Induction of theEscherichia coli UVM response by oxidative stress

UVM (ultravioletmodulation of mutagenesis) is a recently describedrecA-independent, inducible mutagenic phenomenon in which prior UV irradiation ofEscherichia coli cells strongly enhances mutation fixation at a site-specific 3-N⁴-ethenocytosine (C) lesion borne on a transfected single-stranded M13 DNA vector. Subsequent studies demonstrated that UVM is also induced by alkylating agents, and is distinct from both the SOS response and the adaptive response to alkylation damage. Because of the increasing significance being attributed to oxidative DNA damage, it is interesting to ask whether this class of DNA damage can also induce UVM. By transfecting M13 vector DNA bearing a site-specificC lesion into cells pretreated with inducing agents, we show here that the oxidative agent H₂O₂ is a potent inducer of UVM, and that the induction of UVM by H₂O₂ does not requireoxyR-regulated gene expression. UVM induction by H₂O₂ appears to be mediated by DNA damage, as indicated by the observation of a concomitant reduction in cellular toxicity and UVM response in OxyR^c cells. Available evidence suggests that UVM represents a generalized cellular response to a broad range of chemical and physical genotoxicants, and that DNA damage constitutes the most likely signal for its induction.     

HIV-1 integrase blocks infection of bacteria by single-stranded DNA and RNA bacteriophages

Expression of human immunodeficiency virus-1 integrase in Escherichia coli, at levels that had no effect on bacterial cell growth, blocked plaque formation by bacteriophages having single-stranded genomic DNA (M13) or RNA (R17, Q, PRR1). Plaque formation by phages having double-stranded genomic DNA (T4, PR4) was unaffected. Integrase also inhibited infection by the phagemid M13KO7, but it had no effect on production of phage once infection by M13KO7 was established. This result indicated that integrase affects an early stage in infection. Integrase also inhibited phage production following transfection by either single-stranded or double-stranded (replicative form) M13 DNA, it blocked M13 DNA replication, as assayed by incorporation of radioactive nucleotides into DNA, and it failed to affect bacterial pilus function. These data suggest that integrase interacts in vivo with phage nucleic acid, a conclusion supported by studies in which integrase was shown to have a DNA-binding activity in its C-terminal portion. This portion of integrase was both necessary and sufficient for interference of plaque formation by M13 in the present study. Expression of the N-terminal portion of integrase at the same level as intact integrase had little effect on phage growth, indicating that expression of foreign protein in general was not responsible for the inhibitory effect. The simple bacteriophage assay described is potentially useful for identifying integrase mutants that lack single-stranded DNA binding activity.     

Efficiency in cloning and sequencing using the single-stranded bacteriophage M13

A number of approaches to sequence DNA by the chain termination method are based on cloning into M13 phage vectors and the use of a universal primer. In this paper we investigate some of the factors which influence the speed and efficiency of these approaches. A modification of the template preparation, sequencing reaction, and gel system was used to obtain more reliable and clearer ladder gels. Redundancy and deficiency of shotgun DNA sequencing were reduced by a mapping technique and the use of synthetic primers. The mapping and cloning technique was used to organize the data entry so that the computer time necessary to reconstruct the sequence out of overlaps was reduced.     

Mechanisms of mutagenesis by exocyclic DNA adducts. Transfection of M13 viral DNA bearing a site-specific adduct shows that ethenocytosine is a highly efficient RecA-independent mutagenic noninstructional lesion

