Excision repair of uracil incorporated in DNA as a result of a defect in dUTPase.

Mutants of Escherichia coli that are severely defective in the enzyme dUTPase (dut) accumulate short (4 to 5 S) Okazaki fragments following brief pulses with [³H]thymidine. The transient appearance of DNA fragments in these mutants is plausibly explained by the misincorporation of uracil in DNA as a result of an increase in available dUTP, followed by its rapid excision and repair. The evidence in support of this interpretation is the following: (1) accumulation of short DNA fragments can be partially suppressed by a mutation in dCTP deaminase, presumably by decreasing the intracellular level of dUTP relative to dTTP; (2) accumulation of the short DNA fragments can be almost completely suppressed by a mutation in uracil N-glycosidase, probably by preventing the introduction of nicks at the sites of uracil incorporation; (3) introduction of DNA polymerase I or DNA ligase mutations into dUTPase-defective strains results in the persistence of the 4 to 5 S fragments and rapid cessation of DNA synthesis. Uracil N-glycosidase, DNA polymerase I and DNA ligase must therefore be involved in the excision repair of uracil-containing DNA.     

DNA intermediates at the Escherichia coli replication fork. II. Studies using dut and ung mutants in vitro.

The incorporation of uracil into and excision from DNA were studied in vitro using lysates on cellophane discs made from Escherichia coli strains with defects in the enzymes dUTPase (dut) and uracil-DNA glycosylase (ung).Results with dut ung lysates indicate that dUTP is competitively incorporated with dTTP at the replication fork. Such incorporation is not due to DNA polymerase I. There is a mild discrimination (2.5-fold) against incorporation of dUTP versus dTTP. These data, together with in vivo uracil incorporation data (Tye et al., 1978) permit a rough estimate of the pool of dUTP in vivo (~0.5% of the dTTP pool).These in vitro data indicate that uracil-DNA glycosylase is the initial step in at least 90% of uracil excision events. However, in a strain defective in uracil-DNA glycosylase (ung-1), uracil-containing DNA is still more subject to single-strand scission than non-uracil-containing DNA, albeit at a rate at least tenfold less than in an ung⁺ strain.A number of qualitative statements may also be made about different steps in uracil incorporation and subsequent excision and repair events. When high levels of dUTP are added in vitro, a dut ung⁺ strain has a higher steady-state level of uracil in newly synthesized DNA than does an isogenic dut⁺ ung strain. Thus the dUTPase in these lysates has a higher capacity to be overloaded than does the excision system (i.e. uracil DNA glycosylase). However, the DNA sealing system (presumably DNA polymerase I and DNA ligase) apparently can handle all single-strand interruptions being introduced by uracil excision at the maximal rate, at least so that DNA synthesis can continue.     

Expanding the DNA alphabet in the fruit fly

DNA integrity is under the control of multiple pathways of nucleotide metabolism and DNA damage recognition and repair. Unusual sets of protein factors involved in these control mechanisms may result in tolerance and accumulation of non-canonical bases within the DNA. We investigate the presence of uracil in genomic DNA of Drosophila melanogaster. Results indicate a developmental pattern and strong correlations between uracil-DNA levels, dUTPase expression and developmental fate of different tissues. The intriguing lack of the catalytically most efficient uracil-DNA glycosylase in Drosophila melanogaster may be a general attribute of Holometabola and is suggested to be involved in the specific characteristics of uracil-DNA metabolism in these insects.     

