Small Staphylococcus aureus plasmids are transduced as linear multimers that are formed and resolved by replicative processes

The molecular processes involved in the transduction of small staphylococcal plasmids by a generalized transducing phage, phi 11, have been analysed. The plasmids are transduced in the form of linear concatemers containing only plasmid DNA; plasmid-initiated replication is required for their generation but additive interplasmid recombination is not. Concatemers are probably generated by the interaction of one or more phage functions with replicating plasmid DNA. Insertion of any restriction fragment of the phage into the plasmid causes an approximately 10(5)-fold increase in transduction frequency, regardless of the size or genetic content of the fragment. The resulting transducing particles (Hft particles) contain mostly pure linear concatemers composed of tandem repeats of the plasmid::phage chimera, and their production requires active plasmid-initiated replication. The high frequency of transduction is a consequence of homologous recombination between the linear chimeric and phage concatemers, which has the effect of introducing an efficient pac site into the former. Following introduction into lysogenic recipient bacteria, the transducing DNA is first converted to the supercoiled form, then processed to monomers by a mechanism that requires the active participation of the plasmid replication system.     

Bacteriophage T7 DNA packaging. I. Plasmids containing a T7 replication origin and the T7 concatemer junction are packaged into transducing particles during phage infection

Bacteriophage T7 DNA is a linear duplex molecule with a 160 base-pair direct repeat (terminal redundancy) at its ends. During replication, large DNA concatemers are formed, which are multimers of the T7 genome linked head to tail through recombination at the terminal redundancy. We define the sequence that results from this recombination, a mature right end joined to the left end of T7 DNA, as the concatemer junction. To study the processing and packaging of T7 concatemers into phage particles, we have cloned the T7 concatemer junction into a plasmid vector. This plasmid is efficiently (at least 15 particles/infected cell) packaged into transducing particles during a T7 infection. These transducing particles can be separated from T7 phage by sedimentation to equilibrium in CsCl. The packaged plasmid DNA is a linear concatemer of about 40 x 10(3) base-pairs with ends at the expected T7 DNA sequences. Thus, the T7 concatemer junction sequence on the plasmid is recognized for processing and packaging by the phage system. We have identified a T7 DNA replication origin near the right end of the T7 genome that is necessary for efficient plasmid packaging. The origin, which is associated with a T7 RNA polymerase promoter, causes amplification of the plasmid DNA during T7 infection. The amplified plasmid DNA sediments very rapidly and contains large concatemers, which are expected to be good substrates for the packaging reaction. When cloned in pBR322, a sequence containing only the mature right end of T7 DNA is sufficient for efficient packaging. Since this sequence does not contain DNA to the right of the site where a mature T7 right end is formed, it was expected that right ends would not form on this DNA. In fact, with this plasmid the right end does not form at the normal T7 sequence but is instead formed within the vector. Apparently, the T7 packaging system can also recognize a site in pBR322 DNA to produce an end for packaging. This site is not recognized solely by a "headful" mechanism, since there can be considerable variation in the amount of DNA packaged (32 x 10(3) to 42 x 10(3) base-pairs). Furthermore, deletion of this region from the vector DNA prevents packaging of the plasmid. The end that is formed in vector DNA is somewhat heterogeneous. About one-third of the ends are at a unique site (nucleotide 1712 of pBR322), which is followed by the sequence 5'-ATCTGT-3'. This sequence is also found adjacent to the cut made in a T7 DNA concatemer to produce a normal T7 right end.     

