Quantitative analysis of plasmid forms by agarose and capillary gel electrophoresis.

Plasmids may appear in different forms: circular with different degrees of coiling, partially cleaved or linear, and multimeric as concatamers or catenates. Capillary gel electrophoresis (CGE) of plasmid samples allows the determination of plasmid form distribution. Monomeric and dimeric plasmid DNA forms were separated by both CGE and agarose gel electrophoresis (AGE). The pattern of isoform bands from AGE was compared to the corresponding peak pattern from CGE, and differences in the relative mobility of the plasmid forms between the two methods were found. The comparison of AGE and CGE allows the assignment of AGE bands to CGE peaks. Additionally, the different isoforms can now be quantified by CGE. Routine plasmid form analysis by CGE may be automated, allowing easy, fast, and highly reliable quantification. CGE also offers high resolution and the amount of DNA required is very low. Therefore this method is very useful for the analysis of therapeutics based on plasmid DNA during their production, isolation, and formulation.     

Impact of engineering flow conditions on plasmid DNA yield and purity in chemical cell lysis operations

Chemical lysis of bacterial cells using an alkaline solution containing a detergent may provide an efficient scalable means for selectively removing covalently closed circular plasmid DNA from high-molecular-weight contaminating cellular components including chromosomal DNA. In this article we assess the chemical lysis of E. coli cells by SDS in a NaOH solution and determine the impact of pH environment and shear on the supercoiled plasmid and chromosomal DNA obtained. Experiments using a range of plasmids from 6 kb to 113 kb determined that in an unfavorable alkaline environment, where the NaOH concentration during lysis is greater than 0.15 +/- 0.03 M (pH 12.9 +/- 0.2), irreversible denaturation of the supercoiled plasmid DNA occurs. The extent of denaturation is shown to increase with time of exposure and NaOH concentration. Experiments using stirred vessels show that, depending on NaOH concentration, moderate to high mixing rates are necessary to maximize plasmid yield. While NaOH concentration does not significantly affect chromosomal DNA contamination, a high NaOH concentration is necessary to ensure complete conversion of chromosomal DNA to single-stranded form. In a mechanically agitated lysis reactor the correct mixing strategy must balance the need for sufficient mixing to eliminate potential regions of high NaOH concentrations and the need to avoid excessive breakage of the shear sensitive chromosomal DNA. The effect of shear on chromosomal DNA is examined over a wide range of shear rates (10(1)-10(5) s(-1)) demonstrating that, while increasing shear leads to fragmentation of chromosomal DNA to smaller sizes, it does not lead to significantly increased chromosomal DNA contamination except at very high shear rates (about 10(4)-10(5) s(-1)). The consequences of these effects on the choice of lysis reactor and scale-up are discussed.     

Electrophoretic profiles of mitochondrial plasmids in Neurospora suggest they replicate by a rolling circle mechanism.

Migratory behaviour of mitochondrial plasmids from Neurospora crassa Mauriceville-1c and N. intermediate LaBelle has been studied by pulsed field gel electrophoresis (PFGE). Electrophoretic profiles demonstrate that long, linear molecules of a heterogeneous size are the prevailing form of plasmid DNA in vivo. Circular forms represent less than 8-9% of plasmid DNA. Single stranded DNA regions are abundant and lead to electrophoretic inertia of a significant amount of plasmid DNA. These profiles indicate that both plasmids replicate by the recombination dependent rolling circle mechanism.     

Expression of Escherichia coli dam gene in Bacillus subtilis provokes DNA damage response: N6-methyladenine is removed by two repair pathways.

