Conversion of bacteriophage fd into an efficient single-stranded DNA vector system

Summary Single-stranded DNA vectors were constructed in vitro by insertion of various DNA fragments into the Intergenic Region of the single-stranded DNA phage fd. These inserts introduce into the phage genome unique cleavage sites for restriction nucleases which are suited for sticky joining in cloning experiments. Since these sites are usually located within genes coding for antibiotic resistance, inactivation of a resistance gene by insertion can be used as a marker for the successful cloning of a DNA fragment. Resistance genes also allow to select for recombinant DNA phages and to minimize the loss of DNA inserts which otherwise becomes significant above an insert size of about one kb. Cloning of several DNA fragments is described and strand separation of double-stranded DNA fragments by means of cloning into fd DNA is given as an example for application of single-stranded DNA vectors.Abbreviations Ap ampicillin - Cm chloramphenicol - Km kanamycin - Sm streptomycin - kb, kbp a unit length equivalent to 1000 bases, respectively 1000 base pairs - wt wild type     

Nucleotide sequence of bacteriophage fd DNA.

The sequence of the 6,408 nucleotides of bacteriophage fd DNA has been determined. This allows to deduce the exact organisation of the filamentous phage genome and provides easy access to DNA segments of known structure and function.     

Transposition of DNA inserted into deletions of the Tn5 kanamycin resistance element

Summary Tn5-trp hybrid transposons have been constructed by insertion of a trpPOED Hind III fragment into an in vivo Tn5 internal deletion mutant or by substitution of trp for the internal Tn5 Hind III fragment. These hybrids are called, respectively, Tn409 and Tn410. Both Tn409 and Tn410 will transpose into in the presence of a complementing Tn5 element. In the absence of a wild Tn5, lysogens carrying R1162::Tn409 and R1162::Tn410 plasmids will yield trp phages at less than six per cent of the complemented frequency. This reduction indicates that Tn409 and Tn410 lack a diffusible transposition function provided by wild Tn5 elements. However, the formation of trp phages without complementation is real. Most of these transducing particles contain Tn409 and Tn410 still linked to the carrier R1162 plasmid. This observation suggests that uncomplemented Tn409 and Tn410 elements mediate the formation of -transposon-plasmid cointegrate structures. Thus, the missing transposition function may be involved in resolving these cointegrate structures to the final ::Tn409 or ::Tn410 product.Abbreviations p.f.u. plaque-forming units - MIC minimal inhibitory concentration - LFT low frequency transducing - HFT high frequency transducing     

Excision of a DNA sequence determining kanamycin resistance from a ColE1-Km recombinant plasmid

Summary A 4.8×10⁶ dalton ECoRI-generated fragment of the R-factor R6-5 carrying the gene for kanamycin resistance (Km) was joined in vitro to ECoRI-treated ColE1 plasmid DNA. Transformation ofE. coli with the ColE1-Km recombinant plasmid yielded clones, which were immune to colicin E1, resistant to kanamycin and failed to produce colicin E1. During multiplication of this recombinant plasmid in the presence of chloramphenicol, cells expressed an increased resistance to kanamycin. Transformation studies with the recombinant DNA molecule showed very frequent loss of Km resistance in those cells harbouring a preexisting F'gal plasmid. Since colicin immunity is not affected and the col^- phenotype is still present, one has to test for a remaining DNA sequence further existing in ColE1 DNA by cleaving the plasmid DNA with the ECoRI restriction endonuclease. The full length of ColE1 DNA (6.2 kb) was restored, which confirmed that no deletion of ColE1 DNA sequences had occured. The remaining DNA sequence was identified as a 2.0 or 2.2 kb segment. On the basis of the length of the excised fragment it is proposed that the insertion sequence IS1 and a part of the inverted repeat sequence with coordinates 21.0 to 22.0 of the R6-5 DNA are recognised by a nucleolytic function.     

