Mapping sequences in loops of nuclear DNA by their progressive detachment from the nuclear cage.

Nuclear DNA is organised into loops, probably by attachment to a supramolecular structure. We describe a method which enables us to map the position of sequences within a loop relative to the point of attachment. Nuclear DNA is isolated unbroken by lysing HeLa cells in 2M NaCl to release structures which retain many of the morphological features of nuclei. Their DNA is supercoiled and so must remain unbroken and looped during lysis. Nucleoids are digested to various degrees with a restriction endonuclease and the cages - and any associated DNA - sedimented free from unattached DNA. The cage-associated DNA is purified and completely fragmented using the same restriction endonuclease. Equal weights of fragmented DNA are separated by gel electrophoresis, transferred to a filter and the relative amounts of the alpha, beta and gamma globin genes on the filter determined by hybridisation to the appropriate probes. The alpha genes, unlike the beta and gamma genes, resist detachment from the cage and so must lie close to the point of attachment to the cage. Our ability to map these genes implies that sequences cannot be attached at random to the cage; rather, specific sequences must be attached, so looping the DNA.     

Sequence specificity of cytosine methylation in the DNA of the Chinese hamster ovary (CHO-K1) cell line

We have determined the DNA renaturation kinetics for those DNA sequences of the Chinese hamster ovary (CHO-K1) cells in which enzymatic cytosine methylation occurred immediately after strand synthesis and for those in which methylation was delayed after strand synthesis. DNA sequences showing immediate or delayed methylation were found to be distributed throughout all repetition classes of the DNA of these cells, with a slight concentration of immediate methylation in moderately repetitive sequences and with delayed methylation being slightly over-represented in the highly repetitive fraction. However, DNA sequences showing both classes of methylation were represented equally in unique DNA sequences. We interpret these data to mean that the methylase acting near the replication forks (the 'immediate' methylase) is a relatively inefficient enzyme, missing some 20% of hemimethylated sites produced by DNA replication in these cells. We suggest that the methylase performing maintenance methylation at sites remote from the replication forks (the 'delayed' methylase) is simply a back-up enzyme for the first and that it has no true sequence specificity. The implications of this for the function(s) of DNA methylation in mammalian cells are discussed.     

Sequence specificity of cytosine methylation in the DNA of the Chinese hamster ovary (CHO-K1) cell line

We have determined the DNA renaturation kinetics for those DNA sequences of the Chinese hamster ovary (CHO-K1) cells in which enzymatic cytosine methylation occurred immediately after strand synthesis and for those in which methylation was delayed after strand synthesis. DNA sequences showing immediate or delayed methylation were found to be distributed throughout all repetition classes of the DNA of these cells, with a slight concentration of immediate methylation in moderately repetitive sequences and with delayed methylation being slightly over-represented in the highly repetitive fraction. However, DNA sequences showing both classes of methylation were represented equally in unique DNA sequences. We interpret these data to mean that the methylase acting near the replication forks (the ‘immediate’ methylase) is a relatively inefficient enzyme, missing some 20% of hemimethylated sites produced by DNA replication in these cells. We suggest that the methylase performing maintenance methylation at sites remote from the replication forks (the ‘delayed’ methylase) is simply a back-up enzyme for the first and that it has no true sequence specificity. The implications of this for the function(s) of DNA methylation in mammalian cells are discussed.     

Two-base DNA hairpin-loop structures in vivo.

In vitro studies have revealed that DNA hairpin-loops usually contain four unpaired bases. However, a small subset of sequences can form two-base loops. We have previously described an in vivo assay that is sensitive to tight loop formation and have set out to test whether DNA sequences known to form two-base loops in vitro also form tight loops in vivo. It is shown that the sequences 5'dCNNG and 5'dTNNA behave as predicted if they favour two-base loop formation in vivo, a result that is consistent with previously described in vitro studies. The ability of specific DNA sequences to form tight loops in vivo has implications for their potential to form transient structures involved in gene regulation, recombination and mutagenesis.     

