Quantitative analysis of the bacteriophage Qbeta infection cycle

In this study, the infection cycle of bacteriophage Qbeta was investigated. Adsorption of bacteriophage Qbeta to Escherichia coli is explained in terms of a collision reaction, the rate constant of which was estimated to be 4x10(-10) ml/cells/min. In infected cells, approximately 130 molecules of beta-subunit and 2x10(5) molecules of coat protein were translated in 15 min. Replication of Qbeta RNA proceeded in 2 steps-an exponential phase until 20 min and a non-exponential phase after 30 min. Prior to the burst of infected cells, phage RNAs and coat proteins accumulated in the cells at an average of up to 2300 molecules and 5x10(5) molecules, respectively. An average of 90 infectious phage particles per infected cell was released during a single infection cycle up to 105 min.     

The terminal redundant regions of bacteriophage T7 DNA

Summary Some aspects of the involvment of the terminal reduntant regions of T7 DNA on phage production have been studied by transfection experiments with T7 DNA after treatment of the molecules with exonuclease or exonuclease plus exonuclease I. It was found that terminal 5 gaps between 0.08 and 6.4% of the total length did not decrease the infectivity of the molecules although such gaps cannot be filled directly by DNA polymerases. Rather, compared to fully native DNA the infectivity of gapped DNA increased up to 20 fold in rec ⁺ spheroplasts and up to 4 fold in recB spheroplasts. This indicates a protective function of the single-stranded termini against the recBC enzyme in rec ⁺ and possibly another unidentified exonuclease present also in recB. The possibility that spontaneous circularization of the gapped molecules in vivo provides protection against exonucleolytic degradation was tested by transfection with T7 DNA circularization in vitro by thermal annealing. Such molecules were separated from linear molecules by neutral sucrose gradient centrifugation. They displayed a 3 to 6 fold higher infectivity in rec ⁺ and recB compared to linear gapped molecules, which shows that T7 phage production may effectively start from circular DNA.When the 3 single-stranded ends from gapped molecules were degraded by treatment with exonuclease I the infectivity of the molecules was largely abolished in rec ⁺ and recB as soon as 40 to 80 base pairs had been removed per end. It is concluded that the terminal regions of T7 DNA molecules are essential for phage production and that the redundancy comprises probably considerably less than 260 base pairs. The results are discussed with respect to the mode of T7 DNA replication.     

Biological activity of different forms of bacteriophage lambda DNA]

Hershey circles and linear tandem aggregated forms of DNA have been obtained in vitro and treated with polynucleotide ligase to form phosphodiester bond. Using zone centrifugation in glycerol gradient covalently closed circles and linear dimers have been purified and their biological activity investigated. It was found that closed circular molecules lost most, if not all, of their activity in CaCl2-dependent system. In order to investigate the biological activity of tandem dimer molecules, hybrid dimers consisting of DNA's from lambda C1857 and lambda 1434 have been obtained. In plaque assay with the appropriate non-permissive strains of E. coli the efficiency of infectivity of hybrid dimers was measured. Biological activity of dimer molecules sealed with ligase was about 5% of the activity of linear monomers. Ig has been suggested that tandem dimers of lambda DNA joined by phosphodiester bond are able to penetrate into the CaCl2-treated host cells and both components of dimers are active during subsequent multiplication.     

Cleavage of bacteriophage M13 DNA by Haemophilus influenzae endonuclease-R

The restriction enzyme from Haemophilus influenzae, endonuclease-R, has only one cleavage site on the double-stranded replicative form DNA of bacteriophage M13. Circular replicative forms are broken to yield full-length liniar M13-DNA molecules (RF-III). The cleavage site appears to be specific as the RF-III molecules, produced by endonuclease-R, cannot be circularized by denaturation and renaturation.     

Asymmetric repair of bacteriophage T7 heteroduplex DNA

Summary Heteroduplex DNA molecules were prepared in vitro using one strand of DNA carrying a point mutation and one strand of the corresponding wild-type DNA. The heteroduplex DNA was transfected into competent bacteria and the progeny genotypes in the resulting infective centers were determined. From the results were conclude that about 80% of all transfected DNA molecules are repaired before DNA replication starts. This fraction of repaired DNA is independent of the location of the mismatched nucleotide pair. However, mismatch correction occurs preferentially on the H strand of the heteroduplex DNA.The repair does not depend on a known phage coded function but requires the active bacterial genes mut U, mut H, mut S and probably mut L.     

