Nucleotide sequence of bacteriophage f1 DNA.

The nucleotide sequence of the DNA of the filamentous coliphage f1 has been determined. In agreement with earlier conclusions, the genome was found to comprise 6,407 nucleotides, 1 less than that of the related phage fd. Phage f1 DNA differs from that of phage M13 by 52 nucleotide changes, which lead to 5 amino acid substitutions in the corresponding proteins of the two phages, and from phage fd DNA by 186 nucleotide changes (including the single-nucleotide deletion), which lead to 12 amino acid differences between the proteins of phages f1 and fd. More than one-half of the nucleotide changes in each case are found in the sequence of 1,786 nucleotides comprising gene IV and the major intergenic region between gene IV and gene II. The sequence of this intergenic region (nucleotides 5501 to 6005) of phage f1 differs from the sequence reported by others through the inclusion of additional single nucleotides in eight positions and of a run of 13 nucleotides between positions 5885 and 5897, a point of uncertainty in the earlier published sequence. The differences between the sequence of bacteriophage f1 DNA now presented and a complete sequence for the DNA previously published by others are discussed, and the f1 DNA sequence is compared with those of bacteriophages M13 and fd.     

The DNA-binding protein of Pf1 filamentous bacteriophage: amino-acid sequence and structure of the gene

The amino-acid sequence of the single-stranded DNA-binding protein of bacteriophage Pf1 and the nucleotide sequence of the corresponding gene have been determined. The protein has 144 amino acids and a molecular weight of 15 400; the gene consists of 435 nucleotides. The amino-acid sequence was determined by Edman degradation, carboxypeptidase A, B, and P digestion of intact protein and of peptides derived by chymotrypsin, Staphylococcus aureus V8 protease, and trypsin digestion. The nucleotide sequence was determined by the dideoxy method after random cloning of fragments of Pf1 DNA into M13. No sequence homology could be established between the amino-acid sequence of the DNA-binding protein of Pseudomonas aeruginosa-specific bacteriophage Pf1 and bacteriophage fd of Escherichia coli.     

A plasmid cloning system utilizing replication and packaging functions of the filamentous bacteriophage fd

DNA cloning vectors were developed which utilize the replication origin (ori) of bacteriophage fd for their propagation. These vectors depend on the expression of viral gene 2 that was inserted into phage lambda, which in turn was integrated into the host genome. The constitutive expression of gene 2 in the host cells is sufficient for the propagation of at least 100 pfd plasmids per cell. In addition to the fd ori, the pfd vectors carry various antibiotic-resistance genes and unique restriction sites. Some of these vectors have no homologies to commonly used pBR plasmids or to lambda DNA. The nucleotide sequence of the vectors can be deduced from published sequences. Large DNA inserts can be stably propagated in pfd vectors; these are more stable than similar DNA fragments cloned in intact genomes of filamentous bacteriophage. Inclusion of phage sequences required for efficient phage packaging and infection with a helper phage resulted in formation of phage particles containing single-stranded plasmid genomes. Growth at 42 degrees C without selective pressure results in loss of pfd plasmids.     

In vitro deletion mapping of the viral strand replication origin of Pseudomonas bacteriophage Pf3.

The origin of viral strand replication of the filamentous bacteriophage Pf3 has been characterized in Escherichia coli by in vitro deletion mapping techniques. The origin region was functionally identified by its ability to convey replicative properties to a recombinant plasmid in a polA host in which the replication origin of the vector plasmid is not functional. The origin of Pf3 viral strand replication is contained within a DNA sequence of 139 bp. This sequence covers almost completely one of the intergenic regions of the Pf3 genome, and it specifies both replication initiation and termination functions. Although no nucleotide sequence homology is present between the Pf3 origin of viral strand replication and that of the E. coli filamentous phages Ff (M13, f1, and fd) and IKe, their map positions and functional properties are very similar.     

Nucleotide sequences in bacteriophage f1 DNA: nucleotide sequence of genes V, VII, and VIII.

