Physical arrangement of suppressor-sensitive mutations of Bacillus phage M2

Complementation assay of primer protein: gene expression systems of plasmid vectors support the infection of suppressor sensitive mutant phages M2 and phi 29

Two different expression systems of genes of primer proteins (pE for phage M2, and p3 for phi 29) were constructed to study the protein primed DNA replication of Bacillus phages M2 and phi 29. In one system, expression of the genes was under the control of the inducible spac promoter, whereas in the other system, the expression was under the control of the constitutive promoter in plasmid pUB110. Complementation tests in vivo were performed between the primer proteins expressed by these systems and mutant phages having suppressor sensitive mutations in the genes of the primer proteins. The phages M2 susE and phi 29 sus3 were complemented by pE and p3 expressed by the systems, respectively. However, the complementation and apparent phage DNA synthesis were not detected in the combinations between susE of phage M2 and p3 of phage phi 29, and vice versa. Although pE and p3 proteins exhibited structurally and functionally similar characteristics, these proteins showed species specificity in the protein primed DNA replication of bacteriophages M2 and phi 29.

Bacteriophage Nf DNA region controlling late transcription: structural and functional homology with bacteriophage phi 29

The putative region for the control of late transcription of the Bacillus subtilis phage Nf has been identified by DNA sequence homology with the equivalent region of the evolutionary related phage phi 29. A similar arrangement of early and late promoters has been detected in the two phages, suggesting that viral transcription could be regulated in a similar way at late times of the infection. Transcription of late genes requires the presence of a viral early protein, gpF in phage Nf and p4 in phage phi 29, being the latter known to bind to a DNA region located upstream from the phage phi 29 late promoter. We have identified a DNA region located upstream from the putative late promoter of phage Nf that is probably involved in binding protein gpF. Furthermore, we show that the phage phi 29 protein p4 is able to bind to this region and activate transcription from the phage Nf putative late promoter. Sequence alignment has also revealed the existence of significant internal homology between the two early promoters contained in this region of each phage.

Primer protein of bacteriophage M2 exposes the RGD receptor site upon linking the first deoxynucleotide

Primer protein (PP) of bacteriophages M2 and phi 29 contains an Arg-Gly-Asp (RGD) sequence. The RGD-mediated protein-protein interaction in protein-primed DNA replication of M2 was studied in vitro using three purified and indispensable components: PP, DNA polymerase (POL) and template DNA linked to terminal protein (TP). PP competed with a synthetic RGD peptide for binding to the template DNA-TP complex (TP-DNA). In addition, POL bound to template TP-DNA only when complexed with PP. These results indicate that the RGD sequence of PP is responsible for the interaction of the PP-POL complex with TP-DNA, which contains the initiation site for the protein priming of DNA synthesis. At the moment when PP converts to TP upon linking the first deoxynucleotide, a conformational change results in exposure of the RGD binding site.

Primary structure of bacteriophage M2 DNA polymerase: conserved segments within protein-priming DNA polymerases and DNA polymerase I of Escherichia coli

Bacteriophage M2 encodes its own DNA polymerase which catalyses the formation of a primer protein-5'dAMP initiation complex for DNA replication. To understand the relation of structure to function of this 'protein-priming DNA polymerase', we have determined the nucleotide sequence of the M2 DNA polymerase-encoding gene (gene G). The deduced 572-amino acid sequence of M2 DNA polymerase shows 82.3% overall homology to that of phi 29 DNA polymerase. A homology search with the mutation data matrix revealed that six segments (A-F, from the N terminus) of M2 and phi 29 DNA polymerases are homologous with the sequence of Escherichia coli DNA polymerase I (PolI). Segments D and F coincide with the conserved segments of many other DNA polymerases. Therefore, M2 and phi 29 DNA polymerases have structural features, at least in the conserved segments, similar to those of PolI and other DNA polymerases. Based on the homology with PolI and the location of the mutations for aphidicolin resistance and nucleoside analog resistance of M2, phi 29 and herpes simplex virus type-1 DNA polymerases, we propose that segments A-D of the M2 and phi 29 DNA polymerases constitute a structure which forms the cleft for holding template DNA and that segment D is a region for interacting with dNTP.