The dam gene of Escherichia coli encodes a DNA methyltransferase that methylates the N6 position of adenine in the sequence GATC. It was stably expressed from a shuttle vector in a repair- and recombination-proficient strain of Bacillus subtilis. In this strain the majority of plasmid DNA molecules was modified at dam sites whereas most chromosomal DNA remained unmethylated during exponential growth. During stationary phase the amount of unmethylated DNA increased, suggesting that methylated bases were being removed. An ultraviolet damage repair-deficient mutant (uvrB) contained highly methylated chromosomal and plasmid DNA. High levels of Dam methylation were detrimental to growth and viability of this mutant strain and some features of the SOS response were also induced. A mutant defective in the synthesis of adaptive DNA alkyltransferases and induction of the adaptive response (ada) also showed high methylation and properties similar to that of the dam gene expressing uvrB strain. When protein extracts from B. subtilis expressing the Dam methyltransferase or treated with N-methyl-N'-nitro-N-nitroso-guanidine were incubated with [3H]-labelled Dam methylated DNA, the methyl label was bound to two proteins of 14 and 9 kD. Some free N6-methyladenine was also detected in the supernatant of the incubation mixture. We propose that N6-methyladenine residues are excised by proteins involved in both excision (uvrB) and the adaptive response (ada) DNA repair pathways in B. subtilis.     

Cellular uptake and metabolism of DNA frayed wires

DNA frayed wires are a novel, multistranded form of DNA that arises from interactions between single-stranded oligodeoxyribonucleotides with the general sequence d(N(x)G(y)) or d(G(y)N(x)), where y > 10 and x > 5. Frayed wires exhibit greater stability with respect to thermal and chemical denaturation than single- or double-stranded DNA molecules and, thus, may have potential usefulness for DNA drug delivery. However, the stability and uptake of frayed wires have not been investigated in biological systems. Our objective was to examine the cellular uptake and stability of frayed wires in cultured hepatic cells. In these studies, the parent oligonucleotide d(A(15)G(15)) was used to form DNA frayed wires (DNA(FW)) while a random 30-mer oligonucleotide was used as the control nonaggregated DNA (DNA(SS)). Uptake and metabolism studies of DNA(FW) were performed in cultured human hepatoma, HepG2 cells and compared to DNA(SS). Our results indicate that DNA(FW) are not cytotoxic and that their intracellular uptake in HepG2 cells is 2-3.5-fold greater than that of DNA(SS) within the first 2 h (p < 0.05). Similarly, nuclear localization of DNA(FW) is 10-13-fold higher than that of DNA(SS) (p < 0.05). As both internalized and extracellular DNA(FW) appear to be more stable in vitro than DNA(SS), the enhanced uptake may be due to either increased stability or enhanced intracellular transport. These studies also indicate that uptake of DNA(FW) likely occurs via active processes such as receptor-mediated endocytosis similar to mechanisms which have been proposed for DNA(SS). The internalization pathways of DNA(FW) may differ somewhat from that of DNA(SS) insofar as chloroquine does not appear to alter DNA(FW) uptake and degradation, as is the case with DNA(SS).     

Natural Transformation of Acinetobacter calcoaceticus by Plasmid DNA Adsorbed on Sand and Groundwater Aquifer Material

It is known that plasmid DNA and linear duplex DNA molecules adsorb to chemically purified mineral grains of sand and to particles of several clay fractions. It seemed desirable to examine whether plasmid DNA would also adsorb to nonpurified mineral materials taken from the environment and, particularly, whether adsorbed plasmid DNA would be available for natural transformation of bacteria. Therefore, microcosms consisting of chemically pure sea sand plus buffered CaCl₂ solution were compared with microcosms consisting of material sampled directly from a groundwater aquifer (GWA) plus groundwater (GW) with respect to the natural transformation of Acinetobacter calcoaceticus by mineral-associated DNA. The GWA minerals were mostly sand with inorganic precipitates and organic material plus minor quantities of silt and clay (illite and kaolinite). The amount of plasmid DNA which adsorbed to GWA (in GW) was about 80% of the amount which adsorbed to purified sand (in buffered CaCl₂ solution). Plasmid DNA adsorbed on sand transformed A. calcoaceticus significantly less efficiently than did plasmid DNA in solution. In contrast, the transformation by sand-adsorbed chromosomal DNA was as high as that by DNA in solution. In GWA/GW microcosms, the efficiency of transformation by chromosomal DNA was similar to that in sand microcosms, whereas plasmid transformation was not detectable. However, plasmid transformants were found at a low frequency when GWA was loaded with both chromosomal and plasmid DNA. Reasons for the low transformation efficiency of plasmid DNA adsorbed to mineral surfaces are discussed. Control experiments showed that the amounts of plasmid and chromosomal DNA desorbing from sand during incubation with a cell-free filtrate of a competent cell suspension did not greatly contribute to transformation in sand microcosms, suggesting that transformation occurred by direct uptake of DNA from the mineral surfaces. Taken together, the observations suggest that plasmid DNA and chromosomal DNA fragments which are adsorbed on mineral surfaces in a sedimentary or soil habitat may be available (although with different efficiencies for the two DNA species) for transformation of a naturally competent gram-negative soil bacterium.     

