Molecular cloning and physical map of bacteriophage PM2 DNA

The entire genome and the DNA fragments of the lipid-containing bacteriophage pM2 were cloned in the pBR322 plasmid vector. A physical map including the sites for the following restriction enzymes was obtained: HpaII, HaeIII, TthI, Sau96I, AvaII, PstI, BstNI, AccI, HincII, HpaI and HindIII. No restriction sites on PM2 DNA were found for BalI, BamHI, BclI, BglI, BglII, BstEII, KpnI, PvuII, SacI, SalI, Sau3A, XbaI and XhoI.     

Physical map of PM2 DNA.

The cleavage sites of the restriction nucleases HpaI, HpaII, HindII, HindIII, and PstI have been mapped on the DNA of the bacteriophage PM2. This map has been used for the localization of two strong binding sites of Escherichia coli RNA polymerase on PM2 DNA.     

Structure and physical map of Rhodopseudomonas sphaeroides bacteriophage RS1 DNA.

We analyzed, by restriction endonuclease mapping and electron microscopy, the genome of the lytic Rhodopseudomonas sphaeroides-specific bacteriophage RS1 and characterized it as a linear molecule of approximately 60 to 65 kilobases. When the DNA from purified phage particles was examined by several independent methods, considerable size heterogeneity was apparent in the RS1 DNA. This size heterogeneity was concluded to be of biological origin, was independent of the specific host strain used to propagate virus, and was not due to the presence of host DNA within or nonspecifically associated with purified virions. In addition, treatment of RS1 DNA with either BAL 31 nuclease or DNA polymerase I Klenow fragment revealed that several distinct regions exist within the viral chromosome which contain free 3' hydroxyl groups. A restriction endonuclease map of the RS1 genome was constructed by using the restriction endonucleases EcoRI, ClaI, KpnI, BamHI, MluI, SmaI, and BclI; thereby allowing the positioning of some 40 restriction sites within the viral genome. The results are discussed in terms of the significance and the possible biological origin of the unique features discovered within the phage RS1 DNA.     

Mapping of recognition sites for the restriction endonuclease from Escherichia coli K12 on bacteriophage PM2 DNA.

Several mutations in gene B of phage S13 appear to shorten the B protein by elimination of an N-terminal fragment, without destroying the B protein function. The shortened B protein resulting from each of these mutations can block the unique DNA-nicking properties of the S13 gene A protein. Because of the block in gene A function, normal gene B protein may have a function in phage DNA synthesis in addition to its known role in catalyzing capsid assembly.From gel electrophoresis the mutant B protein is estimated to be shorter than the normal S13 B protein by 1720 ± 70 daltons and is therefore believed to be an internal reinitiation fragment. The reinitiated fragments are functional and are made in about twice the amount of the normal B protein.The phage mutants which yield the reinitiation fragments are double mutants, each phage containing the same gene B nonsense mutation and each appearing to contain a different compensating gene B mutation. Various data support the assumption that the compensating mutations are frame-shifts, including the fact that suppression does not restore the normal-sized B protein. The reinitiation is assumed to occur at a pre-existing out-of-phase initiator codon, near the nonsense triplet; the correct reading frame would then be restored by each of the several different compensating mutations.The position of the normal S13 B protein in the gel electrophoresis pattern has been located both by elimination and shifting of the B peak, using appropriate amber mutants. The molecular weight of the S13 B protein is about 17,200, and is 2100 daltons less than the B protein of phage φX174; the S13 B protein can nevertheless substitute for the φX 174 B protein. Thus substantial portions of the B protein can be deleted without destroying its function.     

A physical map of the permuted genome of bacteriophage T1

Summary A restriction map has been constructed for the DNA of coliphage T1 which locates the cleavage sites of the restriction endonucleases, BglI (6 cuts), BglII (16 cuts), EcoRI (2 cuts), HindIII (2 cuts) and PstI (2 cuts). Digestions with BglI and BglII reveal fragments which are present in sub-molar quantities. Two methods, one using the selective removal of molecular ends with exonuclease III and the other involving the comparison of digestion patterns of concatemeric and virion DNA, have shown that the submolar fragments are at or close to the ends of the molecules. Digestions with BglI show that one terminal fragment has a very precise molecular weight whereas all the others are of heterogenous molecular weight. These results are consistent with the model for DNA packaging in which maturation is initiated at a precise site on a concatemeric precursor and proceeds by the encapsidation of up to four successive headfuls of 1.065 genome equivalents (MacHattie and Gill 1977).     

