Genetic studies of the lac repressor. IV. Mutagenic specificity in the lacI gene of Escherichia coli.

An extensive set of amber and ochre sites in the lacI gene has been characterized with respect to the base change required to generate the nonsense codon (Miller et al., 1977; Coulondre &; Miller, 1977). These mutations have been used to analyze the forward mutational spectrum of a series of mutagens in Escherichia coli. The sites induced by N′-methyl-N′-nitro-N-nitrosoguanidine, ethyl methanesulfonate, 4-nitroquinoline-1-oxide, and ultraviolet light, were examined, as well as those which arose spontaneously. Sites induced by the G · C → A · T transition were compared with those generated by 2-aminopurine mutagenesis. All together, more than 4000 independent occurrences of amber and ochre mutations were tabulated in order to define the respective mutagenic specificities. With the exception of the A · T → G · C change, all base substitutions lead to the generation of nonsense codons from wild-type. The A · T → G · C transition was monitored in a reversion system, in which the ochre to amber conversion (UAA → UAG) was scored, as well as the UAA → CAA reversion.Both NG³ and EMS were found to be highly specific for the G · C → A · T transition, less than 1% transversions appearing in either case. At between 1% and 5% the level of the G · C → A · T change, NG can stimulate the A · T → G · C transition. EMS stimulates the A · T → G · C transition at a significantly lower rate. NQO is also highly specific for G · C base-pairs, but approximately 10% of the changes found at these sites are transversions. Mutations found spontaneously or after irradiation with ultraviolet light showed none of the specificities found for EMS, NG or NQO. All transversions were detected in both cases. Moreover, a significant number of tandem double base changes were found to be induced by u.v. irradiation. Some of these have been verified directly by protein sequencing. The frequencies of occurrence of amber and ochre mutations arising from the G · C → A · T transition have been compared for different mutagens, revealing several striking hotspots. The implications of these findings with respect to the mechanism of mutagenesis and the application of different mutagens are discussed.     

Asymmetry in forming 2-aminopurine . hydroxymethylcytosine heteroduplexes; A model giving misincorporation frequencies and rounds of DNA replication from base-pair populations in vivo

We present the first direct measurement of a transient mismatched base-pair in a 2-aminopurine-induced mutagenic pathway. We provide a model to calculate misincorporation rates in vivo from measured base-pair populations. The population of 2-aminopurine · hydroxymethylcytosine (AP · C²) base-pairs at a marker locus in T4 bacteriophage is measured as rII-r⁺ heteroduplex-heterozygotes in a modified single burst experiment after 2-aminopurine mutagenesis. This completes the determination of each of the base-pairs in the 2-aminopurine-induced A · T → G · C transition pathway for the marker rUV199. The observed AP · C population confirms a surprising model prediction that the probability of incorporating HMdCTP opposite a template 2-aminopurine is very large, approximately 2% per round of replication. AP induces A · T → G · C and G · C → A · T transitions at roughly the same rates. A quantitative comparison of 2-aminopurine-induced A · T → G · C and G · C → A · T transition pathways shows a marked asymmetry in the formation of AP · C base-pairs; the probability of forming AP · C base-pair intermediates in the A · T → G · C transition pathway is several orders of magnitude larger than in the G · C → A · T pathway. A set of analytic equations giving the population of each state of an allele undergoing 2-aminopurine mutagenesis (A · T, AP · T, AP · C and G · C) as a function of interstate (e.g. A · T → AP · T) and intrastate (e.g. A · T → A · T) transition rate constants and the number of rounds of replication is derived. The equations also demonstrate that a determination of $\text{AP}\text{·}\text{C}\text{G}\text{·}\text{C}$ base-pair ratios is a direct measure of the number of rounds of replication; thus the value of 0.35 AP · C per G · C base-pair as measured in this experiment reveals that there were eight to nine rounds of DNA replication during the mutagenesis treatment.     