Replication of mycoplasma virus L51. VII. Effect of chloramphenicol on the synthesis of DNA replicative intermediates.

Chloramphenicol affects several steps in the DNA replication of mycoplasma virus L51, a noncytocidal, naked, bullet-shaped virion containing circular single-stranded (SS) DNA of 1.5 X 10(6) daltons (4.5 kilobases). In the presence of chloramphenicol, adsorption was normal and parental SS DNA was converted to double-stranded replicative forms (RF), but subsequent RF leads to RF replication was inhibited. Chloramphenicol added late in infection, when most viral nascent DNA is in progeny SS molecules, inhibited SS synthesis, but nascent RF molecules were formed. However, a chase experiment showed that these RF molecules could not be converted to SS DNA. Therefore, viral RF molecules made in the presence of chloramphenicol are not functional as SS DNA precursors.     

Directed modification of the Tcr gene region of the plasmid pBR322 using complementary single-stranded DNA fragments carrying alkylating groups

A method is suggested for chemical modification of preselected regions of plasmid DNA by complementary single-stranded restriction fragments of DNA (srf DNA), carrying alkylating reagents. The gene coding for tetracycline resistance of plasmid pBR322 was used as a target. Srf DNA was prepared by a partial digestion of a double-stranded EcoRI-BamHI restriction fragment (377 base pairs) from Tcr by E. coli exonuclease III. The residues of an alkylating reagent N,N,N'-tri(beta-chlorethyl)-N'-(p-formylphenyl) propylenediamine 1,3 (TFP) were attached covalently to 4-5% of sfr DNA bases. The alkylating derivative of the sfr DNA was hybridized with supercoiled pBR322 plasmid DNA. The hybridization conditions (37 degrees C, 40% formamide, 0,2 M NaCl, 0,1 M Tris-HCl pH 7,5, 0,001 M EDTA) under which the bases carrying TFP residues are not eliminated from the sfr DNA, and transforming activity of pBR322 DNA does not decrease were established. It was shown that about 20% of plasmid pBR322 molecules form D-loops with alkylating sfr DNA under these conditions. It was shown that sfr DNA, carrying TFP can alkylate the complementary region of plasmid DNA, forming cross-linked D-loops. A method for the site-directed mutagenesis of switching off the preselected genes or non-transcribed DNA functional regions (promotors, introns etc) integrated into plasmids of other vectors is suggested.     

Effect of Growth Conditions on the Formation of the Relaxation Complex of Supercoiled ColE1 Deoxyribonucleic Acid and Protein in Escherichia coli

Colicinogenic factor E1 (ColE1) is present in Escherichia coli strain JC411 (ColE1) cells to the extent of about 24 copies per cell. This number does not appear to vary in situations which give rise to twofold differences in the amount of chromosomal deoxyribonucleic acid (DNA) present per cell. If cells are grown in the absence of glucose, approximately 80% of the ColE1 molecules can be isolated as strand-specific DNA-protein relaxation complexes. When glucose is present in the medium, only about 30% of the plasmid molecules can be isolated as relaxation complexes. Medium shift experiments in which glucose was removed from the medium indicate that within 15 min after the shift the majority (>60%) of the plasmid can be isolated as relaxation complex. This rapid shift to the complexed state is accompanied by a two- to threefold increase in the rate of plasmid replication. The burst of replication and the shift to the complexed state are both inhibited by the presence of chloramphenicol. Inhibition of protein synthesis in log cultures by the addition of chloramphenicol or amino acid starvation allows ColE1 DNA to continue replicating long after chromosomal replication has ceased. Under these conditions, noncomplexed plasmid DNA accumulates while the amount of DNA that can be isolated in the complexed state remains constant at the level that existed prior to treatment. In the presence of chloramphenicol, there appears to be a random dissociation and association of ColE1 DNA and “relaxation protein” during or between rounds of replication.     

