Intracellular organization of bacteriophage T7 DNA: analysis of parenteral bacteriophage T7 DNA-membrane and DNA-protein complexes.

After infection of Escherichia coli with bacteriophage T7, the parenteral DNA forms a stable association with host cell membranes. The DNA-membrane complex isolated in cesium chloride gradients is free of host DNA and the bulk of T7 RNA. The complex purified through two cesium chloride gradients contains a reproducible set of proteins which are enriched in polypeptides having molecular weights of 54,000, 34,000, and 32,000. All proteins present in the complex are derived from host membranes. Treatment of the complex with Bruij-58 removes 95% of the membrane lipid and selectively releases certain protein components. The Brij-treated complex has an S value of about 1,000 and the sedimentation rate of this material is not altered by treatment with Pronase or RNase.     

Association of Replicative T4 Deoxyribonucleic Acid and Bacterial Membranes

Experiments utilizing CsCl density gradient analysis and radioactive labels specific for bacteriophage T4 deoxyribonucleic acid (DNA) and membranes have shown that replicative T4 DNA is associated with host membranes. The association is inhibited by chloramphenicol and takes place just prior to semi-conservative replication of the phage DNA.     

In Vitro Packaging of UV Radiation-Damaged DNA from Bacteriophage T7

When DNA from bacteriophage T7 is irradiated with UV light, the efficiency with which this DNA can be packaged in vitro to form viable phage particles is reduced. A comparison between irradiated DNA packaged in vitro and irradiated intact phage particles shows almost identical survival as a function of UV dose when Escherichia coli wild type or polA or uvrA mutants are used as the host. Although uvrA mutants perform less host cell reactivation, the polA strains are identical with wild type in their ability to support the growth of irradiated T7 phage or irradiated T7 DNA packaged in vitro into complete phage. An examination of in vitro repair performed by extracts of T7-infected E.coli suggests that T7 DNA polymerase may substitute for E. coli DNA polymerase I in the resynthesis step of excision repair. Also tested was the ability of a similar in vitro repair system that used extracts from uninfected cells to restore biological activity of irradiated DNA. When T7 DNA damaged by UV irradiation was treated with an endonuclease from Micrococcus luteus that is specific for pyrimidine dimers and then was incubated with an extract of uninfected E. coli capable of removing pyrimidine dimers and restoring the DNA of its original (whole genome size) molecular weight, this DNA showed a higher packaging efficiency than untreated DNA, thus demonstrating that the in vitro repair system partially restored the biological activity of UV-damaged DNA.     

Modification of intracellular membrane structures for virus replication

Viruses are intracellular parasites that use the host cell they infect to produce new infectious progeny. Distinct steps of the virus life cycle occur in association with the cytoskeleton or cytoplasmic membranes, which are often modified during infection. Plus-stranded RNA viruses induce membrane proliferations that support the replication of their genomes. Similarly, cytoplasmic replication of some DNA viruses occurs in association with modified cellular membranes. We describe how viruses modify intracellular membranes, highlight similarities between the structures that are induced by viruses of different families and discuss how these structures could be formed.     

Purification and structures of recombining and replicating bacteriophage T7 DNA.

During the infection of Escherichia coli by bacteriophage T7, there is a gradual conversion of host DNA to T7 DNA. Recombination and replication occur during this time. We have devised a new way of examining the physical structures of the intermediates of these processes. It is based on the observation that there are no sites in T7 DNA susceptible to cleavage by the restriction endonuclease EcoRI. E. coli DNA, on the other hand, is susceptible to degradation by EcoRI. Thus, phage and host DNA can be separated by sucrose gradient centrifugation after treatment with EcoRI. Concatemeric T7 DNA contains a high proportion of branched, gapped, and whiskered structures. These appear to be intermediates of replication and recombination. This approach also monitors the conversion process from host to T7 DNA.     

Separation of T-even Bacteriophage Deoxyribonucleic Acid from Host Deoxyribonucleic Acid by Hydroxyapatite Chromatography

A simple and rapid method is described for separation of T-even bacteriophage deoxyribonucleic acid (DNA) from host (Escherichia coli) DNA by hydroxyapatite column chromatography with a shallow gradient of phosphate buffer at neutral pH. By this method, bacteriophage T2, T4, and T6 DNA (but not T5, T7, or lambda DNA) could be separated from host E. coli DNA. It was found that glucosylation of the T-even phage DNA is an important factor in separation.     

