An improved assay for DNA ligase reveals temperature-sensitive activity in cdc9 mutants of Saccharomyces cerevisiae

A novel interaction between DNA ligase III and DNA polymerase gamma plays an essential role in mitochondrial DNA stability

The data in the present study show that DNA polymerase gamma and DNA ligase III interact in mitochondrial protein extracts from cultured HT1080 cells. An interaction was also observed between the two recombinant proteins in vitro. Expression of catalytically inert versions of DNA ligase III that bind DNA polymerase gamma was associated with reduced mitochondrial DNA copy number and integrity. In contrast, overexpression of wild-type DNA ligase III had no effect on mitochondrial DNA copy number or integrity. Experiments revealed that wild-type DNA ligase III facilitates the interaction of DNA polymerase gamma with a nicked DNA substrate in vitro, and that the zinc finger domain of DNA ligase III is required for this activity. Mitochondrial protein extracts prepared from cells overexpressing a DNA ligase III protein that lacked the zinc finger domain had reduced base excision repair activity compared with extracts from cells overexpressing the wild-type protein. These data support the interpretation that the interaction of DNA ligase III and DNA polymerase gamma is required for proper maintenance of the mammalian mitochondrial genome.

A non-isotopic method for the determination of activity of the thermostable NAD-dependent DNA ligase from Thermus thermophilus HB8

A simple and accurate method for determination of enzymatic activity of the NAD-dependent DNA ligase of Thermus thermophilus HB8 has been developed that requires no radiolabeled substrates. lambda-DNA digested with BstEII provides two substrate DNA molecules (fragments 1 and 4) containing 12 base pair cohesive ends that are stably annealed at the assay temperature of 45 degrees C. One cohesive end unit is defined as the amount of enzyme required to achieve 50% ligation of fragment 1 in 15 min at 45 degrees C. Percent ligation is determined by analysis of reaction products, produced in reactions containing serial dilutions of enzyme, separated by agarose gel electrophoresis and photographed using a digital imaging device. Imaging software quantifies the amounts of fragment 1 and non-substrate fragment 7 present in the each lane (reaction). The latter is used to normalize the amount of fragment 1. This normalization process corrects for variations in sample loading, electrophoretic artifacts, and optical distortion of the gel image. A negative control containing no enzyme allows calculation of percent substrate ligated into product. Unit activity is then calculated from a dose-response curve in which percent of fragment 1 ligated is plotted against the log(10) of the enzyme dilution factor.

A novel ADP-dependent DNA ligase from Aeropyrum pernix K1

A gene encoding a putative ATP-dependent DNA ligase from the aerobic hyperthermophilic archaeon Aeropyrum pernix K1 was cloned and the biochemical characteristics of the resulting recombinant protein were examined. The gene (accession no. APE1094) from A. pernix encoding a 69-kDa protein showed a 39-61% identity with other ATP-dependent DNA ligases from the archaea. Normally DNA ligase is activated by NAD(+) or ATP. There has been no report about the other activators for DNA ligase. The recombinant ligase was a monomeric protein and catalyzed strand joining on a singly nicked DNA substrate in the presence of ADP and a divalent cation (Mg(2+), Mn(2+), Ca(2+) and Co(2+)) at high temperature. The optimum temperature and pH for nick-closing activity were above 70 degrees C and 7.5 degrees C, respectively. The ligase remained stable for 60 min of treatment at 100 degrees C, and the half-life was about 25 min at 110 degrees C. This is the first report of a novel hyperthermostable DNA ligase that can utilize ADP to activate the enzyme.

