Effect of the recC gene in Escherichia coli on frequencies of ultraviolet-induced mutants

UV induction of Lac^? mutations was compared with UV induction of Mal⁺ mutations in E. coli B/r strains differing in the recC gene. The frequency of Lac^? mutants per survivor induced by the same dose was not significantly affected by the recC gene but the percentage of pure rather than sectored Lac^? colonies was greater when the recC gene was present. On the other hand, as reported previously, frequencies of Mal⁺ mutants induced by the same UV dose were lower when the strain was recC. The reduction factor was the same as for spontaneous Mal⁺ mutants. The difference in the effect of the recC gene on the yields of Lac^? and Mal⁺ mutants can be explained by taking into account the influence of lethal sectoring, which introduces an artifact when mutants arising in the recC strain are scored selectively as in the case for Mal⁺ mutants, but not when the scoring is non-selective as for Lac^? mutants. Lethal sectoring as indicated by a discrepancy between total cell counts and numbers of colony-formers, was observed for the recC strain growing in liquid minimal medium corresponding to the agar medium used to score Mal⁺ mutants but was not observed for the rec⁺ strain. Both strains showed lethal sectoring in the liquid medium corresponding to the agar medium to score Lac^? mutants. The hypothesis concerning the role of lethal sectoring in the selective scoring of mutants arising in a recC background is supported by evidence concerning the UV induction of mutants in a polA1 background. Like the recC gene, the polA1 gene did not affect yields of Lac^? mutants. However, unlike the recC gene, the polA1 gene has previously been shown not to influence UV yields of prototrophic mutations (scored selectively) and not to cause lethal sectoring except under irrelevant conditions.     

Plasmid Copy Number Underlies Adaptive Mutability in Bacteria

The origin of mutations under selection has been intensively studied using the Cairns-Foster system, in which cells of an Escherichia coli lac mutant are plated on lactose and give rise to 100 Lac⁺ revertants over several days. These revertants have been attributed variously to stress-induced mutagenesis of nongrowing cells or to selective improvement of preexisting weakly Lac⁺ cells with no mutagenesis. Most revertant colonies (90%) contain stably Lac⁺ cells, while others (10%) contain cells with an unstable amplification of the leaky mutant lac allele. Evidence is presented that both stable and unstable Lac⁺ revertant colonies are initiated by preexisting cells with multiple copies of the F′lac plasmid, which carries the mutant lac allele. The tetracycline analog anhydrotetracycline (AnTc) inhibits growth of cells with multiple copies of the tetA gene. Populations with tetA on their F′lac plasmid include rare cells with an elevated plasmid copy number and multiple copies of both the tetA and lac genes. Pregrowth of such populations with AnTc reduces the number of cells with multiple F′lac copies and consequently the number of Lac⁺ colonies appearing under selection. Revertant yield is restored rapidly by a few generations of growth without AnTc. We suggest that preexisting cells with multiple F′lac copies divide very little under selection but have enough energy to replicate their F′lac plasmids repeatedly until reversion initiates a stable Lac⁺ colony. Preexisting cells whose high-copy plasmid includes an internal lac duplication grow under selection and produce an unstable Lac⁺ colony. In this model, all revertant colonies are initiated by preexisting cells and cannot be stress induced.     

A novel illegitimate recombination event: precise excision and reintegration with the Mu gem mutant prophage

The bacteriophage Mu is known to insert its DNA more or less randomly within the Escherichia coli chromosome, as do transposable elements, but unlike the latter, precise excision of the prophage, thereby restoring the original sequence, is not observed with wild-type Mu, although it has been reported with certain defective mutants. We show here that the mutant prophage Mu gem2ts can excise precisely from at least three separate loci —malT, Iac and thyA (selected as Mal⁺, Lac⁺ and Thy⁺, respectively). This excision occurs under permissive conditions for phage development, is observed in fully immune (c⁺) lysogens, and is independent of RecA and of Mu transposase. Mu gemts2 excision is invariably accompanied by reintegration of a Mu gem2ts prophage elsewhere in the chromosome, in the case of Mal⁺ revertants, this prophage is systematically located at 94min on the E. coli chromosome. Mu gem2ts excision therefore sheds some light on the long-standing paradox of the lack of precise Mu excisio.     

