The incN plasmid replicon: two pathways of DNA polymerase I-independent replication

The 2,053-bp broad-host-range incompatibility group N replicon of plasmid pCU1 has two components: a region of 1,200 bp that is sufficient for its replication in Escherichia coli PolA+ and PolA- hosts and a regulatory region called the group I iteron region that contains 13 39-bp iterons. Within the 1,200-bp region, there are three replication origins, two of which, called oriB and oriS, function in PolA+ and PolA- hosts and a third, called oriV, which functions only in PolA+ hosts. The region also specifies a protein called RepA. We now show that both oriB and oriS can function in a delta polA strain but that in such a strain, only oriB has an absolute requirement for RepA. oriS can function without RepA and polymerase I provided that the iteron region is deleted and that in this circumstance, it is the only origin, the usage of which is detected. The requirements for oriB usage can thus be distinguished from those for oriS usage. The oriB region can be recovered as a plasmid only if RepA is provided in trans. These complex features of this replicon are also shown to be shared by the IncN replicons of other antibiotic resistance plasmids. Functionally distinguishable origins in a small replicon may be a way of endowing such a replicon with a broad host range.     

Purification and characterization of a DNA binding protein in a nuclear scaffold fraction from rat ascites hepatoma cells

Our most recent work [Hibino et al. (1995) Cancer Lett., 88, 49-55] has shown that the selective binding affinities of highly repetitive DNA components for a nuclear scaffold protein from rat ascites hepatoma cells (P230) depend on the degree of sequence-directed bending of the helix axis. In the present experiment, this protein has been highly purified and isolated by a series of column chromatographic procedures to migrate as a single band to a molecular weight position of 230 kd on a SDS-polyacrylamide gel. A filter binding assay showed that the binding of a repetitive AT-rich component (369 bp XmnI fragment) from the hepatoma nucleus, which has a strongly bent overall structure, to isolated P230 is based on a cooperative mode of interaction. Distamycin A, which binds specifically to AT-rich DNA, removed the bend in the XmnI fragment and inhibited binding to this protein. These results suggest that AT-rich regions in highly repetitive DNA cause bending of the helix axis to be recognized by nuclear scaffold protein(s). Moreover, it has been shown that the nuclear scaffold fraction from rat liver or an actively growing hepatocyte cell line (Ac2F cells) does not contain P230, but does have a repetitive bent DNA binding protein (P130), which has an apparent molecular weight of 130 kd. In addition, the immunoblot analysis showed that mouse anti-P130 antiserum reacts with P230. Thus, the results in the present study imply that there is some difference in the higher order structure of the nuclear DNA attachment region between rat liver or actively growing hepatocytes and the hepatoma, although P230 appears to be immunochemically similar to P130.     

pR plasmid replication provides evidence that single-stranded DNA induces the SOS system in vivo

The aim of this study was to quantitate factors affecting the initial "peak" of the pulmonary artery (PA) drug concentrations after i.v. bolus drug administration, which is a determinant of the subsequent drug uptake into both the lungs and other well-perfused organs. Indocyanine green (ICG) was used as a marker drug in anaesthetized (1.5% halothane) sheep prepared with an inferior vena cava injection catheter and a large-gauge pulmonary artery blood sampling catheter. For three ranges of cardiac output, 2.5-mg doses of ICG were injected in the following combinations: 10 ml injected over 1, 5 or 10 s; 5 or 25 ml injected over 1 s. On-line PA ICG concentrations were recorded for approximately 60 s using a densitometer. The mean maximum PA ICG concentrations (2-8 mg litre-1), the mean times at which they occurred (7-18 s after injection) and the time lags before ICG was detected in the PA (4-9 s), were inversely related to cardiac output, but linearly related to the time over which the injection was made. The area under the curve of the peak was related inversely to cardiac output only, while the aspect ratio of the peak was related inversely to the time over which the injection was made only. The injectate volume had no effect on any of the measured values. We conclude that, in some circumstances, the rate of injection of drugs with narrow margins of safety should be tailored to the cardiac output of an individual.     

Units of DNA replication in S-phase human cells

Current methods of physical mapping allow the estimation of genomic distances (i.e. DNA contents) from linear distances between DNA markers in interphase nuclei, and in this study we estimated the size of focal centers of DNA replication in cultured S-phase human cells. Our results indicate that the conformation of S-phase chromosome fibres in the range of contour lengths 0.1-3.0 microns fits the random walk model and, therefore, the quantitative methods of interphase mapping can be applied to the estimation of sizes of replication units. The obtained data show the existence of multiple non-clustered small units less than 150 kb in size, equivalent to small replicons detected by fiber DNA radioautography, and also a significant fraction of big units more than 500 kb in size, representing groups of small replicons and/or big replicons. These big units are detected as chains of small replication foci, probably reflecting the structural chromatin organization in well-known loop domains, since the experimentally induced decrease of replicons to the average size 12 kb does not lead to any change in the pattern of indicated chains.     