Displacement synthesis of globin complementary DNA: evidence for sequence amplification

We have examined a cDNA displacement synthesis procedure in which the extent of precursor incorporation and the unusual kinetics of displacement synthesis suggest a unique replicative form of DNA and the occurrence of multiple rounds of displacement synthesis, leading to amplification of mRNA sequences. Globin double-stranded DNA containing a hairpin loop was extended by the addition of a homopolymer to the 3' end. This was followed by displacement synthesis with the Klenow fragment of DNA polymerase I that was primed by an oligonucleotide hybridized to the homopolymer. Thus, the hairpin cDNA was copied to form an open duplex with an inverted repetition of globin sequences. These molecules can then serve as templates for additional synthesis which would be primed from oligomers bound the homopolymer. Globin cDNA sequences appear to be amplified 10-fold or more by this procedure. Globin cDNA obtained by displacement synthesis was similar in size to the original template. However, displaced molecules associate to the extent that they are not readily resolved by electrophoresis or sedimentation under nondenaturing conditions. Restriction endonuclease digests of 32P-labeled displaced strands gave fragment patterns similar to rabbit globin cDNA hairpin molecules. S1 nuclease studies demonstrated that displaced complexes and replication intermediates are partially single stranded, which might account for their aggregation properties.     

Titles of related papers in other sections

We have examined a cDNA displacement synthesis procedure in which the extent of precursor incorporation and the unusual kinetics of displacement synthesis suggest a unique replicative form of DNA and the occurrence of multiple rounds of displacement synthesis, leading to amplification of mRNA sequences. Globin double-stranded DNA containing a hairpin loop was extended by the addition of a homopolymer to the 3′ end. This was followed by displacement synthesis with the Klenow fragment of DNA polymerase I that was primed by an oligonucleotide hybridized to the homopolymer. Thus, the hairpin cDNA was copied to form an open duplex with an inverted repetition of globin sequences. These molecules can then serve as templates for additional synthesis which would be primed from oligomers bound the homopolymer. Globin cDNA sequences appear to be amplified 10-fold or more by this procedure. Globin cDNA obtained by displacement synthesis was similar in size to the original template. However, displaced molecules associate to the extent that they are not readily resolved by electrophoresis or sedimentation under nondenaturing conditions. Restriction endonuclease digests of ³²P-labeled displaced strands gave fragment patterns similar to rabbit globin cDNA hairpin molecules. S₁ nuclease studies demonstrated that displaced complexes and replication intermediates are partially single stranded, which might account for their aggregation properties.     

Remodeling of chromatin loops does not account for specification of replication origins during Xenopus development

We have investigated the possible relationship between replicons and chromatin loops during Xenopus development. In early embryos, replication of the ribosomal RNA genes (rDNA) can initiate at apparently any sequence. Nevertheless, the need for a regular spacing of replication origins suggests that some periodic chromatin folding might dictate which sites are actually used for initiation. After the midblastula transition, replication initiation is restricted to the rDNA intergenic spacers. A remodeling of chromatin folding could account for this change in origin usage. Here, it is reported that nuclear matrix anchorage of the Xenopus rDNA occurs at multiple, apparently random sequences, throughout embryonic development as well as in adult cells. In vitro matrix rebinding assays confirmed the lack of specific anchoring sequences in the rDNA, before as well as after specific replication origins are established. Thus, no change in loop attachment sites could explain the change in origin usage at this locus. Nonspecific loop anchorage was a special feature of the rDNA locus, since the same nuclear matrices were able selectively to bind the scaffold attachment region (SAR) of the Drosophila histone gene cluster in vitro. Blastula and gastrula nuclear matrices bound a higher amount of SAR sequences than matrices from later stages or adult cells. This developmental change in SAR binding might explain the increase in size of the bulk of genomic DNA loops that occurs after the gastrula stage. However, no change in chromatin loop organization that could explain the midblastula stage transition from small to large replicons was observed. Received: 15 January 1998; in revised form: 4 March 1998 / Accepted: 9 March 1998     

Depletion of cellular pre-replication complex factors results in increased human cytomegalovirus DNA replication

