Characterization of the early synthesized DNA in germinating Triticum aestivum embryos

A radioactive DNA preparation was isolated from the post-mitochondrial supernatant fraction of thymidine-[¹⁴C] fed wheat embryos. The isolated sDNA preparation was similar to cytoplasmic non-mitochondrial DNA of other eukaryotic cells. The buoyant density and frequency of pyrimidine nucleotide clusters found for the sDNA were, essentially, the same as those found for the nuclear DNA. In contrast to DNA that can be leaked from nuclei or other DNA-containing organelles, the sDNA is firmly bound to a protein component. At an early germination stage (6–12 hr), the sDNA is the only newly-synthesized DNA fraction that can be isolated from the embryo homogenate. Considerable synthesis of nuclear and organellar DNA starts 18 hr after the beginning of germination, just prior to the first maximum of the cell divisions. It is concluded that wheat embryo cells contain cytoplasmic non-mitochondrial DNA and are able to resume its synthesis at an early germination stage, prior to the first post-dormant round of nuclear DNA replication.     

Simultaneous Transmission of Three Stable Genotypes in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

REPLICATION of the double stranded DNA genomes of bacteria takes place by a semi-conservative mechanism¹, but although autoradiographic studies have confirmed that eukaryotic DNA is replicated semi-conservatively^2,3, our lack of knowledge about the structure of the eukaryotic chromosome means that this finding does not prove that the conserved unit is a single polynucleotide strand of DNA. Indirect information supporting the hypothesis that the conserved unit consisted of a single polydeoxyribonucleotide strand has accumulated from transmission studies in chemical mutation experiments. Two phenotypic classes of mutants are readily distinguishable as a result of chemical mutagenesis; mosaic (fractional) mutants and complete (whole body) mutants. Mutation studies assume that the treated gametes contain one DNA polymer per chromosome and that the polymer is made up of two complementary nucleotide strands. With chemical mutagens (excluding acridine dyes) it is probable that only one of the two complementary strands would be chemically altered⁴. Following fertilization, DNA replication occurs, fixing both the mutational event and its complementary wild type site. The zygote will possess a mutation which will be phenotypically expressed in the adult fly depending on the early morphogenic movements in the fly's development. Assuming that only one strand is altered, the two cell lines would contain a mutant genotype and a wild type genotype. Two genotypically mutant cell lines would arise if two mutational events occur in the opposing polydeoxyribonucleotide strands within the same genie region. In this case, there would be no genotypically wild type cells in the embryo.     

Synthesis of small polynucleotide chains in thymine-depleted bacteria

Bacteria that are depleted of intracellular thymidine nucleotide pools incorporate [³H]thymine at full specific activity, allowing the detection of early intermediates in DNA replication. A short pulse of [³H]thymine is incorporated almost exclusively into very small DNA chains which, during further incorporation of thymine, are converted into larger chains and high molecular weight DNA. The synthesis of these small DNA chains depends on the products of dna genes B, E and G. Analysis of the DNA by gel filtration on Sepharose 2B revealed an abundance of extremely short DNA chains while the frequency of larger chains decreased exponentially with increasing size. This size distribution of small DNA chains suggests a mechanism of DNA replication in which larger chains (Okazaki pieces, Okazaki et al., 1968a) arise through joining of extremely short polynucleotide chains in a process resembling crystallization rather than unidirectional chain elongation.     

Synthesis and turnover of Euglena gracilis mitochondrial DNA

Replication of mitochondrial DNA was investigated by a density transfer experiment in a strain of Euglena gracilis lacking chloroplast DNA. DNA was uniformly labeled in a medium containing ³²P-labeled inorganic phosphate and [³H]adenine in the presence of the heavy-density label and transferred to a medium containing ³²P-labeled inorganic phosphate but no [³H]adenine following removal of the heavy-density label. Replication of nuclear DNA within these cells was used as an internal control. The densities and ratios of the peaks of nuclear DNA were those expected for a strict semiconservative replication. In contrast, replication of mitochondrial DNA was dispersive, as illustrated by the following results: (1) both native and denatured mitochondrial DNA exhibited a single density peak at 1.1 and 2.2 cell doublings after the density transfer. (2) The specific activity of ³H-labeled DNA varied across the peak of native or denatured DNA, indicating a heterogeneous population of molecules exhibiting different degrees of density and radioisotope labeling. This dispersive replication could involve either multiple recombination events or extensive turnover of the DNA or a mixture of both. Extensive dispersion of the sample obtained at 1.1 cell doublings after the density transfer is shown by the persistence of the same peak density for duplex DNA reduced to a molecular weight of 6 × 10⁵ by shearing.Two measures of the rate of replication of mitochondrial DNA were obtained from the densities of native duplex DNA and the rate of decrease in ³H-specific activities of duplex DNA during the experiment. The average of these rates indicates that mitochondrial DNA replicates at least 1.5 times as fast as nuclear DNA. Since there is a constant ratio of mitochondrial DNA:nuclear DNA in a logarithmic culture, mitochondrial DNA was calculated to have a half-life of 1.8 cell doublings.     