Ataxia telangiectasia-mutated damage-signaling kinase- and proteasome-dependent destruction of Mre11-Rad50-Nbs1 subunits in Simian virus 40-infected primate cells

Although the mechanism of simian virus 40 (SV40) DNA replication has been extensively investigated with cell extracts, viral DNA replication in productively infected cells utilizes additional viral and host functions whose interplay remains poorly understood. We show here that in SV40-infected primate cells, the activated ataxia telangiectasia-mutated (ATM) damage-signaling kinase, gamma-H2AX, and Mre11-Rad50-Nbs1 (MRN) assemble with T antigen and other viral DNA replication proteins in large nuclear foci. During infection, steady-state levels of MRN subunits decline, although the corresponding mRNA levels remain unchanged. A proteasome inhibitor stabilizes the MRN complex, suggesting that MRN may undergo proteasome-dependent degradation. Analysis of mutant T antigens with disrupted binding to the ubiquitin ligase CUL7 revealed that MRN subunits are stable in cells infected with mutant virus or transfected with mutant viral DNA, implicating CUL7 association with T antigen in MRN proteolysis. The mutant genomes produce fewer virus progeny than the wild type, suggesting that T antigen-CUL7-directed proteolysis facilitates virus propagation. Use of a specific ATM kinase inhibitor showed that ATM kinase signaling is a prerequisite for proteasome-dependent degradation of MRN subunits as well as for the localization of T antigen and damage-signaling proteins to viral replication foci and optimal viral DNA replication. Taken together, the results indicate that SV40 infection manipulates host DNA damage-signaling to reprogram the cell for viral replication, perhaps through mechanisms related to host recovery from DNA damage.     

Replicative Intermediates of Bacteriophage T7 Deoxyribonucleic Acid

After infection with bacteriophage T7, parental and newly synthesized deoxyribonucleic acid (DNA) exhibit an extremely fast sedimentation rate in neutral sucrose gradients. This fast-sedimenting component (intermediate I) has a sedimentation constant of about 1,500S and contains T7 DNA as determined by DNA-DNA hybridization experiments. Pulse-chase experiments indicate that the fast-sedimenting material is metabolically active and serves as a precursor to the formation of T7 DNA. Intermediate I contains about 2.5 to 7% of the total ³H-labeled protein formed between 3 and 9.5 min after T7 infection. Treatment of intermediate I with Pronase results in the release of the DNA from the complex. At early times after infection, a second intermediate (intermediate II) can be detected which contains both parental and newly synthesized DNA sedimenting slower than intermediate I but 2 to 3 times as fast as mature T7 DNA. Intermediates I and II containing parental DNA are formed after infection of the nonpermissive host with an amber mutant in gene 1, a gene whose expression is necessary for the synthesis of most T7 proteins. The two intermediates are also observed when infection with T7 wild type is carried out in the presence of chloramphenicol.     

Differences in sensitivity of T3, T7, T4 and lambda phages to bleomycin and phleomycin]

In contrast to phage lambda the phages T3, T7 and T4 are not inhibited by as much as 150 microgram bleomycin/ml, while the chemically related antibiotic phleomycin increasingly inhibits the propagation of the phages in the order T4-T3-lambda. 20 microgram phleomycin/ml inhibit T3 by 95%. The resistance against bleomycin is surprising, because 10 microgram BM/ml block completely the colony-forming capacity of the host bacterium. The drug resistance of the phage growth correlates with the weak decrease of phage DNA synthesis, while the host cell DNA synthesis ceases rapidly. In accordance with these data is the in vivo inhibition of Escherichia coli cells and the in vitro degradation of their DNA. However, a contradiction exists between the in vivo resistance of T3 and T4 and the in vitro susceptibility of their DNA against nucleolytical fragmentation by bleomycin. The mechanism of the insensitivity of T3, T7 and T4 against bleomycin is unknown.     

Inadequate inhibition of host RNA polymerase restricts T7 bacteriophage growth on hosts overexpressing udk

Overexpression of udk, an Escherichia coli gene encoding a uridine/cytidine kinase, interferes with T7 bacteriophage growth. We show here that inhibition of T7 phage growth by udk overexpression can be overcome by inhibition of host RNA polymerase. Overexpression of gene 2, whose product inhibits host RNA polymerase, restores T7 phage growth on hosts overexpressing udk. In addition, rifampicin, an inhibitor of host RNA polymerase, restores the burst size of T7 phage on udk-overexpressing hosts to normal. In agreement with these findings, suppressor mutants that overcome the inhibition arising from udk overexpression gain the ability to grow on hosts that are resistant to inhibition of RNA polymerase by gene 2 protein, and suppressor mutants that overcome a lack of gene 2 protein gain the ability to grow on hosts that overexpress udk. Mutations that eliminate or weaken strong promoters for host RNA polymerase in T7 DNA, and mutations in T7 gene 3.5 that affect its interaction with T7 RNA polymerase, also reduce the interference with T7 growth by host RNA polymerase. We propose a general model for the requirement of host RNA polymerase inhibition.     

Rescue of abortive T7 gene 2 mutant phage infection by rifampin.