NuA4 subunit Yng2 function in intra-S-phase DNA damage response

While regulated transcription requires acetylation of histone N-terminal tails to promote an open chromatin conformation, a similar role for histone acetylation in DNA replication and/or repair remains to be established. Cells lacking the NuA4 subunit Yng2 are viable but critically deficient for genome-wide nucleosomal histone H4 acetylation. We found that yng2 mutants are specifically sensitized to DNA damage in S phase induced by cdc8 or cdc9 mutations, hydroxyurea, camptothecin, or methylmethane sulfonate (MMS). In yng2, MMS treatment causes a persistent Mec1-dependent intra-S-phase checkpoint delay characterized by slow DNA repair. Restoring H4 acetylation with the histone deacetylase inhibitor trichostatin A promotes checkpoint recovery. In turn, mutants lacking the histone H3-specific acetyltransferase GCN5 are similarly sensitive to intra-S-phase DNA damage. The inviability of gcn5 yng2 double mutants suggests overlapping roles for H3 and H4 acetylation in DNA replication and repair. Paradoxically, haploid yng2 mutants do not tolerate mutations in genes important for nonhomologous end joining repair yet remain proficient for homologous recombination. Our results implicate nucleosomal histone acetylation in maintaining genomic integrity during chromosomal replication.

Cloning and functional characterization of an NAD(+)-dependent DNA ligase from Staphylococcus aureus

A Staphylococcus aureus mutant conditionally defective in DNA ligase was identified by isolation of complementing plasmid clones that encode the S. aureus ligA gene. Orthologues of the putative S. aureus NAD(+)-dependent DNA ligase could be identified in the genomes of Bacillus stearothermophilus and other gram-positive bacteria and confirmed the presence of four conserved amino acid motifs, including motif I, KXDG with lysine 112, which is believed to be the proposed site of adenylation. DNA sequence comparison of the ligA genes from wild type and temperature-sensitive S. aureus strain NT64 identified a single base alteration that is predicted to result in the amino acid substitution E46G. The S. aureus ligA gene was cloned and overexpressed in Escherichia coli, and the enzyme was purified to near homogeneity. NAD(+)-dependent DNA ligase activity was demonstrated with the purified enzyme by measuring ligation of (32)P-labeled 30-mer and 29-mer oligonucleotides annealed to a complementary strand of DNA. Limited proteolysis of purified S. aureus DNA ligase by thermolysin produced products with apparent molecular masses of 40, 22, and 21 kDa. The fragments were purified and characterized by N-terminal sequencing and mass analysis. The N-terminal fragment (40 kDa) was found to be fully adenylated. A fragment from residues 1 to 315 was expressed as a His-tagged fusion in E. coli and purified for functional analysis. Following deadenylation with nicotinamide mononucleotide, the purified fragment could self-adenylate but lacked detectable DNA binding activity. The 21- and 22-kDa C-terminal fragments, which lacked the last 76 amino acids of the DNA ligase, had no adenylation activity or DNA binding activity. The intact 30-kDa C terminus of the S. aureus LigA protein expressed in E. coli did demonstrate DNA binding activity. These observations suggest that, as in the case with the NAD(+)-dependent DNA ligase from B. stearothermophilus, two independent functional domains exist in S. aureus DNA ligase, consisting of separate adenylation and DNA binding activities. They also demonstrate a role for the extreme C terminus of the ligase in DNA binding. As there is much evidence to suggest that DNA ligase is essential for bacterial survival, its discovery in the important human pathogen S. aureus indicates its potential as a broad-spectrum antibacterial target for the identification of novel antibiotics.

Mitochondrial DNA ligase function in Saccharomyces cerevisiae

The Saccharomyces cerevisiae CDC9 gene encodes a DNA ligase protein that is targeted to both the nucleus and the mitochondria. While nuclear Cdc9p is known to play an essential role in nuclear DNA replication and repair, its role in mitochondrial DNA dynamics has not been defined. It is also unclear whether additional DNA ligase proteins are present in yeast mitochondria. To address these issues, mitochondrial DNA ligase function in S.cerevisiae was analyzed. Biochemical analysis of mitochondrial protein extracts supported the conclusion that Cdc9p was the sole DNA ligase protein present in this organelle. Inactivation of mitochondrial Cdc9p function led to a rapid decline in cellular mitochondrial DNA content in both dividing and stationary yeast cultures. In contrast, there was no apparent defect in mitochondrial DNA dynamics in a yeast strain deficient in Dnl4p (Deltadnl4). The Escherichia coli ECO:RI endonuclease was targeted to yeast mitochondria. Transient expression of this recombinant ECO:RI endonuclease led to the formation of mitochondrial DNA double-strand breaks. While wild-type and Deltadnl4 yeast were able to rapidly recover from this mitochondrial DNA damage, clones deficient in mitochondrial Cdc9p were not. These results support the conclusion that yeast rely upon a single DNA ligase, Cdc9p, to carry out mitochondrial DNA replication and recovery from both spontaneous and induced mitochondrial DNA damage.

