Gene X of bacteriophage f1 is required for phage DNA synthesis. Mutagenesis of in-frame overlapping genes

The gene II protein of bacteriophage f1 is a site-specific endonuclease required for initiation of phage viral strand DNA synthesis. Within gene II is another gene, X, encoding a protein of unknown function identical to the C-terminal 27% of the gene II protein, and separately translated from codon 300 (AUG) of gene II. By oligonucleotide mutagenesis, we constructed phage mutants in which this codon has been changed to UAG (amber) or UUG (leucine), and propagated them on cells carrying a cloned copy of gene X on a plasmid. The amber mutant makes no gene X protein, and cannot grow in the absence of the complementing plasmid; the leucine-inserting mutant can make gene X protein, and grows normally without the plasmid. Without gene X protein, phage DNA synthesis (particularly viral strand synthesis) is impaired. We discuss this finding in the context of other known in-frame overlapping genes (particularly genes A and A* of phage phi X174), many of which are also involved in the specific initiation of DNA synthesis, and suggest applications for the mutagenic strategy we employed.     

Differential survival and chloramphenicol-insensitive error-prone repair of hydroxylamine-inactivated phi X174 bacteriophage mutants

Features of inactivation, repair and concomitant mutagenesis of hydroxylamine-treated phi X174 bacteriophages are reported here. (1) For reasons unknown, the nonsense phage mutants tested here were far more sensitive to hydroxylamine than the wild-type phage. In contrast, the sensitivities of these same phi X174 mutants to UV-irradiation are indistinguishable. (2) Hydroxylamine-treated amber phages mutated to ochre but not to wild-type particles, i.e., G leads to A transition events were recovered. (3) The repair of phi X174 phages from hydroxylamine-induced damage was error-prone, but unlike UV damage, did not require protein synthesis de novo. Possible mechanisms of these novel features are discussed.     

Kinetics of induction and decay of error-prone DNA repair activity in Escherichia coli after treatment with nalidixic acid

Inducible error-prone DNA repair activity was detected by infecting nalidixic acid-pretreated E. coli cells with UV-irradiated phage phi X174. Induction and decay kinetics of reactivation very much resembled that of mutagenesis of the UV-damaged phage. Repair as well as mutagenic activity increased for about 30 min. The maximal error-prone repair capacity, which was induced in the cell during the 30 min nalidixic acid treatment, rapidly died out during subsequent cell growth in absence of nalidixic acid. Induction of this repair mode was not observed in a recA- mutant. In the presence of nalidixic acid plus rifampicin both repair and mutagenic effects were abolished.     

Mechanism of replication of bacteriophage phi X174. XXII. Site-specific mutagenesis of the A* gene reveals that A* protein is not essential for phi X174 DNA replication

The A and A* proteins of phage phi X174 are encoded in the same reading frame in the viral genome; the smaller A protein is the result of a translational start signal with the A gene. To differentiate their respective functions, oligonucleotide-directed site-specific mutagenesis was used to change the ATG start codon of the phi X 174 A* gene, previously cloned into pCQV2 under lambda repressor control, into a TAG stop codon. The altered A gene was then inserted back into phi X replicative form DNA to produce an amber mutant, phi XamA*. Two different Escherichia coli amber suppressor strains infected with this mutant produced viable progeny phage with only a slight reduction in yield. In Su+ cells infected with phi XamA*, phi X gene A protein, altered at one amino acid, was synthesized at normal levels; A* protein was not detectable. These observations indicate that the A* protein increases the replicative efficiency of the phage, perhaps by shutting down host DNA replication, but is not required for replication of phi X174 DNA or the packaging of the viral strand under the conditions tested.     

Mutation spectrum of copper-induced DNA damage.

