Utilization of 5-Bromouracil by Thymineless Bacteria

Several thymineless Escherichia coli strains have been examined for their ability to replicate their deoxyribonucleic acid when bromouracil is substituted for thymine. The procedure we describe was used to identify a thymineless strain with characteristics relatively favorable to its use in bromouracil labeling experiments. In addition, mutants with an “absolute” thymine requirement could be easily distinguished from one with a “leaky” thymine requirement.     

Effect of Bromouracil-containing Deoxyribonucleic Acid on Bacillus subtilis

Gimlin, Dixie M. (Oklahoma State University, Stillwater), Sue D. Hardman, Betty N. Kelley, Grace C. Butler, and Franklin R. Leach. Effect of bromouracil-containing deoxyribonucleic acid on Bacillus subtilis. J. Bacteriol. 92:366-374. 1966.-Replacement of one-half of the thymine with bromouracil in Bacillus subtilis transforming deoxyribonucleic acid (DNA) resulted in a slight decrease in transforming activity, but, when used at high concentrations, this DNA preparation inhibited cell growth. Acid-hydrolyzed DNA, or addition of equivalent concentrations of the free base bromouracil in a transforming mixture, was without effect on cell growth. Treatment of the DNA preparation with deoxyribonuclease completely destroyed transforming activity and killing effect, whereas treatments with ribonuclease and trypsin were without effect on either transformation or killing activity. Growth of competent B. subtilis cells in test tubes was inhibited by high concentrations of both normal and bromouracil-containing DNA, with the bromouracil-containing DNA being significantly more inhibitory. This type of inhibition was also reflected in the time of division of the cells. The inhibitory effect was not due to viscosity, or to mutagenicity. The time course of killing paralleled transformation, and competency was required. These results can be interpreted as being due to uptake of homologous but imperfect DNA (containing bromouracil instead of thymine) by means of the systems involved in transformation, followed by either integration (resulting in lethal transformation, activation of a defective, nonlytic but lethal prophage) or interference with the recombination mechanism.     

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.     

Bromouracil mutagenesis and mismatch repair in mutator strains of Escherichia coli.

A screening procedure based on the formation of papillae on individual bacterial colonies was used to isolate mutants of Escherichia coli with high mutation rates in the presence of bromouracil. Most of the mutants obtained had high spontaneous mutation rates and mapped close to the previously known mutators mutT, mutS, mutR, uvrE and mutL. Except for mutants of mutT type, these mutators also showed high mutability by bromouracil. Transfection experiments were performed with heteroduplex lambda DNA to test for mismatch repair. The results suggest a reduced efficiency of repair of mismatched bases in mutators mutS, mutR, uvrE and mutL, whereas mutants mapping as mutT appear normal. The results support a connection between spontaneous and bromouracil-induced mutability and repair of mismatched bases in DNA.     

Electron microscope visualization of the products of Bacillus subtilis transformation.

The reduced alkalinity required to denature DNA in which bromouracil has replaced thymine has permitted the visualization of the molecular products of transformation of Bacillus subtilis with bromouracil-substituted DNA. The appearance of these molecules suggests that several distinct segments of a single bound DNA molecule can be integrated into the genome of a recipient bacterium.     

Biological consequences of photoproducts in mammalian cell DNA partially substituted with 5-bromouracil

The response of Chinese hamster ovary cells in which 10 per cent of the thymine of one DNA strand was substituted with bromouracil (BU) was compared with normal cells following u.v. irradiation. The bromouracil substitution resulted in a 21/2 fold enhancement of both u.v.-induced killing and mutation induction at the HGPRT locus. These BU-photoproducts do not, however, result in any further inhibition of DNA replication or inhibition of the repair of u.v.-induced DNA photoproducts identified as antibody-binding sites.     