Replication intermediate of a hybrid plasmid carrying the replication terminus (ter) site of R6K as revealed by agarose gel electrophoresis

Summary A 4.32 kb DNA fragment, on which the DNA replication terminus (terR) site of plasmid R 6K was located, was inserted into the unique EcoRI site of plasmid pUC9. To detect replication intermediate molecules with a replication fork halted at the terR site, a cell DNA extract was digested with EcoRI, electrophoresed through an agarose gel and stained with ethidium bromide. In addition to two major bands, one derived from vector DNA and the other from the ter insert fragment, two extra minor bands were detected. Following DNA-DNA hybridization and electron microscopic observation we concluded that the two minor bands corresponded to the two Y-shaped molecules, produced from the -shaped intermediate molecules by EcoRI digestion.Abbreviations Ap ampicillin - kb kilobase pair(s) - EtBr ethidium bromide     

A new DNA extraction method by controlled alkaline treatments from consolidated subsurface sediments

Microbial communities that thrive in subterranean consolidated sediments are largely unknown owing to the difficulty of extracting DNA. As this difficulty is often attributed to DNA binding onto the silica-bearing sediment matrix, we developed a DNA extraction method for consolidated sediment from the deep subsurface in which silica minerals were dissolved by being heated under alkaline conditions. NaOH concentrations (0.07 and 0.33 N), incubation temperatures (65 and 94 °C) and incubation times (30-90 min) before neutralization were evaluated based on the copy number of extracted prokaryotic DNA. Prokaryotic DNA was detected by quantitative PCR analysis after heating the sediment sample at 94 °C in 0.33 N NaOH solution for 50-80 min. Results of 16S rRNA gene sequence analysis of the extracted DNA were all consistent with regard to the dominant occurrence of the metallophilic bacterium, Cupriavidus metallidurans, and Pseudomonas spp. Mineralogical analysis revealed that the dissolution of a silica mineral (opal-CT) during alkaline treatment was maximized at 94 °C in 0.33 N NaOH solution for 50 min, which may have resulted in the release of DNA into solution. Because the optimized protocol for DNA extraction is applicable to subterranean consolidated sediments from a different locality, the method developed here has the potential to expand our understanding of the microbial community structure of the deep biosphere.     

Studies on the phi X174 gene A protein-mediated termination of leading strand DNA synthesis

Recombinant RF (replicate form) I DNAs containing the bacteriophage phi X174 gene A protein-recognition sequence are cleaved by the phi X A protein yielding a phi X RF II X A protein complex (Zipursky, S.L., Reinberg, D., and Hurwitz, J. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 5182-5186). Such complexes support DNA synthesis in both RF I leads to SS(c) and RF I leads to RF I phi X DNA replication reactions in vitro. Two phi X A protein-recognition sequences were inserted into plasmid pBR322. Both sequences were contiguous with the same strand of the vector DNA and separated by 667 and 4275 base pairs. This recombinant plasmid (G27-4) was cleaved by the phi X A protein at either insert and both inserts support the initiation of RF leads to SS(c) DNA synthesis. This was verified by the finding that replication products were circular molecules of 667 and 4275 nucleotides. This finding is in keeping with the multifunctional activities associated with the phi X A protein; these include the site-specific nicking of RF I DNA which initiates DNA synthesis and site-specific termination resulting in the circularization of the displaced DNA strand. The phi X A protein and the Escherichia coli rep and SSb proteins catalyze the unwinding of phi X RF I DNA in vitro (Scott, J.F., Eisenberg, S., Bertsch, L.L., and Kornberg, A. (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 193-197). Recombinant plasmid G27-4 RF I DNA was also unwound in vitro by this enzyme system; in this case, both circular and linear single-stranded DNA molecules of 667 and 4275 nucleotides, as well as full length circular single-stranded DNA were formed. Full length linear DNA was not detected. The two single-stranded circular DNA products formed as leading strands in RF leads to SS(c) reaction mixtures containing G27-4 RF I DNA differed in their ability to support lagging strand DNA synthesis. It was shown that the large single-stranded circular product included DNA sequences homologous to a replication factor Y effector sequence required for RF leads to RF and SS(c) leads to RF replication (Zipursky, S.L., and Marians, K.J. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 6521-6525). The 4275-nucleotide, but not the 667-nucleotide, single-stranded circular DNA product was converted to a duplex structure.     