Endonuclease V (nfi) Mutant of Escherichia coli K-12

Endonuclease V (deoxyinosine 3′ endonuclease), the product of the nfi gene, has a specificity that encompasses DNAs containing dIMP, abasic sites, base mismatches, uracil, and even untreated single-stranded DNA. To determine its importance in DNA repair pathways, nfi insertion mutants and overproducers (strains bearing nfi plasmids) were constructed. The mutants displayed a twofold increase in spontaneous mutations for several markers and an increased sensitivity to killing by bleomycin and nitrofurantoin. An nfi mutation increased both cellular resistance to and mutability by nitrous acid. This agent should generate potential cleavage sites for the enzyme by deaminating dAMP and dCMP in DNA to dIMP and dUMP, respectively. Relative to that of a wild-type strain, an nfi mutant displayed a 12- to 1,000-fold increase in the frequency of nitrite-induced mutations to streptomycin resistance, which are known to occur in A · T base pairs. An nfi mutation also enhanced the lethality caused by a combined deficiency of exonuclease III and dUTPase, which has been attributed to unrepaired abasic sites. However, neither the deficiency nor the overproduction of endonuclease V affected the growth of the single-stranded DNA phages M13 or X174 nor of Uracil-containing bacteriophage λ. These results suggest that endonuclease V has a significant role in the repair of deaminated deoxyadenosine (deoxyinosine) and abasic sites in DNA, but there was no evidence for its cleavage in vivo of single-stranded or uracil-containing DNA.     

Comparative Genome-Wide Screening Identifies a Conserved Doxorubicin Repair Network That Is Diploid Specific in Saccharomyces cerevisiae

The chemotherapeutic doxorubicin (DOX) induces DNA double-strand break (DSB) damage. In order to identify conserved genes that mediate DOX resistance, we screened the Saccharomyces cerevisiae diploid deletion collection and identified 376 deletion strains in which exposure to DOX was lethal or severely reduced growth fitness. This diploid screen identified 5-fold more DOX resistance genes than a comparable screen using the isogenic haploid derivative. Since DSB damage is repaired primarily by homologous recombination in yeast, and haploid cells lack an available DNA homolog in G1 and early S phase, this suggests that our diploid screen may have detected the loss of repair functions in G1 or early S phase prior to complete DNA replication. To test this, we compared the relative DOX sensitivity of 30 diploid deletion mutants identified under our screening conditions to their isogenic haploid counterpart, most of which (n = 26) were not detected in the haploid screen. For six mutants (bem1Δ, ctf4Δ, ctk1Δ, hfi1Δ,nup133Δ, tho2Δ) DOX-induced lethality was absent or greatly reduced in the haploid as compared to the isogenic diploid derivative. Moreover, unlike WT, all six diploid mutants displayed severe G1/S phase cell cycle progression defects when exposed to DOX and some were significantly enhanced (ctk1Δ and hfi1Δ) or deficient (tho2Δ) for recombination. Using these and other “THO2-like” hypo-recombinogenic, diploid-specific DOX sensitive mutants (mft1Δ, thp1Δ, thp2Δ) we utilized known genetic/proteomic interactions to construct an interactive functional genomic network which predicted additional DOX resistance genes not detected in the primary screen. Most (76%) of the DOX resistance genes detected in this diploid yeast screen are evolutionarily conserved suggesting the human orthologs are candidates for mediating DOX resistance by impacting on checkpoint and recombination functions in G1 and/or early S phases.     

Uracil-containing DNA in Drosophila: stability, stage-specific accumulation, and developmental involvement

Base-excision repair and control of nucleotide pools safe-guard against permanent uracil accumulation in DNA relying on two key enzymes: uracil-DNA glycosylase and dUTPase. Lack of the major uracil-DNA glycosylase UNG gene from the fruit fly genome and dUTPase from fruit fly larvae prompted the hypotheses that i) uracil may accumulate in Drosophila genomic DNA where it may be well tolerated, and ii) this accumulation may affect development. Here we show that i) Drosophila melanogaster tolerates high levels of uracil in DNA; ii) such DNA is correctly interpreted in cell culture and embryo; and iii) under physiological spatio-temporal control, DNA from fruit fly larvae, pupae, and imago contain greatly elevated levels of uracil (200-2,000 uracil/million bases, quantified using a novel real-time PCR-based assay). Uracil is accumulated in genomic DNA of larval tissues during larval development, whereas DNA from imaginal tissues contains much less uracil. Upon pupation and metamorphosis, uracil content in DNA is significantly decreased. We propose that the observed developmental pattern of uracil-DNA is due to the lack of the key repair enzyme UNG from the Drosophila genome together with down-regulation of dUTPase in larval tissues. In agreement, we show that dUTPase silencing increases the uracil content in DNA of imaginal tissues and induces strong lethality at the early pupal stages, indicating that tolerance of highly uracil-substituted DNA is also stage-specific. Silencing of dUTPase perturbs the physiological pattern of uracil-DNA accumulation in Drosophila and leads to a strongly lethal phenotype in early pupal stages. These findings suggest a novel role of uracil-containing DNA in Drosophila development and metamorphosis and present a novel example for developmental effects of dUTPase silencing in multicellular eukaryotes. Importantly, we also show lack of the UNG gene in all available genomes of other Holometabola insects, indicating a potentially general tolerance and developmental role of uracil-DNA in this evolutionary clade.     