A DNA ligase from a hyperthermophilic archaeon with unique cofactor specificity

A gene encoding DNA ligase (lig(Tk)) from a hyperthermophilic archaeon, Thermococcus kodakaraensis KOD1, has been cloned and sequenced, and its protein product has been characterized. lig(Tk) consists of 1,686 bp, corresponding to a polypeptide of 562 amino acids with a predicted molecular mass of 64,079 Da. Sequence comparison with previously reported DNA ligases and the presence of conserved motifs suggested that Lig(Tk) was an ATP-dependent DNA ligase. Phylogenetic analysis indicated that Lig(Tk) was closely related to the ATP-dependent DNA ligase from Methanobacterium thermoautotrophicum DeltaH, a moderate thermophilic archaeon, along with putative DNA ligases from Euryarchaeota and Crenarchaeota. We expressed lig(Tk) in Escherichia coli and purified the recombinant protein. Recombinant Lig(Tk) was monomeric, as is the case for other DNA ligases. The protein displayed DNA ligase activity in the presence of ATP and Mg(2+). The optimum pH of Lig(Tk) was 8.0, the optimum concentration of Mg(2+), which was indispensable for the enzyme activity, was 14 to 18 mM, and the optimum concentration of K(+) was 10 to 30 mM. Lig(Tk) did not display single-stranded DNA ligase activity. At enzyme concentrations of 200 nM, we observed significant DNA ligase activity even at 100 degrees C. Unexpectedly, Lig(Tk) displayed a relatively small, but significant, DNA ligase activity when NAD(+) was added as the cofactor. Treatment of NAD(+) with hexokinase did not affect this activity, excluding the possibility of contaminant ATP in the NAD(+) solution. This unique cofactor specificity was also supported by the observation of adenylation of Lig(Tk) with NAD(+). This is the first biochemical study of a DNA ligase from a hyperthermophilic archaeon.

Mitochondrial DNA ligase III function is independent of Xrcc1

Hamster EM9 cells, which lack Xrcc1 protein, have reduced levels of DNA ligase III and are defective in nuclear base excision repair. The Xrcc1 protein stabilizes DNA ligase III and may even play a direct role in catalyzing base excision repair. Since DNA ligase III is also thought to function in mitochondrial base excision repair, it seemed likely that mitochondrial DNA ligase III function would also be dependent upon Xrcc1. However, several lines of evidence indicate that this is not the case. First, western blot analysis failed to detect Xrcc1 protein in mitochondrial extracts. Second, DNA ligase III levels present in mitochondrial protein extracts from EM9 cells were indistinguishable from those seen in similar extracts from wild-type (AA8) cells. Third, the mitochondrial DNA content of both cell lines was identical. Fourth, EM9 cells displayed no defect in their ability to repair spontaneous mitochondrial DNA damage. Fifth, while EM9 cells were far more sensitive to the cytotoxic effects of ionizing radiation due to a defect in nuclear DNA repair, there was no apparent difference in the ability of EM9 and AA8 cells to restore their mitochondrial DNA to pre-irradiation levels. Thus, mitochondrial DNA ligase III function is independent of the Xrcc1 protein.

The yeast RAD7 and RAD16 genes are required for postincision events during nucleotide excision repair. In vitro and in vivo studies with rad7 and rad16 mutants and purification of a Rad7/Rad16-containing protein complex

In eukaryotes, nucleotide excision repair (NER) is a complex reaction requiring multiple proteins. In the yeast Saccharomyces cerevisiae, two of these proteins, Rad7 and Rad16, are specifically involved in the removal of lesions from transcriptionally silent regions of the genome in vivo. Extracts prepared from rad7 or rad16 mutant cells are deficient, but not totally defective, in both oligonucleotide excision and repair synthesis of damaged plasmid DNA. We show that these extracts are, however, fully proficient in the incision step of the NER reaction in vitro. Furthermore, using a cdc9 mutant to trap incision intermediates, we demonstrate that rad7 and rad16 mutants are proficient in NER-dependent DNA incision in vivo. A purified protein complex containing both Rad7 and Rad16 proteins complements the oligonucleotide excision and repair synthesis defects in rad7 and rad16 mutant extracts. We conclude that the products of the RAD7 and RAD16 genes are involved in a postincision event(s) during NER in yeast.