Origin-specific initiation of mammalian nuclear DNA replication in a Xenopus cell-free system

Mean field analysis of FKBP12 complexes with FK506 and rapamycin has been performed by using structures obtained from molecular docking simulations on a simple, yet robust molecular recognition energy landscape. When crystallographic water molecules are included in the simulations as an extension of the FKBP12 protein surface, there is an appreciable stability gap between the energy of the native FKBP12-FK506 complex and energies of conformations with the "native-like" binding mode. By contrast, the energy spectrum of the FKBP12-rapamycin complex is dense regardless of the presence of the water molecules. The stability gap in the FKBP12-FK506 system is determined by two critical water molecules from the effector region that participate in a network of specific hydrogen bond interactions. This interaction pattern protects the integrity and precision of the composite ligand-protein effector surface in the binary FKBP12-FK506 complex and is preserved in the crystal structure of the FKBP12-FK506-calcineurin ternary complex. These features of the binding energy landscapes provide useful insights into specific and nonspecific aspects of FK506 and rapamycin recognition.     

Convenient plasmid for extrachromosomal DNA recombination in mouse cells

We constructed a convenient plasmid for DNA recombination assay. The plasmid, pMR1, contains a double prokaryotic terminator to decrease the background and two unique restriction enzyme sites on both sides of the double terminator to allow for easy construction. The assay is capable of selecting the bacterial cells containing recombined plasmid DNA on a selective plate containing ampicillin and chloramphenicol. We adapted pMR1 for V(D)J recombination and homologous recombination and detected both types of recombination in murine PreB cell line. As pMR1 has the double terminator, background on the selective plate decreases effectively and we select only the recombined clones. We consider the vector, pMR1, to be convenient for the analysis of homologous and non-homologous recombinations.     

Three novel plasmid R6K proteins act in concert to distort DNA within the alpha and beta origins of DNA replication

Three novel R6K genes which are responsible for expression of DNA distortion polypeptides (DDP) were identified. The DDPs act in vivo in concert to induce similar stepwise DNA helix distortions within two long inverted repeats (alpha LIR and beta LIR), which are essential elements for the two distally located R6K alpha and beta DNA replication origins. DDP1 and DDP2 are encoded by two tandem genes located at the 5' end of alpha LIR, whereas a gene coding for DDP3 is located at the 3' end of beta LIR. DDP1 and DDP2 are required for primary DNA distortion within alpha LIR or beta LIR, while DDP3 is essential for generation of secondary DNA distortion in these LIR sequences. Creation of DNA distortion within alpha LIR depends on its specific interaction with DDP1 and on the presence of the R6K primase DNA-binding site. The possible relevance of these findings to R6K replication is discussed.     

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.     

The structure of supercoiled intermediates in DNA replication

We studied the structure of replication intermediates accumulated by Tus-induced arrest of plasmid DNA replication at termination sites. For intermediates generated both in vitro with purified components and in vivo, superhelical stress is distributed throughout the entire partially replicated molecule; daughter DNA segments are wound around each other, and the unreplicated region is supercoiled. Thus, unlinking of parental DNA strands by topoisomerases can be carried out both behind and in front of the replication fork. We explain why previous studies with prokaryotic and eukaryotic replication intermediates discerned only supercoiling in the unreplicated portion.     

Eukaryotic DNA polymerases in DNA replication and DNA repair

DNA polymerases carry out a large variety of synthetic transactions during DNA replication, DNA recombination and DNA repair. Substrates for DNA polymerases vary from single nucleotide gaps to kilobase size gaps and from relatively simple gapped structures to complex replication forks in which two strands need to be replicated simultaneously. Consequently, one would expect the cell to have developed a well-defined set of DNA polymerases with each one uniquely adapted for a specific pathway. And to some degree this turns out to be the case. However, in addition we seem to find a large degree of cross-functionality of DNA polymerases in these different pathways. DNA polymerase alpha is almost exclusively required for the initiation of DNA replication and the priming of Okazaki fragments during elongation. In most organisms no specific repair role beyond that of checkpoint control has been assigned to this enzyme. DNA polymerase delta functions as a dimer and, therefore, may be responsible for both leading and lagging strand DNA replication. In addition, this enzyme is required for mismatch repair and, together with DNA polymerase zeta, for mutagenesis. The function of DNA polymerase epsilon in DNA replication may be restricted to that of Okazaki fragment maturation. In contrast, either polymerase delta or epsilon suffices for the repair of UV-induced damage. The role of DNA polymerase beta in base-excision repair is well established for mammalian systems, but in yeast, DNA polymerase delta appears to fulfill that function.     