Characterization of Saccharomyces cerevisiae dna2 Mutants Suggests a Role for the Helicase Late in S Phase

The TOR proteins, originally identified as targets of the immunosuppressant rapamycin, contain an ATM-like “lipid kinase” domain and are required for early G1 progression in eukaryotes. Using a screen to identify Saccharomyces cerevisiae mutants requiring overexpression of Tor1p for viability, we have isolated mutations in a gene we call ROT1 (requires overexpression of Tor1p). This gene is identical to DNA2, encoding a helicase required for DNA replication. As with its role in cell cycle progression, both the N-terminal and C-terminal regions, as well as the kinase domain of Tor1p, are required for rescue of dna2 mutants. Dna2 mutants are also rescued by Tor2p and show synthetic lethality with tor1 deletion mutants under specific conditions. Temperature-sensitive (Ts) dna2 mutants arrest irreversibly at G2/M in a RAD9- and MEC1-dependent manner, suggesting that Dna2p has a role in S phase. Frequencies of mitotic recombination and chromosome loss are elevated in dna2 mutants, also supporting a role for the protein in DNA synthesis. Temperature-shift experiments indicate that Dna2p functions during late S phase, although dna2 mutants are not deficient in bulk DNA synthesis. These data suggest that Dna2p is not required for replication fork progression but may be needed for a later event such as Okazaki fragment maturation.     

Rad52 Sumoylation Prevents the Toxicity of Unproductive Rad51 Filaments Independently of the Anti-Recombinase Srs2

The budding yeast Srs2 is the archetype of helicases that regulate several aspects of homologous recombination (HR) to maintain genomic stability. Srs2 inhibits HR at replication forks and prevents high frequencies of crossing-over. Additionally, sensitivity to DNA damage and synthetic lethality with replication and recombination mutants are phenotypes that can only be attributed to another role of Srs2: the elimination of lethal intermediates formed by recombination proteins. To shed light on these intermediates, we searched for mutations that bypass the requirement of Srs2 in DNA repair without affecting HR. Remarkably, we isolated rad52-L264P, a novel allele of RAD52, a gene that encodes one of the most central recombination proteins in yeast. This mutation suppresses a broad spectrum of srs2Δ phenotypes in haploid cells, such as UV and γ-ray sensitivities as well as synthetic lethality with replication and recombination mutants, while it does not significantly affect Rad52 functions in HR and DNA repair. Extensive analysis of the genetic interactions between rad52-L264P and srs2Δ shows that rad52-L264P bypasses the requirement for Srs2 specifically for the prevention of toxic Rad51 filaments. Conversely, this Rad52 mutant cannot restore viability of srs2Δ cells that accumulate intertwined recombination intermediates which are normally processed by Srs2 post-synaptic functions. The avoidance of toxic Rad51 filaments by Rad52-L264P can be explained by a modification of its Rad51 filament mediator activity, as indicated by Chromatin immunoprecipitation and biochemical analysis. Remarkably, sensitivity to DNA damage of srs2Δ cells can also be overcome by stimulating Rad52 sumoylation through overexpression of the sumo-ligase SIZ2, or by replacing Rad52 by a Rad52-SUMO fusion protein. We propose that, like the rad52-L264P mutation, sumoylation modifies Rad52 activity thereby changing the properties of Rad51 filaments. This conclusion is strengthened by the finding that Rad52 is often associated with complete Rad51 filaments in vitro.     