The Origin of Mutants Under Selection: How Natural Selection Mimics Mutagenesis (Adaptive Mutation)

Selection detects mutants but does not cause mutations. Contrary to this dictum, Cairns and Foster plated a leaky lac mutant of Escherichia coli on lactose medium and saw revertant (Lac⁺) colonies accumulate with time above a nongrowing lawn. This result suggested that bacteria might mutagenize their own genome when growth is blocked. However, this conclusion is suspect in the light of recent evidence that revertant colonies are initiated by preexisting cells with multiple copies the conjugative F′lac plasmid, which carries the lac mutation. Some plated cells have multiple copies of the simple F′lac plasmid. This provides sufficient LacZ activity to support plasmid replication but not cell division. In nongrowing cells, repeated plasmid replication increases the likelihood of a reversion event. Reversion to lac⁺ triggers exponential cell growth leading to a stable Lac⁺ revertant colony. In 10% of these plated cells, the high-copy plasmid includes an internal tandem lac duplication, which provides even more LacZ activity—sufficient to support slow growth and formation of an unstable Lac⁺ colony. Cells with multiple copies of the F′lac plasmid have an increased mutation rate, because the plasmid encodes the error-prone (mutagenic) DNA polymerase, DinB. Without DinB, unstable and stable Lac⁺ revertant types form in equal numbers and both types arise with no mutagenesis. Amplification and selection are central to behavior of the Cairns–Foster system, whereas mutagenesis is a system-specific side effect or artifact caused by coamplification of dinB with lac. Study of this system has revealed several broadly applicable principles. In all populations, gene duplications are frequent stable genetic polymorphisms, common near-neutral mutant alleles can gain a positive phenotype when amplified under selection, and natural selection can operate without cell division when variability is generated by overreplication of local genome subregions.     

Characterization of revertants of stmF mutants of Dictyostelium discoideum: Evidence that stmF is the structural gene of the cgmp-specific phosphodiesterase

stmF mutants of Dictyostelium discoideum produce long, banded aggregation streams on growth plates and exhibit altered cGMP metabolism. To learn more about the role of cGMP in chemotaxis and the nature of the defect in these mutants, 15 nonstreaming (Stm⁺) revertants of two stmF mutants were isolated and characterized. Fourteen of the revertants continued to show the elevated cAMP-induced cGMP response and very low cGMP-specific phosphodiesterase (cGPD) activity characteristic of their stmF parents. Parasexual genetic analysis revealed that many of these Stm⁺ revertants carried phenotypic suppressors unlinked to stmF. One Stm⁺ revertant, strain HC344, exhibited a low, prolonged cGMP response and relatively high cGPD activity throughout development. To determine whether the elevated cGPD activity in this revertant resulted from increased enzyme production or enhanced enzyme activity, cGPDs were partially purified from the wild-type strain, the stmF parent and revertant HC344, and properties of the enzymes were compared. cGPDs from the stmF mutant and the revertant showed similar differences from the wild-type enzyme in kinetic properties, thermal stability, and sensitivity to certain inhibitors. These results suggest that stmF is the structural gene of the cGPD. In addition, the unusual cGMP response in revertant HC344 appeared to be due to increased production of an altered cGPD.     

High rotational mobility of DNA in animal cells and its modulation by histone acetylation

Summary Several spontaneous Lac⁻ deletion derivatives of the β-galactosidase gene ofLactobacillus bulgaricus were analyzed for their phenotypic stability. We found that one of these mutants,lac139, carrying a deletion of 30 by within the gene, was able to revert to a Lac⁺ phenotype. Genetical analysis of revertants indicated that an internal region of 72 by was duplicated immediately next to the deletion site. The region involved in the duplication event is flanked by direct repeated sequences of 13 by in length. Both events, the deletion and the duplication, were mediated by the presence of such short direct repeats. Enzymatic studies of the purified proteins indicated identical kinetic parameters, but showed considerable instability of the revertant protein.     