Although HCMV encodes many genes required for the replication of its DNA genome, no HCMV-encoded orthologue of the origin binding protein, which has been identified in other herpesviruses, has been identified. This has led to speculation that HCMV may use other viral proteins or possibly cellular factors for the initiation of DNA synthesis. It is also unclear whether cellular replication factors are required for efficient replication of viral DNA during or after viral replication origin recognition. Consequently, we have asked whether cellular pre-replication (pre-RC) factors that are either initially associated with cellular origin of replication (e.g. ORC2), those which recruit other replication factors (e.g. Cdt1 or Cdc6) or those which are subsequently recruited (e.g. MCMs) play any role in the HCMV DNA replication. We show that whilst RNAi-mediated knock-down of these factors in the cell affects cellular DNA replication, as predicted, it results in concomitant increases in viral DNA replication. These data show that cellular factors which initiate cellular DNA synthesis are not required for the initiation of replication of viral DNA and suggest that inhibition of cellular DNA synthesis, in itself, fosters conditions which are conducive to viral DNA replication.     

Nuclear matrix support of DNA replication

In higher eukaryotic cells, DNA is tandemly arranged into 10(4) replicons that are replicated once per cell cycle during the S phase. To achieve this, DNA is organized into loops attached to the nuclear matrix. Each loop represents one individual replicon with the origin of replication localized within the loop and the ends of the replicon attached to the nuclear matrix at the bases of the loop. During late G1 phase, the replication origins are associated with the nuclear matrix and dissociated after initiation of replication in S phase. Clusters of several replicons are operated together by replication factories, assembled at the nuclear matrix. During replication, DNA of each replicon is spooled through these factories, and after completion of DNA synthesis of any cluster of replicons, the respective replication factories are dismantled and assembled at the next cluster to be replicated. Upon completion of replication of any replicon cluster, the resulting entangled loops of the newly synthesized DNA are resolved by topoisomerases present in the nuclear matrix at the sites of attachment of the loops. Thus, the nuclear matrix plays a dual role in the process of DNA replication: on one hand, it represents structural support for the replication machinery and on the other, provides key protein factors for initiation, elongation, and termination of the replication of eukaryotic DNA.     

Rolling-circle replication of bacterial plasmids.

Many bacterial plasmids replicate by a rolling-circle (RC) mechanism. Their replication properties have many similarities to as well as significant differences from those of single-stranded DNA (ssDNA) coliphages, which also replicate by an RC mechanism. Studies on a large number of RC plasmids have revealed that they fall into several families based on homology in their initiator proteins and leading-strand origins. The leading-strand origins contain distinct sequences that are required for binding and nicking by the Rep proteins. Leading-strand origins also contain domains that are required for the initiation and termination of replication. RC plasmids generate ssDNA intermediates during replication, since their lagging-strand synthesis does not usually initiate until the leading strand has been almost fully synthesized. The leading- and lagging-strand origins are distinct, and the displaced leading-strand DNA is converted to the double-stranded form by using solely the host proteins. The Rep proteins encoded by RC plasmids contain specific domains that are involved in their origin binding and nicking activities. The replication and copy number of RC plasmids, in general, are regulated at the level of synthesis of their Rep proteins, which are usually rate limiting for replication. Some RC Rep proteins are known to be inactivated after supporting one round of replication. A number of in vitro replication systems have been developed for RC plasmids and have provided insight into the mechanism of plasmid RC replication.     

AT-rich region and repeated sequences - the essential elements of replication origins of bacterial replicons

Repeated sequences are commonly present in the sites for DNA replication initiation in bacterial, archaeal, and eukaryotic replicons. Those motifs are usually the binding places for replication initiation proteins or replication regulatory factors. In prokaryotic replication origins, the most abundant repeated sequences are DnaA boxes which are the binding sites for chromosomal replication initiation protein DnaA, iterons which bind plasmid or phage DNA replication initiators, defined motifs for site-specific DNA methylation, and 13-nucleotide-long motifs of a not too well-characterized function, which are present within a specific region of replication origin containing higher than average content of adenine and thymine residues. In this review, we specify methods allowing identification of a replication origin, basing on the localization of an AT-rich region and the arrangement of the origin's structural elements. We describe the regularity of the position and structure of the AT-rich regions in bacterial chromosomes and plasmids. The importance of 13-nucleotide-long repeats present at the AT-rich region, as well as other motifs overlapping them, was pointed out to be essential for DNA replication initiation including origin opening, helicase loading and replication complex assembly. We also summarize the role of AT-rich region repeated sequences for DNA replication regulation.     