Physical mapping of the transfer RNA genes on lambda-h80dglytsu+36

The three Escherichia coli transfer RNA genes of the DNA of the transducing phage λ80cI857S^?t68dglyTsu⁺₃₆tyrTthrT (abbreviated λh80T), which specify the structures of tRNA^Gly₂(su⁺₃₆), tRNA^Tyr₂ and tRNA^Thr₃, have been mapped by hybridizing ferritin-labeled E. coli tRNA to heteroduplexes of λh80T DNA with the DNA of the parental phage (λh80cI857S^?t68) and examining the product in the electron microscope. The DNA of λh80T contains a piece of bacterial DNA of length 0·43 λ unit³ that replaces a piece of phage DNA of length 0·46 λ unit, proceeding left from B · P′ (the junction of bacterial DNA and phage DNA) (i.e. att⁸⁰). A cluster of three ferritin binding sites, and thus of tRNA genes, is seen at a position of 0·24 λ unit (1·1 × 10⁴ nucleotides) to the left of B· P′. The three tRNA genes of the cluster are separated by the unequal spacings of 260 (±30) and 140 (± 30) nucleotides, proceeding left from B·P′. The specific map positions have been identified by hybridization competition between ferritin-labeled whole E. coli tRNA with unlabeled purified tRNA^Tyr₂ and with unlabeled partially purified tRNA^Gly₂. The central gene of the cluster is tRNA^Tyr₂. The tRNA^Gly₂gene is probably the one furthest from B·P′. Thus, the gene order and spacings, proceeding left from B·P′, are: tRNA^Thr₃, 260 nucleotides, tRNA^Try₂, 140 nucleotides, tRNA^Gly₂.     

Mutator mutations in Escherichia coli induced by the insertionof phage Mu and the transposable resistance elements Tn5 and Tn10

Mutator mutations in the mutS gene induced by the insertion of phage Mu or the transposable resistance elements Tn5 or Tn10 and those in the mutL gene induced by Tn5 and T10 gave mutagenic activities similar to that of the previously described mutS3 and mutL25 mutations. Various combinations of mutS::Tn5,mutL::Tn5, uvrE156, and the deletion mutation δmutH2 did not produce an additive effect. This supports the idea that the products of these genes function in the same pathway of error correction during DNA synthesis.     

Structural features of lambda site-specific recombination at a secondary att site in galT.

Integration of bacteriophage λ DNA into the chromosome of its E. coli host proceeds via a site-specific recombination between specific loci (att sites) on the phage and bacterial chromosomes. Infection of an E. coli host deleted for the primary bacterial att site results in λ integration with reduced efficiency at a number of different “secondary att sites” scattered around the E. coli chromosome. The first DNA sequence analysis of such a secondary att site, that occurring in the galT gene, is reported here, and several features pertinent to the mechanism of int-dependent site-specific recombination are discussed.Previous studies have shown that the crossover in int-dependent recombination must be somewhere within a 15 bp sequence (core region) common to the phage and primary bacterial att sites, as well as to the left and right prophage att sites which are at the junctures between prophage and host DNA. Comparison of the galT secondary prophage att sites with the primary prophage att sites allows determination of the analogous “core” region in the galT secondary att site. The 15 bp sequence thus identified shows an interrupted homology (8 out of 15) with the wild-type core. The extent and arrangement of nonhomologous bases allow precise placement of the crossover point for this recombination to the +4–+5 internucleotide bond of the core region.Sequences flanking the core region show no obvious homology with analogous sequences of the phage or primary bacterial att sites. Comparison of the galT left prophage att site with the analogous wild-type site is of particular interest and is discussed in relation to binding studies with purified int protein.     

Bromouracil mutagenesis in Escherichia coli evidence for involvement of mismatch repair.

Summary Bromouracil mutagenesis was studied in several strains of E. coli in combination with measurement of incorporation of bromouracil in DNA. For levels below 10% total replacement of bromouracil for thymine, mutagenesis was negligible compared with higher levels of incorporation. Such a nonlinear response occurred both when the bromouracil was evenly distributed over the genome and when a small proportion of the genome was highly substituted. Also, the mutation frequency could be drastically lowered by amino acid starvation following bromouracil incorporation. These observations suggest the involvement of repair phenomena. Studies of mutagenesis in recA ^– and uvrA ^– mutants, as well as studies of prophage induction, did not support an error prone repair pathway of mutagenesis. On the other hand, uvrD ^– and uvrE ^– mutants, which are deficient in DNA mismatch repair, had much increased mutation frequencies compared with wild type cells. The mutagenic action of bromouracil showed specificity under the conditions used, as demonstrated by the inability of bromouracil to revert an ochre codon that was easily revertable by ultraviolet light irradiation. The results are consistent with a mechanism of bromouracil mutagenesis involving mispairing, but suggest that the final mutation frequencies depend on repair that removes mismatched bases.     