Reiterated DNA fragments in defective genomes of Autographa californica nuclear polyhedrosis virus are competent for AcMNPV-dependent DNA replication

We previously reported on the generation of approximately 50-kb size defective genomes (DGs) which appeared to retain less than 2.2% of the standard Autographa californica nuclear polyhedrosis virus (AcMNPV) DNA between 85.0 and 87.2 MU while the rest of the virus DNA had been largely deleted (Lee and Krell, J. Virol., 66:4339-4347, 1992). To investigate these presumably repeated sequences further, we cloned and analyzed the most abundant hypermolar 1.80-kb Xhol DNA fragment as well as a minor but also supermolar 1.74-kb Xhol fragment of the DGs. These two DNA segments collectively covered 2371-bp of the standard AcMNPV DNA with a 1174-bp overlap around the Xhol site at 85.9 MU. Analysis of DGs by two-dimensional gel electrophoresis indicated that the 1.80- and 1.74-kb Xhol fragments (and most other novel Xhol fragments of the DG) were organized as tandem repeats in the DGs. We identified, in the DG population, small supercoiled DNA molecules approximately 1.0- to 8.2-kb (and possibly up to around 50 kb, the size of the major defective DNA species) in size and which contained the same DNA sequence as that of the major 1.80-kb repeat in the DGs. Furthermore, these cloned repeat sequences, represented by pLK1.80 and pLK1.74 showed AcMNPV infection-dependent autonomous replication, suggesting that an origin of DNA replication might reside within the HindIII to EcoRI segment (85.1 to 86.6 MU) of the HindIII-K fragment.     

The influence of DNA sequence on the immunostimulatory properties of plasmid DNA vectors

To determine the influence of DNA sequence on immunostimulatory properties of vaccine vectors, we tested the induction of in vitro and in vivo immune responses by plasmids modified to contain extended runs of dG sequences. Studies with oligonucleotides indicate that dG sequences can directly stimulate B cells as well as enhance the activity of immunostimulatory CpG motifs because of interaction with the macrophage scavenger receptor (MSR); this receptor can bind a variety of polyanions including dG sequences. To modify vectors, we introduced stretches of 20-60 dG residues into the pCMV-beta and pSG5rab.gp vectors and measured the ability of these plasmids to induce IL-12 and IFN-gamma production by murine splenocytes. The induction of in vivo antibody responses to rabies glycoprotein was also assessed with the pSG5rab.gp vectors. In in vitro cultures, cytokine production induced by plasmids with and without dG sequences was similar. Furthermore, the addition of dG sequences to pSG5rab.gp vectors failed to enhance the anti-rabies glycoprotein response to immunization. To assess further mechanisms by which plasmids stimulate macrophages, we measured the effects of MSR ligands on in vitro cytokine induction. In in vitro cultures, poly(G), dG30, and fucoidan inhibited IL-12 induction by plasmids. IL-12 induction was also inhibited by mammalian DNA but was unaffected by polyanions that are not MSR ligands. Together, these results suggest that the addition of 20 to 60-base dG sequences to plasmids does not significantly affect their properties as immunostimulators or vaccines. Furthermore, these results suggest that MSR ligands can block cytokine induction by plasmid DNA whether or not the plasmid contains extended runs of dG.     

Generation of conditional mutants in higher eukaryotes by switching between the expression of two genes

A regulatory system for the in-depth study of gene functions in higher eukaryotic cells has been developed. It is based on the tetracycline-controlled transactivators and reverse tTA, which were remodeled to discriminate efficiently between two different promoters. The system permits one to control reversibly the activity of two genes, or two alleles of a gene, in a mutually exclusive way, and also allows one to abrogate the activities of both. This dual regulatory circuit, which can be operated by a single effector substance such as doxycycline, overcomes limitations of conventional genetic approaches. The conditional mutants that can now be generated will be useful for the study of gene function in vitro and in vivo. In addition, the system may be of value for a variety of practical applications, including gene therapy.     