The sequence of nucleotides comprising genes V, VII, and VIII of bacteriophage f1 was determined. The sequence was found to differ from that of the corresponding region of the related fd genome by eight base substitutions in gene V and one in gene VIII. The structure of gene VII was completely conserved between these two viruses and was identical to that of bacteriophage M13. Both transitions and transversions were found in cases where bases were substituted, but all substitutions were in the third codon position and had no effect on the structure of the corresponding protein product. The gene V protein product could thus be deduced to be identical to that of the corresponding proteins from bacteriophages fd and M13. A potential EcoRII cleavage site was formed by nucleotides 172 to 176 of gene V. Replicative form DNA form DNA from bacteriophage f1 is normally resistant to this enzyme, and evidence is presented to suggest that the sequence was modified through methylation of cytosine 173. The probable locations of other modified nucleotides in the sequence are discussed.     

Nucleotide sequence and genetic organization of the genome of the N-specific filamentous bacteriophage IKe. Comparison with the genome of the F-specific filamentous phages M13, fd and f1

The nucleotide sequence and genetic organization of the genome of the N-specific filamentous single-stranded DNA phage IKe has been established and compared with that of the F-specific filamentous phages M13, fd and f1 (Ff). The IKe DNA sequence comprises 6883 nucleotides, which is 476 (475) nucleotides more than the nucleotide sequence of the Ff genome. The data indicate that IKe and Ff have evolved from a common ancestor (overall homology approx. 55%) and that their genomes contain ten homologous genes, the order of which is identical. Similar to Ff, the major coat protein and the gene III-encoded pilot protein of IKe are synthesized via precursor molecules. The extent of homology between the genes of IKe and Ff differs significantly from one gene to another. Genes that code for viral capsid proteins are less homologous than genes whose products are involved in the processes of DNA replication and phage morphogenesis. During evolution, large nucleotide sequence rearrangements have occurred in the gene (gene III) whose product is needed for the attachment of the virion to the conjugative pili of the host cell, suggesting that these rearrangements have led to phages with different host specificities. Extensive nucleotide sequence homology was noted between the structural elements involved in DNA replication and phage morphogenesis, indicating that the mechanisms involved in DNA replication and morphogenesis are highly conserved.     

Selection and characterization of randomly produced mutants of gene V protein of bacteriophage M13.

Gene V protein of bacteriophage Ff (M13, f1, fd) is a master regulator of phage DNA replication and phage mRNA translation. It exerts these two functions by binding to single-stranded viral DNA or to specific sequences in the 5' ends of its target mRNAs, respectively. To study the structure/function relationship of gene V protein, M13 gene V was inserted in a phagemid expression vector and a library of missense and nonsense mutants was constructed by random chemical mutagenesis. Phagemids encoding gene V proteins with decreased biological activities were selected and the nucleotide sequences of their gene V fragments were determined. Furthermore, the mutant proteins were characterized both with respect to their ability to inhibit the production of phagemid DNA transducing particles and their ability to repress the translation of a chimeric lacZ reporter gene whose expression is controlled by the promoter and translational initiation signals of M13 gene II. From the data obtained, it can be deduced that the mechanism by which gene V protein binds to single-stranded DNA differs from the mechanism by which it binds to its target sequence in the gene II mRNA.     

Characterization of the DNA binding protein encoded by the N-specific filamentous Escherichia coli phage IKe. Binding properties of the protein and nucleotide sequence of the gene

A DNA binding protein encoded by the filamentous single-stranded DNA phage IKe has been isolated from IKe-infected Escherichia coli cells. Fluorescence and in vitro binding studies have shown that the protein binds co-operatively and with a high specificity to single-stranded but not to double-stranded DNA. From titration of the protein to poly(dA) it has been calculated that approximately four bases of the DNA are covered by one monomer of protein. These binding characteristics closely resemble those of gene V protein encoded by the F-specific filamentous phages M13 and fd. The nucleotide sequence of the gene specifying the IKe DNA binding protein has been established. When compared to the nucleotide sequence of gene V of phage M13 it shows an homology of 58%, indicating that these two phages are evolutionarily related. The IKe DNA binding protein is 88 amino acids long which is one amino acid residue larger than the gene V protein sequence. When the IKe DNA binding protein sequence is compared with that of gene V protein it was found that 39 amino acid residues have identical positions in both proteins. The positions of all five tyrosine residues, a number of which are known to be involved in DNA binding, are conserved. Secondary structure predictions indicate that the two proteins contain similar structural domains. It is proposed that the tyrosine residues which are involved in DNA binding are the ones in or next to a beta-turn, at positions 26, 41 and 56 in gene V protein and at positions 27, 42 and 57 in the IKe DNA binding protein.     