Cloning of a lac+, bamHI fragment into transposon Tn3 and transposition of the Tn3[lac] element

By use of recombinant DNA techniques, we have inserted the lac⁺ operon into a transposon (Tn3). We constructed the recombinant in such a way that the essential step in assaying for transposition consisted of screening for bacteria with a thermostable Lac⁺ phenotype. Our results showed that transposition of the Tn3[lac⁺] element occurred and that its frequency was derepressed compared to frequencies reported by others for wild-type Tn3 transposition.     

Isolation of mutant promoters in the Escherichia coli galactose operon using local mutagenesis on cloned DNA fragments

We have worked out a system to obtain mutations that map in the promoter region of the Escherichia coli galactose operon. In order to easily detect small changes in gal promoter activity, we constructed a plasmid containing an operon fusion in which the lactose operon structural genes were controlled by the galactose operon promoter region. In cells harbouring this plasmid, even modest variations in the expression of the lac genes could be detected on MacConkey lactose indicator plates.Enrichment for mutations that map in the promoter segment of the galactose operon was achieved by mutagenesis in vitro of a small fragment of DNA covering the promoter region. After insertion of the mutagenized gal promoter fragment into the gal-lac fusion plasmid, lac^?1 cells were transformed and screened for an altered Lac⁺ phenotype on indicator plates. Several mutants were isolated due to lesions mapping in the small fragment covering the galactose promoter. In these mutants, the level of β-galactosidase was between 15 and 50% of the wild-type level.The mutant promoters were subsequently reinserted into a plasmid containing the intact galactose operon. Cells harbouring such plasmids, reconstituted with mutant galactose promoters, contained decreased levels of galactokinase that paralleled the decreases in β-galactosidase. The biochemical properties of these mutants are reported in the accompanying paper (Busby et al., 1982).     

Donor Strains of the Soft-Rot Bacterium Erwinia chrysanthemi and Conjugational Transfer of the Pectolytic Capacity

Donor strains of Erwinia chrysanthemi ICPB EC16, a member of the soft-rot (pectolytic) section of the enterobacterial genus Erwinia, were obtained by chromosomal integration of an F′lac⁺ plasmid originating from Escherichia coli. These stable donor strains, selected from an unstable F′lac⁺ heterogenote by repeated platings of single Lac⁺ colonies on lactose minimal agar, do not segregate (as does the parent F′lac⁺ heterogenote) into Lac⁻ or F⁻ clones, in either the presence or absence of acridine orange. One representative donor strain (from the 12 that have been selected) has been examined in more detail; it can transfer ade⁺, gal⁺, gtu⁺ (utilization of galacturonate), his⁺, lac⁺, leu⁺, lys⁺, mcu⁺ (multiple carbohydrate utilization), pat⁺ (production of polygalacturonic acid trans-eliminase), thr⁺, and trp⁺ in a polarized manner to appropriate recipient strains of E. chrysanthemi; the frequencies of ade⁺, leu⁺, and thr⁺ transfer were higher than those of the other markers tested to date. This donor strain transfers lac⁺ genes during a 6-h mating on membranes; most of the Lac⁺ recombinants are donors of chromosomal markers. The kinetics of entry as well as the frequencies of transfer of chromosomal markers indicate that thr⁺ and leu⁺ enter the recipient as proximal markers and that lac⁺ enters as a distal marker. Analysis of the recombinants demonstrates close linkage between thr and leu, ade and thr, his and pat, and his and trp loci. The results suggest that the integration of F′lac⁺ into the chromosome of E. chrysanthemi has occurred at a region adjacent to the leu-thr loci, and that the chromosome is transferred in the following sequence: origin----leu--thr--ade--lys--mcu--pat--his--trp--gal--gtu--lac--F. Plant-tissue maceration occurs in Pat⁺ recombinants and not in Pat⁻ recombinants, even though both form another pectolytic enzyme, hydrolytic polygalacturonase. This genetic evidence supports the idea that the E. chrysanthemi polygalacturonic acid trans-eliminase plays an essential role in bringing about plant-tissue maceration.     