Gene conversion in the chicken immunoglobulin locus: a paradigm of homologous recombination in higher eukaryotes

Gene conversion was first defined in yeast as a type of homologous recombination in which the donor sequence does not change. In chicken B cells, gene conversion builds the antigen receptor repertoire by introducing sequence diversity into the immunoglobulin genes. Immunoglobulin gene conversion continues at high frequency in an avian leukosis virus induced chicken B cell line. This cell line can be modified by homologous integration of transfected DNA constructs offering a model system for studying gene conversion in higher eukaryotes. In search for genes which might participate in chicken immunoglobulin gene conversion, we have identified chicken counterparts of the yeast RAD51, RAD52, and RAD54 genes. Disruption and overexpression of these genes in the chicken B cell line may clarify their role in gene conversion and gene targeting.     

Utilization of the same DNA replication origin by human cells of different derivation

In the past, a highly sensitive and efficient method was developed to map DNA replication origins in human cells, based on quantitative PCR performed on nascent DNA samples. This method allowed the identification of a replication origin in the myeloid HL-60 cell line, located on chromosome 19 within an approximately 500 bp segment near the lamin B2 gene [Giacca et al. (1994) Proc. Natl. Acad. Sci. USA, 91, 7119]. The same procedure has now been further simplified and extended to a variety of other exponentially growing human cells of different histological derivation (three neural, one connectival and one epithelial), with a nearly diploid chromosomal content. In all the six cell lines tested, the origin activity within the lamin B2 gene domain was localized to the same region. Furthermore, the lamin B2 origin was also found to be active in stimulated, but not in quiescent, peripheral blood lymphocytes.     

Function of DnaA protein, the initiator for chromosomal DNA replication in E. coli]

DnaA protein is an initiator for chromosomal DNA replication in E. coli. We have examined the function of the protein to answer the following four questions; 1. How DnaA protein is inactivated after DNA replication for the suppression of re-initiation? 2. How DnaA protein is activated for the initiation of DNA replication? 3. Does DnaA protein have functions other than that for DNA replication? 4. Is DnaA protein is a good target for new antibiotics? In this review, I summarize our recent studies for these questions.     

A nuclear membrane-associated DNA complex in cultured mammalian cells capable of synthesizing DNA in vitro

A DNA-nuclear membrane complex has been isolated by two different methods from the nuclei of cultured mouse fibroblast (3T3) cells. One method, utilizing the detergent sarkosyl (sodium lauroyl sarkosinate), yields a DNA-nuclear membrane complex (the M band), which contains virtually all of the DNA in the nuclei. However, treatment of the M band by sonication, vortexing, or freeze-thaw reduces the amount of DNA in the complex by approximately 50-80%, depending upon the phase of the cell cycle from which the complex was extracted. The remaining DNA is tightly bound to the nuclear membrane and resists further shearing procedures. Over 90% of the choline-labeled phospholipid present in nuclei is also found in these sheared M bands. The percentage of DNA associated with the nuclear membrane varies during the cell cycle and correlates well with the onset, continuation, and cessation of DNA synthesis. Thus, although DNA-membrane complexes can be detected throughout the cell cycle, the percentage of DNA bound to membrane increases during late G1 and S and decreases during G2. In addition, there are distinct qualitative differences in the type of DNA present in the membrane fraction, with a more highly d(A-T) rich DNA being present in confluent (G0) cells than in cells during the S phase. This d(A-T) rich DNA may be related to the mouse satellite DNA identified by others. The M band can be separated into two DNA-nuclear membrane subfractions by centrifugation through a continuous sucrose gradient. The relative proportions of these two subfractions depend upon the percentage of sarkosyl present in the M band prior to centrifugation, with complete removal of sarkosyl resulting in a very large increase in the sedimentation velocity of the complex and in the formation of only one fraction. Evidence that this is a complex of DNA with membrane is given by the finding that DNA is dissociated from the complex with Pronase, deoxycholate, or high levels of sarkosyl. Removal of virtually all of the DNA with DNase from this rapidly sedimenting complex does not dissociate any of the phospholipid which still sediments rapidly as a single band. A second method, which yields a DNA-membrane fraction from nuclei, utilizes sedimentation of lysed nuclei to equilibrium in CsCl density gradients. This low-density CsCl fraction contains only 10-15% of the total DNA, but contains most of the nascent DNA, which may be chased into a membrane-free fraction. The DNA-membrane fraction from CsCl gradients possesses properties in common with the M-band fraction and can be converted into an M band. DNA membrane complexes from sucrose gradients, as well as the crude M-band preparation and a non-membrane-associated DNA fraction from nuclei can synthesize DNA in vitro without the addition of an external DNA template or DNA polymerase. In contrast to the activity in the non-membrane-associated DNA fraction, the membrane-associated polymerase activity is strongly stimulated by adenosine triphosphate and is unaffected by ethidium bromide...