Architecture and assembly of poly-SUMO chains on PCNA in Saccharomyces cerevisiae

Posttranslational modifications of proliferating cell nuclear antigen (PCNA), the eukaryotic processivity clamp for DNA polymerases, regulate the pathways by which replication problems are resolved. In the budding yeast Saccharomyces cerevisiae, ubiquitylation of PCNA in response to DNA damage facilitates the replicative bypass of lesions, whereas conjugation of the ubiquitin-related modifier (SUMO) prevents unscheduled crossover events during S phase. We have analyzed the SUMO modification pattern of budding yeast PCNA in vivo and in vitro and found that most aspects of our in vitro sumoylation reactions reflect the situation under physiological conditions. We show that two oligomeric SUMO chains of two to three moieties each, linked via internal sumoylation consensus motifs within the SUMO sequence, are assembled on PCNA. The SUMO-specific ligase Siz1 both stimulates the overall efficiency of sumoylation and selects the modification site on PCNA. Furthermore, ubiquitin and SUMO chains are assembled independently, and we found evidence that both modifiers can coexist in vivo on a common PCNA subunit. Our results demonstrate for the first time the in vivo assembly of polymeric SUMO chains of defined linkage on a physiological substrate in yeast, but they also indicate that SUMO-SUMO polymers are dispensable for PCNA^SUMO function in replication and recombination.     

Accumulation of short DNA fragments in hydroxyurea treated mouse L-cells

Treatment of L-cells with hydroxyurea markedly inhibits the incorporation of [³H]thymidine into DNA. The ³H incorporation that persists during hydroxyurea inhibition is largely into 7S DNA chains. The labelled fragments can be chased into higher MW DNA, suggesting that they are intermediates in the replication process. This interpretation concurs with that of earlier reports which describe a similar effect of hydroxyurea on the replication of viral DNA.     

Critical DNA damage and mammalian cell reproduction

Synchronous Chinese hamster cells accumulated ¹²⁵I-induced DNA damage in the G₂ + M2 period at 4 °C. The position of the ¹²⁵I within the nuclear DNA was varied by incorporating [¹²⁵I]iododeoxyuridine at various times during the previous DNA replication period. When the initial cell inactivation efficiency was compared for damage accumulated in various regions of nuclear DNA, it was found that the efficiency of inactivation was least in early replicating DNA, and that it gradually increased, reaching a maximum during the fourth and fifth hours of the six-hour DNA replication period. Because the DNA that replicated during this maximum corresponds to that DNA which later forms centromeric and near-centromeric regions of the chromosomes, damage in centromeric region DNA may be critical in causing mammalian cell inactivation.     

DNA replication in Escherichia coli: evidence for two classes of small deoxyribonucleotide chains

We have used [³H]thymidine to pulse label cultures growing at 20 or 37 °C. At these temperatures, thymidine can be used interchangeably with thymine for labeling periods of 0.1 minute or longer. Incorporation does not stop immediately when cultures are poured on to ice-cold medium-KCN mixtures, but can be stopped by pouring on to the same mixture plus pyridine.We have extracted DNA from cells pulse-labeled with [³H]thymidine and measured the number of short deoxynucleotide chains by treating them with bacterial alkaline phosphatase and labeling their 5′ ends with ³²P using [γ-³²P]ATP and polynucleotide kinase. There are at least 40 deoxynucleotide chains per bacterium (20 per replicating chromosome) whose sedimentation coefficient is less than 15 S.The small deoxynucleotide chains labeled by a pulse of [³H]thymidine behave as intermediates in the replication of DNA. They accumulate if ligase is inhibited and they disappear if their synthesis is blocked by inactivating a gene product responsible for their synthesis. In contrast, the ³²P-labeled pieces do not accumulate rapidly or disappear under the same experimental conditions. The data indicate that many of the ³²P-labeled short chains are not located at the replication fork and that they do not behave as intermediates in the replication of DNA.The size distribution of³H pulse-labeled pieces and of the short chains labeled with ³²P are apparently the same when measured by sedimentation through alkaline sucrose. About 25% of the molecules are extremely short. The remainder are distributed in such a way that, roughly, the number of pieces greater than any particular length decreases exponentially as that length increases.     