Identification of essential residues in Thermus thermophilus DNA ligase

DNA ligases play a pivotal role in DNA replication, repair and recombination. Reactions catalyzed by DNA ligases consist of three steps: adenylation of the ligase in the presence of ATP or NAD+, transferring the adenylate moiety to the 5'-phosphate of the nicked DNA substrate (deadenylation) and sealing the nick through the formation of a phosphodiester bond. Thermus thermophilus HB8 DNA ligase (Tth DNA ligase) differs from mesophilic ATP-dependent DNA ligases in three ways: (i) it is NAD+ dependent; (ii) its optimal temperature is 65 instead of 37 degrees C; (iii) it has higher fidelity than T4 DNA ligase. In order to understand the structural basis underlying the reaction mechanism of Tth DNA ligase, we performed site-directed mutagenesis studies on nine selected amino acid residues that are highly conserved in bacterial DNA ligases. Examination of these site-specific mutants revealed that: residue K118 plays an essential role in the adenylation step; residue D120 may facilitate the deadenylation step; residues G339 and C433 may be involved in formation of the phosphodiester bond. This evidence indicates that a previously identified KXDG motif for adenylation of eukaryotic DNA ligases [Tomkinson, A.E., Totty, N.F., Ginsburg, M. and Lindahl, T. (1991) Proc. Natl. Acad. Sci. USA, 88, 400-404] is also the adenylation site for NAD+-dependent bacterial DNA ligases. In a companion paper, we demonstrate that mutations at a different Lys residue, K294, may modulate the fidelity of Tth DNA ligase.

Interactions among mutations affecting spontaneous mutation, mitotic recombination, and DNA repair in yeast

The mutant alleles mms9-1, mms13-1, or mms21-1 of Saccharomyces cerevisiae confer pleiotropic effects, including sensitivity to the alkylating agent methyl methanesulfonate, elevations in spontaneous mutation and mitotic recombination, defects in meiosis, and cross-sensitivity to radiation. We constructed double-mutant strains containing an mms mutation and a defect in either excision repair, mutagenic repair, or recombinational repair and measured the levels of spontaneous mutation and mitotic recombination. Double mutants lacking excision repair show elevations in spontaneous mutation but with predominantly unchanged levels of mitotic recombination. RAD52 function was required for the expression of the hyper-recombination phenotype of the mms9-1, mms13-1, and mms21-1 alleles; double mutants displayed the very low recombination levels characteristic of rad52 mutants. Phenotypes of double mutants containing one of the mms alleles and either of the hyper-recombination/mutator rad6-1 or rad3-102 alleles suggest that the mutagenic lesions in mms strains may not be identical to the recombinogenic lesions.

Molecular characterisation of a DNA ligase gene of the extremely thermophilic archaeon Desulfurolobus ambivalens shows close phylogenetic relationship to eukaryotic ligases

A 3382 bp fragment containing a gene for a DNA ligase from the extremely thermophilic, acidophilic, and facultatively anaerobic archaeon (archaebacterium) Desulfurolobus ambivalens was cloned and sequenced. The deduced amino acid sequence (600 amino acids, 67619 molecular weight) showed 30-34% sequence identity with the ATP-dependent eucaryal (eukaryotic) DNA ligases of Schizosaccharomyces pombe, Saccharomyces cerevisiae, the human DNA ligase I, and with the Vaccinia DNA ligase. Distant similarity to the DNA ligases from the bacteriophages T3, T4, T6, T7 and the African swine fever virus was found, whereas no similarities were detectable to the NAD-dependent DNA ligases from the bacteria (eubacteria) Escherichia coli and Thermus thermophilus, to the ATP-dependent RNA-ligase of bacteriophage T4, and to the tRNA-Ligase from S.cerevisiae. A detailed comparison of the phylogenetic relationship of the amino acid sequences of all known DNA and RNA ligases is presented including a complete alignment of the ATP-dependent DNA ligases. The in vivo-transcription initiation and termination sites of the D.ambivalens gene were mapped. The calculated transcript length was 1904-1911 nt.