Involvement of the bacterial groM gene product in bacteriophage T7 reproduction. I. Arrest at the level of DNA packaging

The multiplication of bacteriophage T7 is blocked in Escherichia coli M. The genetic determinant of this ability (groM) to inhibit T7 growth was transferred to an E. coli K-12 recipient by means of conjugation. We determined at which precise step T7 maturation is blocked. Phage-directed protein and DNA synthesis as well as degradation of host DNA were not qualitatively affected. Instead of infective phages, only preheads were produced. These, however, were maturable in vitro. The newly synthesized phage DNA accumulated in a concatemeric form and matured from its tetrameric or longer forms (very fast sedimenting DNA) only into its dimeric form (fast-sedimenting DNA) or longer forms. The following step, i.e., the maturation of the dimeric to unit-length DNA, was not observed. Since the concatemeric form of T7 DNA accumulated in spite of the presence of maturable preheads, it is likely that the maturation process was blocked at the level of DNA packaging. As intermediates in the packaging process, we found some prehead-DNA complexes. We interpreted these as true assembly intermediates (or breakdown products thereof), since the attached DNA was still in its concatemeric form. This shows that the very first DNA packaging step, the binding of the progeny DNA to the preheads, was obviously not blocked. Rather, a later step, such as the filling of the preheads with T7 DNA or the stabilization of completely packaged particles (i.e., the final cutting of the concatemers into unit-size length), was inhibited.     

Bacteriophage T7 DNA packaging. III. A "hairpin" end formed on T7 concatemers may be an intermediate in the processing reaction

An unusual left end (M-end) has been identified on bacteriophage T7 DNA isolated from T7-infected cells. This end has a "hairpin" structure and is formed at a short inverted repeat sequence centered around nucleotide 39,587 of T7, 190 base-pairs to the left of the site where a mature left end is formed on the T7 concatemer. We do not detect the companion right end that would be formed if the M-end is produced by a double-stranded cut on the T7 concatemer. This suggests that the hairpin left end may be generated from a single-stranded cut in the DNA that is used to prime rightward DNA synthesis. The formation of M-end does not require the products of T7 genes 10, 18 or 19, proteins that are essential for the formation of mature T7 ends. During infection with a T7 gene 3 (endonuclease) mutant, phage DNA synthesis is reduced and the concatemers are not processed into unit length DNA molecules, but both M-end and the mature right end are formed on the concatemer DNA. These two ends are also found associated with the large, rapidly sedimenting concatemers formed during a normal T7 infection while the mature left end is present only on unit length T7 DNA molecules. We propose that DNA replication primed from the hairpin end produced by a nick in the inverted repeat sequence provides a mechanism to duplicate the terminal repeat before DNA packaging. Packaging is initiated with the formation of a mature right end on the branched concatemer and, as the phage head is filled, the T7 gene 3 endonuclease may be required to trim the replication forks from the DNA. Concatemer processing is completed by the removal of the 190 base-pair hairpin end to produce the mature left end.     

DNA Replication of Induced Prophage in Haemophilus influenzae

DNA synthesis during transition from the lysogenic state to the lytic cycle and throughout the latter has been studied in Haemophilus influenzae BC200 (HP1c1). Following exposure to ultraviolet light, there is a 30-min delay in DNA synthesis after which there is a rapidly increasing rate of phage DNA synthesis. The phage genome is replicated without extensive utilization of segments or of breakdown products of the bacterial chromosome. The mode of phage DNA replication was investigated by zonal sedimentation of labeled DNA in 5 to 20% neutral and alkaline sucrose gradients. Tritiated thymidine, incorporated during a 2-min pulse given at 38 min, chases rapidly into DNA, sedimenting like linear DNA of approximately 2 x 10(8) daltons, and then, at the expense of label in this peak, chases into slower-sedimenting phage DNA (2 x 10(7) daltons). The fast-sedimenting, rapidly labeled DNA satisfies certain criteria for being a concatenated replicative intermediate. Observations in the electron microscope revealed linear concatemers in the faster-sedimenting material and circular phage-sized DNA in the slower-sedimenting DNA. When induced cells are gently lysed with lysozyme and Brij 58 to maintain DNA-membrane associations and sedimented in neutral sucrose over a cesium chloride shelf, the concatemer is found with the cell-membrane-wall complex. Membrane-associated label chases to membrane-free material sedimenting like deproteinized HP1c1 DNA. When membrane-associated DNA from the cesium chloride shelf is deproteinized and resedimented in neutral sucrose, the sedimentation profile reveals that sedimentation rates of labeled DNA from this complex are indicative of sizes ranging from 2 x 10(8) daltons down to phage-sized pieces of 2 to 3 x 10(7) daltons. A model is presented which places HP1c1-DNA replication on the cell membrane where a concatemer of phage DNA is synthesized and subsequently degraded to phage-equivalent DNA. Phage-equivalent DNA is then either released from the membrane for packaging or is packaged while still membrane associated. Thus, the cell membrane is not only the site of DNA replication during which phage DNA is synthesized in multiple phage-equivalent concatemers but it is also the site at which these concatemers are selectively reduced to phage-sized pieces.     