Effect of p-Fluorophenylalanine on Chromosome Replication in Escherichia coli

The effect of p-fluorophenylalanine (FPA) on deoxyribonucleic acid (DNA) synthesis and chromosome replication was studied in a thymine-requiring mutant of Escherichia coli. The rate and extent of chromosome replication were followed by labeling the DNA with isotopic thymine and a density marker, bromouracil. The DNA was extracted and analyzed by CsCl gradient centrifugation. The block in chromosome replication caused by high concentrations of FPA occurred at the same point on the chromosome as that caused by amino acid starvation. In a random culture, DNA in cells treated with FPA replicated only slightly slower than the DNA from cells that were not exposed to the analogue. In cultures which had been previously starved for thymine, however, the DNA from the cells treated with FPA showed a marked decrease in the rate and extent of replication. It was concluded that the E. coli cell is most sensitive to FPA when a new cycle of chromosome replication is being initiated at the beginning of the chromosome.     

Attempts to induce mutations in Haemophilus influenzae with the base analogues 5-bromodeoxyuridine and 2-aminopurine.

Attempts were made to induce mutations in Haemophilus influenzae with the base analogues 5-bromodeoxyuridine and 2-aminopurine. These attempts were unsuccessful. Incorporation studies with BrdUrd showed, in agreement with earlier studies on Escherichia coli, that BrdUrd was discriminated against when dThd was also present but was incorporated to essentially the same extent as dThd when only BrdUrd was present. In this latter case, strands fully substituted with BrdUrd was produced, but survival data suggest that bacteria deriving their DNA by replication on such fully substituted templates were inviable. However, bacteria with about 20% of the thymine substituted with bromouracil were usually viable. No mutations could be detected in the descendants of such bacteria. The reasons for this are discussed and it is concluded that in all probability the replication system in species rarely if every treats incorporated bromouracil as anything except a thymine analogue. The alternative possibility, that the negative results are a consequence of the absence of the reclex (SOS) error-prone repair system in this species, is considered much less likely.     

Temperature-Sensitive Mutants for the Replication of Plasmids in ESCHERICHIA COLI I. Isolation and Specificity of Host and Plasmid Mutations

Temperature-sensitive mutants of Escherichia coli defective in the replication of the plasmid colicinogenic factor E1 (ColE(1)) were isolated following mutagenesis of E. coli K12 strain carrying the ColE(1) factor. Following the mutagenic treatment an enrichment procedure utilizing the replacement of thymine with bromouracil in the ColE(1) DNA duplicated at the restrictive temperature was used. The mutants isolated following this enrichment step were the result of a mutation event either in the host chromosome or in the ColE(1) plasmid. The host mutants fell into three phenotypic classes based on the effect each mutation had on the maintenance of a variety of other extrachromosomal DNA elements. Phenotypic class I mutations affected all E. coli plasmids, both the I and F sex factor types as well as the ColE(1) factor. Phenotypic class II mutations affected the maintenance of the ColE(1) and the F sex factor type plasmids and not the I type, while phenotypic class III mutations affected only ColE(1) replication. None of these mutations was found to have a significant effect on the replication of the E. coli chromosome. The plasmid-linked mutations fell into two phenotypic classes on the basis of the ability of the Flac episome to complement the mutation in the ColE(1) plasmid.     

Bromodeoxyuridine 5'-monophosphate incorporation into yeast nuclear and mitochondrial deoxyribonucleic acid.

Standard laboratory yeast strains can be enriched for thymidine 5'-monophosphate (TMP) uptake derivatives that generate only a low percentage of respiratory-deficient colonies (petites) under inhibition of TMP biosynthesis. Such mutants incorporated bromodeoxyuridine 5'-monophosphate (BrdUMP) into both nuclear and mitochondrial deoxyribonucleic acid (mtDNA); however, they showed a selectivity for TMP over BrdUMP incorporation. The preferential incorporation of [3H]TMP or BrdUMP into mtDNA was strain dependent. The density increments after growth in the presence of BrdUMP reached 50 mg/ml for nuclear DNA and 22 mg/ml for mtDNA in CsCl gradients. Density shifts corresponding to 4% bromouracil substitution were easily detected. Preliminary density transfer experiments confirm that mtDNA does not replicate in synchrony with nuclear DNA.     