It is widely accepted that mutagenic DNA lesions fall into two categories: mispairing lesions hydrogen bond with an incorrect incoming base, generally do not stop replication, and possess high mutagenic efficiency without any requirement for induced functions; noninstructional lesions lack accessible template information, act as strong blocks to DNA replication (and are therefore toxic), and their mutagenic effects are SOS-dependent. Our recent results show that ethenocytosine (epsilon C), a noninstructional exocyclic DNA lesion induced by vinyl chloride, may have unusual mutagenic properties. To obtain more definitive experimental evidence for the observed effects, we have introduced a single epsilon C residue at a specific site of coliphage M13AB28 replicative form DNA by a "single-stranded linker-ligation" technique. The resulting DNA was purified and transfected into appropriate recA+ or recA- Escherichia coli host cells. The effect of epsilon C on survival was determined from transfection efficiency. Both the frequency and specificity of mutations induced by epsilon C were determined by direct sequence analysis of randomly picked progeny phage plaques. The results indicated that epsilon C has little effect on the survival of M13 DNA. Approximately 30% of the progeny phage obtained by transfecting epsilon C DNA had a base substitution mutation precisely at the lesion site. No such mutations were observed in progeny plaques obtained by transfecting the control DNA construct. All epsilon C-induced mutations were either C-to-T transitions or C-to-A transversions. Neither survival nor mutagenic efficiency was significantly affected in recA- host cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Replication of bacteriophage M13 DNA in plasmolysed Escherichia coli cells

Plasmolysed M13 infected E. coli cells utilize deoxynucleoside triphosphates to synthesize phage-specific DNA in an ATP-dependent, nalidixic acid sensitive, semi-conservative replication process. Whereas the major fraction of the reaction product consists of replicative form I molecules (RF) labeled asymmetrically in the viral strand, a minor fraction of the label is found in mature viral single strands. We therefore conclude that the system is capable of initiating second rounds of replication, for which ring closure seems to be a precondition.     

Replication of M13 duplex DNA in soluble extracts of Escherichia coli. Effect of helix-destabilising proteins.

Soluble extracts of M13-am5-infected Escherichia coli cells can carry out multiple rounds of M13 duplex DNA replication when supplemented with helix-destabilising protein of E. coli. Similarly addition of the helix-destabilising M13 gene 5 protein in low concentrations (up to 30 micrograms/ml) stimulates the replication of double-stranded M13 DNA. In contrast, higher concentrations of gene 5 protein (but not of E. coli helix-destabilising protein) cause a preferential inhibition of complementary strand synthesis resulting in a switch from double-strand replication to single-strand synthesis. Depending on the addition of the appropriate amounts of these two helix-destabilising proteins either stage of M13 DNA replication can now be studied with cell-free preparations.     

DNA fingerprints of sheep using an M13 probe

The bacteriophage M13 DNA was used to detect hypervariable minisatellites in several families of Booroola sheep as well as Merino and Suffolk sheep. Digestion of sheep DNA gave rise to three to eight fragments with different restriction enzymes demonstrating considerable polymorphism between the different breeds. The length of informative DNA fragments varied in size from 6 to 20kb. The DNA fingerprints generated were individual specific and allowed for differentiation between closely related animals. The pattern obtained with sheep DNA was different from that observed with humans and other vertebrates in the proportion of high molecular weight DNA fragments present. Pedigree analysis of DNA patterns of dams and their offspring for several sets of twins and triplets showed a clear distinction between individuals and failed to reveal the presence of monozygosity.     

Replication of bacteriophage M13. XII. In vivo cross-linking of a phage-specific DNA binding protein to the single-stranded DNA of bacteriophage M13 by ultraviolet irradiation.

Ultraviolet irradiation of bacteriophage M13-infected Escherichia coli induces the formation of a covalent crosslink between progeny single-stranded DNA and the M13 DNA binding protein, the product of gene 5. The crosslinked complex is readily isolated from detergent-treated lysates by sucrose-gradient velocity sedimentation and CsCl equilibrium sedimentation in the presence of detergent. The crosslinked complex produced with optimal levels of irradiation sediments 1.06 times faster than uncomplexed M13 single-stranded DNA, has a buoyant density of approximately 1.62 to 1.64 g/cm³ and a protein to DNA mass ratio of 2 mg protein per mg DNA. Cleavage of the crosslinked complex with cyanogen bromide or trypsin yields products similar to those produced by cleavage of purified M13 gene 5 protein. The crosslink is located close to the carboxyl terminus of the protein.