Studies on the interaction between Cd(2+) ions and DNA

Cadmium is a potent carcinogen in rodents and has recently been accepted by the International Agency for Research on Cancer as a category 1 (human) carcinogen, but the molecular mechanism of its action remains largely unclear. It has however been suggested that cadmium-induced carcinogenesis may involve either direct or indirect interaction of Cd²⁺ with DNA. Cd²⁺ is believed to bind covalently with N7 centres of adenine and guanine. At low concentrations (≤50 mM), Cd²⁺ is found to react with plasmid DNA to produce a mixture of Form I and Form II bands whereas at higher concentrations (≥100 mM), Cd²⁺ causes extensive damage to DNA at a pH 5.8 solution of cadmium nitrate. Within the range 0–100 mM (when pH is adjusted to 7.4 by adding NaOH) an increase in concentration of Cd²⁺ is found to cause a decrease in the gel mobility rate of plasmid and an increase in the intensity of the Form II band. When plasmid DNA is digested with BamH1, only the Form III band is observed both in the presence and absence of Cd²⁺. However, the mobility of the band is found to decrease with the increase in the concentration of Cd²⁺. When the enzyme Ssp1 which cuts plasmid DNA at the AT sites is used instead of BamH1, two bands are observed in the presence of cadmium as against one band in the absence of cadmium. These results suggest that Cd²⁺ binds covalently with DNA (possibly at G, A and T centres) and can form intrastrand bifunctional AT adducts but not the GG adducts. It may also be that neither GG nor AT adducts are formed and yet Ssp1 digestion is prevented because of a structural modification introduced in adenine by its interaction with Cd²⁺. In the presence of antioxidants such as cysteine, glutathione and ascorbate (especially cysteine and ascorbate), DNA damage is found to be greater than expected for the combined effects of the antioxidant and Cd²⁺. The increased DNA damage is believed to be due to the formation of reactive oxygen species (ROS).     

Characterization of two circular plasmids from the marine diatom Cylindrotheca fusiformis: plasmids hybridize to chloroplast and nuclear DNA.

Summary This paper reports the discovery and initial characterization of two small plasmids, pCfl and pCf2, in the marine diatomCylindrotheca fusiformis. Extracted diatom DNA separates into two bands in CsCI-Hoechst 33258 dye gradients. Upon agarose gel electrophoresis of a sample of the upper band of the gradient we observed, in addition to high molecular weight (genomic) chloroplast and mitochondrial DNA, pairs of lower molecular weight bands. These bands contained two species of circular plasmid DNA molecules, as shown by electron microscopy. The nucleotide composition of the plasmids, and chloroplast and mitochondrial DNAs is similar, as indicated by their co-banding in the gradients. They were cloned, and their restriction maps determined, showing that pCfl is 4.27 and pCf2 4.08 kb in size. By hybridization analysis, we showed that pCfl and pCf2 share regions of similarity, but not identity. Neither plasmid hybridizes with mitochondrial DNA. Both plasmids hybridize with chloroplast DNA, and pCf2 also hybridizes with nuclear DNA.     

The determination of the sequences present in the shadow bands of a dinucleotide repeat PCR.