Virogenic BrdU and BrdU-sensitive DNA sequences are disproportionately concentrated in the template-active chromatin of rat embryo cells

In order to characterize the molecular mechanism responsible for the BrdU-mediated activation of endogenous retrovirus from normal rat embryo cells, the previously reported selective distribution of bromouracil in DNA was correlated with the corresponding organization of the nucleo-protein complex in regard to nucleosome structure and template - active and -inactive chromatin. Following micrococcal nuclease digestion of chromatin labeled with either [(3)H]thymidine or [(3)H]BrdU, the amount and specific activities of the respective nucleosomal DNA were indistinguishable. Comparable findings were obtained following direct examination of the nuclease-sensitive, "spacer" DNA. However, when each chromatin type was fractionated into template-active and -inactive components, it was evident that [(3)H]bromouracil was nonrandomly more concentrated in the template-active portion in comparison to the random distribution of [(3)H]thymine moieties. Furthermore, it was apparent that the template-active chromatin fraction was substantially enriched in the nucleotide sequences of rat DNA known to be sensitive to the virogenic action of BrdU.     

Mutants of Saccharomyces cerevisiae That Incorporate Deoxythymidine-5′-Monophosphate Into Deoxyribonucleic Acid In Vivo

Spontaneous mutants of Saccharomyces cerevisiae able to incorporate deoxythymidine-5′-monophosphate (dTMP) into deoxyribonucleic acid (DNA) have been selected based on their ability to grow in the presence of aminopterin and sulfanilamide if dTMP is present. Essentially all mutants (called tup) selected in this way required dTMP for growth in the presence of the two drugs, but none required dTMP in the absence of the drugs. Neither thymine nor thymidine would satisfy this requirement. Equimolar amounts of ³²P- and ³H-base-labeled dTMP were incorporated by the mutants into alkali-stable, deoxyribonuclease-sensitive material. In the presence of aminopterin and sulfanilamide, this incorporation was sufficient to account for a substantial proportion of the thymine residues in the cellular DNA, whereas in the absence of the drugs only about 40% as much of the thymine residues originated from the medium. Of 29 mutants examined, all were recessive and 17 showed 2:2 segregation in crosses with a wild-type strain. The lesions in these mutants fell into four complementation groups: one (tup1) occurs on chromosome III; another (tup3) is on chromosome II; and a third (tup4) was centromere linked. Strains of the genotype α tup1 mated with lower than normal efficiency with a strains, but with higher than normal efficiency with α strains. Strains of genotype a/α tup1/tup1 failed to sporulate, whereas homozygous diploids for tup2, tup3, or tup4 sporulated normally, as did a/α tup1/+ strains.     

Strand breaks and alkali-labile bonds induced by ultraviolet light in DNA with 5-bromouracil in vivo.

Supercircular gamma phage DNA with 10 bromouracils/100 thymine bases, irradiated with 313 nm light in Tris buffer and sedimented on alkaline and neutral gradients, showed 4.6 alkali-labile bonds per true single-strand break, in agreement with Hewitt and Marburger (1975 Photochem. Photobiol. 21:413). The same DNA irradiated in Escherichia coli host cells showed about the same number of breaks in alkaline gradients for equal fluence, but only 0.5 alkali-labile bond per true break. Similarly, E. coli DNA with bromouracil irradiated in the cells showed only 10--20% more breaks when denatured with 0.1 M NaOH than under neutral conditions with 9 M sodium perchlorate at 50 degrees C. These results show that true single-strand breaks occur more frequently than alkali-labile bonds after ultraviolet irradiation of DNA containing bromouracil in cells.     

Formation and possible functions of alpha-putrescinylthymine in bacteriophage phi W-14 DNA: analysis of bacteriophage mutants with decreased levels of alpha-putrescinylthymine in their DNAs.