Architecture of the bacteriophage T4 replication complex revealed with nanoscale biopointers

Our previous electron microscopy of DNA replicated by the bacteriophage T4 proteins showed a single complex at the fork, thought to contain the leading and lagging strand proteins, as well as the protein-covered single-stranded DNA on the lagging strand folded into a compact structure. "Trombone" loops formed from nascent lagging strand fragments were present on a majority of the replicating molecules (Chastain, P., Makhov, A. M., Nossal, N. G., and Griffith, J. D. (2003) J. Biol. Chem. 278, 21276-21285). Here we probe the composition of this replication complex using nanoscale DNA biopointers to show the location of biotin-tagged replication proteins. We find that a large fraction of the molecules with a trombone loop had two pointers to polymerase, providing strong evidence that the leading and lagging strand polymerases are together in the replication complex. 6% of the molecules had two loops, and 31% of these had three pointers to biotin-tagged polymerase, suggesting that the two loops result from two fragments that are being extended simultaneously. Under fixation conditions that extend the lagging strand, occasional molecules show two nascent lagging strand fragments, each being elongated by a biotin-tagged polymerase. T4 41 helicase is present in the complex on a large fraction of actively replicating molecules but on a smaller fraction of molecules with a stalled polymerase. Unexpectedly, we found that 59 helicase-loading protein remains on the fork after loading the helicase and is present on molecules with extensive replication.     

On the molecular length of the replicative form DNA of bacteriophage phiX174

This paper describes an electron microscopic study of the circular replicative form DNA of bacteriophage φX174. The study has been carried out using a preparative technique in which the DNA molecules are adsorbed from solution on to the cleavage surface of mica and visualized in the electron microscope as a metal-shadowed replica (Gordon &; Kleinschmidt, 1969,1970). Contour lengths of open circular molecules were measured in samples obtained from preparations in which the following experimental parameters were varied: the ionic strength of the solution from which the DNA was adsorbed on the mica and the way in which the molecules were dried before shadowing. At the 0.05 significance level, varying these parameters had no effect on the mean length and variances of samples of molecules obtained from five experiments; the samples were therefore regarded as being drawn from the same molecular population with a mean length and variance of, respectively, 1.83 μm and 0.0117 μm².It was argued that the DNA molecules adsorbed on the mica are “frozen” into the molecular conformation present in solution at the time of adsorption and that, therefore, the experimentally determined contour lengths represent authentic molecular lengths in solution. Based on current estimates of the replicative form DNA molecular weight, the mean contour length obtained was slightly but significantly larger than the length predicted for molecules in an exact B configuration. The variance was larger than could be attributed solely to experimental error, indicating that the molecular population in aqueous solution is heterogeneous in contour length. These experimental results were shown to be consistent with a model for DNA structure in aqueous solution in which individual molecules are dynamic variants of a perturbed B form structure (von Hippel &; Wong, 1971).     

Orientation of the DNA in the filamentous bacteriophage f1

The filamentous bacteriophage f1 consists of a molecule of circular single-stranded DNA coated along its length by about 2700 molecules of the B protein. Five molecules of the A protein and five molecules of the D protein are located near or at one end of the virion, while ten molecules of the C protein are located near or at the opposite end. The two ends of the phage can be separated by reacting phage fragments, which have been generated by passage of intact phage through a French press, with antibody directed against the A protein (Grant et al., 1981a). By hybridizing the DNA isolated from either end of ³²P-labeled phage to specific restriction fragments of fl replicative form I DNA, we have determined that the single-stranded DNA of the filamentous bacteriophage f1 is oriented within the virion. For wild-type phage, the DNA that codes for the gene III protein is located at the A and D protein end and that which corresponds to the intergenic region is located close to the C protein end of the particle. The intergenic region codes for no protein but contains the origins for both viral and complementary strand DNA synthesis. Analysis of the DNA orientation in phage in which the plasmid pBR322 has been inserted into different positions within the intergenic region of fl shows that the C protein end of all sizes of filamentous phage particles appears to contain a common sequence of phage DNA. This sequence is located near the junction of gene IV and the intergenic region, and probably is important for normal packaging of phage DNA into infectious particles. There appears to be no specific requirement for the origins of viral and complementary strand DNA synthesis to be at the end of a phage particle.     

Mechanism of replication of bacteriophage phi X174 XX. Sensitivity of nascent DNA to single-strand-specific nucleases.

We reported earlier that dephosphorylated nascent phi X174 viral strand DNA molecules were less extensively degraded from the 5' end by spleen exonuclease than were non-nascent molecules. Experiments described here revealed that the insensitivity to the 5'-OH end-specific nuclease was more evident among the longer molecules in the population than among the shorter, all of the molecules being less than unit length in size. The smallest molecules in the population were about as sensitive to the enzyme as the control molecules and hence must possess unblocked 5'-terminal nucleotides. Degradation of the nascent DNA with the 3' end-specific snake venom phosphodiesterase revealed only a small enrichment for [3H]thymidine near the 3' end, seemingly insufficient to account completely for the apparent insensitivity of the longer molecules to spleen exonuclease. When the nascent molecules were isolated without the use of proteolytic enzymes, some pronase-sensitive material was found associated with the DNA, particularly the longer molecules. We suggest that the resistance of the longer nascent (pronase-treated) molecules to spleen exonuclease occurs because they have remnants of the viral gene A or A* protein covalently bound to the 5' end.     