Affinity and sequence specificity of DNA binding and site selection for primer synthesis by Escherichia coli primase

Primase is an essential DNA replication enzyme in Escherichia coli and responsible for primer synthesis during lagging strand DNA replication. Although the interaction of primase with single-stranded DNA plays an important role in primer RNA and Okazaki fragment synthesis, the mechanism of DNA binding and site selection for primer synthesis remains unknown. We have analyzed the energetics of DNA binding and the mechanism of site selection for the initiation of primer RNA synthesis on the lagging strand of the replication fork. Quantitative analysis of DNA binding by primase was carried out using a number of oligonucleotide sequences: oligo(dT)(25) and a 30 bp oligonucleotide derived from bacteriophage G4 origin (G4ori-wt). Primase bound both sequences with moderate affinity (K(d) = 1.2-1.4 x 10(-)(7) M); however, binding was stronger for G4ori-wt. G4ori-wt contained a CTG trinucleotide, which is a preferred site for initiation of primer synthesis. Analysis of DNA binding isotherms derived from primase binding to the oligonucleotide sequences by fluorescence anisotropy indicated that primase bound to DNA as a dimer, and this finding was further substantiated by electrophoretic mobility shift assays (EMSAs) and UV cross-linking of the primase-DNA complex. Dissection of the energetics involved in the primase-DNA interaction revealed a higher affinity of primase for DNA sequences containing the CTG triplet. This sequence preference of primase may likely be responsible for the initiation of primer synthesis in the CTG triplet sites in the E. coli lagging strand as well as in the origin of replication of bacteriophage G4.     

Identification of the stable DNA-matrix complex (type II) as a site of replication fork

The two types of DNA-matrix complexes (the weak and tight ones, or type I and type II, respectively) identified in our previous work were studied with respect to their involvement in DNA replication. Nuclei isolated from human fibrosarcoma HT1080 cell line were treated with either restriction endonucleases or ultrasonic desintegrator and afterwards subjected to the triple-gradient Nucleoprotein--Celite chromatography. This permitted fractionation of nuclear DNA into fragments not attached, weakly attached, and tightly attached to the nuclear matrix (DNA 0, DNA I, and DNA II, respectively). It was shown that pulse labelled RNA migrates from DNA II fraction where it resides initially to DNA 0 and further to DNA I during the 2 h chase period. This finding allowed us to consider the tight DNA-matrix complex as the replicative one. The experiments aiming to follow the movements of specific DNA sequences (histone genes) in relation to the DNA-matrix attachment sites were conducted on synchronous HT1080 cells progressing through S phase. The histone sequences appeared to undergo similar movements during the first 30 min of S phase. They reside initially in DNA 0 and DNA I fractions, but as soon as DNA synthesis was restored they migrate consequently to DNA II and DNA 0 fractions. This approach can appear to be a useful tool for studying the schedule of replication of specific genes during S phase.     

The Cik1/Kar3 motor complex is required for the proper kinetochore-microtubule interaction after stressful DNA replication

In budding yeast Saccharomyces cerevisiae, kinetochores are attached by microtubules during most of the cell cycle, but the duplication of centromeric DNA disassembles kinetochores, which results in a brief dissociation of chromosomes from microtubules. Kinetochore assembly is delayed in the presence of hydroxyurea, a DNA synthesis inhibitor, presumably due to the longer time required for centromeric DNA duplication. Some kinetochore mutants are sensitive to stressful DNA replication as these kinetochore proteins become essential for the establishment of the kinetochore-microtubule interaction after treatment with hydroxyurea. To identify more genes required for the efficient kinetochore-microtubule interaction under stressful DNA replication conditions, we carried out a genome-wide screen for yeast mutants sensitive to hydroxyurea. From this screen, cik1 and kar3 mutants were isolated. Kar3 is the minus-end-directed motor protein; Cik1 binds to Kar3 and is required for its motor function. After exposure to hydroxyurea, cik1 and kar3 mutant cells exhibit normal DNA synthesis kinetics, but they display a significant anaphase entry delay. Our results indicate that cik1 cells exhibit a defect in the establishment of chromosome bipolar attachment in the presence of hydroxyurea. Since Kar3 has been shown to drive the poleward chromosome movement along microtubules, our data support the possibility that this chromosome movement promotes chromosome bipolar attachment after stressful DNA replication.     