Genetic and molecular analysis of DNA43 and DNA52: two new cell-cycle genes in Saccharomyces cerevisiae

Two Saccharomyces cerevisiae genes previously unknown to be required for DNA synthesis have been identified by screening a collection of temperature-sensitive mutants. The effects of mutations in DNA43 and DNA52 on the rate of S phase DNA synthesis were detected by monitoring DNA synthesis in synchronous populations that were obtained by isopycnic density centrifugation. dna43-1 and dna52-1 cells undergo cell-cycle arrest at the restrictive temperature (37 degrees C), exhibiting a large-budded terminal phenotype; the nuclei of arrested cells are located at the neck of the bud and have failed to undergo DNA replication. These phenotypes suggest that DNA43 and DNA52 are required for entry into or completion of S phase. DNA43 and DNA52 were cloned by their abilities to suppress the temperature-sensitive lethal phenotypes of dna43-1 and dna52-1 cells, respectively. DNA sequence analysis suggested that DNA43 and DNA52 encode proteins of 59.6 and 80.6 kDa, respectively. Both DNA43 and DNA52 are essential for viability and genetic mapping experiments indicate that they represent previously unidentified genes: DNA43 is located on chromosome IX, 32 cM distal from his5 and DNA52 is located on chromosome IV, 0.9 cM from cdc34.

Cloning, nucleotide sequence, and engineered expression of Thermus thermophilus DNA ligase, a homolog of Escherichia coli DNA ligase

We have cloned and sequenced the gene for DNA ligase from Thermus thermophilus. A comparison of this sequence and those of other ligases reveals significant homology only with that of Escherichia coli. The overall amino acid composition of the thermophilic ligase and the pattern of amino acid substitutions between the two proteins are consistent with compositional biases in other thermophilic enzymes. We have engineered the expression of the T. thermophilus gene in Escherichia coli, and we show that E. coli proteins may be substantially removed from the thermostable ligase by a simple heat precipitation step.

Coordination of expression of DNA synthesis genes in budding yeast by a cell-cycle regulated trans factor

All of the DNA synthesis genes of budding yeast examined so far are periodically expressed and hence under cell-cycle control (Table 1). Expression occurs near the G1/S phase boundary and the genes seem to be coordinately regulated (reviewed in ref. 4). The upstream promoter sequences of these genes have only a hexamer element, ACGCGT (an MluI restriction site), in common. Here we show that this hexamer is able to impart periodic expression to a heterologous gene and, significantly, this expression occurs coincidentally with that of CDC9, one of the DNA synthesis genes (Table 1). We have also identified a protein that binds specifically to these sequences in a similar periodic manner. These ACGCGT sequences and the transcription factor that binds to them therefore seem to be the elements controlling both the periodic expression and coordinate regulation of the DNA synthesis genes.