The DNA synthesized in the nonpermissive host by the noncomplementing mutants am36 and am42 of bacteriophage phi W-14 contains about half the wild-type level of alpha-putrescinylthymine (putThy) and a correspondingly greater level of thymine. The mechanisms whereby thymine nucleotides are excluded from replicating DNA are functional in both mutants because neither of them incorporates exogenous thymidine into DNA. It is proposed that (i) in wild-type phi W-14, the conversion of hydroxymethyluracil to putThy at the polynucleotide level is sequence specific, but that to thymine is nonspecific; and (ii) in the mutants, the sequence-specific recognition is impaired so that more thymine and less putThy are formed. The thymine-rich DNA can be packaged into phage particles. In the case of am42, the phage particles are morphologically indistinguishable from and have essentially the same polypeptide composition as wild-type particles. However, the DNA molecules they contain are about 11% shorter than those in wild-type phage, am42rev4, a revertant of am42, contains DNA with about 70% of the normal level of putThy; these molecules are about 3% shorter than wild-type DNA. The properties of am42 and am42rev4 are consistent with the suggestion that putThy facilitates the very tight packing of phi W-14 DNA (Scraba et al., Virology 124:152-160, 1983). It also appears that the putThy content of phi W-14 DNA can be reduced by no more than 30% without adversely affecting the production of viable progeny; for example, the burst size of am42rev4 is about 25% of that of the wild type.     

The effect of 313 nanometer light on initiation of replicons in mammalian cell DNA containing bromodeoxyuridine.

After unifilar substitution of thymine with bromouracil in either human HeLa or bovine cells, exposure to 313 nm light inhibits initiation of clusters of replicons. Since this treatment results in damage only to DNA and because the effect is the same as observed after 100-1000 rads of X-ray irradiation to the same cells, we infer that the effect of the later treatment is also mediated almost exclusively by DNA damage.     

Isolation and preliminary characterization of amber mutants of bacteriophage phi W-14 defective in DNA synthesis.

Of 42 amber mutants of bacteriophage phi W-14, 6 were defective in DNA synthesis. Three of the mutants synthesized DNA in the nonpermissive host, but were defective in post-replicational modification of the DNA. The DNA synthesized by two of these mutants, am36 and am42, contained more thymine and less alpha-putrescinylthymine than did wild-type DNA; that synthesized by the third mutant, am37, contained the normal amount of thymine, no alpha-putrescinylthymine, and hydroxymethyluracil. The properties of these mutants suggested that the presence of the normal amount of alpha-putrescinylthymine in phi W-14 DNA was essential for the production of viable progeny. Three of the mutants, am6, am35, and am45, failed to synthesize DNA in the nonpermissive host. These mutants were analogous to the DNA off mutants of T4. Nonpermissive cells infected with DNA off mutants accumulated dATP, dGTP, dCTP, and hydroxymethyl dUTP, but not dTTP or alpha-putrescinyldeoxythymidine triphosphate, confirming that both thymine and alpha-putrescinylthymidine in phi W-14 DNA are formed from hydroxymethyluracil at the polynucleotide level. The synthesis of phi W-14 DNA is unusual because (i) thymine is formed from hydroxymethyluracil at the polynucleotide level, (ii) the hypermodification forming alpha-putrescinylthymine is essential, and (iii) thymine and alpha-putrescinylthymine must be made in the correct proportions. Complementation tests showed that the mutants defined three genes involved in DNA polymerization and two genes involved in post-replicational modification.     

SOS processing of unique oxidative DNA damages in Escherichia coli

phi X174 replicative form (RF) I transfecting DNA containing thymine glycols (5,6-dihydroxy-5,6-dihydrothymine), urea glycosides or apurinic (AP) sites was used to study SOS processing of unique DNA damages in Escherichia coli. All three lesions can be found in DNA damaged by chemical oxidants or radiation and are representative of several common structural modifications of DNA bases. When phi X DNA containing thymine glycols was transfected into host cells that were ultraviolet-irradiated to induce the SOS response, a substantial increase in survival was observed compared to transfection into uninduced hosts. Studies with mutants demonstrated that both the activated form of RecA and UmuDC proteins were required for this reactivation. In contrast, no increase in survival was observed when DNA containing urea glycosides or AP sites was transfected into ultraviolet-induced hosts. These data suggest that SOS-induced reactivation does not reflect a generalized repair system for all replication-blocking, lethal lesions but rather that the efficiency of reactivation is damage dependent. Further, we found that a significant fraction of potentially lethal thymine glycols could be ultraviolet-reactivated in an umuC lexA recA-independent manner, suggesting the existence of an as yet uncharacterized damage-inducible SOS-independent mode of thymine glycol repair.     