Recombination-dependent concatemeric plasmid replication.

The replication of covalently closed circular supercoiled (form I) DNA in prokaryotes is generally controlled at the initiation level by a rate-limiting effector. Once initiated, replication proceeds via one of two possible modes (theta or sigma replication) which do not rely on functions involved in DNA repair and general recombination. Recently, a novel plasmid replication mode, leading to the accumulation of linear multigenome-length plasmid concatemers in both gram-positive and gram-negative bacteria, has been described. Unlike form I DNA replication, an intermediate recombination step is most probably involved in the initiation of concatemeric plasmid DNA replication. On the basis of structural and functional studies, we infer that recombination-dependent plasmid replication shares important features with phage late replication modes and, in several aspects, parallels the synthesis of plasmid concatemers in phage-infected cells. The characterization of the concatemeric plasmid replication mode has allowed new insights into the mechanisms of DNA replication and recombination in prokaryotes.     

Origin of Concatemeric T7DNA

The observed concatemers of T7 DNA are consistent with replication schemes resulting in double-helical molecules with 3´ ended tails. Right-ended and left-ended molecules can then join to form dimers which on further replication similarly form larger concatemers.     

Infecting bacteriophage mu DNA forms a circular DNA-protein complex

Upon superinfection of immune (lysogenic) cells with bacteriophage Mu, a form of Mu DNA accumulates that sediments about twice as fast as the linear phage DNA marker in neutral sucrose gradients. This form is also detected upon infection of sensitive cells with Mu. We have purified it and examined its physical nature. Under the electron microscope it appears circular and supertwisted. Upon treatment with Pronase, phenol or sodium dodecyl sulfate, however, it is converted to a linear Mu-length form, indicating that the circle is not covalently closed. The linear DNA still has heterogeneous host sequences at its termini. The circular DNA is resistant to the action of Escherichia coli exonuclease III and T7 exonuclease, but becomes sensitive to these nucleases after treatment with Pronase showing the presence of a protein that binds non-covalently to the ends of the DNA to circularize it as well as protect it from digestion with exonucleases. The complex is resistant to high salt (up to 6 M-NaCl) but can undergo transitions between forms that are partially open, open circular, linear and circular dimers and trimers. Examination of DNA from mature phage particles reveals that a circular DNA species is present in at least 0.1 to 1% of the population. The purified complex is extremely efficient in transfection of E. coli spheroplasts. We estimate the molecular weight of the protein in this DNA-protein complex to be approximately 64,000, and suggest that this complex might represent the integrative precursor of infecting Mu DNA.     

Concatemers in DNA replication: Electron microscopic studies of partially denatured intracellular lambda DNA

We have verified, by identification of individual molecules in the electron microscope, that λ DNA concatemers are long linear molecules containing repeats of the mature phage DNA sequence. The molecules are not made up of whole multiples of the length of mature λ DNA and do not seem to contain specific start or end points. The concatemers, comprising about 20% of the molecular forms extracted late in infection, can be found in the absence of genetic recombination and in the presence or absence of maturation defects. It may be concluded that concatemers are normal intermediates in the late stage of λ replication.     