Distinct characteristics of loop sequences of two Drosophila foldback transposable elements.

A few foldback (FB) transposable elements have, between their long terminal inverted repeats, central loop sequences which have been shown to be different from FB inverted repeat sequences. We have investigated loop sequences from two such FB elements by analyzing their genomic distribution and sequence conservation and, in particular, by determining if they are normally associated with FB elements. One of these FB loop sequences seems to be present in a few conserved copies found adjacent to FB inverted repeat sequences, suggesting that it represents an integral component of some FB elements. The other loop sequence is less well-conserved and not usually associated with FB inverted repeats. This sequence is a member of another family of transposable elements, the HB family, and was found inserted in an FB element only by chance. We compare the complete DNA sequences of two HB elements and examine the ends of four HB elements.     

Aphidicolin inhibition of the production of replicative-form DNA during bovine parvovirus infection.

Since parvoviruses apparently do not possess a DNA polymerase activity, one or more of the host cell DNA polymerases must be responsible for replicating the single-stranded DNA genome. We have focused on determining which polymerase, alpha, beta, or gamma (pol alpha, pol beta, or pol gamma, respectively), is responsible for the first step in bovine parvoviral DNA replication: conversion of the single-stranded DNA genome to a parental replicative form (RF). In this study, we used aphidicolin, a specific inhibitor of DNA pol alpha, to assay for the requirement of pol alpha activity in parental RF formation in vivo. Synchronized cell cultures were infected with bovine parvovirus with or without aphidicolin, and the products of viral replication were separated on agarose gels and identified by Southern blot analysis. We found that complete inhibition of viral DNA synthesis resulted when 20 microM aphidicolin was present throughout the infection. In addition, viral DNA synthesis was inhibited by as little as 1 microM aphidicolin, whereas lower concentrations (0.1 and 0.01 microM) resulted in partial inhibition of the replication process. Using 32P-labeled bovine parvovirus as the input virus we differentiated parental RF from daughter RF and progeny DNA synthesis. We conclude that DNA pol alpha is required for the production of RF during bovine parvovirus replication in vivo and that this requirement is most likely for the conversion of bovine parvovirus input single-stranded DNA to parental RF. These results do not rule out a possible role for DNA pol gamma in the first step, nor do they rule out a role for pol alpha or pol gamma in later stages of the replication cycle.     

DNA intermediates in transposition of phage Mu

Transposable genetic elements can insert into DNA sites that have no homology to themselves. Evidence that there is a physical linkage between a transposable element and its target DNA sequence during transposition comes from studies on bacteriophage Mu DNA transposition in which plasmids containing Mu DNA have been shown to attach to host DNA. We report the isolation of key structures, seen after induction of Mu DNA replication, after cloning lac operator into Mu DNA and using the lac repressor-operator interaction to trap Mu DNA on nitrocellulose filters. We have localized Mu sequences within these structures in the electron microscope by visualizing the lac operator-repressor interaction after binding with ferritin-conjugated antibody. This analysis shows that key structures contain replicating Mu DNA linked to non-Mu DNA and that replication can begin at either end of Mu.     

Bacteriophage T4 proteins replicate plasmids with a preformed R loop at the T4 ori(uvsY) replication origin in vitro

Bacteriophage T4 DNA replication proteins catalyze complete unidirectional replication of plasmids containing the T4 ori(uvsY) replication origin in vitro, beginning with a preformed R loop at the position of the origin R loop previously identified in vivo. T4 DNA polymerase, clamp, clamp loader, and 32 protein are needed for initial elongation of the RNA, which serves as the leading-strand primer. Normal replication is dependent on T4 41 helicase and 61 primase and is strongly stimulated by the 59 helicase loading protein. 59 protein slows replication without the helicase. As expected, leading-strand synthesis stalls prematurely in the absence of T4 DNA topoisomerase. A DNA unwinding element (DUE) is essential for replication, but the ori(uvsY) DUE can be replaced by other DUE sequences.