Nucleotide sequence of the J gene and surrounding untranslated regions of phage G4 DNA: Comparison with phage φX174

A 290 nucleotide long region of the bacteriophage G4 genome including the end of the overlapping genes D and E, the entire gene J and the untranslated region between genes J and F has been sequenced and compared with the same region in bacteriophage φX174. Deletions, insertions, duplications and single base changes in G4 relative to φX174 have resulted in the following changes: the loss of the φX174 overlapping gene D termination and gene J initiation codons, resulting in their separation by 32 untranslated nucleotides; the deletion of one third of the gene J coding region, so that the G4 J protein is only 24 amino acids long compared with 37 amino acids in φX174; and the establishment of a longer untranslated region between G4 genes J and F, which despite many nucleotide changes retains the ability to form a stable hairpin loop in the same place and with the same geometry as in φX174. The G4 overlapping gene E is longer than in φX174 and extends beyond gene D. Sixteen nucleotides at the end of genes D and E in φX174 are duplicated in G4 before gene J.     

Mechanism of replication of bacteriophage phi X174 XIX. Initiation of phi X174 viral strand DNA synthesis at internal sites on the genome.

Bacteriophage phi X174 viral strand DNA molecules shorter than genome length found late in the infectious cycle in Escherichia coli were 5' end labeled with 32P. Hybridization of the 32P-labeled molecules to restriction enzyme fragments of phi X replicative form DNA revealed an excess of phi X molecules whose 5' ends mapped in HaeIII fragments Z3 and Z4 in comparison with fragments Z1 and Z2. This suggests that initiation of phi X174 viral strand DNA synthesis may occur at internal sites on the complementary strand. There are several appropriately located sequences that might serve as n' (factor Y) recognition sequences and thereby facilitate discontinuous synthesis of the viral strand.     

Properties of the A and A proteins of bacteriophage G4. The origin of G4 replicative-form DNA replication

The A and A proteins of the bacteriophage G4 have been purified. The proteins have been analysed for their enzymatic activities on single-stranded and double-stranded DNA. The A protein introduces a single-stranded break at a specific place in the G4 replicative form I DNA. This cleavage site has been localized between nucleotides 506 and 507 in the viral (+) strand. The A protein binds covalently to the 5' end of the cleavage site. The A protein initiates the replication of the viral (+) DNA [Borrias, et al. (1979) Virology, 31, 288-298]; the cleavage site therefore identifies the origin of replication. The A protein cleaves viral (+) strand DNA at many different sites and also binds covalently to the 5' ends of the nick sites. The properties of both proteins strongly resemble the properties of the A and A proteins of the related and much butter analysed phage phi X174. These results indicate that the G4 and phi X174A and A proteins have comparable functions and also that both phages initiate the replicative form DNA in a similar way.     

Gene A protein cleavage of recombinant plasmids containing the phi X174 replication origin

Synthetic oligonucleotides, DNA ligase and DNA polymerase were used to construct double-stranded DNA fragments homologous to the first 25, 27 or 30 b.p. of the origin of replication of bacteriophage phi X174 (nucleotides 4299-4328 of the phi X174 DNA sequence). The double-stranded DNA fragments were cloned into the unique SmaI or HindIII restriction sites in the kanamycin-resistance gene of pACYC177 (AmpR, KmR). Recombinant plasmids were picked up by colony hybridization. DNA sequencing showed that not only recombinant plasmids with the expected insert were formed, but also recombinant plasmids with a shorter insert. Recombinant plasmids with an insert homologous to the first 24, 25, 26, 27, 28 or all 30 b.p. of the phi X174 origin region were thus obtained. Supercoiled plasmids containing a sequence homologous to the first 27, 28 or 30 b.p. of the phi X174 origin region are nicked by the phi X174 gene A protein. However, the other supercoiled plasmids are not nicked by the phi X174 gene A protein. These results show that the first 27 b.p. of the phi X174 origin region are sufficient as well as required for the initiation step in phi X174 RF DNA replication, i.e. the cleavage by gene A protein.     