Studies on an Endonuclease Activity Associated with the Bacteriophage T7 DNA-Membrane Complex

Infection of Escherichia coli with bacteriophage T7 results in the formation of an endonuclease which is selectively associated with the T7 DNA-membrane complex. A specificity of association with the complex is indicated by the finding that the enzyme is completely resolved from a previously described T7 endonuclease I. When membrane complexes containing (3)H-labeled in vivo synthesized DNA are incubated in the standard reaction mixture a specific cleavage product is formed which is about one-fourth the size of T7 DNA. The endonuclease associated with the complex produces a similar cleavage product after extensive incubation with native T7 DNA or T7 concatemers. Degradation of concatemers occurs by a mechanism in which the DNA is converted to molecules one-half the size of T7. This product is in turn converted to fragments one-fourth the size of mature phage DNA. The endonuclease is not present in membrane complexes from uninfected cells or cells infected with gene 1 mutants. The enzyme activity is, however, present in cells infected with mutants defective in T7 DNA synthesis or maturation.     

Multidimensional analysis of intracellular bacteriophage T7 DNA: effects of amber mutations in genes 3 and 19.

By use of rate-zonal centrifugation, followed by either one- or two-dimensional agarose gel electrophoresis, the forms of intracellular bacteriophage T7 DNA produced by replication, recombination, and packaging have been analyzed. Previous studies had shown that at least some intracellular DNA with sedimentation coefficients between 32S (the S value of mature T7 DNA) and 100S is concatemeric, i.e., linear and longer than mature T7 DNA. The analysis presented here confirmed that most of this DNA is linear, but also revealed a significant amount of circular DNA. The data suggest that these circles are produced during DNA packaging. It is proposed that circles are produced after a capsid has bound two sequential genomes in a concatemer. The size distribution of the linear, concatemeric DNA had peaks at the positions of dimeric and trimeric concatemers. Restriction endonuclease analysis revealed that most of the mature T7 DNA subunits of concatemers were joined left end to right end. However, these data also suggest that a comparatively small amount of left-end to left-end joining occurs, possibly by blunt-end ligation. A replicating form of T7 DNA that had an S value greater than 100 (100S+ DNA) was also found to contain concatemers. However, some of the 100S+ DNA, probably the most branched component, remained associated with the origin after agarose gel electrophoresis. It has been found that T7 protein 19, known to be required for DNA packaging, was also required to prevent loss, probably by nucleolytic degradation, of the right end of all forms of intracellular T7 DNA. T7 gene 3 endonuclease, whose activity is required for both recombination of T7 DNA and degradation of host DNA, was required for the formation of the 32S to 100S molecules that behaved as concatemers during gel electrophoresis. In the absence of gene 3 endonuclease, the primary accumulation product was origin-associated 100S+ DNA with properties that suggest the accumulation of branches, primarily at the left end of mature DNA subunits within the 100S+ DNA.     

The plasmid prophage N15: a linear DNA with covalently closed ends

Coliphage N15 is a temperate bacteriophage whose prophage is a linear plasmid molecule with covalently closed ends (telomeres). The N15 prophage provided the first example of such DNA in prokaryotes and, up to now, it is the only known example of a linear plasmid in Escherichia coli. The linear N15 mature phage DNA has single-stranded cohesive ends. The phage and plasmid prophage DNAs are circularly permuted. The nucleotide structure of the telomere-forming site tel RL in phage DNA corresponds to the structures of the terminal hairpin loops. It suggests a unique mechanism for conversion of the circular phage DNA to the linear plasmid form, which is performed by the prokaryotic telomerase (protelomerase). The results of a comparison of the protelomerase with integrases lead us to suggest that these proteins may have evolved from a common ancestor. The mechanism of plasmid N15 replication is unknown. We propose that the protelomerase participates in linear plasmid replication, acting as a resolvase of replicative intermediates that are tail-to-tail linear dimers. The sequence analysis of the N15 DNA showed that it represents an evolutionary 'link' between plasmids F, P1, P4 and lambdoid bacteriophages.     