Localization of DNA replicator sites near the nuclear membrane in plant cells

By means of optical and electron microscope autoradiography, following the administration of [³H]thymidine, we have detected a DNA replication near or on the nuclear membrane of meristematic cells of Haplopappus gracilis. This replication was observed only in the latter part of the S period. No localization to the nuclear membrane was seen at the beginning of the S period. Localization of the grains to the nuclear membrane in late S was observed both after short pulses and pulses as long as 1 h, and with chases of up to 2 h. It is concluded that the peripherally localized DNA replication is due to a DNA fraction located at the nuclear membrane, which replicates in the last part of the S period. It is suggested that such a DNA fraction may in part correspond to the constitutive heterochromatin.     

Nuclear DNA content and the control of chloroplast replication in wheat leaves

During development of the first leaf of breadwheat (Triticum aestivum L.) the number of chloroplasts per mesophyll cell increases between three- and four-fold. To establish if chloroplast replication is accompanied by endoreduplication, the nuclear DNA content of the cells was determined by chemical assay of isolated nuclei from mesophyll protoplasts and by microdensitometry of nuclei in mesophyll tissue. The DNA content of the nuclei was constant (27 to 32 pg) at each phase of chloroplast replication. Approximately 93% of the cells had a nuclear DNA content close to the 2C value of 32 pg. It is concluded that chloroplast replication is not dependent on nuclear endoreduplication in seedling leaves of wheat.     

A single‐molecule approach to DNA replication in Escherichia coli cells demonstrated that DNA polymerase III is a major determinant of fork speed

The replisome catalyses DNA synthesis at a DNA replication fork. The molecular behaviour of the individual replisomes, and therefore the dynamics of replication fork movements, in growing Escherichia coli cells remains unknown. DNA combing enables a single‐molecule approach to measuring the speed of replication fork progression in cells pulse‐labelled with thymidine analogues. We constructed a new thymidine‐requiring strain, eCOMB (E. coli for combing), that rapidly and sufficiently incorporates the analogues into newly synthesized DNA chains for the DNA‐combing method. In combing experiments with eCOMB, we found the speed of most replication forks in the cells to be within the narrow range of 550–750 nt s^?1 and the average speed to be 653 ± 9 nt s^?1 (± SEM). We also found the average speed of the replication fork to be only 264 ± 9 nt s^?1 in a dnaE173‐eCOMB strain producing a mutant‐type of the replicative DNA polymerase III (Pol III) with a chain elongation rate (300 nt s^?1) much lower than that of the wild‐type Pol III (900 nt s^?1). This indicates that the speed of chain elongation by Pol III is a major determinant of replication fork speed in E. coli cells.     

Incorporation of uracil into the growing strand of adenovirus 12 DNA.

The amount of rapidly labeled short DNA chains in adenovirus 12(Ad12)-infected cells was markedly increased in the presence of either uridine or deoxycytidine which could be converted to dUTP. When the infected cells were labeled with [³H]uridine or [³H] deoxycytidine and the labeled nucleotides in the short DNA chains from the Hirt supernatant were analysed by thin-layer chromatography, approximately 90 or 20% of the label was detected in dUTP. These results suggest that at least a portion of short DNA chains formed during Ad12 DNA replication is derived from an excision-repair mechanism of uracil containing nascent strands.     

Cell lethality after selective irradiation of the DNA replication fork

Summary It has been suggested that nascent DNA located at the DNA replication fork may exhibit enhanced sensitivity to radiation damage. To evaluate this hypothesis, Chinese hamster ovary cells (CHO) were labeled with¹²⁵I-iododeoxyuridine (¹²⁵IUdR) either in the presence or absence of aphidicolin. Aphidicolin (5 µg/ml) reduced cellular¹²⁵IUdR incorporation to 3–5% of the control value. The residual¹²⁵I incorporation appeared to be restricted to low molecular weight (sub-replicon sized) fragments of DNA which were more sensitive to micrococcal nuclease attack and less sensitive to high salt DNase I digestion than randomly labeled DNA. These findings suggest that DNA replicated in the presence of aphidicolin remains localized at the replication fork adjacent to the nuclear matrix.Based on these observations an attempt was made to compare the lethal consequences of¹²⁵I decays at the replication fork to that of¹²⁵I decays randomly distributed over the entire genome. Regardless of the distribution of decay events, all treatment groups exhibited identical dose-response curves (D₀: 101¹²⁵I decays/cell). Since differential irradiation of the replication complex did not result in enhanced cell lethality, it can be concluded that neither the nascent DNA nor the protein components (replicative enzymes, nuclear protein matrix) associated with the DNA replication site constitute key radiosensitive targets within the cellular genome.     