DNA repair and sequence context affect 1O2-induced mutagenesis in bacteria

Electronic excited molecular oxygen (singlet oxygen, ¹O₂) is known to damage DNA, yielding mutations. In this work, the mutagenicity induced by ¹O₂ in a defined sequence of DNA was investigated after replication in Escherichia coli mutants deficient for nucleotide and base excision DNA repair pathways. For this purpose a plasmid containing a ¹O₂-damaged 14 base oligonucleotide was introduced into E.coli by transfection and mutations were screened by hybridization with an oligonucleotide with the original sequence. Mutagenesis was observed in all strains tested, but it was especially high in the BH20 (fpg), AYM57 (fpg mutY) and AYM84 (fpg mutY uvrC) strains. The frequency of mutants in the fpg mutY strain was higher than in the triple mutant fpg mutY uvrC, suggesting that activity of the UvrABC excinuclease can favor the mutagenesis of these lesions. Additionally, most of the mutations were G→T and G→C transversions, but this was dependent on the position of the guanine in the sequence and on repair deficiency in the host bacteria. Thus, the kind of repair and the mutagenesis associated with ¹O₂-induced DNA damage are linked to the context of the damaged sequence.     

Epilepsy,Behavioral Abnormalities,and Physiological Comorbidities in Syntaxin-Binding Protein 1 (STXBP1) Mutant Zebrafish

Mutations in the synaptic machinery gene syntaxin-binding protein 1, STXBP1 (also known as MUNC18-1), are linked to childhood epilepsies and other neurodevelopmental disorders. Zebrafish STXBP1 homologs (stxbp1a and stxbp1b) have highly conserved sequence and are prominently expressed in the larval zebrafish brain. To understand the functions of stxbp1a and stxbp1b, we generated loss-of-function mutations using CRISPR/Cas9 gene editing and studied brain electrical activity, behavior, development, heart physiology, metabolism, and survival in larval zebrafish. Homozygous stxbp1a mutants exhibited a profound lack of movement, low electrical brain activity, low heart rate, decreased glucose and mitochondrial metabolism, and early fatality compared to controls. On the other hand, homozygous stxbp1b mutants had spontaneous electrographic seizures, and reduced locomotor activity response to a movement-inducing “dark-flash” visual stimulus, despite showing normal metabolism, heart rate, survival, and baseline locomotor activity. Our findings in these newly generated mutant lines of zebrafish suggest that zebrafish recapitulate clinical phenotypes associated with human syntaxin-binding protein 1 mutations.     

Excision repair of uracil during replication of phiX174 DNA in vitro.

Each of the stages in the replication of ØX174 DNA $\text{in vitro}$, e. g., conversion of circular single stranded parental DNA to the duplex replicative form (SS → RF), replication of the closed circular duplex form (RF → RF), and synthesis of circular single stranded progeny DNA (RF →SS), may be affected by a reduced level of dUTPase. Thus, in enzyme preparations from mutant strains defective in dUTPase ($\text{dut}$^?), the complementary strand synthesized in the SS → RF reaction is abnormally short (7–8S vs. 14S), and the extent of RF replication is decreased 10-fold. Preferential removal of dUTPase during fractionation of enzyme preparations from wild type ($\text{dut}$⁺) cells may produce comparable effects. In particular, the single stranded circular DNA synthesized in the RF → SS reaction by a set of highly purified enzymes is rapidly degraded upon incubation with the less pure enzymes required for its conversion to RF. All of these effects are plausibly accounted for by the incorporation into DNA of uracil from dUTP, possibly present as a contaminant in one or more components of the reaction, followed by excision of the uracil and phosphodiester bond cleavage at the resulting apyrimidinic site.     

Increased uracil insertion in DNA is cytotoxic and increases the frequency of mutation,double strand break formation and VSG switching in Trypanosoma brucei