A Polymerase Chain Reaction (PCR) of a DNA sequence containing a CA repeat produces a main band but also several shadow bands that differ by 2 base pairs below the main band. In the experiments described in this paper, these shadow bands were excised from a DNA sequencing gel and directly sequenced. It was found that the sequence in the CA repeat was ambiguous. However, the sequence 5' and 3' to the CA repeat was clear and unambiguous. It is proposed that the shadow bands are generated by 2 base pair random deletions in the CA repeat region. During this process the sequence becomes 'scrambled' only in the CA repeat region. The shadow bands were shown to occur during the PCR since the genomic DNA template did not contain the shadow bands. It is probable that the shadow bands arise by slippage during the PCR. It is predicted that a thermostable DNA polymerase with a high processivity would greatly reduce the occurrence of shadow bands.     

Mechanisms underlying production of double-strand breaks in plasmid DNA after decay of 125I-Hoechst

Previously, the kinetics of strand break production by (125)I-labeled m-iodo-p-ethoxyHoechst 33342 ((125)IEH) in supercoiled (SC) plasmid DNA had demonstrated that approximately 1 DSB is produced per (125)I decay both in the presence and absence of the hydroxyl radical scavenger DMSO. In these experiments, an (125)IEH:DNA molar ratio of 42:1 was used. We now hypothesize that this DSB yield (but not the SSB yield) may be an overestimate due to subsequent decays occurring in any of the 41 (125)IEH molecules still bound to nicked (N) DNA. To test our hypothesis, (125)IEH was incubated with SC pUC19 plasmids ((125)IEH:DNA ratio of approximately 3:1) and the SSB and DSB yields were quantified after the decay of (125)I. As predicted, the number of DSBs produced per (125)I decay is one-half that reported previously ( approximately 0.5 compared to approximately 1, +/- DMSO) whereas the number of SSBs ( approximately 3/(125)I decay) is similar to that obtained previously ( approximately 90% are generated by OH radicals). Direct visualization by atomic force microscopy confirms formation of L and N DNA after (125)IEH decays in SC DNA and supports the strand break yields reported. These findings indicate that although SSB production is independent of the number of (125)IEH bound to DNA, the DSB yield can be augmented erroneously by (125)I decays occurring in N DNA. Further analysis indicates that 17% of SSBs and 100% of DSBs take place within the plasmid molecule in which an (125)IEH molecule decays, whereas 83% of SSBs are formed in neighboring plasmid DNA molecules.     

Transformation of Neurospora crassa with recombinant plasmids containing the cloned glutamate dehydrogenase (am) gene: evidence for autonomous replication of the transforming plasmid.

We have characterized Neurospora crassa transformants obtained with plasmid pJR2, which consists of the Neurospora glutamate dehydrogenase (am) gene cloned in pUC8 and an am132 host strain which contains a deletion encompassing the cloned fragment. Every one of 33 transformants tested showed extreme meiotic instability: less than 1 or 2% am+ progeny were obtained in initial or successive backcrosses between am+ transformants and am132 or in intercrosses between am+ progeny. Furthermore, am+ progeny from backcrosses gave a high proportion of auxotrophic (am) mitotic segregants during vegetative growth. These results indicate that the am+ character is not stably integrated into chromosomal DNA in any of the transformants tested. Nuclear DNAs from six transformants were analyzed by Southern hybridization. All six transformants contained sequences homologous to pJR2. Four showed restriction fragments expected for unmodified pJR2, but most showed additional bands. Southern blots of undigested DNAs showed that the plasmid sequences are present predominantly in high-molecular-weight form (larger than 20 kilobases). Southern blots showed that auxotrophic (am) progeny from a backcross to am132 had lost restriction bands corresponding to free plasmid but retained additional bands, apparently integrated into chromosomal DNA in a nonfunctional manner. Considered together, these results are most reasonably interpreted as follows: recombinant plasmids containing the am+ gene can replicate autonomously in N. crassa, the free plasmids are present in oligomeric or modified form or both, and plasmid sequences also integrate at multiple sites in the deletion host but in a nonfunctional manner. An alternate interpretation--that tandem repeats of the plasmid are integrated into chromosomal DNA but eliminated during meiosis--cannot be completely excluded. However, stable integration of the am gene can be obtained under a variety of other conditions, viz., using the am gene cloned in a phage lambda vector (J. A. Kinsey and J. A. Rambosek, Mol. Cell. Biol. 4:117-122, 1984), using derivatives of pJR2, or using pJR2 to transform a frameshift mutant.     