Nucleotide sequence and genome organization of bacteriophage S13 DNA

The complete sequence of bacteriophage S13 DNA has been determined. The molecule has 5386 nucleotides and differs from φX174 by 87 transitions and 24 transversions. All the proteins, A, A^*, B, C, D, E, F, G, H, J and K found in φX174 are also present in S13. Due to changes in the H/A intergenic region of S 13, the start of an additional protein. A′, has been identified. Genes F and H coding for the capsid and spike proteins, respectively, are the least conserved in comparison to φX174. Many of the silent changes, as well as some amino acid changes, are found in the same nucleotide sequence positions in phage G4, confirming the interrelationship between the three phages.     

Studies on bacteriophage fd DNA. II. Localization of RNA initiation sites on the cleavage map of the fd genome.

In an in vitro RNA synthesizing system, a single size of A-start RNA and three different sizes of G-start RNA are predominantly transcribed on the doubly closed replicative form (RFI) DNA of phage fd. When the RFI DNA was cleaved into three fragments (HinH-A, HinH-B and HinH-C) by a restriction endonuclease from Haemophilus influenzae H-I, the A-start RNA was predominantly initiated on HinH-B and the three G-start RNAs on HinH-A. RFI DNA was further cleaved into smaller pieces by two other restriction endonucleases from H. aphirophilus and H. gallinarum. Upon mixing the digests with RNA polymerase, two specific fragments derived from HinH-A were bound to the polymerase with GTP present. G-start RNA was efficiently initiated on the fragments isolated by this procedure. On the basis of these observations and estimates of the size of RNA formed on each fragment, the initiation sites for major RNA species were localized on the cleavage map of the phage fd genome previously constructed.     

Evolution of antibiotic resistance genes: the DNA sequence of a kanamycin resistance gene from Staphylococcus aureus

The kanamycin resistance gene from Staphylococcus aureus has been sequenced and its structure compared with similar genes isolated from Streptomyces fradiae and from two transposons, Tn5 and Tn903, originally isolated from Klebsiella pneumoniae and Salmonella typhimurium, respectively. The genes are all homologous but, since their common ancestor, have undergone extensive divergence, with more than 43% divergence between the closest pair. The phylogeny of the genes cannot be made congruent to the phylogeny of the taxa from which they were isolated without requiring rather improbable differences in rates. One is therefore led to conclude that there have been multiple occurrences of gene transfer between these species. Thus, although they are homologous, they are neither orthologous nor paralogous. It is suggested that homologous genes of this type be called xenologous.      

Pauses at positions of secondary structure during in vitro replication of single-stranded fd bacteriophage DNA by T4 DNA polymerase

Since bacteriophage T4 DNA polymerase is unable to use duplex DNA molecules as templates (B. Alberts, J. Barry, M. Brittner, M. Davies, H. Hama-Inaba, C. C. Liu, D. Mace, L. Moran, C. F. Morris, J. Piperno, and N. Sinha, 1977, in Nucleic Acids and Protein Recognition, Vogel, H. J., ed., pp. 31–63, Academic Press, New York), a technique involving synchronous and uniquely primed synthesis of DNA on the single-stranded fd DNA by the T4 DNA polymerase has been developed to probe regions exhibiting secondary structure on this genome. As the polymerase proceeds, the template secondary structure acts as a kinetic barrier to delay the continuous chain extension catalyzed by this enzyme. These kinetic pause sites can be mapped by denaturing agarose gel electrophoresis of replication intermediates and used to generate a secondary structure map. Using this method, we are able to establish a list including at least seven plausible stable helical regions in fd DNA. Two of the most stable secondary structures have been mapped near fd sequence positions 3350 and 5650, respectively. The latter has been reported to be the region where fd DNA replication begins (C. P. Gray, R. Sommer, C. Polke, E. Beck, and H. Schaller, 1978, Proc. Nat. Acad. Sci. USA, 75, 50–53). However, the biological function associated with the former has yet to be investigated. Following a two-state model, we estimate the first-order rate constant for progression through the duplex regions near position 5650 in fd DNA to be about 0.042 min^?1 for fd DNA synthesis by the T4 DNA polymerase under our reaction conditions. A 7.5-fold increase in this rate constant is obtained upon the addition of the T4 DNA helix destabilizing protein (i.e., gene 32 protein). The general pattern of our secondary structure map agrees well with a computer search for duplex regions on the fd genome. Both the stability and the size of a stable secondary structure at a particular position on the fd template determine the time that the newly made DNA molecules spend at that site. A structure with a stem of less than 8 base pairs does not interrupt significantly the procession of the T4 DNA polymerase during the process of fd DNA synthesis.     