An inhibitory effect of RGD peptide on protein-priming reaction of bacteriophages phi 29 and M2

The amino acid sequence, arginine-glycine-aspartic acid (RGD), found in some cell adhesive proteins, is a recognition signal for the receptor protein. It is interesting that we have found the RGD sequence in terminal protein (TP) of bacteriophages phi 29 and M2 near an amino acid, the serine residue at 232, covalently linked to the terminal nucleotide of their DNAs. At the initiation of protein-primed DNA replication, TP is essential for the recognition of replication machinery containing DNA polymerase and primer protein (PP; PP becomes TP upon linking the first nucleotide, and hence the primary structure of TP is the same as that of PP). Synthetic peptide RGD specifically inhibited transfection of phi 29 and M2. The target of the RGD peptide is shown to be TP by marker rescue experiments, suggesting that a receptor for the RGD sequence exists in TP. Furthermore, the peptide inhibited the in vitro protein-priming reaction of DNA replication. We propose that the RGD sequence of PP and a putative receptor on TP is utilized for the molecular recognition initiating DNA replication.

Aphidicolin-resistant mutants of bacteriophage phi 29: genetic evidence for altered DNA polymerase

Aphidicolin-resistant mutants (Aphr) of Bacillus subtilis bacteriophage phi 29 were isolated after mutagenesis with hydroxylamine. Efficiency of plating (e.o.p.) of the resistant mutants was not reduced at 500 microM aphidicolin, although e.o.p. of wild type phi 29 was less than 10(-5) at the same concentration of aphidicolin. By recombination and complementation analyses, both sites of the mutations, aph-71 and aph-101, of Aphr71 and Aphr101, respectively, were mapped in gene 2 which encodes phi 29 DNA polymerase. The activity of wild type phi 29 DNA polymerase, in a partially purified fraction, was inhibited by aphidicolin. DNA polymerases from Aphr71 and Aphr101, prepared in the same manner as that of wild type, were resistant to the drug. These results indicate that the acquisition of the aphidicolin resistance of Aphr71 and Aphr101 of bacteriophage phi 29 results from a structural alteration of phi 29 DNA polymerase which reduces sensitivity to aphidicolin.

Nucleotide sequence of gene F of Bacillus phage Nf

The nucleotide sequence of Bacillus phage Nf gene F has been determined. The deduced amino acid sequence of gpF is very similar to that of gp4, the transcriptional activator of phage phi 29. Both proteins contain the consensus structure that is conserved for the DNA-protein interacting domain of DNA-binding proteins such as the repressor, Cro and CII proteins of phage lambda.

Bacteriophage phi 29 DNA replication in vitro: participation of the terminal protein and the gene 2 product in elongation

From phi 29-infected Bacillus subtilis cells, we have isolated a protein fraction which promotes in vitro replication of phi 29 DNA. This fraction catalyses both initiation and elongation, indicating that it contains the product of gene 3 (tp: terminal protein) and the product of gene 2 (gp2: probably a DNA polymerase), since initiation requires the two products (Blanco et al. 1983; Matsumoto et al. 1983). The fractions isolated from cells infected with temperature-sensitive (ts) mutants of gene 2 and gene 3 were thermolabile in both the initiation and elongation assays. When the pre-initiated material from the ts fractions of each mutant was heat-inactivated and mixed no complementation, restoring the elongation activity, was found. These results indicate: (i) tp and gp2 participate not only in the initiation but also in the elongation of phi 29 DNA replication, (ii) they probably function in tight physical association with each other.

In vitro initiation of bacteriophage phi 29 and M2 DNA replication: genes required for formation of a complex between the terminal protein and 5'dAMP

Cell-free extracts prepared from phi 29 and M2-infected Bacillus subtilis cells catalyse the formation of complexes between terminal protein and [alpha-32P]-dAMP in the presence of [alpha-32P]-dATP, MgCl2, ATP, and phage DNA with terminal protein covalently linked at both the 5'ends. The complex formation does not take place when proteinase K-treated DNA is added or when uninfected extract is used. The phi 29 complex thus formed is smaller than the M2 complex, primarily due to the different molecular weights of the respective terminal proteins. Extracts prepared from cells infected with suppressor-sensitive mutants of genes 2 or 3 of phi 29 or genes G or E of M2 do not support complex formation. When the pair of extracts of phi 29 or M2-infected cells are mixed, however, formation of the complex takes place as a result of in vitro complementation. These results indicate that the complex formation observed in vitro reflects in vivo initiation of phage DNA replication. The product of gene 2 of phi 29 may be the enzyme that catalyses formation of the complex.