Dynamics of DNA binding of replication initiation proteins during de novo formation of pre-replicative complexes in Xenopus egg extracts

We investigated the dynamics of DNA binding of replication initiation proteins during formation of the pre-replicative complex (pre-RC) on plasmids in Xenopus egg extracts. The pre-RC was efficiently formed on plasmids at 23 degrees C, with one or a few origin recognition complex (ORC) molecules and approximately 10-20 mini-chromosome maintenance 2 (MCM2) molecules loaded onto each plasmid. Although geminin inhibited MCM loading, MCM interacted weakly but stoichiometrically with the plasmid in an ORC-dependent manner, even in the presence of geminin (with approximately 10 MCM2 molecules per plasmid). Interestingly, DNA binding of ORC, CDC6, and CDT1 was significantly stabilized in the presence of geminin, under which conditions approximately 10-20 molecules each of ORC and CDC6 were bound. Moreover, a similarly stable ORC-CDC6-CDT1 complex rapidly formed on DNA at lower temperature (0 degrees C) without geminin, with approximately 10-20 molecules each of ORC and CDC6 bound to the plasmid, but almost no binding of MCM. However, upon shifting the temperature to 23 degrees C, most ORC, CDC6, and CDT1 molecules were displaced from the DNA, leaving about one ORC molecule on the plasmid, whereas approximately 10 MCM2 molecules were loaded onto each plasmid. Furthermore, it was possible to load MCM onto DNA when the isolated ORC-CDC6-CDT1-DNA complex was mixed with purified MCM proteins. These results suggest that an ORC-CDC6-CDT1 complex pre-formed on DNA is directly involved in MCM loading and imply that each DNA-bound ORC molecule loads only one or a few MCM2-7 complexes during metazoan pre-RC formation.     

Rapid and reliable dideoxy sequencing of double-stranded DNA

We report a simple and reliable protocol for nucleotide sequencing using the Sanger dideoxy technique on linearized double-stranded DNA molecules with specific oligonucleotide primers. The method is demonstrated for restriction fragments cloned into the plasmid vectors pSP64 and pSP65 using two vector-specific primers, the M 13 reverse primer and a new SP6 primer, flanking the multiple cloning site. Template DNA may be prepared by a rapid alkaline lysis procedure. Mild linearization conditions with the appropriate restriction endonuclease avoid the appearance of artifact bands.     

Synthesis and repair of RNA-containing supercoiled plasmid ColE1 DNA in Escherichia coli

Supercoiled plasmid molecules sensitive to nicking by RNase or alkali have been shown to accumulate during replication of colicinogenic factor E1 (ColE1) in Escherichia coli in the presence of chloramphenicol. The possibility that this sensitivity is due to the covalent integration of RNA molecules during the synthesis of plasmid DNA is supported by the demonstration that (a) strands of supercoiled ColE1 newly replicated in the presence of chloramphenicol exhibit sensitivity to RNase and alkali treatment, while (b) RNase- and alkali-resistant circular strands of plasmid DNA synthesized either before or after the addition of chloramphenicol remain resistant during subsequent replication of the plasmid in the presence of chloramphenicol. Furthermore, newly made plasmid DNA strands cannot act as templates for further rounds of replication if they possess an RNA segment. The existence of a repair mechanism for the removal of the RNA segment from supercoiled ColE1 DNA molecules was demonstrated by pulse-chase experiments. It was observed that the proportion of RNase-sensitive molecules is considerably higher in pulse-labeled as compared to continuously labeled ColE1 DNA synthesized in the presence of chloramphenicol, and the proportion of pulse-labeled ColE1 DNA that is RNase sensitive is greatly reduced during a chase period. Removal of the RNA segment is also carried out effectively at the restrictive temperature in temperature-sensitive DNA polymerase I mutants. In a survey of other bacterial mutants defective in the repair of damaged DNA, a substantial increase in the rate of accumulation of RNase-and alkali-sensitive supercoiled ColE1 DNA in the presence of chloramphenicol was observed in recBC and uvrA mutants in comparison with the wild-type strains.