Cdc6 and DNA replication: Limited to humble origins

The budding yeast Cdc6 protein is important for regulating DNA replication intiation. Cdc6p acts at replication origins, and cdc6-1 mutants arrest with unreplicated DNA and show elevated minichromosome loss rates. Overexpression of the related Cdc 18 protein in fission yeast results in DNA rereplication; however, Cdc6p overexpression does not cause this result. A recent paper⁽¹⁾ further defines the role of Cdc6p in DNA replication. Cdc6p only promotes DNA replication between the end of mitosis and late G₁, and although the Cdc6 protein is highly unstable, neither degradation nor nuclear localization is critical for limiting DNA replication to this interval.     

DNA Synthesis during Maturation of Starfish Oocytes

IN Xenopus, nuclear DNA is replicated at an early stage of meiosis and there is no measurable DNA synthesis during the long diplotene stage characterized by the presence of the lampbrush chromosomes^1–3; this is probably a general phenomenon in animals. But in the case of pollen formation in plants, autoradiographic data suggest that, in addition to normal replication during S phase, some chromosomal DNA is synthesized throughout meiosis⁴. Limited DNA synthesis also follows replication during the S phase in Lilium anthers⁵.     

Cyclin B-Cdk1 Kinase Stimulates ORC- and Cdc6-Independent Steps of Semiconservative Plasmid Replication in Yeast Nuclear Extracts

Nuclear extracts from Saccharomyces cerevisiae cells synchronized in S phase support the semiconservative replication of supercoiled plasmids in vitro. We examined the dependence of this reaction on the prereplicative complex that assembles at yeast origins and on S-phase kinases that trigger initiation in vivo. We found that replication in nuclear extracts initiates independently of the origin recognition complex (ORC), Cdc6p, and an autonomously replicating sequence (ARS) consensus. Nonetheless, quantitative density gradient analysis showed that S- and M-phase nuclear extracts consistently promote semiconservative DNA replication more efficiently than G₁-phase extracts. The observed semiconservative replication is compromised in S-phase nuclear extracts deficient for the Cdk1 kinase (Cdc28p) but not in extracts deficient for the Cdc7p kinase. In a cdc4-1 G₁-phase extract, which accumulates high levels of the specific Clb-Cdk1 inhibitor p40^SIC1, very low levels of semiconservative DNA replication were detected. Recombinant Clb5-Cdc28 restores replication in a cdc28-4 S-phase extract yet fails to do so in the cdc4-1 G₁-phase extract. In contrast, the addition of recombinant Xenopus CycB-Cdc2, which is not sensitive to inhibition by p40^SIC1, restores efficient replication to both extracts. Our results suggest that in addition to its well-characterized role in regulating the origin-specific prereplication complex, the Clb-Cdk1 complex modulates the efficiency of the replication machinery itself.     

Chromatin replication in isolated nuclei from bovine lymphocytes

DNA replication in isolated nuclei from Concanavalin A-stimulated and resting bovine lymphocytes has been studied. Nuclei from S phase lymphocytes incorporate 4–7 times more (³H)dTTP than nuclei from resting cells. The DNA synthesis was dependent on ATP, Mg²⁺ and all four deoxynucleoside triphosphates and was linear for about 60 min. The newly synthesized DNA is nuclear and DNase-sensitive and is the product of discontinuous and semiconservative replication. After limited digestion with micrococcal nuclease the $\text{in vitro}$ replicated DNA was found to occur in nucleosomes prior to joining of primary DNA pieces. Addition of a protein extract from replicating cells stimulated the DNA synthesizing capacity of nuclei from resting lymphocytes. A preliminary characterization of this extract is given.     

Mitochondrial DNA synthesis in cell cycle mutants of saccharomyces cerevisiae

Mitochondrial DNA replication was examined in mutants for seven different Saccharomyces cerevisiae genes which are essential for nuclear DNA replication. In cdc8 and cdc21, mutants defective in continued replication during the S phase of the cell cycle, mitochondrial DNA replication ceases at the nonpermissive temperature. Replication is temperature sensitive even when these mutants are arrested in the G1 phase of the cell cycle with α factor, a condition where mitochondrial DNA replication continues for the equivalent of several generations at the permissive temperature. Therefore the cessation of replication results from a defect in mitochondrial replication per se, rather than from an indirect consequence of cells being blocked in a phase of the cell cycle where mitochondrial DNA is not normally synthesized. Since the temperature-sensitive mutations are recessive, the products of genes cdc8 and cdc21 must be required for both nuclear and mitochondrial DNA replication. In contrast to cdc8 and cdc21, mitochondrial DNA replication continues for a long time at the nonpermissive temperature in five other cell division cycle mutants in which nuclear DNA synthesis ceases within one cell cycle: cdc4, cdc7, and cdc28, which are defective in the initiation of nuclear DNA synthesis, and cdc14 and cdc23, which are defective in nuclear division. The products of these genes, therefore, are apparently not required for the initiation of mitochondrial DNA replication.