Infection of spheroplasts of Pseudomonas with DNA of bacteriophage PM2

Summary Spheroplasts of Pseudomonas BAL-31/PM2, obtained by treatment of the bacteria with lysozyme, can be infected with purified DNA from bacteriophage PM2. After 4 h of incubation the yield of progeny phage reaches a value of 10⁷-6×10⁷ plaque forming units/g PM2 DNA. The yield increases linearly with the concentration of DNA over at least 3 orders of magnitude.The biological activity of double-stranded circular PM2 DNA containing one or more single-strand breaks per molecule (component II), does not differ significantly from that of intact PM2 DNA (component I). Single-stranded PM2 DNA obtained by denaturation of component II, and the irreversible alkali-denatured form of component I are also infective.     

New map of bacteriophage lambda DNA.

A map of bacteriophage lambda was constructed, including accurate positions for all 41 cut sites made by 12 different restriction enzymes. Over 100 fragments from single, multiple, and partial enzyme digestions were measured versus standards that were calibrated with respect to DNA molecules of known sequence. The data were subjected to least-squares analysis to assign map coordinates. In no case did a fragment size predicted from the map differ from the measurement of the fragment by more than +/- 5%. This low error rate was consistent in all size ranges of fragments. The total length of lambda was calculated as 49,133 nucleotide pairs. This probably is accurate to within 500 base pairs.     

Cloning of bacteriophage PM2 DNA in Escherichia coli K12.

Summary DNA fragments of phage PM2 restricted with Hin dIII endonuclease was cloned in the vector pBR 322 in an Escherichia coli K 12 host. The attempt to clone full length PM2 DNA restricted with PstI endonuclease has been unsuccesful. From six randomly chosen recombinant clones DNA was purified and analysed with EcoRI, PstI and HindIII endonucleases. The physical map of three chimeric plasmids was unequivocally established. It was shown, that the whole PM2 genome was cloned, although in separate fragments. However, most of the recombinant clones were instable in the absence of selective pressure.     

Physical map of the DNA of bacteriophage phiB

A physical map of DNA phi B bacteriophage was constructed. Using the data of denaturation maps and heteroduplex analysis the positions of 10 (from 11) peaks were estimated. These peaks belong to DNA regions obtained after hydrolysis of phi B DNA by EcoRI endonuclease. This map is orientated to the end of the DNA molecule, which first entered the head, during phage maturation. The disposition of AT-enriched regions of the DNA molecule were shown.     

A physical map of the group A streptococcal pyrogenic exotoxin bacteriophage T12 genome

A physical map of group A streptococcal bacteriophage T12 was constructed with restriction endonucleases Sal/I, PstI, and EcoRI. The map is circularly permuted with a total length of 36.0 kb. Sub-molar quantities of certain restriction fragments, some of very precise MW and some of heterogeneous MW, were observed. This observation, together with mapping data, suggests that DNA packaging is initiated at a precise site on a concatemeric precursor and proceeds for a limited number of rounds.     

Left-handed Z-DNA regions are present in negatively supercoiled bacteriophage PM2 DNA

Bacteriophage PM2 DNA is a 10-kb covalently closed circular (ccc) molecule with a reported superhelical density of sigma = -0.12. Here we describe the binding of anti-Z-DNA antibodies to PM2 form I DNA under high and low salt conditions. The binding to PM2 DNA has been demonstrated by competitive radioimmunoassay (RIA), retardation of the DNA:antibody complexes in agarose gels and visualization by electron microscopy. The antibody binding is dependent on the degree of negative supercoiling. Thus, PM2 form II and form III did not bind the antibody. The low salt RIA results indicated the presence of 200-400 bp of left-handed DNA per PM2 molecule. This could reduce the effective superhelical density to sigma = -0.04 to -0.08, a range comparable with those found for other ccc DNAs in vivo. Electron microscopy revealed that a maximum of 22 antibody molecules bind to PM2. Single-site restriction with HpaII of the fixed DNA:antibody complex showed a cluster of four to five antibody molecules bound near one end of the linear DNA molecule. The evidence presented indicates that PM2 DNA contains regions of left-handed conformation under physiological conditions (low salt concentration) as well as at high salt concentrations. In addition, electrophoretic analyses of PM2 topoisomers indicate the presence of left-handed regions at superhelical densities less than that of isolated PM2 DNA.     