The ability of metal ions to damage DNA and cause mutagenesis has been analyzed with reversion and forward mutation assays using single-stranded DNA templates. We previously reported that incubation of phi X174 am3 DNA with Fe2+ in vitro results in mutagenesis when the treated DNA is transfected into Escherichia coli spheroplasts (Loeb, L. A., James, E. A., Waltersdorph, A. M., and Klebanoff, S. J. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 3918-3922, 1988). We now extend these studies to other metal ions. Of the metal ions tested, copper ions were the most mutagenic; the frequency of mutants produced was equal to or greater than that produced by Fe2+. Mutagenesis by Cu+ was diminished by catalase, mannitol, and superoxide dismutase suggesting the involvement of H2O2, hydroxyl ions, and superoxide, respectively. However, the findings that Cu+ and Cu2+ are nearly equally mutagenic and that the mutagenic activities are not completely inhibited by oxygen free radical scavengers make it unlikely that the mechanism for mutagenesis is simply the production of hydroxyl free radicals. The spectra of mutations produced by either copper ion using the lacZ gene as a target are very similar and differ from those reported with other agents. The predominant mutagenic sequence changes are single-base substitutions, the most frequent being replacement of a template C by a T. This transition presumably results from mispairing of an altered C with deoxyadenosine. Copper-induced mutations are not randomly distributed. Instead, they are found predominantly in clusters suggesting direct interaction of copper ions with specific nucleotide sequences in DNA. Evidence is considered that the high frequency of C----T transitions may be a common manifestation of DNA damage by oxygen radicals.     

Genotoxicity and mutagenicity of chromium(VI)/ascorbate-generated DNA adducts in human and bacterial cells

Reduction of carcinogenic Cr(VI) by vitamin C generates ascorbate-Cr(III)-DNA cross-links, binary Cr(III)-DNA adducts, and can potentially cause oxidative DNA damage by intermediate reaction products. Here, we examined the mutational spectrum and the importance of different forms of DNA damage in genotoxicity and mutagenicity of Cr(VI) activated by physiological concentrations of ascorbate. Reduction of Cr(VI) led to a dose-dependent formation of both mutagenic and replication-blocking DNA lesions as detected by propagation of the pSP189 plasmids in human fibroblasts. Disruption of Cr-DNA binding abolished mutagenic responses and normalized the yield of replicated plasmids, indicating that Cr-DNA adducts were responsible for both mutagenicity and genotoxicity of Cr(VI). The absence of DNA breaks and abasic sites confirmed the lack of a significant production of hydroxyl radicals and Cr(V)-peroxo complexes in Cr(VI)-ascorbate reactions. Ascorbate-Cr(III)-DNA cross-links were much more mutagenic than smaller Cr(III)-DNA adducts and accounted for more than 90% of Cr(VI) mutagenicity. Ternary adducts were also several times more potent in the inhibition of replication than binary complexes. The Cr(VI)-induced mutational spectrum consisted of an approximately equal number of deletions and G/C-targeted point mutations (51% G/C --> T/A and 30% G/C --> A/T). In Escherichia coli cells, Cr(VI)-induced DNA adducts were only highly genotoxic but not mutagenic under either normal or SOS-induced conditions. Lower toxicity and high mutagenicity of ascorbate-Cr(III)-DNA adducts in human cells may result from the recruitment of an error-prone bypass DNA polymerase(s) to the stalled replication forks. Our results suggest that phosphotriester-type DNA adducts could play a more important role in human than bacterial mutagenesis.     

Alteration of the ATG start codon of the A protein of bacteriophage phi X174 into an ATT codon yields a viable phage indicating that A protein is not essential for phi X174 reproduction

Bacteriophage phi X174 gene A encodes two proteins: the gene A protein and the smaller A protein, which is synthesized from a translational start signal within the A gene in the same reading frame as the gene A protein. The gene A protein is involved in initiation, elongation and termination of rolling circle DNA replication. The role of the A protein in the life cycle of phi X174, however, is unknown. Using oligonucleotide-directed mutagenesis a viable phi X174 mutant was constructed in which the ATG start codon of the A protein was changed into an ATT codon. This mutant, phi X-4499T, does not synthesize A protein. The burst size of phi X-4499T amounted to 50% of that of wild type phi X174. This indicates that A protein, although advantageous for phage reproduction, is not essential during the life cycle of bacteriophage phi X174.     