Repair mechanisms involved in prophage reactivation and UV reactivation of UV-irradiated phage lambda

Survival of UV-irradiated phage λ is increased when the host is lysogenic for a homologous heteroimmune prophage such as λimm434 (prophage reactivation). Survival can also be increased by UV-irradiating slightly the non-lysogenic host (UV reactivation).Experiments on prophage reactivation were aimed at evaluating, in this recombination process, the respective roles of phage and bacterial genes as well as that of the extent of homology between phage and prophage.To test whether UV reactivation was dependent upon recombination between the UV-damaged phage and cellular DNAs, lysogenic host cells were employed. Such hosts had thus as much DNA homologous to the infecting phage as can be attained. Therefore, if recombination between phage and host DNAs was involved in this repair process, it could clearly be evidenced.By using unexposed or UV-exposed host cells of the same type, prophage reactivation and UV reactivation could be compared in the same genetic background.The following results were obtained: (1) Prophage reactivation is strongly decreased in a host carrying recA mutations but quite unaffected by mutation lex-I known to prevent UV reactivation; (2) In the absence of the recA⁺ function, the red⁺ but not the int⁺ function can substitute for recA⁺ to produce prophage reactivation, although less efficiently; (3) Prophage reactivation is dependent upon the number of prophages in the cell and upon their degree of homology to the infecting phage. The presence in a recA host of two prophages either in cis (on the chromosome) or in trans (on the chromosome and on an episome) increases the efficiency of prophage reactivation; (4) Upon prophage reactivation there is a high rate of recombination between phage and prophage but no phage mutagenesis; (5) The rate of recombination between phage and prophage decreases if the host has been UV-irradiated whereas the overall efficiency of repair is increased. Under these conditions UV reactivation of the phage occurs as in a non-lysogen, as attested by the high rate of mutagenesis of the restored phage.These results demonstrate that UV reactivation is certainty not dependent upon recombination between two pre-existing DNA duplexes. The hypothesis is offered that UV reactivation involves a repair mechanism different from excision and recombination repair processes.     

Electron microscope study of the structures of the Bacillus subtilis prophages, SPO2 and phi105

Circular duplex structures of the correct length are observed in the electron microscope in hybridization mixtures of lysogen DNA and mature phage DNA for the case of the temperate Bacillus subtilis bacteriophage SPO2. This result shows that the sequence order of the prophage is a circular permutation of that of the mature phage. By making heteroduplexes of prophage DNA with that of the SPO2 deletion mutants, R90 and S25, the att site of the phage has been mapped at 61.2 ± 0.6% from one end of the mature phage DNA, which has a length of 38,600 base pairs. In the same co-ordinate system, the R90 deletion extends from 58.9 ± 0.7 to 66.8 ± 0.8% on the SPO2 chromosome, whereas the S25 deletion extends from 63.2 ± 0.6 to 66.9 ± 0.7%. In similar experiments with lysogen and mature phage DNA's of the temperate B. subtilis phage, φ105, no circular structures were seen. This result shows that the sequence order in the prophage and the phage are colinear, without circular permutation.     

The role of prophage for genome diversification within a clonal lineage of Lactobacillus johnsonii: characterization of the defective prophage LJ771

Two independent isolates of the gut commensal Lactobacillus johnsonii were sequenced. These isolates belonged to the same clonal lineage and differed mainly by a 40.8-kb prophage, LJ771, belonging to the Sfi11 phage lineage. LJ771 shares close DNA sequence identity with Lactobacillus gasseri prophages. LJ771 coexists as an integrated prophage and excised circular phage DNA, but phage DNA packaged into extracellular phage particles was not detected. Between the phage lysin gene and attR a likely mazE (“antitoxin”)/pemK (“toxin”) gene cassette was detected in LJ771 but not in the L. gasseri prophages. Expressed pemK could be cloned in Escherichia coli only together with the mazE gene. LJ771 was shown to be highly stable and could be cured only by coexpression of mazE from a plasmid. The prophage was integrated into the methionine sulfoxide reductase gene (msrA) and complemented the 5′ end of this gene, creating a protein with a slightly altered N-terminal sequence. The two L. johnsonii strains had identical in vitro growth and in vivo gut persistence phenotypes. Also, in an isogenic background, the presence of the prophage resulted in no growth disadvantage.     