A restriction endonuclease cleavage map of bacteriophage P2

Summary A restriction endonuclease cleavage map of phage P2 was constructed. The enzymes used and, within parenthesis, the number of their cleavage sites on the P2 lg cc DNA molecule were: AvaI(3), BalI(1), BamI(3), BglII(3), HaeIII (more than 40; only three were mapped), HindIII(0), HpaI(10), KpnI(3), PstI(3), SalI(2) and SmaI(1). The EcoRI cleavage sites (3), as determined earlier, were used as reference points for this study. The DNAs of a variety of P2 mutants carrying chromosomal aberrations (del1, del2, del3, del6, vir22, vir37(2), vir79 and vir94) were also similarly examined.     

Sedimentation and intrinsic viscosity behavior of PM2 bacteriophage DNA in alkaline solution

The sedimentation coefficient and intrinsic viscosity of nicked and closed circular PM2 bacteriophage DNA have been measured as a function of pH in the alkaline region. A gradual increase in the sidimentation coefficient, and a corresponding decrease in the intrinsic viscosity, are observed for the superhelical (closed) circle in the pH region from 10.5 to about 10.9. This has been tentatively interpreted in terms of the known dependence of sedimentation coefficient upon the number of superhelical turns. At slightly higher pH values, the curve passes through the minimum (sedimentation coefficient) and maximum (intrinsic viscosity) expected when the superhelical turns present at neutral pH are unwound by partial alkaline denaturation. Sedimentation studies of the relaxed (nicked) circular species have revealed the existence of DNA forms in the pH region from 11.27 to 11.37 which sediment considerably faster than the closed circle in the same pH region. These have been identified as partially denatured nicked circles, in which varying fractions of the duplex structure have undergone alkaline denaturation, but strand separation has not yet occurred. Varying fractions of a slower species, either undenatured or completely denatured nicked circles, are also observed in some of these experiments. A corresponding result is observed in the intrinsic viscosity vs. pH curve. When nicked circular PM2 DNA is exposed to various alkaline pH's, rapidly neutralized, and sedimented at neutral pH, the expected sharp transition from native to denatured (strand-separated) molecules is seen. However, a very narrow pH range is noted in which native and denatured forms coexist in a single experiment. The above experiments carried out upon the closed form also reveal a narrow pH range in which the bulk of the transition from native closed circles to the collapsed cyclic coil takes place, in acccord with an earlier study on a different DNA. This transition is shown never to be completely effected, however, as there is a fraction (7–8%)of the closed circles which renature to the native form, regardless of the alkaline pH employed. This same phenomenon was not observed in the case of artificially closed λb₂b₅c DNA circles. Possible explanations for some of the above results are discussed.     

Derivation of a restriction map of bacteriophage T3 DNA and comparison with the map of bacteriophage T7 DNA.

The DNA of bacteriophage T3 was characterized by cleavage with seven restriction endonucleases. AvaI, XbaI, BglII, and HindIII each cut T3 DNA at 1 site, KpnI cleaved it at 2 sites, MboI cleaved it at 9 sites, and HpaI cleaved it at 17 sites. The sizes of the fragments produced by digestion with these enzymes were determined by using restriction fragments of T7 DNA as molecular weight standards. As a result of this analysis, the size of T3 DNA was estimated to be 38.74 kilobases. The fragments were ordered with respect to each other and to the genetic map to produce a restriction map of T3 DNA. The location and occurrence of the restriction sites in T3 DNA are compared with those in the DNA of the closely related bacteriophage T7.     

Establishment of a physical and genetic map for bacteriophage PRD1

DNA was isolated from the lipid-containing bacteriophage PRD1 and subjected to restriction endonuclease analysis. The total genome size is 14.7 kb. PRD1 DNA was resistant to cutting by fifteen restriction endonucleases with six base specificity. HaeII made thirty-seven cuts in the DNA, MboI made one cut, and MnlI made six cuts. DNA that was not treated with protease yielded two fewer fragments when treated with HaeII. Evidence is presented to indicate that the PRD1 DNA has protein at the ends of the DNA. The thirty-eight HaeII fragments were ordered using the ladder technique of Smith and Birnstiel (1976) on MboI and MnlI fragments of the genome. Clones of HaeII partial digests of PRD1 DNA in pBR322 were analyzed by HaeII digestion and were then assigned to specific regions of the genome by their HaeII fragment composition. A comparison of the marker rescue characteristics of the cloned DNA with the overall restriction fragment map generated a physical map of the genome. Some genes that have not been mapped because of a lack of mutants or leakiness at restrictive conditions were mapped by studying the in vitro protein synthesis of restriction endonuclease fragments.