Multiple Initiation of Bacteriophage T4 DNA Replication: Delaying Effect of Bromodeoxyuridine

Effects of bromodeoxyuridine (BUdR) substitutions in phage T4 DNA on the initial stages of DNA replication were investigated. Electron microscope studies of partially replicated, light (thymidine-containing) T4 DNA revealed the presence of multiple loops and forks. These DNA preparations had no BUdR in either parental or newly synthesized DNA, and the observations thus show that multiple initiation of DNA replication is a normal event in T4 development and is not caused by the presence of BUdR. A comparison of early replicative stages of light and heavy (BUdR-containing) DNA in cells mixedly infected with light and heavy T4 phage showed that early DNA synthesis occurs preferentially on the light template. Heavy and light parental DNA became associated with the protein complex of replicative DNA with equal efficiency, and there was no effect of BUdR on the net rate of DNA synthesis after infection. Newly synthesized DNA from heavy templates sedimented more slowly through alkaline sucrose gradients than did newly synthesized DNA from light templates and appeared to represent fewer replicative regions per molecule. These data indicate that BUdR substitutions in the DNA caused a slight delay in initiation but that replication of heavy DNA proceeded normally once initiated.     

Der Einfluss extrazellul?rer UV-Bestrahlung des Phagen T2 auf die Replikation Seiner DNA

Summary The effects of extracellular UV-irradiation on the replication of DNA were tested with phage T2. Cells ofE. coli B/1 were multiply infected with UV-irradiated T2. The kinetics of P³²-incorporation into phage DNA were significantly different from the unirradiated control.With unirradiated phages the time curve is linear during the second half of the latent period after as short nonlinear increase. With UV-irradiated phages however the amount of DNA increases exponentially during the whole latent period. Such kinetics might be expected from semiconservative DNA-replication if templates were limiting. The reported findings suggest that other regulatory mechanisms normally limiting DNA-synthesis are inactivated by UV. The kinetics determined by semiconservative replication could then be clearly observed with irradiated phages. The nature of the normally regulating mechanisms is discussed.

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Persistence and replication of plasmid DNA microinjected into early embryos of Xenopus laevis

The persistence and replication of defined circular and linear plasmid DNA molecules microinjected into fertilized eggs of Xenopus laevis were analyzed. For all plasmids tested, a small fraction of microinjected circular molecules was replicated; however, the overall copy numbers of either free form I or form II molecules usually did not increase through blastulation. In contrast, extensive amplification of input DNA sequences was seen whenever the microinjected DNA was assembled into high molecular weight concatemers. Moreover, the appearance and subsequent replication of injected sequences in high molecular weight DNA were enhanced when linear (form III), rather than circular, molecules were microinjected. The injected form III DNA was rapidly converted into long linear concatemers. All possible orientations of monomeric molecules within the concatemers were observed although, on occasion, head-to-tail orientations were favored. Long linear concatemers were replicated very efficiently, irrespective of the sequence of the input DNA. Form I and form II DNA molecules were also formed in the embryo from microinjected form III DNA. A small fraction of these circular forms was replicated, although overall copy numbers did not increase significantly. Form III molecules that remained monomeric were not observed to be replicated at all within our limits of detection. In some batches of embryos, form I and form II DNA molecules were replicated to the extent that overall copy number increased. Even in these cases, however, the amplification of long linear concatemers of the input DNA sequences was more efficient.     

Bypass of a primase requirement for bacteriophage T4 DNA replication in vivo by a recombination enzyme, endonuclease VII.

A primase, the product of phage T4 gene 61, is required to initiate synthesis of Okazaki pieces and to allow bidirectional replication from several T4 origins. However, primase-defective T4 gene 61 mutants are viable. In these mutants, leading-strand DNA synthesis starts at the same time as in wild type infections, but, in contrast to wild type, initiation is unidirectional and the first replicative intermediates are large displacement loops. Rapid double-strand DNA replication occurs later after infection, generating multiple branched concatemers, which are cut and packaged into viable progeny particles, as in wild-type T4. Evidence is presented that this late double-strand DNA replication requires functional endonuclease VII (endo VII), the product of the T4 gene 49. We propose that endo VII can provide a backup mechanism when primase is defective, because it cuts recombinational junctions, generating 3' ends. These ends can prime DNA synthesis to copy the DNA strands that had been displaced during the initial origin-dependent replication. We explain the DNA-delay phenotype and the commonly observed temperature dependence of DNA replication in primase-deficient gene 61 mutants as a consequence of temperature-dependent translational control of gene 49 expression. In the presence or absence of functional primase endo VII is essential for correct packaging of DNA. The powerful selection that keeps the function of endo VII and expression of its gene at levels that are optimal for T4 development determines both the efficiency and the limitations of the bypass mechanism.     