To shape a cell: an inquiry into the causes of morphogenesis of microorganisms

We recognize organisms first and foremost by their forms, but how they grow and shape themselves still largely passes understanding. The objective of this article is to survey what has been learned of morphogenesis of walled eucaryotic microorganisms as a set of problems in cellular heredity, biochemistry, physiology, and organization. Despite the diversity of microbial forms and habits, some common principles can be discerned. (i) That the form of each organism represents the expression of a genetic program is almost universally taken for granted. However, reflection on the findings with morphologically aberrant mutants suggests that the metaphor of a genetic program is misleading. Cellular form is generated by a web of interacting chemical and physical processes, whose every strand is woven of multiple gene products. The relationship between genes and form is indirect and cumulative; therefore, morphogenesis must be addressed as a problem not of molecular genetics but of cellular physiology. (ii) The shape of walled cells is determined by the manner in which the wall is laid down during growth and development. Turgor pressure commonly, perhaps always, supplies the driving force for surface enlargement. Cells yield to this scalar force by localized, controlled wall synthesis; their forms represent variations on the theme of local compliance with global force. (iii) Growth and division in bacteria display most immediately the interplay of hydrostatic pressure, localized wall synthesis, and structural constraints. Koch's surface stress theory provides a comprehensive and quantitative framework for understanding bacterial shapes. (iv) In the larger and more versatile eucaryotic cells, expansion is mediated by the secretion of vesicles. Secretion and ancillary processes, such as cytoplasmic transport, are spatially organized on the micrometer scale. The diversity of vectorial physiology and of the forms it generates is illustrated by examples: apical growth of fungal hyphae, bud formation in yeasts, germination of fucoid zygotes, and development of cells of Nitella, Closterium, and other unicellular algae. (v) Unicellular organisms, no less than embryos, have a remarkable capacity to impose spatial order upon themselves with or without the help of directional cues. Self-organization is reviewed here from two perspectives: the theoretical exploration of morphogens, gradients, and fields, and experimental study of polarization in Fucus cells, extension of hyphal tips, and pattern formation in ciliates. Here is the heart of the matter, yet self-organization remains nearly as mysterious as it was a century ago, a subject in search of a paradigm.

Human DNA ligase I cDNA: cloning and functional expression in Saccharomyces cerevisiae

Human cDNA clones encoding the major DNA ligase activity in proliferating cells, DNA ligase I, were isolated by two independent methods. In one approach, a human cDNA library was screened by hybridization with oligonucleotides deduced from partial amino acid sequence of purified bovine DNA ligase I. In an alternative approach, a human cDNA library was screened for functional expression of a polypeptide able to complement a cdc9 temperature-sensitive DNA ligase mutant of Saccharomyces cerevisiae. The sequence of an apparently full-length cDNA encodes a 102-kDa protein, indistinguishable in size from authentic human DNA ligase I. The deduced amino acid sequence of the human DNA ligase I cDNA is 40% homologous to the smaller DNA ligases of S. cerevisiae and Schizosaccharomyces pombe, homology being confined to the carboxyl-terminal regions of the respective proteins. Hybridization between the cloned sequences and mRNA and genomic DNA indicates that the human enzyme is transcribed from a single-copy gene on chromosome 19.

Eukaryotic DNA ligases

Recent studies on eukaryotic DNA ligases are briefly reviewed. The two distinguishable enzymes from mammalian cells, DNA ligase I and DNA ligase II, have been purified to homogeneity and characterized biochemically. Two distinct DNA ligases have also been identified in Drosophila melanogaster embryos. The genes encoding DNA ligases from Schizosaccharomyces pombe, Saccharomyces cerevisiae and vaccinia virus have been cloned and sequenced. These 3 proteins exhibit about 30% amino acid sequence identity; the 2 yeast enzymes share 53% amino acid sequence identity or conserved changes. Altered DNA ligase I activity has been found in cell lines from patients with Bloom's syndrome, although a causal link between the enzyme deficiency and the disease has not yet been proven.

Effects of DNA-binding drugs on T4 DNA ligase

A number of DNA intercalating and externally binding drugs have been found to inhibit nick sealing, cohesive and blunt end ligation, AMP-dependent DNA topoisomerization and EDTA-induced DNA nicking mediated by bacteriophage T4 DNA ligase. The inhibition seems to arise from drug-substrate interaction so that formation of active DNA-Mg2(+)-AMP-enzyme complex is impaired while assembled and active complexes are not disturbed by drug binding to the substrate.

Degradation of DNA and structure-activity relationship between bleomycins A2 and B2 in the absence of DNA repair