Induction of mutation in vitro in phage phi X174 am3 by N4-aminodeoxycytidine triphosphate

When phi X174 am3-phage-infected E. coli is treated with N4-aminocytidine, reversion of the phage to the wild type is efficiently induced. The mechanism of this reversion is considered to consist of metabolic conversion of N4-aminocytidine into its deoxynucleoside 5'-triphosphate followed by incorporation of the nucleotide into the replicating phage DNA, thereby causing AT-to-GC transition at the am3 locus. The second half of this mechanism has now been experimentally proved, using an in vitro mutagenesis system. Thus, by nick-translation, N4-aminodeoxycytidine 5'-triphosphate was incorporated into the replicative form of phi X174 am3 DNA, and the DNA was used to transfect CA++-treated E. coli HF4714 (sup+). The reversion frequency of the phage produced was up to one-order of magnitude greater than that of the control in which the nick-translation had been done without the addition of N4-aminodeoxycytidine triphosphate. This nucleotide analog may be useful as a reagent for in vitro site-directed mutagenesis.     

Mutagenesis resulting from depurination is an SOS process

When bacteriophage phi X174 am3 DNA depurinated in vitro is transfected into E. coli spheroplasts prepared from bacteria previously exposed to UV light, a strong mutagenic response is observed. This mutagenic response does not occur in spheroplasts derived from pre-irradiated bacteria carrying defective recA, recF or umuC genes. These findings indicate that mutagenesis at apurinic sites is an SOS-dependent process. The mutagenic response is not dependent on the multiplicity of transfection. This suggests that mutagenesis is not mediated by recombination.     

Non-oxidative mechanisms are responsible for the induction of mutagenesis by reduction of Cr(VI) with cysteine: role of ternary DNA adducts in Cr(III)-dependent mutagenesis

Intracellular reduction of carcinogenic Cr(VI) generates Cr-DNA adducts formed through the coordination of Cr(III) to DNA phosphates (phosphotriester-type adduct). Here, we examined the role of Cr(III)-DNA adducts in mutagenesis induced by metabolism of Cr(VI) with cysteine. Reduction of Cr(VI) caused a strong oxidation of 2', 7'-dichlorofluoroscin (DCFH) and extensive Cr-DNA binding but no DNA breakage. Cr-DNA adducts induced unwinding of supercoiled plasmids and structural distortions in the DNA helix as detected by decreased ethidium bromide binding. Propagation of Cr-treated pSP189 plasmids in human fibroblasts led to a dose-dependent formation of the supF mutants and inhibition of replication. Blocking of Cr(III)-DNA binding by occupation of DNA phosphates with Mg(2+) or by sequestration of Cr(III) by inorganic phosphate or EDTA eliminated mutagenic responses and restored a normal yield of replicated plasmids. Dissociation of Cr(III) from DNA by a phosphate-based reversal procedure returned mutation frequency to background levels. The mutagenic responses at the different phases of the reduction reaction were unrelated to the amount of reduced Cr(VI) but reflected the number and the spectrum of Cr(III)-DNA adducts that were formed. Ternary cysteine-Cr(III)-DNA adducts were approximately 4-5 times more mutagenic than binary Cr(III)-DNA adducts. Although intermediate reaction products (CrV/IV, thiyl radicals) were capable of oxidizing DCFH, they were insufficiently reactive to damage DNA. Single-base substitutions at G/C pairs were the predominant type of Cr-induced mutations. The majority of mutations occurred at the sites where G had adjacent purine in the 3' or 5' position. Overall, our results present the first evidence that Cr(III)-DNA adducts play the dominant role in the mutagenicity caused by the metabolism of Cr(VI) by a biological reducing agent.     