Studies of intracellular thymidine nucleotides. Relationship between the synthesis of deoxyribonucleic acid and the thymidine triphosphate pool in Escherichia coli K12.

The two types of mutant strains which show resistance to T-even phage infection have been isolated and been shown to have either a higher or lower ratio of dTDP-sugar to dTTP than that of the parent strains. The one with a higher ratio of dTDP-sugar to dTTP than the parents has a large dTDP-sugar pool and small dTTP pool, and a high level of dTDPG pyrophosphorylase activity. The other one, with a lower ratio of dTDP-sugar to dTTP than the parents, has a small dTDP-sugar pool and large dTTP pool, and a low or deficient level of this enzyme activity. They form an entirely mucoid colony in the synthetic agar plate. Mutant cells (Ter-6 and Ter-21) which have deficient dTDPG pyrophosphorylase activity show 2 -- 3 times higher activity of UDPG pyrophosphoyrlase than that of parent cells. The dTDPG pyrophosphorylase-deficient mutants (Ter-15 and Ter-21) have a 3 -- 4 times higher concentration of dTTP and a faster rate of DNA synthesis and cell division than those of parent strains in growth with external thymine. The dTDPG pyrophosphorylase constitutive mutant (Ter-4) has a 0.5 -- 0.33 smaller dTTP pool and a slower rate of DNA synthesis and cell division than those of parent cells grown in the same medium. In the Ter-15 and Ter-21 mutants, the intracellular dTTP-dependent DNA synthesis rapidly disappeared in thymine suboptimal concentration, but the Ter-4 mutant maintained its dTTP-dependent DNA synthesis over a 20 muM concentration of external thymine. In high concentration (100 muM) of external thymidine, the thymidine effects on the intracellular dTTP concentration do not significantly appear in these enzyme-deficient mutants (Ter-15 and Ter-21). Also, the concentration of intracellular dTTP in the cell growth with external thymidine is 2.5 times greater than that with external thymine in these enzyme-deficient mutants (Ter-15 and Ter-21).     

Some Characteristics of the Resistance Transfer Factor (RTF) Episome as Determined by Inactivation with Tritium, P32, and Gamma Radiation

The resistance transfer factor (RTF) episome was studied by measuring its inactivation by Co⁶⁰ gamma radiation, by incorporated P³², and by tritium incorporated as tritium-labeled thymine. The D₃₇ for Co⁶⁰ irradiation was 7 to 9 × 10⁴ rad. Growth of the bacteria harboring the RTF in BUdR (bromouracil deoxyriboside) increased the sensitivity of the RTF to the gamma radiation. The RTF was markedly inactivated by tritium after growth of the host (thymine requiring) bacteria in tritium-labeled thymine, thus further establishing the presence of thymine in the genome of the RTF. Assuming the efficiency of inactivation by P³² to be 10%, the phosphorus content of the RTF was estimated to be about 2 × 10⁵ P atoms/episome. The data suggest the RTF contains double stranded DNA with a molecular weight of the order of 3 to 8 × 10⁷.     

5-Bromouracil-tolerant mutants of Bacillus subtilis

5-Bromouracil (BU)-tolerant mutants of Bacillus subtilis 23 (thy his) have been isolated. Several classes of tolerant mutants were obtained by a sequential selection procedure. The classes can be distinguished by their relative BU tolerance as well as several other phenotypic characteristics. The mutants can grow for an extended period of time in minimal medium supplemented with amino acids and BU, in which the sensitive parental strain (Bu(+)) undergoes rapid cell death. Both mutants But-1 and But-1310 have a greater rate of deoxyribonucleic acid (DNA) synthesis by a factor of two in the presence of BU than Bu(+), But-1 being somewhat faster than But-1310. The preferential incorporation of thymine to BU of But-1 is about half that of the Bu(+) strain during DNA replication in minimal medium supplemented with 10 mug of BU/ml and 1 mug of thymine/ml. It is not known at what step or steps this reduction in selectivity occurs.