Adaptive amplification and point mutation are independent mechanisms: evidence for various stress-inducible mutation mechanisms

“Adaptive mutation” denotes a collection of processes in which cells respond to growth-limiting environments by producing compensatory mutants that grow well, apparently violating fundamental principles of evolution. In a well-studied model, starvation of stationary-phase lac⁻ Escherichia coli cells on lactose medium induces Lac⁺ revertants at higher frequencies than predicted by usual mutation models. These revertants carry either a compensatory frameshift mutation or a greater than 20-fold amplification of the leaky lac allele. A crucial distinction between alternative hypotheses for the mechanisms of adaptive mutation hinges on whether these amplification and frameshift mutation events are distinct, or whether amplification is a molecular intermediate, producing an intermediate cell type, in colonies on a pathway to frameshift mutation. The latter model allows the evolutionarily conservative idea of increased mutations (per cell) without increased mutation rate (by virtue of extra gene copies per cell), whereas the former requires an increase in mutation rate, potentially accelerating evolution. To resolve these models, we probed early events leading to rare adaptive mutations and report several results that show that amplification is not the precursor to frameshift mutation but rather is an independent adaptive outcome. (i) Using new high-resolution selection methods and stringent analysis of all cells in very young (micro)colonies (500–10,000 cells), we find that most mutant colonies contain no detectable lac-amplified cells, in contrast with previous reports. (ii) Analysis of nascent colonies, as young as the two-cell stage, revealed mutant Lac⁺ cells with no lac-amplified cells present. (iii) Stringent colony-fate experiments show that microcolonies of lac-amplified cells grow to form visible colonies of lac-amplified, not mutant, cells. (iv) Mutant cells do not overgrow lac-amplified cells in microcolonies fast enough to mask the lac-amplified cells. (v) lac-amplified cells are not SOS-induced, as was proposed to explain elevated mutation in a sequential model. (vi) Amplification, and not frameshift mutation, requires DNA polymerase I, demonstrating that mutation is separable from amplification, and also illuminating the amplification mechanism. We conclude that amplification and mutation are independent outcomes of adaptive genetic change. We suggest that the availability of alternative pathways for genetic/evolutionary adaptation and clonal expansion under stress may be exploited during processes ranging from the evolution of drug resistance to cancer progression.     

Carbohydrate Accumulation and Metabolism in Escherichia coli: the Close Linkage and Chromosomal Location of ctr Mutations

Six pleiotropic ctr mutations of Escherichia coli, affecting the ability to utilize 10 carbohydrates, were found to be closely linked to one another and to the mutation of strain MM6 causing lack of enzyme 1 of the phosphotransferase system. These mutations are located at 46 to 47 min on the E. coli map. Preliminary biochemical evidence indicates that the ctr mutants also lack enzyme 1, although they have a different phenotype from MM6.     

Evolution of the long range structure of satellite DNAs in the genus Apodemus.

The temperate bacteriophage Mu causes mutations by inserting its DNA randomly into the genes of its host bacterium Escherichia coli. It is shown here that Mu DNA can be precisely excised from the different integration sites and that as a result wild-type function of the gene into which Mu was inserted is restored. The excision of Mu DNA is observable only if the Mu prophage carries mutations at the X locus. Thus, lac⁺ revertants from six strains, containing heat-inducible prophage Mu cts62 at different locations in the Z gene of the lac operon, were readily obtained by first introducing the X mutation into Mu cts62. The lac⁺ revertants produced wild-type β-galactosidase, and no trace of Mu DNA could be detected in them; this indicates that the junction of Mu DNA and host DNA can be specifically recognized. However, the excision of Mu DNA is generally not perfect, because in most cases it does not lead to the wild-type genotype. The function of gene A of Mu appears to be required for excision. Since the lethal functions of Mu are completely blocked in the Mu cts62 X prophage, the X locus probably has a regulatory function. At least one X mutation is caused by an insertion of about 900 base-pairs in Mu DNA. The discovery of the X mutants opens the way for studying the reversible interaction of the host and Mu chromosomes, and for using Mu to manipulate the host genome in various ways.     