The contribution of DNA repair to the net number of DNA breaks produced during chemical degradation of DNA was determined by using temperature-sensitive mutant cells deficient in ATP-dependent DNA ligase [poly(deoxyribonucleotide):poly(deoxyribonucleotide) ligase, EC 6.5.1.1]. In a very sensitive assay for determining lesions introduced into Saccharomyces cerevisiae DNAs, 2-14C- and 6-3H-prelabeled DNAs from ligase-proficient and ligase-deficient cells were sedimented together through precalibrated, isokinetic alkaline sucrose gradients. DNA ligation was slower after chemical degradation of DNA by bleomycin than after gamma irradiation. DNA breaks increased approximately linearly with drug concentrations, and were approximately equivalent for ligase-proficient and ligase-deficient cells. These results were unexpected because ligase-deficient, but not ligase-proficient, cells lacked the capacity to eliminate DNA breaks produced by bleomycin. The results indicated that DNA repair did not occur during the chemical degradation of DNA under the experimental conditions. Bleomycin B2 produced considerably more DNA breaks than bleomycin A2 over a range of concentrations in ligase-proficient cells, which tolerated higher numbers of DNA breaks in general than ligase-deficient cells. The chemical analogues are structurally identical except for their cationic C-terminal amine. The actual number of DNA breaks produced by bleomycin A2 or bleomycin B2, and not the concentration of bleomycin A2 or bleomycin B2 per se, determined the amount of cell killing. DNA repair is critical in quantitating DNA breaks produced by chemicals, but was ruled out as a factor in the higher DNA breakage by bleomycin B2 than bleomycin A2.

Checkpoints: controls that ensure the order of cell cycle events

The events of the cell cycle of most organisms are ordered into dependent pathways in which the initiation of late events is dependent on the completion of early events. In eukaryotes, for example, mitosis is dependent on the completion of DNA synthesis. Some dependencies can be relieved by mutation (mitosis may then occur before completion of DNA synthesis), suggesting that the dependency is due to a control mechanism and not an intrinsic feature of the events themselves. Control mechanisms enforcing dependency in the cell cycle are here called checkpoints. Elimination of checkpoints may result in cell death, infidelity in the distribution of chromosomes or other organelles, or increased susceptibility to environmental perturbations such as DNA damaging agents. It appears that some checkpoints are eliminated during the early embryonic development of some organisms; this fact may pose special problems for the fidelity of embryonic cell division.

Mapping and characterizing a new DNA replication mutant in Saccharomyces cerevisiae

A detailed characterization of the mak1-3 mutation of Saccharomyces cerevisiae has been made possible by modifying its genetic background. The mak1-3 mutation, which confers temperature sensitivity for growth, was originally identified as one of four mak1 mutations (Wickner and Leibowitz, 1976). Mak1-1, 1-2 and 1-4 mutants are deficient in DNA topoisomerase I activity and thus have been renamed 'top1' (Thrash et al., 1984). Studies presented here show that the map position of MAK1-3 on chromosome XVI distinguishes it from TOP1 which maps on chromosome XV (Wickner and Leibowitz, 1976). An investigation of in vivo macromolecular synthesis in the mak1-3 mutant shows that it is deficient in DNA replication at the restrictive temperature. Experiments in which DNA synthesis was measured in synchronized cell populations indicate that the mak1-3 mutant is deficient in the initiation step of DNA synthesis. Furthermore, crude extracts from the mak1-3 mutant cells support temperature-sensitive in vitro DNA synthesis on yeast chromosomal DNA replication origin containing plasmid pARS1, suggesting that the MAK1 gene product is directly required for in vitro DNA replication. The conclusion that mak1-3 is a newly identified DNA replication mutation is based on the observations that it (1) complements all DNA synthesis mutants examined, (2) maps to a previously undetected chromosomal location and (3) has a distinct terminal morphology. In light of these distinctions and of the role mak1-3 plays in DNA replication, it has been renamed 'dna1'.

Bleomycin-induced DNA repair by Saccharomyces cerevisiae ATP-dependent polydeoxyribonucleotide ligase

In contrast to ligase-deficient (cdc9) Saccharomyces cerevisiae, which did not rejoin bleomycin-induced DNA breaks, ligase-proficient (CDC9) yeast cells eliminated approximately 90% of DNA breaks within 90 to 120 min after treatment. Experimental conditions restricted enzymatic removal of the unusual 3'-phosphoglycolate termini in DNA cleaved by bleomycin and involved doses producing equivalent numbers of DNA breaks or doses producing equivalent killing.