Effects of genome size on bacteriophage phi X174 DNA packaging in vitro

Effects of the size of template DNA on the DNA packaging reaction of bacteriophage phi X174 were studied using plasmids of various sizes which contain the phi X174 origin of DNA replication and the in vitro phage synthesizing system (Aoyama, A., Hamatake, R. K., and Hayashi, M. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 4195-4199). DNA between 78.5% and 101% of the length of phi X174 DNA produced infectious particles efficiently. Packaging of DNA smaller or larger than this range produced uninfectious defective particles. Although these particles contained circular single-stranded DNA, they suffered structural changes which altered the sedimentation properties or the ability to adsorb to the cells. Mutant phage were found from the packaging reaction of DNA larger than 101% of phi X174 DNA. These mutants deleted the termination region of DNA, suggesting that they were produced by early termination of the phage synthesizing reaction.     

Regions of incompatibility in single-stranded DNA bacteriophages phi X174 and G4.

The intracellular presence of a recombinant plasmid containing the intercistronic region between the genes H and A of bacteriophage phi X174 strongly inhibits the conversion of infecting single-stranded phi X DNA to parental replicative-form DNA. Also, transfection with single-stranded or double-stranded phi X174 DNA of spheroplasts from a strain containing such a "reduction" plasmid shows a strong decrease in phage yield. This phenomenon, the phi X reduction effect, was studied in more detail by using the phi X174 packaging system, by which plasmid DNA strands that contain the phi X(+) origin of replication were packaged as single-stranded DNA into phi X phage coats. These "plasmid particles" can transduce phi X-sensitive host cells to the antibiotic resistance coded for by the vector part of the plasmid. The phi X reduction sequence in the resident plasmid strongly affected the efficiency of the transduction process, but only when the transducing plasmid depended on primosome-mediated initiation of DNA synthesis for its conversion to double-stranded DNA. The combination of these results led to a model for the reduction effect in which the phi X reduction sequence interacted with an intracellular component that was present in limiting amounts and that specified the site at which phi X174 replicative-form DNA replication takes place. The phi X reduction sequence functioned as a viral incompatibility element in a way similar to the membrane attachment site model for plasmid incompatibility. In the DNA of bacteriophage G4, a sequence with a similar biological effect on infecting phages was identified. This reduction sequence not only inhibited phage G4 propagation, but also phi X174 infection.     

Selective cloning of a DNA single-strand initiation determinant from phi X174 replicative-form DNA.

An M13 phage deletion mutant, M13 delta E101, developed as a vector for selecting DNA sequences that direct DNA strand initiation on a single-stranded template, has been used for cloning restriction enzyme digests of phi X174 replicative-form DNA. Initiation determinants, detected on the basis of clear-plaque formation by the chimeric phage, were found only in restriction fragments containing the unique effector site in phi X174 DNA for the Escherichia coli protein n' dATPase (ATPase). Furthermore, these sequences were functional only when cloned in the orientation in which the phi X174 viral strand was joined to the M13 viral strand. A 181-nucleotide viral strand fragment containing this initiation determinant confers a phi X174-type complementary-strand replication mechanism on M13 chimeras. The chimeric phage is converted to the parental replicative form in vivo by a mechanism resistant to rifampin, a specific inhibitor of the normal RNA polymerase-dependent mechanism of M13. In vitro, the chimeric single-stranded DNA promotes the assembly of a functional multiprotein priming complex, or primosome, identical to that utilized by intact phi X174 viral strand DNA. Chimeric phage containing the sequence complementary to the 181-nucleotide viral strand sequence shows no initiation capability, either in vivo or in vitro.     

The complete 30-base-pair origin region of bacteriophage phi X174 in a plasmid is both required and sufficient for in vivo rolling-circle DNA replication and packaging