Physical study of prophage excision and curing of lambda prophage from lysogenic Escherichia coli

A sex factor, F′450(λ), which can be isolated as a covalent circle of DNA, has been examined by alkaline sucrose gradient centrifugation of lysates of induced cells in order to study λ prophage excision. Thermal derepression of the prophage results in loss of F′450(λ) covalent circles, which is mediated by systems involved in excision and initiation of replication. When protocols known to result in prophage curing are used, the F′450(λ) is converted to an F′450 and a λ covalent circle; in normal excision leading to phage development, F′450 covalent circles are not found. We have shown that: (1) excision usually occurs later than initiation of DNA replication of the prophage so that the excised prophage is usually already replicated or in the act of replication; (2) the DNA growing points of the prophage leave the prophage and enter the bacterial DNA; (3) the int and xis genes are involved in the earliest detectable stage of the excision process, i.e. breakage of the DNA at the attachment region; (4) the xis gene product is involved in a weak non-specific nuclease activity in addition to its highly specific activity in excision; and (5) the excision system fails to attack a single attachment site.     

The bacterial attachment site of the temperate Rhizobium phage 16-3 overlaps the 3′ end of a putative proline tRNA gene

Bacteriophage 16-3 inserts its genome into the chromosome of Rhizobium meliloti strain 41 (Rm41) by site-specific recombination. The DNA regions around the bacterial attachment site (attB) and one of the hybrid attachment sites bordering the integrated prophage (attL) were cloned and their nucleotide sequences determined. We demonstrated that the 51 by region, where the phage and bacterial DNA sequences are identical, is active as a target site for phage integration. Furthermore it overlaps the 3′ end of a putative proline tRNA gene. This gene shows 79% similartiy to the corresponding proline tRNA-like genomic target sequence of certain integrative plasmids in Actinomycetes.     

Phage-associated mutator phenotype in group A streptococcus

Defects in DNA mismatch repair (MMR) occur frequently in natural populations of pathogenic and commensal bacteria, resulting in a mutator phenotype. We identified a unique genetic element in Streptococcus pyogenes strain SF370 that controls MMR via a dynamic process of prophage excision and reintegration in response to growth. In S. pyogenes, mutS and mutL are organized on a polycistronic mRNA under control of a common promoter. Prophage SF370.4 is integrated between the two genes, blocking expression of the downstream gene (mutL) and resulting in a mutator phenotype. However, in rapidly growing cells the prophage excises and replicates as an episome, allowing mutL to be expressed. Excision of prophage SF370.4 and expression of MutL mRNA occur simultaneously during early logarithmic growth when cell densities are low; this brief window of MutL gene expression ends as the cell density increases. However, detectable amounts of MutL protein remain in the cell until the onset of stationary phase. Thus, MMR in S. pyogenes SF370 is functional in exponentially growing cells but defective when resources are limiting. The presence of a prophage integrated into the 5′ end of mutL correlates with a mutator phenotype (10⁻⁷ to 10⁻⁸ mutation/generation, an approximately a 100-fold increase in the rate of spontaneous mutation compared with prophage-free strains [10⁻⁹ to 10⁻¹⁰ mutation/generation]). Such genetic elements may be common in S. pyogenes since 6 of 13 completed genomes have related prophages, and a survey of 100 strains found that about 20% of them are positive for phages occupying the SF370.4 attP site. The dynamic control of a major DNA repair system by a bacteriophage is a novel method for achieving the mutator phenotype and may allow the organism to respond rapidly to a changing environment while minimizing the risks associated with long-term hypermutability.     

Non-phenotypic selection of N-methyl-N′-nitro-N-nitrosoguanidine-directed mutation at a predicted hotspot site

The striking mutational specificity of N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) exhibited in the lacI gene in Escherichia coli allows comment on the phenotypic consequences of mutation at specific sequences that are not recovered after MNNG mutagenesis. We predict that the I⁺ phenotype is maintained when such silent positions are substituted by amino acids whose codons are generated by the MNNG-directed G:C → A:T transition. We chose the mutationally silent Gly200 codon (an MNNG hotspot motif sequence) to test this prediction. Through MNNG mutagenesis we have generated, identified and isolated a G:C → A:T transition at position 627 (5′-GG-C3′) under non-selective conditions which creates the Gly200→Asp substitution. The I⁺ phenotype is retained for this altered repressor.     

Prophage Curing in Lactobacillus casei by Isolation of a Thermoinducible Mutant

To eliminate the occurrence of virulent phage in industrial fermentation, attempts were made to obtain prophage-cured derivatives from Lactobacillus casei lysogenic strain S-1. A thermoinducible mutant lysogen was isolated from mutagenized strain S-1, since S-1 cannot be induced under laboratory conditions. The mutation responsible for thermoinducibility was located on the prophage. Prophage-cured strains were selected after heat induction of the mutant. These cured strains did not produce the virulent phage and should be valuable for industrial fermentation.     