Cloning of a functional replication origin of phage G4 into the genome of phage M13.

A chimeric single-stranded DNA phage, M13Gori1, has been formed as a result of the in vitro insertion of a 2216 base-pair HaeII fragment of bacteriophage G4 replicative form DNA into the replicative form DNA of bacteriophage M13. The inserted G4 DNA carries the dnaG-dependent origin for G4 complementary strand synthesis. The cloned G4 origin functions both in vivo and in vitro in the conversion of M13Gori1 single-stranded viral DNA to the duplex replicative form by a rifampicin-resistant mechanism. Labelling of the 3′ terminus of the single discontinuity in M13Gori1 replicative form II molecules synthesized in crude extracts and subsequent restriction analysis indicate that M13Gori1 complementary strand synthesis can be initiated at either the RNA polymeraseprimed M13 origin or at the dnaG-primed G4 origin. The M13Gori1 complementary strand initiated at the G4 origin terminates in the vicinity of the G4 origin after progressing around the circular template and traversing the M13 origin region, indicating the absence of a specific nucleotide sequence in the M13 origin for termination of the newly formed complementary strand. The ability of this chimeric phage to utilize the cloned G4 origin in vivo even in the presence of the presumed M13 pilot protein (gene 3 protein) indicate that the nucleotide sequence of the replication origin is sufficient for recognizing the appropriate initiation enzymes. Since decapsidation of M13 is tightly coupled to replicative form formation, initiation at the G4 origin, located over 1000 nucleotides from the M13 complementary strand origin, indicates that widely separated nucleotide sequences contained in the filamentous virion can be exposed to the cell cytoplasm during eclipse.     

Single RNA Polymerase Binding Site Isolated

One approach to study the structure of promoter regions^1–3 is to isolate RNA polymerase binding sites. Several attempts have been made to isolate such sites as protected DNA fragments^4–10, but so far the DNA isolated has not definitely shown to be only one or a few specific sites. We report here the isolation of a single RNA polymerase binding site from the replicative form (RF) DNA of bacteriophage fd. The site as isolated is a short double-stranded DNA with a unique nucleotide sequence.     

Nucleotide sequence of the genome of the filamentous bacteriophage I2-2: Module evolution of the filamentous phage genome

Summary The nucleotide sequence of the circular single-stranded genome of the filamentous Escherichia coli phage I2-2 has been determined and compared with those of the filamentous E. coli phages Ff(M13, fl, or fd) and IKe. The I2-2 DNA sequence comprises 6744 nucleotides; 139 nucleotides less than that of the N- and I2-plasmid-specific phage IKe, and 337 (336) nucleotides more than that of the F-plasmid-specific phage Ff. Nucleotide sequence comparisons have indicated that I2-2, IKe, and Ff have a similar genetic organization, and that the genomes of I2-2 and IKe are evolutionarily more closely related than those of I2-2 and Ff. The studies have further demonstrated that the I2-2 genome is a composite replicon, composed of only two-thirds of the ancestral genome of IKe. Only a contiguous I2-2 DNA sequence of 4615 nucleotides encompassing not only the coat protein and phage assembly genes, but also the signal required for efficient phage morphogenesis, was found to be significantly homologous to sequences in the genomes of IKe and Ff. No homology was observed between the consecutive DNA sequence that contains the origins for viral and complementary strand replication and the replication genes. Although other explanations cannot be ruled out, our data strongly suggest that the ancestor filamentous phage genome of phages I2-2 and IKe has exchanged its replication module during evolution with that of another replicon, e.g., a plasmid that also replicates via the so-called rolling circle mechanism. Offprint requests to: R.N.H. Konings     

Corrected nucleotide sequence of M13mp18 gene III.