Two ribosome binding sites from the gene 0.3 messenger RNA of bacteriophage T7

Ribosome-protected regions have been isolated and analyzed from the bacteriophage T7 gene 0.3 mRNA labeled in vivo. Two discrete sites which are nearly equally protected by ribosomes are obtained from what was previously assumed to be a monocistronic message. Use of appropriate T7 deletion mutant RNAs has allowed mapping of both ribosome-recognized regions. Site a is positioned very close to the 5′ terminus of the mRNA and is apparently the initiator region for the major gene 0.3 protein, which acts to overcome the host DNA restriction system. Site b is located within several hundred nucleotides of the 3′ end of the RNA and probably initiates synthesis of a small polypeptide of unknown function. Both ribosome binding sites exhibit features common to other initiator regions from Escherichia coli and bacteriophage mRNAs. The proximity of site a to the RNase III cleavage site at the left end of gene 0.3 may explain why processing by RNase III is required for efficient translation of the major gene 0.3 protein.     

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.     

Coordinated leading- and lagging-strand synthesis at the Escherichia coli DNA replication fork. III. A polymerase-primase interaction governs primer size.

Studies with a rolling-circle DNA replication system reconstituted in vitro with a tailed form II DNA template, the DNA polymerase III holoenzyme (Pol III HE), the Escherichia coli single-stranded DNA binding protein, and the primosome, showed that within the context of a replication fork, the oligoribonucleotide primers that were formed were limited to a length in the range of 9 to 14 nucleotides, regardless of whether they were subsequently elongated by the lagging-strand DNA polymerase. This is in contrast to the 8-60-nucleotide-long primers synthesized by the primosome in the absence of DNA replication on a bacteriophage phi X174 DNA template, although when primer synthesis and DNA replication were catalyzed concurrently in this system, the extent of RNA polymerization decreased. As described in this report, we therefore examined the effect of the DNA Pol III HE on the length of primers synthesized by primase in vitro in the absence of DNA replication. When primer synthesis was catalyzed either: i) by the primosome on a phi X174 DNA template, ii) by primase on naked DNA with the aid of the DnaB protein (general priming), or iii) by primase alone at the bacteriophage G4 origin, the presence of the DNA Pol III HE in the reaction mixtures resulted in a universal reduction in the length of the heterogeneous RNA products to a uniform size of approximately 10 nucleotides. dNTPs were not required, and the addition of dGMP, an inhibitor of the 3'----5' exonuclease of the DNA Pol III HE, did not alter the effect; therefore, neither the 5'----3' DNA polymerase activity nor the 3'----5' exonuclease activity of the DNA Pol III HE was involved. E. coli DNA polymerase I, and the DNA polymerases of bacteriophages T4 and T7 could not substitute for the DNA Pol III HE. The Pol III core plays a crucial role in mediating this effect, although other subunits of the DNA Pol III HE are also required. These observations suggest that the association of primase with the DNA Pol III HE during primer synthesis regulates its catalytic activity and that this regulatory interaction occurs independently of, and prior to, formation of a preinitiation complex of the DNA Pol III HE on the primer terminus.     

Evidence that the respiratory syncytial virus polymerase is recruited to nucleotides 1 to 11 at the 3' end of the nucleocapsid and can scan to access internal signals

The 3'-terminal end of the respiratory syncytial virus genomic RNA contains a 44-nucleotide leader (Le) region adjoining the gene start signal of the first gene. Previous mapping studies demonstrated that there is a promoter located at the 3' end of Le, which can signal initiation of antigenome synthesis. The aim of this study was to investigate the role of the 3' terminus of the RNA template in (i) promoter recognition and (ii) determining the initiation site for antigenome synthesis. A panel of minigenomes containing additional sequence at the 3' end of the Le were analyzed for their ability to direct antigenome and mRNA synthesis. Minigenomes containing heterologous extensions of 6 nucleotides or more were unable to support efficient RNA synthesis. However, the activity of a minigenome with a 56-nucleotide extension could be restored by insertion of Le nucleotides 1 to 11 or 1 to 13 at the 3' end, indicating that these nucleotides, in conjunction with the 3' terminus, are sufficient to recruit polymerase to the template. Northern blot and 5' rapid amplification of cDNA ends analysis of antigenome RNA indicated that antigenome initiation occurred at the first position of Le, irrespective of the terminal extension. This finding demonstrates that the 3' terminus of the RNA is not necessary for determining the antigenome initiation site. Data are presented which suggest that following recruitment to a promoter at the 3' end of Le, the polymerase is able to scan and respond to a promoter signal embedded within the RNA template.     