Distribution of "minor" nicks in bacteriophage T5 DNA.

Bacteriophage T5 DNA can be released from the phage particle in such a way that one end of 5 to 10% of the DNA molecules remains attached to either the phage head or tail. Under partial denaturation conditions, the DNA preferentially denatures in the vicinity of a nick so that the nicks can be located relative to the end that remains attached to the phage head or tail. Two classes of nicks were found. "Major" nicks were those found in more than 20% of the molecules and were located at the same points along the DNA molecule as reported by others. "Minor" nicks were found in 5 to 10% of the molecules and often occurred at specific locations near a "major" nick.     

Hexamer of bacteriophage f2 coat protein as a repressor of bacteriophage RNA polymerase synthesis.

Formation of complex I between phage f2 RNA and coat protein, leading to repression of phage RNA polymerase synthesis, depends nonlinearly upon the concentration of the coat protein. Maximum formation of complex I was observed when six molecules of coat protein were bound to one molecule of RNA. RNase digestion of a glutaraldehyde-fixed complex left, as the products, coat protein oligomers. The heaviest, hexamers, predominated in the mixture. It was also shown that, in an ionic environment required for phage protein synthesis, coat protein at a concentration optimum for complex I formation exists in solution as a dimer. The results indicate that the translational repression of the RNA polymerase cistron is due to a cooperative attachment to phage template of three dimers of coat protein, forming a hexameric cluster on an RNA strand.     

Membrane binding of bacteriophage SPP1 DNA

Summary A fast sedimenting complex was isolated from B. subtilis cells infected with bacteriophage SPP1 by renografin centrifugation. This complex was identified as membrane bound parental and replicating SPP1 DNA. Synthesis of SPP1 DNA takes place in close association with the membrane. This newly synthesized DNA is then released into the cytoplasm. During release, concatemeric SPP1 DNA is sized into monomeric DNA molecules.Experiments reported were part of the Doctoral Thesis submitted by K.J. Burger to the Freie Universität Berlin     

Studies on the structure of replicative intermediates in bacteriophage M13 single stranded DNA synthesis.

Pulse-labeled replicative intermediates in M 13 single stranded DNA synthesis can be separated by dye-buoyant density centrifugation into two major fractions: Supercoiled molecules (RI I) containing viral strands of more than one genome length, and "relaxed" molecules (RI II) with labeled DNA chains shorter than unit length. It is postulated that RI II molecules might be formed in vivo by site-specific nicking of RF I molecules.     

Dimeric circular duplex DNA of bacteriophage phiX174 and recombination

Summary Bacteriophage X174 replicative from DNA (RF DNA) was formed in the presence of chloramphenicol at a concentration of 40 g per ml and isolated at 12 and at 55 min. after infection. The component I RF DNA (double stranded covalently closed and twisted form) was separated and divided into a monomer and multimer (dimer) fraction.The frequency of recombinants found after phage formation in the chloramphenicol treated cells and that found after spheroplast infection with the monomer molecules both increase with the time of RF formation. However, the frequency of recombinant molecules among the dimers remained constant. This finding is explained by the hypothesis that two separate mechanisms act in X174 recombination, one of which is restricted to the formation of dimers.Irradiation with UV of phage prior to infection showed that the frequency of recombinants in monomers increased, as the recombination frequency of phage after (a single) growth (step) did, but that neither the frequency of recombinant molecules in dimers is raised, nor the frequency of dimers. Using a recombination negative host the frequency of recombinant dimer molecules was three to fourfold decreased, whereas the frequency of dimers was only slightly lower (relative to the normal host). These results support the hypothesis mentioned above and moreover lend support to the view that the greater part of the dimers is not formed by recombination events.     