There are seven differences between the actual nucleotide (nt) sequence of bacteriophage M13mp18 gene III and the previously reported nt sequence (which had been compiled based on the nt sequence of wild-type bacteriophage M13 gene III).     

An efficient synthetic primer for the M13 cloning dideoxy sequencing system

The deoxytetradecamer d(AAAACGACGGCCAG) has been shown to be an excellent universal primer for sequence determination of DNA cloned into the bacteriophage M13 mp7, mp8, and mp9 series. This new primer offers several advantages over others currently available and it has been used to define the cloning of Hinf I fragments of bacteriophage S13 DNA into the Eco RI site of M13 mp7, utilizing the homologous complementary base pairing of the two restriction sites. Of the four possible sequence derivatives of the Hinf I GANTC recognition site, only those corresponding to GAATC and GATTC have been found at cloning sites in chimeras.     

Molecular cloning and characterization of a complete DNA copy of potato spindle tuber viroid RNA.

Double-stranded cDNA has been synthesized from RNA of a severe strain of potato spindle tuber viroid using a synthetic oligodeoxyribonucleotide as a primer. Upon cloning in bacteriophage M13mp9, two recombinant phages were selected to construct a pBR322-derived plasmid containing a complete viroid DNA copy. Elucidation of the nucleotide sequence revealed four differences with the previously established sequence of another PSTV strain, three of which were base exchanges and one a deletion.     

Detection and identification of minor nucleotides in intact deoxyribonucleic acids by mass spectrometry.

A mass spectral method is described for the detection and identification of unusual nucleotide residues present in DNAs. Analysis by this method of intact, underivatized DNA from salmon sperm, calf thymus, mouse L-cells, wheat germ, M. lysodeikticus, E. Coli, and the bacteriophages 0X-174, fd, and lamda, yields diagnostic ions for the four common components of DNA as well as characteristic ions for 5-methyldeoxycytidine residues. The spectrum from T2 DNA contains ions indicative of 5-hydroxymethyldeoxycytidine and 5-methyldoxycytidine components but no ions corresponding to deoxycytidine residues. The DNAs of phages fd and 0X-174 also display ion products indicative of N6-methyldeoxyadenosine residues. Additional series of ions in the spectra of all four bacteriophage DNAs suggest the presence of 5-substituted deoxyuridine residues. The detection method exhibits considerable sensitivity in that amounts of DNA as low as 0.01 A260nm units can be used in the analysis, and thus, the procedure should prove of some value in the detection and location of modified components in specific regions of the various genomes by analysis of the appropriate endonuclease restriction fragments.     

Cleavage maps of the filamentous bacteriophages M13, fd, fl, and ZJ/2.

The replicative form DNAs of bacteriophage M13, fd, f1, and ZJ/2 were found to be sensitive to cleavage by the restriction endonucleases endoR-HapII, endoR-HaeII, endoR-HaeIII, endoR-HindII, endoR-AluI, endoR-Hha, and endoR-Hinf. With respect to M13 DNA the number of cleavage sites varied from 21 for endoR-Hinf, 18 for endoR-AluI, 15 for endoR-Hha, 13 for endoR-HapII, 10 for endoR-HaeIII, 3 for endoR-HaeII, to only a single site for endoR-HindII. In contrast to M13, fd and f1, the ZJ/2 DNA molecule was not cleaved by the endoR-HindII endonuclease. No cleavage site on either phage DNA was detected for the endonucleases endoR-Hsu, endoR-EcoRI and endoR-Sma. When compared with M13 DNA, several differences were noted in the number and size of cleavage products obtained with DNA of phage fd, f1, and ZJ/2. From the results of these analyses, using the M13 enzyme cleavage maps as a reference, the endoR-HapII, endoR-HaeII, endoR-HaeIII, endoR-HindII and endoR-AluI maps of phage fd, f1, and ZJ/2 could be constructed. As is expected for very closely related phages, the enzyme cleavage patterns exhibit a high degree of homology. Phage f1 and ZJ/2 are most related since an identical pattern was obtained with seven different restriction endonucleases. Evidence is provided also that f1 is more similar to M13 than to fd. Furthermore, characteristic differences exist within the endoR-Hinf enzyme cleavage pattern of all the four phages tested. Digestion of phage DNA with this enzyme, therefore, provides a new and sensitive method of distinguishing these closely related filamentous coliphages .     