AMP-dependent DNA relaxation catalyzed by DNA ligase occurs by a nicking-closing mechanism

In the presence of AMP and Mg2+, a covalently closed duplex DNA containing negative superhelical turns was treated with DNA ligase isolated from bacteriophage T4-infected E. coli. This resulted in the gradual and not sudden loss of superhelical turns as for example in the case of type I DNA topoisomerase. All DNA products remain covalently closed. Since T4 enzyme-mediated DNA relaxation is inhibited by both pyrophosphate and by ATP this suggests that DNA relaxing and DNA joining activities probably coincide. EDTA addition in the presence of a large excess of enzyme, induces the formation of nicked DNA products while protein denaturing treatments are not very effective. Our observations might suggest an involvement of the relaxing activity of DNA ligase during the ligation process.

DNA ligase I deficiency in Bloom's syndrome

Certain rare human diseases with autosomal recessive mode of inheritance are associated with a greatly increased cancer frequency which may reflect specific defects in DNA repair or replication. These disorders include xeroderma pigmentosum, ataxia-telangiectasia, Fanconi's anaemia and Bloom's syndrome. Cells from individuals with Bloom's syndrome usually grow slowly in culture and exhibit increased chromosomal breakage and rearrangement, an elevated frequency of sister chromatid exchanges, retarded rates of progression of DNA replication forks, delayed conversion of replication intermediates to high-molecular-weight DNA, and slightly increased sensitivity to DNA-damaging agents. Several of these features are also characteristic of Escherichia coli and yeast mutants with a defective DNA ligase. In this investigation we show that one of the two DNA ligases of human cells, ligase I, is defective in a representative lymphoid cell line of Bloom's syndrome origin.

Induction of yeast DNA ligase genes in exponential and stationary phase cultures in response to DNA damaging agents

UV-irradiation of stationary phase cells of Saccharomyces cerevisiae and Schizosaccharomyces pombe leads to a 9-fold and 90-fold increase in transcript levels from the respective DNA ligase genes CDC9 and CDC17, whereas exponential cells show only 3-fold and 2-fold increases. Induction of CDC9 after MMS treatment and gamma-irradiation was also observed by using a CDC9-lacZ translational fusion and assaying for beta-galactosidase. Surprisingly, irradiation of S. cerevisiae induces only a 50% increase in DNA ligase itself, probably reflecting the extremely high in vivo stability of the enzyme. The UV-induction of ligase may be part of a "fail-safe" mechanism which, together with the enzyme stability, ensures adequate supplies of this essential enzyme.

Cloning and characterization of the Schizosaccharomyces pombe DNA ligase gene CDC17

The Schizosaccharomyces pombe CDC17 gene has been cloned by complementation of the cdc17 mutant coding for temperature-sensitive DNA ligase. An allele-specific suppressor active only in the presence of a high osmotic pressure was also isolated. The cloned CDC17 gene failed to complement the analogous DNA ligase mutation, cdc9, in Saccharomyces cerevisiae, although the reverse complementation was successful [Barker and Johnston, Eur. J. Biochem. 134 (1983) 315-319]. The CDC17 gene specifies a 2.8-kb transcript.

The nucleotide sequence of the DNA ligase gene (CDC9) from Saccharomyces cerevisiae: a gene which is cell-cycle regulated and induced in response to DNA damage

The CDC9 gene of Saccharomyces cerevisiae encodes a DNA ligase, and we have determined the nucleotide sequence of a 3.85 kb fragment of DNA which encompasses the convergently transcribed CDC9 and CDC36 genes. S1 nuclease mapping has revealed a major 5' end for the CDC9 mRNA, and one major and one minor site for 3' polyadenylation. These two sites lie within the C-terminal coding region of the CDC36 gene, implying that these two genes are transcribed from overlapping sequences. An interesting structural feature of the CDC9 gene is a series of 6 hexanucleotide repeats (ATGATT) which occur within the 650 bp immediately upstream from the site of transcription initiation. These repeat elements may be implicated in the cell division cycle regulated expression of CDC9. Comparison of the predicted amino acid sequence of the yeast DNA ligase (Mr 84,806) with the sequences of the T4 and T7 bacteriophage DNA ligases reveals little similarity except for a stretch of approximately 45 amino acids, comprising 3 short homologous segments. This region may represent an ATP-binding domain common to polynucleotide ligases.