A DNA-BINDING PEPTIDE FROM A PHAGE DISPLAY LIBRARY

A DNA-binding peptide was selected from a random peptide phage display library. For competitive elution using the DNA methyltransferase M · TaqI in the selection step, a biotin-labeled duplex oligodeoxyribonucleotide containing the 5′-TCGA-3′ recognition sequence of M · TaqI was employed. Nine of ten phages selected were found to have the same deduced amino acid sequence SVSVGMKPSPRP. The selected phage binds to DNA, as demonstrated in an ELISA.     

Isolation of P22 Specialized Transducing Phage following F''-Episome Fusion

A P22 specialized transducing phage has been constructed which carries the structural gene for aspartate transcarbamylase (ATCase). This gene (pyrB) was first brought close to the P22 attachment site by fusing an F' pyrB⁺ episome to an F' prolac episome which carries a P22 prophage attachment site. A prophage was added to these fused F' episomes and the lysogen was UV-induced. The specialized transducing phage was isolated from the resulting lysate. The phage also carries argI, the structure gene for ornithine transcarbamylase.     

Distribution of Gifsy-3 and of Variants of ST64B and Gifsy-1 Prophages amongst Salmonella enterica Serovar Typhimurium Isolates: Evidence that Combinations of Prophages Promote Clonality

Salmonella isolates harbour a range of resident prophages which can influence their virulence and ability to compete and survive in their environment. Phage gene profiling of a range of phage types of Salmonella enterica subsp. enterica serovar Typhimurium (S. Typhimurium) indicates a significant level of correlation of phage gene profile with phage type as well as correlation with genotypes determined by a combination of multi-locus variable-number tandem repeat (VNTR) typing and clustered regularly interspaced short palindromic repeats (CRISPR) typing. Variation in phage gene profiles appears to be partly linked to differences in composition of variants of known prophages. We therefore conducted a study of the distribution of variants of ST64B and Gifsy-1 prophages and coincidently the presence of Gifsy-3 prophage in a range of S. Typhimurium phage types and genotypes. We have discovered two variants of the DT104 variant of ST64B and at least two new variants of Gifsy-1 as well as variants of related phage genes. While there is definite correlation between phage type and the prophage profile based on ST64B and Gifsy-1 variants we find stronger correlation between the VNTR/CRISPR genotype and prophage profile. Further differentiation of some genotypes is obtained by addition of the distribution of Gifsy-3 and a sequence variant of the substituted SB26 gene from the DT104 variant of ST64B. To explain the correlation between genotype and prophage profile we propose that suites of resident prophages promote clonality possibly through superinfection exclusion systems.     

Extensive regions of homology in front of the two hsp70 heat shock variant genes in Drosophila melanogaster

The major heat shock protein of 70,000 M_r in Drosophila melanogaster is encoded by two variant gene types located, respectively, at the chromosomal sites 87A7 and 87C1. We present the DNA sequence of a complete hsp70² gene of the 87A7 type and of the adjacent regions from both variants, extending to 1·2 × 10³ bases upstream from the start of the messenger coding region. We find an untranslated region of 250 nucleotides at the 5′ end of the messenger coding sequence in both variants. There is only one open reading frame which allows coding of a 70,000 M_r protein within the 87A7 variant, as found for an 87C1 variant (Ingolia et al., 1980). We observe 4·2% nucleotide divergence between these two variants with complete conservation of the reading frame. There is a conserved sequence of 355 nucleotides in front of each hsp70 gene, which is 85% homologous between the two variants. The presence of the same sequence element in γ, in front of the αβ heat shock genes (R. W. Hackett & J. T. Lis, personal communication) suggests that this element contains the regulatory signals for the coordinate expression of both the hsp70 and the αβ heat shock genes. Finally we find a very A + T-rich sequence of 150 basepairs which is highly conserved (91·8%) 0·6 × 10³ bases upstream from two hps70 gene variants.     

Escherichia coli mutY-dependent mismatch repair involves DNA polymerase I and a short repair tract

Repair of heteroduplex DNA containing an A/G mismatch in a mutL background requires the Escherichia coli mutY gene function. The mutY-dependent in vitro repair of A/G mismatches is accompanied by repair DNA synthesis on the DNA strand bearing mispaired adenines. The size of the mufY-dependent repair tract was measured by the specific incorporation of α-[³²P]dCTP into different restriction fragments of the repaired DNA. The repair tract is shorter than 12 nucleotides and longer than 5 nucleotides and is localized to the 3′ side of the mismatched adenine. This repair synthesis is carried out by DNA polymerase I.