An immunochemical characterization of glucosylation in bacteriophage T4

A filter retention assay was used to examine the immunochemical reactivity of denatured T4 phage DNA fragments. In wild-type DNA, all fragments are completely reactive with antibody directed to α-glucosylhydroxymethylcytosinyl residues and 70% are reactive with anti-β-glucosylhydroxymethylcytosinyl. Separated r-strands react in a manner identical to that observed with unfractionated DNA. DNA from phage stocks of glucosyl transferase mutants or T41 phage react to different extents with the various antibodies, and the level of immunochemical reactivity correlates with the efficiency of plating on a restrictive host.When phage with non-glucosylated DNA infect a host under glucosylating conditions, the parental phage molecules become glucosylated. The parental DNA acquires complete α-glucosyl reactivity within ten minutes of infection, while β-glucosylation is slower and only approaches wild-type levels towards the end of the infectious cycle.We describe immunochemical methods for fractionating mixtures of antigenically distinct T4 DNA molecules and apply them to the isolation of recombinant parental DNA. The kinetics of recombination under different physiological conditions are examined by this technique.     

Complex of bacteriophage M13 single-stranded DNA and gene 5 protein

Lysates of bacteriophage M13-infected cells contain numerous unbranched filamentous structures approximately 1·1 μm long × 160 Å wide, that is, slightly longer and considerably wider than M13 virions. These structures are complexes of viral single-stranded DNA molecules with M13 gene 5 protein, a non-capsid protein required for single-stranded DNA production. All, or nearly all, of the single-stranded DNA from the infected cells and at least half to two-thirds of the gene 5 protein molecules are found as complex in the lysates. The complex contains about 1300 gene 5 protein molecules per DNA molecule but little if any of the two known capsid proteins. The complex is much less stable than virions in the presence of salt or ionic detergent solutions and in electron micrographs it appears to have a much looser and more open structure. If an excess of M13 single-stranded DNA is added to complex in a lysate, the gene 5 protein molecules from the complex redistribute onto all of the added as well as the original DNA, again suggesting a rather loose association of protein and DNA.By electron microscopy, the complex from infected cells appears to differ structurally from complex formed in vitro between purified single-stranded DNA and purified gene 5 protein. Because of this apparent structural difference and because previous experiments suggested the presence of complex in vivo, we presume that the complex which we have found in lysates of infected cells previously did exist as such inside the cells, but we have been unable to exclude that it formed during or after lysis. If it is assumed that complex does occur in vivo, the results of pulse-chase radioactive labeling experiments on infected cells can be interpreted as showing that with time the single-stranded DNA leaves complex, presumably to be matured into virions, while the gene 5 protein molecules are re-used to form more complex.     

Structure of replicating DNA molecules of Bacillus subtilis bacteriophage phi 29.

We isolated phi 29 DNA replicative intermediates from extracts of phage-infected Bacillus subtilis, pulsed-labeled with [3H]thymidine, by velocity sedimentation in neutral sucrose followed by CsCl equilibrium density gradient centrifugation. During a chase, the DNA with a higher sedimentation coefficient in neutral sucrose and a lower sedimentation rate in alkaline sucrose than that of viral phi 29 DNA was converted into mature DNA. The material with a density higher than that of mature phi 29 DNA consisted of replicative intermediates, as analyzed with an electron microscope. We found two major types of molecules. One consisted of unit-length duplex DNA with one single-stranded branch at a random position. The length of the single-stranded branches was similar to that of one of the double-stranded regions. The other type of molecules was unit-length DNA with one double-stranded region and one single-stranded region extending a variable distance from one end. Partial denaturation of the latter molecules showed that replication was initiated with a similar frequency from either DNA end. These findings suggest that phi 29 DNA replication occurs by a mechanism of strand displacement and that replication starts non-simultaneously from either DNA end, as in the case of adenovirus.     

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.     

Packing of binding stained DNA strands in bacteriophage lambda

Distribution of stainable DNA strands in phage lambda has been studied by polarized fluorescence. The effect of tight DNA-packing on fluorescence depolarization of complex dye-DNA was calculated. It is shown that stainable DNA in the phage is not concentrated in the central region. The arrangement of acridine orange molecules on the surface layers of the packed DNA is the most probable one.     

Structural aberrations in T-even bacteriophage. VI. Molecular weight of DNA from giant heads

Cummings et al. (1973) reported that whenl-canavanine was chased from a T-even. bacteriophage-infected culture with its analog,l-arginine, a new type of aberrant particle was formed. These particles, which were termed “lollipops”, had giant heads as long as 44 normal head lengths, and were filled with DNA. We have now separated these particles into different size classes ranging from about three to 13 normal head lengths and measured the molecular weight of their DNA. The DNA released from intact phage particles by neutral or alkaline detergent lysis was characterized using a recently described biophysical technique which determines DNA molecular weight from solution viscoelasticity. The maximum DNA size correlated roughly with phage head length, indicating that these giant heads were often filled with single, long DNA molecules rather than with several normal-sized molecules. Many of the heads, however, must have contained several molecules, since a large amount of DNA of less than maximum size was present. In alkali the native molecules separated into single strands of approximately the same length as that of the native molecules.