Deoxyuridine 5′-triphosphate pyrophosphatase (dUTPase) and uracil-DNA glycosylase (UNG) are key enzymes involved in the control of the presence of uracil in DNA. While dUTPase prevents uracil misincorporation by removing dUTP from the deoxynucleotide pool, UNG excises uracil from DNA as a first step of the base excision repair pathway (BER). Here, we report that strong down-regulation of dUTPase in UNG-deficient Trypanosoma brucei cells greatly impairs cell viability in both bloodstream and procyclic forms, underscoring the extreme sensitivity of trypanosomes to uracil in DNA. Depletion of dUTPase activity in the absence of UNG provoked cell cycle alterations, massive dUTP misincorporation into DNA and chromosomal fragmentation. Overall, trypanosomatid cells that lack dUTPase and UNG activities exhibited greater proliferation defects and DNA damage than cells deficient in only one of these activities. To determine the mutagenic consequences of uracil in DNA, mutation rates and spectra were analyzed in dUTPase-depleted cells in the presence of UNG activity. These cells displayed a spontaneous mutation rate 9-fold higher than the parental cell line. Base substitutions at A:T base pairs and deletion frequencies were both significantly enhanced which is consistent with the generation of mutagenic AP sites and DNA strand breaks. The increase in strand breaks conveyed a concomitant increase in VSG switching in vitro. The low tolerance of T. brucei to uracil in DNA emphasizes the importance of uracil removal and regulation of intracellular dUTP pool levels in cell viability and genetic stability and suggests potential strategies to compromise parasite survival.     

Escherichia coli HU protein has a role in the repair of abasic sites in DNA

HU is one of the most abundant DNA binding proteins in Escherichia coli. We find that it binds strongly to DNA containing an abasic (AP) site or tetrahydrofuran (THF) (apparent K_d ≈50 nM). It also possesses an AP lyase activity that cleaves at a deoxyribose but not at a THF residue. The binding and cleavage of an AP site was observed only with the HUαβ heterodimer. Site-specific mutations at K3 and R61 residues led to a change in substrate binding and cleavage. Both K3A(α)K3A(β) and R61A(α)R61A(β) mutant HU showed significant reduction in binding to DNA containing AP site; however, only R61A(α)R61A(β) mutant protein exhibited significant loss in AP lyase activity. Both K3A(α)K3A(β) and R61K(α)R61K(β) showed slight reduction in AP lyase activities. The function of HU protein as an AP lyase was confirmed by the ability of hupA or hupB mutations to further reduce the viability of an E. coli dut(Ts) xth mutant, which generates lethal AP sites at 37°C; the hupA and hupB derivatives, respectively, had a 6-fold and a 150-fold lower survival at 37°C than did the parental strain. These data suggest, therefore, that HU protein plays a significant role in the repair of AP sites in E. coli.     

Genetic interaction of RAD53 protein kinase with histones is important for DNA replication

Studies in budding yeast suggest the protein kinase Rad53 plays novel roles in controlling initiation of DNA replication and in maintaining cellular histone levels, and these roles are independent of Rad53-mediated regulation of the checkpoint and of nucleotide levels. In order to elucidate the role of Rad53 in replication initiation, we isolated a novel allele of RAD53, rad53-rep, that separates the checkpoint function of RAD53 from the DNA replication function. rad53-rep mutants display a chromosome loss phenotype that is suppressed by increased origin dosage, providing further evidence that Rad53 plays a role in the initiation of DNA replication. Deletion of the major histone H3–H4 pair suppresses rad53-rep-cdc7-1 synthetic lethality, suggesting Rad53''s functions in degradation of excess cellular histone and in replication initiation are related. Rad53-rep is active as a protein kinase yet fails to interact with origins of replication and like the rad53Δ mutant, the rad53-rep mutant accumulates excess soluble histones, and it is sensitive to histone dosage. In contrast, a checkpoint defective allele of RAD53 with mutations in both FHA domains, binds origins and growth of this mutant is unaffected by histone dosage. Based on these observations, we hypothesize that the origin binding and the histone degradation activities of Rad53 are central to its function in DNA replication and are independent of its checkpoint functions. We propose a model in which Rad53 acts as a “nucleosome buffer”, interacting with origins of replication to prevent the binding of excess histones to origin DNA and to maintain proper chromatin configuration.Key words: DNA replication, Rad53, histones, checkpoint, origins of replication     

Temperature Compensation of Circadian Period Length in Clock Mutants of Neurospora crassa