Transposition of the kanamycin resistance determinant (Tn601) from plasmid 5T to the genome of bacteriophage lambda and the expression of this gene after prophage induction

Tn601, determinging kanamycin resistance of Escherichia coli, has been transposed into the bacteriophage lambda genome from R6 plasmid. After curing lambda gtc1857 (Tn601) lysogenes on the kanamycin containing medium, the clones with stable and unstable integrations of the Tn6-1 into the chromosome were obtained. After the lysogenization of these clones with the phage lambda att80c1857S7, the phages lambda att80c1857S7 (Tn601) were obtained. These phages contained the Tn601 from the sites of stable or unstable integrations. The frequency of the Tn601 transposition from the sites of unstable integration was 10(-7), that was two order of magnitude higher than the frequency of the Tn601 transpostion from the site of stable integration. Temperature induction of the lambda att80c1857 (Tn601) prophage resulted in 10--15 times increase of the yeild of aminoglycoside-3'-phosphotransferase I, the enzyme coded by the aphA gene of the Tn601.     

Incorporation of bacteriophage DNA into the genome of cultured human lymphocytes

Summary After exposure of phytohemagglutinin-stimulated human lymphocytes to high doses of tritiated-thymidine labelled Φ X-174 or T2 bacteriophage, label from the phage genome became incorporated into lymphocyte DNA. Exposure to bacteriophage DNA, whether biologically active inactive, or fragmented, had a depressive effect on lymphocyte DNA replication. Incorporation of label from phage DNA into the lymphocyte DNA, however, was maximum for biologically active phage.     

Isolation and characterization of transducing coliphage fd carrying a kanamycin resistance gene.

The DNA segment (Tn903) with a size of 3100 nucleotide pairs which carries a gene specifying kanamycin resistance derived from a chimeric plasmid pML21 (Hershfield et al., 1976) was transposed to various sites on the filamentous phage fd DNA. Wild type fd can be restored by excision of Tn903 from the resulting hybrid DNA molecule. The fd DNA carrying Tn903 when converted to the mature phage particle, was capable of transducing the kanamycin marker, and its replicative form DNA could be maintained in a bacterial cell like a plasmid.     

The role of single-stranded DNA in the integration of SV40 genome into cellular DNA

The integration of temperature-sensitive SV40 mutant DNA (tsA239) into the Chinese hamster cellular genome at an early stage of infection was studied. The content of single-stranded DNA structures in the infected and control cells at a non-permissive temperature (40 degrees C) differed drastically from that in control cells at permissive temperatures (33 degrees C, 37 degrees C). The role of single-stranded structures in the integration of the SV40 genome into cellular DNA was shown by blot hybridization. The integration mechanism is discussed.     

DNA regions essential for the function of a bacteriophage fd promoter.

The promoter for the major coat protein gene of bacteriophage fd contains a unique sequence. TATAAT, in the non-transcribed region corresponding to the Pribnow box. A R-Hha I cleavage site which destroys functions is located five pairs upstream from the TATAAT sequence (fifteen base pairs upstream from the RNA initiation site). The promoter was cleaved into two fragments by R-Hha I and each promoter fragment was joined to DNA fragments derived from other regions. Ligation of the TATAAT-containing fragment to any of the DNA fragments examined resulted in recovery of promoter function. The results suggest for this type of promoter that no unique sequence is necessary upstream from the R-Hha I cleavage site although a contiguous DNA chain must be present in this area.     

Location of the cooperative melting regions in bacteriophage fd DNA

Differential melting profiles of the linear replicative form (RF-III) DNA of bacteriophage fd, of the fragments obtained by the restriction endonuclease R.HinHI and of those obtained by R.Hga were investigated. With these results a physical map which locates the cooperative melting regions on the DNA was constructed, and compared with the genetic map.