Novel mutations of Escherichia coli that produce recombinogenic lesions in DNA. I. Identification and mapping of arl mutations

Hyper-rec mutants of Escherichia coli were originally identified as lac-diploid strains whose colonies exhibited unusually high numbers of Lac⁺ papillae during growth on indicator plates (Konrad, 1977). For this work, 38 hyper-rec strains with particularly high frequencies of papillation were selected and screened further, in order to identify those unusually proficient in recombination of bacteriophage λ. The screening procedure, plate-stock growth of λ duplication phages, yielded four strains that exhibited both enhanced recombination of λ and normal (or higher) yields of progeny phage. The mutants displayed the same novel phenotype: phage recombination was normal during the first lytic infection, but was stimulated four- to sixfold if the phages had previously been propagated for several cycles in the mutants. Phages thus appeared to accumulate an enhanced potential for recombination during growth in these four strains. The mutations responsible were designated arl. Enhanced recombination of the phages propagated on arl strains occurred in subsequent test infections of both arl and arl⁺ bacteria, but not in recA cells. Both the high frequency of Lac⁺ papillae and the effects on λ recombination appeared to result from the same mutations. The former phenotype was used for genetic analysis of two arl mutants; their location is near 2 minutes on the E. coli map. Known alleles of two nearby genes, polB and mutT, do not confer a hyper-rec phenotype (by the lac-diploid assay). High-level RecA-constitutive strains do not exhibit enhanced recombination of duplication phages.     

The effect of extracellular metabolites on the frequency of thy+ revertants in Salmonella typhimurium populations

There is convincing evidence that adaptation and survival processes in bacterial populations depend on cell-to-cell interactions. Our studies showed that the frequency of stress-induced His⁺ reversions in an amino-acid-starved Salmonella typhimurium culture is inversely proportional to cell density in this culture. The effects of cell density and of different culture liquids prepared from cultures starved for histidine on the frequency of Thy⁺ revertants were also studied. It was found that the frequency of Thy⁺ revertants is inversely proportional (r = ?0.74) to the density of the bacterial culture starved of thymine. The culture liquid prepared from the culture starved of histidine exerted an inhibitory effect on the frequency of Thy⁺ reversions, indicating that mutations induced by different types of stress have a common mechanism. The study of the effect of the culture liquid prepared from a histidine-starved culture on the frequency of ethyl-methanesulfonate-induced His⁺ revertants showed that this liquid prevented the induction of His⁺ reversions.     

The DNA gyrase of Escherichia coli participates in the formation of a spontaneous deletion by recA-independent recombination in vivo

Summary A system for detecting a spontaneous deletion in Escherichia coli was developed and the role of DNA gyrase in deletion formation was studied. A derivative of plac5, AM36, was isolated in which whole pBR322 DNA was inserted in the lacZ gene and 227 by of the lac gene duplicated at both sides of the pBR322 DNA. E. coli lac ^–strains lysogenized by AM36 had a Lac^– phenotype and segregated Lac^– revertants. Sequence analyses showed that the revertant was formed by a deletion that eliminated the inserted pBR322 DNA and one copy of the duplicated segments. The frequency of lac ^– revertant formation was independent of recA function, was increased by oxolinic acid, an inhibitor of DNA gyrase, but was not increased in a lysogen of a nalidixic acid-resistant derivative. The reversion frequencies of temperature sensitive mutants of gyrA gene are 10 to 100 times lower than that of the wild-type strain. These results indicate that the DNA gyrase of E. coli participated in the in vivo deletion formation resulting from the direct repeats.     

Fusions of the lac operon to the transfer RNA gene tyrT of Escherichia coli.

The tyrT gene codes for one of the tyrosirie tRNA species. Using the Casadabatn (1976a) technique, strains of Escherichia coli were isolated in which the lac structural genes are fused to the promoter of the tyrT gene. This procedure involved obtaining a number of insertions of phage Mu DNA in the tyrT gene, lysogenizing the Mu insertion strains with a λplac-Mu hybrid phage, and selecting Lac⁺ derivatives of such lysogens. In a number of Lac⁺ strains thus obtained, the synthesis of β-galactosidase, the product of the lacZ gene, is regulated in a similar fashion to the synthesis of stable RNA. The fusion strains were shown directly to be tyrT-lac fusions by demonstrating that a Mu insertion in the tyrT gene when genetically recombined into the presumed fusion, inactivates the expression of the lac genes. This result shows that tyrT gene sequences are fused to and control the expression of the lac genes in these strains. This is the first report in which genes which code for proteins have been fused to a stable RNA gene in vivo.     

Dominant constitutive mutations in malT, the positive regulator gene of the maltose regulon in Escherichia coli.