The origin of replication of the isometric single-stranded DNA bacteriophages is located in a specific sequence of 30 nucleotides, the origin region, which is highly conserved in these phage genomes. Plasmids harboring this origin region are subject to rolling-circle DNA replication and packaging of single-stranded (ss) plasmid DNA into phage coats in phi X174 or G4-phage-infected cells. This system was used to study the nucleotide sequence requirements for rolling-circle DNA replication and DNA packaging employing plasmids which contain the first 24, 25, 26, 27, 28 and the complete 30-base-pair (bp) origin region of phi X174. No difference in plasmid ss DNA packaging was observed for plasmids carrying only the 30-bp origin region and plasmids carrying the 30-bp origin region plus surrounding sequences (i.e. plasmids carrying the HaeIII restriction fragment Z6B of phi X174 replicative-form DNA). This indicates that all signals for DNA replication and phage morphogenesis are contained in the 30-bp origin region and that no contribution is made by sequences which immediately surround the origin region in the phi X174 genome. The efficiency of packaging of plasmid ssDNA for plasmids containing deletions in the right part of the origin region decreases drastically when compared with the plasmid containing the complete 30-bp origin region (for a plasmid carrying the first 28 bp of the origin region to approximately 5% and 0.5% in the phi X174 and G4 systems respectively). Previous studies [Fluit, A.C., Baas, P.D., van Boom, J.H., Veeneman, G.H. and Jansz, H.S. (1984) Nucleic Acids Res. 12, 6443--6454] have shown that the presence of the first 27 bp of the origin region is necessary as well as sufficient for cleavage of the viral strand in the origin region by phi X174 gene A protein. Moreover, Brown et al. [Brown, D.R., Schmidt-Glenewinkel, T., Reinberg, D. and Hurwitz, J. (1983) J. Biol. Chem. 258, 8402--8412] have shown that omission of the last 2 bp of the origin region does not interfere with phi X174 rolling-circle DNA replication in vitro. Our results therefore suggest that for optimal phage development in vivo, signals in the origin region are utilized which have not yet been noticed by the in vitro systems for phi X174 phage DNA replication and morphogenesis.     

Growth and DNA synthesis of bacteriophage phi x174 in a dnaP mutant of Escherichia coli.

phi X174am3trD, a temperature-resistant mutant of bacteriophage phi X174am3, exhibited a reduced ability to grow in a dnaP mutant, Escherichia coli KM107, at the restrictive temperature (43 degrees C). Under conditions at which the dnaP gene function was inactivated, the amount and the rate of phi X174am3trD DNA synthesis were reduced. The efficiency of phage attachment to E. coli KM107 at 43 degrees C was the same as to the parental strain, E. coli KD4301, but phage eclipse and phage DNA penetration were inhibited in E. coli KM107 at 43 degrees C. It is suggested that the dnaP gene product, which is necessary for the initiation of host DNA replication, participates in the conversion of attached phages to eclipsed particles and in phage DNA penetration in vivo in normal infection.     

Synthesis of bacteriophage phi X174 in vitro: mechanism of switch from DNA replication to DNA packaging

Replication of a replicative form DNA of bacteriophage phi X174 initiates by rolling-circle synthesis of the viral DNA followed by discontinuous synthesis of the complementary DNA. Gene C protein of phi X174, which is involved in DNA packaging, inhibits the rolling-circle DNA synthesis by binding to the initiation complex in vitro. The gene C protein-associated initiation complex can synthesize and package the viral DNA to produce infectious phage when supplemented with phi X174 gene J protein and the prohead. Multiple rounds of phage synthesis occur without dissociation of the gene C protein from the complex. These results indicate that gene C protein is central in the switch from replication of a replicative form DNA to synthesis and concomitant packaging of viral DNA into phage capsid, which occurs in the late stage of infection.     

Construction and properties of a ribosome-binding site mutation in gene E of phi X174 bacteriophage.

Oligodeoxyribonucleotide mutagenesis has been used to produce a G----A mutation at nucleotide 557 of the phi X174 genome. This changes the ribosome-binding sequence GAGG of gene E to GAAG without affecting the amino acid, glutamine, encoded by the overlapping gene D. The phi X174rb(E)557 mutant does not lyse infected Escherichia coli C and therefore results in the accumulation of a large number intracellular mature phage particles. Thus, the mutation inactivates production of the gene E lytic product, presumably by blocking translation of gene E, without affecting other phage functions.     