Fine mapping of secondary structures of fd phage DNA in the region of the replication origin.

A synthetic heptaribonucleotide, GACCCCC, which is complementary to a unique site on fd bacteriophage DNA, primes DNA synthesis of fd by T4 bacteriophage DNA polymerase. The rate of the GACCCCC-primed DNA synthesis was not uniform as reflected by the appearance of discrete DNA fragments as replication intermediates on an alkaline agarose gel. After 10 minutes of synthesis a significant fraction of the DNA product ran as a single band with a length of about 1960 nucleotides. We have isolated this DNA fragment, hybridized back to unlabeled fd DNA template, and mapped the Taq I restriction fragments by urea polyacrylamide gel electrophoresis. This fine mapping procedure has located two major pause sites at fd nucleotide positions 5575 and 5674. These sites reside in the stem of two very stable hairpin helices near the origin of DNA replication of fd. Models for the functional roles of these two hairpin helices are presented.     

A new concept in (adenoviral) oncogenesis: integration of foreign DNA and its consequences

A new concept for viral oncogenesis is presented which is based on experimental work on the chromosomal integration of adenovirus DNA into mammalian genomes. The mechanism of adenovirus DNA integration is akin to non-sequence-specific insertional recombination in which patch homologies between the recombination partners are frequently observed. This reaction has been imitated in a cell-free system by using nuclear extracts from hamster cells and partly purified fractions derived from them. As a consequence of foreign DNA insertion into the mammalian genome, the foreign DNA is extensively de novo methylated in specific patterns, presumably as part of a mammalian host cell defense mechanism against inserted foreign DNA which can be permanently silenced in this way. A further corollary of foreign (adenovirus or bacteriophage λ) DNA integration is seen in extensive changes in cellular DNA methylation patterns at sites far remote from the locus of insertional recombination. Repetitive cellular, retrotransposon-like sequences are particularly, but not exclusively, prone to these increases in DNA methylation. It is conceivable that these changes in DNA methylation are a reflection of a profound overall reorganization process in the affected genomes. Could these alterations significantly contribute to the transformation events during viral or other types of oncogenesis? These sequelae of foreign DNA integration into established mammalian genomes will have to be critically considered when interpreting results obtained with transgenic, knock-out, and knock-in animals and when devising schemes for human somatic gene therapy.The interpretation of de novo methylation as a cellular defense mechanism has prompted investigations on the fate of food-ingested foreign DNA. The gastrointestinal (GI) tract provides a large surface for the entry of foreign DNA into any organism. As a tracer molecule, bacteriophage M13 DNA has been fed to mice. Fragments of this DNA can be found in small amounts (about 1 % of the administered DNA) in all parts of the intestinal tract and in the feces. Furthermore, M13 DNA can be traced in the columnar epithelia of the intestine, in Peyer's plaque leukocytes, in peripheral white blood cells, in spleen, and liver. Authentic M13 DNA has been recloned from total spleen DNA. If integrated, this DNA might elicit some of the described consequences of foreign DNA insertion into the mammalian genome. Food-ingested DNA will likely infiltrate the organism more frequently than viral DNA.     

Specific-primer-directed DNA sequencing

A simple and rapid strategy for DNA sequence analysis based on the Sanger chain-termination method is described. This procedure utilizes full-sized inserts of 1 to 4 kb of DNA cloned into M13 bacteriophage vectors. After the sequence of the first 600-650 bp of the insert DNA has been determined with the commercially available universal vector primer, a specific oligonucleotide is synthesized utilizing the sequence data obtained from the 3' end of the sequence and used as a primer to extend the sequence analysis for another 600-650 nucleotides. Additional primers are synthesized in a similar manner until the nucleotide sequence of the entire insert DNA has been determined. General guidelines for the selection of oligonucleotide length and composition and the use of unpurified primers are discussed. The use of the specific-primer-directed approach to dideoxynucleotide sequence analysis, in association with highly purified single-stranded template DNA, reduces considerably the time required for the analysis of large segments of DNA.