A series of Escherichia coli strains in which the lacZ gene is fused to any of the three maltose operons were previously isolated (Silhavy et al, 1976, 1977). Starting from one such strain, in which β-galactosidase synthesis is induced by maltose, mutants could be selected which synthesize this enzyme constitutively. Several of these mutants carry a mutation in malT, the positive regulator gene of the maltose system. The mutations, called malT^c, are both cis and trans dominant over wild type. The failure of the malT⁺ product to repress the constitutive expression resulting either from a malT^c mutation (this paper) or from initiator constitutive mutations (Hofnung &; Schwartz 1971) strongly suggests that, in contrast to the l-arabinose system, the maltose system is regulated in a strictly positive manner.     

Preferential mutagenesis of lacZ integrated at unique sites in the Escherichia coli chromosome

To study the variation in spontaneous mutation frequencies in different chromosomal domains, a mini-Mu-kan-lacZ ^?transposable element was constructed to insert the lacZ ^?(Trp570 → Opal) allele into many different loci in the Escherichia coli chromosome. Papillation on MacConkey lactose plates was used to screen for mini-Mu insertion mutants with elevated levels of spontaneous mutagenesis of lacZop → LacZ⁺ candidates were then screened for normal mutation frequencies in other genes. Two different insertion mutants with this enhanced mutagenesis phenotype were isolated from 14?000 colonies, and named plm-1 (preferential lacZmutagenesis) and plm-2. The frequency of LacZ^?→ LacZ⁺ mutations in these plm mutants was over 400-fold higher than that in isogenic strains containing mini-Mu-kan-lacZop insertions at other loci. Six Lac⁺ reversion (or suppression) mutations obtained from each of the two plm mutants were mapped by P1 transduction and all were found to be linked to the Kan^r gene in the mini-Mu-kan-lacZop, suggesting that a localized mutagenic event is responsible for the preferential mutagenesis. Furthermore, both the LacZ⁺→ LacZ^?and Kan^r→ Kan^s mutant frequencies of these Lac⁺ revertants were in the range of 10^?3 to 10^?2, indicating that this putative localized mutagenesis is neither allele nor gene specific. To identify the plm loci, the chromosomal regions flanking the mini-Mu insertion sites were cloned and sequenced. A computer-assisted database search of homologous sequences revealed that the plm-1 locus is identical to the mutS gene; the mini-Mu insertion most probably results in the production of a truncated MutS protein. We suggest that the enhanced lacZ mutation frequency in plm-1 may be associated with an active process involving the putative truncated MutS protein. The DNA sequence of the plm-2 locus matched a putative malate oxidoreductase gene located at 55.5 min of the E. coli chromosome.     

LAC4 Is the Structural Gene for β-Galactosidase in KLUYVEROMYCES LACTIS

Using genetic and biochemical techniques, we have determined that β-galactosidase in the yeast Kluyveromyces lactis is coded by the LAC4 locus. The following data support this conclusion: (1) mutations in this locus result in levels of β-galactosidase activity 100-fold lower than levels in uninduced wild type and all other lac^- mutants; (2) three of five lac4 mutations are suppressible by an unlinked suppressor whose phenotype suggests that it codes for a nonsense suppressor tRNA; (3) a Lac⁺ revertant, bearing lac4–14 and this unlinked suppressor, has subnormal levels of β-galactosidase activity, and the K_m for hydrolysis of o-nitrophenyl-β, D-galactoside and the thermal stability of the enzyme are altered; (4) the level of β-galactosidase activity per cell is directly proportional to the number of copies of LAC4; (5) analysis of cell-free extracts of strains bearing mutations in LAC4 by two-dimensional acryl-amide gel electrophoresis shows that strains bearing lac4–23 and lac4–30 contain an inactive β-galactosidase whose subunit co-electrophoreses with the wild-type subunit, while no subunit or fragment of the subunit is observable in lac4–8, lac4–14 or lac4–29 mutants; (6) of all lac4 mutants, only those bearing lac4–23 or lac4–30 contain a protein that cross-reacts with anti-β-galactosidase antibody, a finding consistent with the previous result; and (7) β-galactosidase activity in several Lac⁺ revertants of strains carrying lac4–23 or lac4–30 has greatly decreased thermostability.