Comparison of the relative mutagenicities of O-alkylthymines site-specifically incorporated into phi X174 DNA

The relative mutagenicities of O-alkylthymine-DNA adducts were analyzed in vivo by site-specific mutagenesis. Purified DNA polymerases were used to incorporate O4-methyl (Me)-, O4-ethyl (Et)-, O4-isopropyl (iPr)-, or O2-Me-dTTP onto the 3' terminus of a synthetic oligonucleotide (15-mer) hybridized to phi X174 am3 DNA. The product oligonucleotides were further extended in the presence of unmodified dNTPs to yield 21-mers containing single O-alkylthymine adducts opposite the adenine residue of the bacteriophage amber codon. Polyacrylamide gel electrophoresis and nearest-neighbor analyses confirmed the identities and nucleotide positions of the adducts. Transfection and replication of the site-specifically alkylated DNAs in ada- Escherichia coli (defective in the alkyltransferase capable of repairing O4-alkylthymine-DNA adducts) yielded mutant progeny phage with reversion frequencies of: O4-Me-dThd (19.5 X 10(-6) ) greater than O4-Et-dThd (7.5 X 10(-6) ) greater than O4-iPr-dThd (3.0 X 10(-6) ) greater than or equal to O2-Me-dThd (1.0 X 10(-6) ) approximately equal to dThd (2.0 X 10(-6) ). None of the adducts produced mutations above background following replication in ada+ E. coli. DNA sequence analyses of 40 independently isolated mutant phage derived from the O4-Me- or O4-Et-dThd-containing DNAs showed that all mutants contained guanine residues opposite the original site of the alkylthymines. These data are consistent with a mechanism of mutagenesis involving the formation of O4-alkyl-T.G base pairs during DNA replication in E. coli and suggest that the formation of A.T----G.C transition mutations is characteristic of mutagenesis by O4-Me- and O4-Et-dThds in vivo.     

Inactivation of bacteriophage phi X174 by mitomycin C in the presence of sodium hydrosulfite and cupric ions

Bacteriophage phi X174 was inactivated by mitomycin C reduced with sodium hydrosulfite in the presence of cupric ions (Cu2+). 99% of the phage particles lost their plaque-forming abilities when incubated with 1.5 . 10(-4) M mitomycin C, 5.7 . 10(-4) M sodium hydrosulfite and 1.0 . 10(-4) M CuCl2 for 120 min at 37 degrees C in 0.05 M Tris--HCl buffer (pH 8.1). Sodium borohydride and thiol-reducing agents such as L-cysteine, 2-mercaptoethanol or dithiothreitol could not serve as a substitute for sodium hydrosulfite and other transition metal ions such as Fe2+, Fe3+, Mn2+, Co2+ and Zn2+ were of no effect. Inactivated phage sedimented at 114S just as intact phage, but phage DNA was degraded. Strand-scission was observed when phi X174 single-stranded DNA was directly reacted with mitomycin C reduced with sodium hydrosulfite in the presence of CuCl2. Phage inactivation was inhibited bycatalase, EDTA and several scavengers such as cysteamine, 2-aminoethylisothiuronium bromide HBr (AET), 4,5-dihydroxy-1,3-benzene-disulfonic acid (Tiron), or 1,4-diazabicyclo[2,2,2]octane (DABCO). These results suggest that free oxygen radicals and mitomycin C semiquinone radical generated during autoxidation of reduced mitomycin C in the presence of cupric ions cause the degradation of phy X174 DNA.     

Absence of a role for DNA polymerase II in SOS-induced translesion bypass of phi X174.

In order to examine the possible role of Escherichia coli DNA polymerase II in SOS-induced translesion bypass, Weigle reactivation and mutation induction were measured with single-stranded phi X174 transfecting DNA containing individual lesions. No decrease in bypass of thymine glycol or cyclobutane pyrimidine dimers in the absence of DNA polymerase II was observed. Furthermore, DNA polymerase II did not affect bypass of abasic sites when either survival or mutagenesis was the endpoint. Lastly, repair of gapped DNA molecules, intermediates in methyl-directed mismatch repair, was also unaffected by the presence or absence of DNA polymerase II.