Infection of Escherichia coli with T7 gene 2 mutant phage was abortive; concatemeric phage DNA was synthesized but was not packaged into the phage head, resulting in an accumulation of DNA species shorter in size than the phage genome, concomitant with an accumulation of phage head-related structures. Appearance of concatemeric T7 DNA in gene 2 mutant phage infection during onset of T7 DNA replication indicates that the product of gene 2 was required for proper processing or packaging of concatemer DNA rather than for the synthesis of T7 progeny DNA or concatemer formation. This abortive infection by gene 2 mutant phage could be rescued by rifampin. If rifampin was added at the onset of T7 DNA replication, concatemeric DNA molecules were properly packaged into phage heads, as evidenced by the production of infectious progeny phage. Since the gene 2 product acts as a specific inhibitor of E. coli RNA polymerase by preventing the enzyme from binding T7 DNA, uninhibited E. coli RNA polymerase in gene 2 mutant phage-infected cells interacts with concatemeric T7 DNA and perturbs proper DNA processing unless another inhibitor of the enzyme (rifampin) was added. Therefore, the involvement of gene 2 protein in T7 DNA processing may be due to its single function as the specific inhibitor of the host E. coli RNA polymerase.     

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.     

Amber Mutants of Bacteriophages T3 and T7 Defective in Phage-directed Deoxyribonucleic Acid Synthesis

Amber mutants of the related phages T3 and T7 were isolated and tested for their ability to restore-as the wild type does-thymidine incorporation in ultraviolet (UV)-irradiated, UV-sensitive, nonpermissive host bacteria (Escherichia coli B(s-1)). Most amber mutants had this ability. However, in both T3 and T7, mutants unable to promote thymidine incorporation under these conditions were found and classified into two well-defined complementation groups: T3DO-A and T3DO-B, T7DO-A and T7DO-B. Infection of B(s-1) cells with representatives of groups DO-A had the following characteristics: (i) phage-directed uridine uptake in UV-irradiated cells was reduced to less than 20% of normal; (ii) breakdown of host deoxyribonucleic acid (DNA) was delayed and incomplete; (iii) no serum-blocking antigens appeared; (iv) no cell lysis occurred; (v) the ability to exclude the heterologous wild type was impaired. Amber mutants of the DO-B groups, infecting B(s-1), were able to: (i) promote an efficient phage-directed uridine uptake in UV-irradiated cells; (ii) bring about rapid breakdown of host DNA; (iii) synthesize serum-blocking antigens; (iv) lyse the host cells, generally after the normal latent period; (v) exclude efficiently the heterologous wild type. Although physiological similarities between the respective DO-A mutants or DO-B mutants of T3 and T7 were evident, no physiological cross-complementation occurred, and genetic crosses gave no evidence of genetic homologies between groups of T3 and T7.     

Transport of phage P22 DNA across the cytoplasmic membrane

Although a great deal is known about the life cycle of bacteriophage P22, the mechanism of phage DNA transport into Salmonella is poorly understood. P22 DNA is initially ejected into the periplasmic space and subsequently transported into the host cytoplasm. Three phage-encoded proteins (gp16, gp20, and gp7) are coejected with the DNA. To test the hypothesis that one or more of these proteins mediate transport of the DNA across the cytoplasmic membrane, we purified gp16, gp20, and gp7 and analyzed their ability to associate with membranes and to facilitate DNA uptake into membrane vesicles in vitro. Membrane association experiments revealed that gp16 partitioned into the membrane fraction, while gp20 and gp7 remained in the soluble fraction. Moreover, the addition of gp16, but not gp7 or gp20, to liposomes preloaded with a fluorescent dye promoted release of the dye. Transport of ³²P-labeled DNA into liposomes occurred only in the presence of gp16 and an artificially created membrane potential. Taken together, these results suggest that gp16 partitions into the cytoplasmic membrane and mediates the active transport of P22 DNA across the cytoplasmic membrane of Salmonella.     

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.     

In vivo effects of recBC DNase, exonuclease I, and DNA polymerases of Escherichia coli on the infectivity of native and single-stranded DNA of bacteriophage T7.

The effect of several enzymes of the DNA metabolism of Escherichia coli on the biological activity of native and single-stranded T7 DNA was studied by transfection of lysozyme-EDTA spheroplasts prepared from various E. coli mutants. It is shown that the presence of the recBC DNase in the recipient cells decreases the infectivity of native and denatured DNA by about 100- and 10-fold, respectively. Lack of exonuclease I did not stimulate transfection by single-stranded DNA. Separated light (l) and heavy (r) strands of T7 DNA are fully infective, with a linear dependence on DNA concentrations, whereas heat-denatured DNA shows a two-hit kinetics. Single-stranded DNA was observed to depend on a functional DNA polymerase III for infectivity in polAB cells, whereas transfection with native T7 DNA was independent of the host DNA polymerases. The results are discussed with respect to the mode of T7 DNA replication.