (containing a 5 base-pair helix and an 8 nucleotide loop) and a single-stranded segment that contains the Shine-Dalgarno sequence of the ribosome binding site. In the distantly related bacteriophage RB69 there is a remarkable conservation of this hairpin and loop sequence at the ribosome binding site of its DNA polymerase gene. We have constructed phage operator mutants that overproduce gp43 in vivo, yet are unchanged for in vivo replication rates and phage yield. We present data that show that the replicative and autoregulatory functions are mutually exclusive activities of this polymerase, and suggest a model for gp43 synthesis that links autoregulation to replicative demand.     

Dual functions of single-stranded DNA-binding protein in helicase loading at the bacteriophage T4 DNA replication fork

Semi-conservative DNA synthesis reactions catalyzed by the bacteriophage T4 DNA polymerase holoenzyme are initiated by a strand displacement mechanism requiring gp32, the T4 single-stranded DNA (ssDNA)-binding protein, to sequester the displaced strand. After initiation, DNA helicase acquisition by the nascent replication fork leads to a dramatic increase in the rate and processivity of leading strand DNA synthesis. In vitro studies have established that either of two T4-encoded DNA helicases, gp41 or dda, is capable of stimulating strand displacement synthesis. The acquisition of either helicase by the nascent replication fork is modulated by other protein components of the fork including gp32 and, in the case of the gp41 helicase, its mediator/loading protein gp59. Here, we examine the relationships between gp32 and the gp41/gp59 and dda helicase systems, respectively, during T4 replication using altered forms of gp32 defective in either protein-protein or protein-ssDNA interactions. We show that optimal stimulation of DNA synthesis by gp41/gp59 helicase requires gp32-gp59 interactions and is strongly dependent on the stability of ssDNA binding by gp32. Fluorescence assays demonstrate that gp59 binds stoichiometrically to forked DNA molecules; however, gp59-forked DNA complexes are destabilized via protein-protein interactions with the C-terminal "A-domain" fragment of gp32. These and previously published results suggest a model in which a mobile gp59-gp32 cluster bound to lagging strand ssDNA is the target for gp41 helicase assembly. In contrast, stimulation of DNA synthesis by dda helicase requires direct gp32-dda protein-protein interactions and is relatively unaffected by mutations in gp32 that destabilize its ssDNA binding activity. The latter data support a model in which protein-protein interactions with gp32 maintain dda in a proper active state for translocation at the replication fork. The relationship between dda and gp32 proteins in T4 replication appears similar to the relationship observed between the UL9 helicase and ICP8 ssDNA-binding protein in herpesvirus replication.