Temperature compensation of circadian period length in 12 clock mutants of Neurospora crassa has been examined at temperatures between 16 and 34°C. In the wild-type strain, below 30°C (the “breakpoint” temperature), the clock is well-compensated (Q₁₀ = 1), while above 30°C, the clock is less well-compensated (Q₁₀ = 1.3). For mutants at the frq locus, mutations that shorten the circadian period length (frq-1, frq-2, frq-4, and frq-6) do not alter this temperature compensation response. In long period frq mutants (frq-3, frq-7, frq-8), however, the breakpoint temperature is lowered, and the longer the period length of the mutants the lower the breakpoint temperature. Long period mutants at other loci exhibit other types of alterations in temperature compensation—e.g. chr is well-compensated even above 30°C, while prd-3 has a Q₁₀ significantly less than 1 below 30°C. Prd-4, a short period mutant, has several breakpoint temperatures. Among four double mutants examined, the only unusual interaction between the individual mutations occurred with chr prd, which had an unusually low Q₁₀ value of 0.86 below 27°C. There was no correlation between circadian period length and growth rate. These strains should be useful tools to test models for the temperature compensation mechanism.     

A Major Role of the RecFOR Pathway in DNA Double-Strand-Break Repair through ESDSA in Deinococcus radiodurans

In Deinococcus radiodurans, the extreme resistance to DNA–shattering treatments such as ionizing radiation or desiccation is correlated with its ability to reconstruct a functional genome from hundreds of chromosomal fragments. The rapid reconstitution of an intact genome is thought to occur through an extended synthesis-dependent strand annealing process (ESDSA) followed by DNA recombination. Here, we investigated the role of key components of the RecF pathway in ESDSA in this organism naturally devoid of RecB and RecC proteins. We demonstrate that inactivation of RecJ exonuclease results in cell lethality, indicating that this protein plays a key role in genome maintenance. Cells devoid of RecF, RecO, or RecR proteins also display greatly impaired growth and an important lethal sectoring as bacteria devoid of RecA protein. Other aspects of the phenotype of recFOR knock-out mutants paralleled that of a ΔrecA mutant: ΔrecFOR mutants are extremely radiosensitive and show a slow assembly of radiation-induced chromosomal fragments, not accompanied by DNA synthesis, and reduced DNA degradation. Cells devoid of RecQ, the major helicase implicated in repair through the RecF pathway in E. coli, are resistant to γ-irradiation and have a wild-type DNA repair capacity as also shown for cells devoid of the RecD helicase; in contrast, ΔuvrD mutants show a markedly decreased radioresistance, an increased latent period in the kinetics of DNA double-strand-break repair, and a slow rate of fragment assembly correlated with a slow rate of DNA synthesis. Combining RecQ or RecD deficiency with UvrD deficiency did not significantly accentuate the phenotype of ΔuvrD mutants. In conclusion, RecFOR proteins are essential for DNA double-strand-break repair through ESDSA whereas RecJ protein is essential for cell viability and UvrD helicase might be involved in the processing of double stranded DNA ends and/or in the DNA synthesis step of ESDSA.     

Staphylococcus aureus protein SAUGI acts as a uracil-DNA glycosylase inhibitor

DNA mimic proteins are unique factors that control the DNA binding activity of target proteins by directly occupying their DNA binding sites. The extremely divergent amino acid sequences of the DNA mimics make these proteins hard to predict, and although they are likely to be ubiquitous, to date, only a few have been reported and functionally analyzed. Here we used a bioinformatic approach to look for potential DNA mimic proteins among previously reported protein structures. From ∼14 candidates, we selected the Staphylococcus conserved hypothetical protein SSP0047, and used proteomic and structural approaches to show that it is a novel DNA mimic protein. In Staphylococcus aureus, we found that this protein acts as a uracil-DNA glycosylase inhibitor, and therefore named it S. aureus uracil-DNA glycosylase inhibitor (SAUGI). We also determined and analyzed the complex structure of SAUGI and S. aureus uracil-DNA glycosylase (SAUDG). Subsequent BIAcore studies further showed that SAUGI has a high binding affinity to both S. aureus and human UDG. The two uracil-DNA glycosylase inhibitors (UGI and p56) previously known to science were both found in Bacillus phages, and this is the first report of a bacterial DNA mimic that may regulate SAUDG’s functional roles in DNA repair and host defense.