Nucleotide sequence of the genome of the bacteriophage alpha 3: interrelationship of the genome structure and the gene products with those of the phages, phi X174, G4 and phi K.

The complete nucleotide sequence of the genome of the circular single-stranded DNA (isometric) phage alpha 3 has been determined and compared with that of the related phages phi X174 and G4. The alpha 3 genome consists of 6087 nucleotides, which is 701 nucleotides longer than the nucleotide sequence of the phi X174 genome and 510 nucleotides more than that of the G4 genome. The results demonstrated that the three phage species have 11 homologous genes (A, A*, B, C, K, D, E, J, F, G and H), the order of which is fundamentally identical, suggesting that they have evolved from a common ancestor. The sequence of some genes and untranslated intergenic regions, however, differs significantly from phage to phage: for example, the degree of amino acid sequence homology of the gene product is averaged at 47.7% between alpha 3 and phi X174 and 46.9% between alpha 3 and G4, and alpha 3 has a remarkable longer intergenic region composed of 758 nucleotides between the genes H and A compared with the counterparts of phi X174 and G4. Meanwhile, in vivo experiments of genetic complementation showed that alpha 3 can use none of the gene products of phi X174 and G4, whereas the related phage phi K can rescue alpha 3 nonsense mutants of the genes B, C, D and J. These sequencing and in vivo rescue results indicated that alpha 3 is closely related to phi K, but distantly remote from phi X174 or G4, and supported an evolutional hypothesis which has been so far proposed that the isometric phages are classified into three main groups: the generic representatives are phi X174, G4 and alpha 3.     

Mutational analysis of the bacteriophage phi X174 replication origin

Bacteriophage phi X174 mutants within the 30 base-pair replication origin were constructed using oligodeoxynucleotide-directed mutagenesis. A total of 18 viable base substitution mutants at 13 different positions within the origin region were obtained. The majority of these ori mutants have a plaque morphology and burst size comparable to that of wild-type phi X174. Two phi X174 ori mutants with a reduced growth ability spontaneously acquired additional mutations that enhanced the growth rate. The additional mutation was located at the same site as the original mutation or was located in the N-terminal part of the gene A protein. This latter secondary mutation is responsible for a better binding and/or recognition of the gene A protein to the mutated origin. In a Darwinian experiment wild-type phi X174 outgrows all phi X174 ori mutants, indicating the superiority of the wild-type ori sequence for the reproduction of bacteriophage phi 174. Insertions and deletions were constructed at different positions within the phi X174 replication origin cloned in a plasmid. Small insertions and deletions in the A + T-rich spacer region do not inhibit phi X174 gene A protein cleavage in vitro, but severely impair packaging of single-stranded plasmid DNA in viral coats.     

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.     

3'-->5'-exonucleases of the rat liver and the correction of replication errors]

Mammalian nuclear DNA polymerases alpha and beta are lack of the proofreading 3'-->5' exonucleolytic activity. 40 and 50 kDa 3'-->5' exonucleases were isolated from rat liver. The exonucleases were shown to excise mismatched nucleotides from poly[d(A--T)] template 10 and 2 fold faster than matched ones. The addition of either exonuclease to DNA polymerase alpha from rat liver or calf thymus 5-10 times increased the accuracy of reproduction of primed DNA from bacteriophage phi X174 amber 3, values of exonuclease and DNA polymerase activities being approximately equal. The exonuclease activity surpasses the DNA polymerase one by an order of magnitude in chromatin and nuclear membrane. These data, taken together, are indicative of potent proofreading into hepatocytes.