Mechanism of pBR322 transduction mediated by cytosine-substituting T4 bacteriophage

Summary A cytosine-substitution type mutant of bacteriophage T4 (T4dC phage) has been shown to mediate the transfer of plasmid pBR322. The transduction frequency was around 10^-2 per singly infected cell at low multiplicity of infection. The transductants contained either a monomer or multimers of pBR322. The transducing capacity of T4dC phage was resistant to methylmethanesulfonate treatment. The results of Southern blotting experiments have indicated that the pBR322 DNA exists as head-to-tail concatemers in the transducing particles. The mechanism of transfer of pBR322 mediated by T4dC phages is discussed     

In vivo inhibition of trypanosome mitochondrial topoisomerase II: effects on kinetoplast DNA maxicircles.

Kinetoplast DNA, the mitochondrial DNA of trypanosomes, is a topologically complex structure composed of interlocked minicircles and maxicircles. We previously reported that etoposide, a potent inhibitor of topoisomerase II, promotes the cleavage of about 20% of network minicircle DNA (T. A. Shapiro, V. A. Klein, and P. T. Englund, J. Biol. Chem. 264:4173-4178, 1989). We now find that virtually all maxicircles are released from kinetoplast DNA networks after trypanosomes are treated with etoposide. As expected for a topoisomerase II cleavage product, the linearized maxicircles have protein bound to both 5' ends. After etoposide treatment, the residual minicircle catenanes have a sedimentation coefficient which is only 70% that of controls, and by electron microscopy the networks are less compact. Double-size networks, the characteristic dumbbell-shape forms that normally arise in the final stages of network replication, are replaced by aberrant unit-size forms.     

Recombination-dependent replication of plasmids during bacteriophage T4 infection

The replication of plasmids containing fragments of the T4 genome, but no phage replication origins, was analyzed as a possible model for phage secondary (recombination-dependent) replication initiation. The replication of such plasmids after T4 infection was reduced or eliminated by mutations in several phage genes (uvsY, uvsX, 46, 59, 39, and 52) that have previously been shown to be involved in secondary initiation. A series of plasmids that collectively contain about 60 kilobase pairs of the T4 genome were tested for replication after T4 infection. With the exception of those known to contain tertiary origins, every plasmid replicated in a uvsY-dependent fashion. Thus, there is no apparent requirement for an extensive nucleotide sequence in the uvsY-dependent plasmid replication. However, homology with the phage genome is required since the plasmid vector alone did not replicate after phage infection. The products of plasmid replication included long concatemeric molecules with as many as 35 tandem copies of plasmid sequence. The production of concatemers indicates that plasmid replication is an active process and not simply the result of passive replication after the integration of plasmids into the phage genome. We conclude that plasmids with homology to the T4 genome utilize the secondary initiation mechanism of the phage. This simple model system should be useful in elucidating the molecular mechanism of recombination-dependent DNA synthesis in phage T4.     

The role of bacteriophage T7 exonuclease (gene 6) in genetic recombination and production of concatemers

Genetic analysis reported here shows that bacteriophage T7 exonuclease (gene 6) is necessary for intragenic and intergenic recombination in several areas of the T7 genetic map. This supports our previous conclusion (Lee & Miller, 1974) that the enzyme is necessary for T7 molecular recombination.Results of sucrose gradient analysis show that DNA concatemers are formed when both the T7 exonuclease (gene 6) and the T7 endonuclease (gene 3) are absent. Further results show that concatemers cannot be maintained in the absence of the exonuclease unless the endonuclease is also eliminated. Therefore, concatemers are formed by a process other than normal phage recombination. Selective defects in the recombination system do interfere with the stability of concatemers, however.