Regulated replication of DNA microinjected into eggs of Xenopus laevis

Purified circular DNA of SV40 or polyoma virus has been injected into unfertilized eggs of Xenopus laevis. Injected DNA initiates and completes multiple rounds of semiconservative replication while observing cellular regulatory signals. Thus replication initiation of double-stranded templates is induced after the oocyte is matured in vitro by progesterone. Only one round of replication of injected DNA is observed in a single cell cycle. When protein synthesis is inhibited unreplicated molecules continue to initiate replication at an undiminished rate, but reinitiation on previously replicated molecules is completely and selectively abolished. The DNA sequence requirements for the replication of injected DNA have been investigated. A variety of procaryotic DNA molecules and circularized fragments of SV40 or polyoma DNA replicate, regardless of whether they contain the viral origin of DNA replication. These results suggest that a specialized DNA sequence is not essential for the initiation of semiconservative DNA replication in the Xenopus embryo, nor is a specialized sequence essential for the mechanism which prevents reinitiation on a molecule which has already replicated within a cell cycle. The possibility is discussed that viral origins of replication are not valid models for the eucaryotic chromosome but are adaptations for uncoupling viral replication from the mechanism which prevents reinitiation within a cell cycle.     

The replication behavior of Saccharomyces cerevisiae DNA in human cells

We studied the replication of random genomic DNA fragments from Saccharomyces cerevisiae in a long-term assay in human cells. Plasmids carrying large yeast DNA fragments were able to replicate autonomously in human cells. Efficiency of replication of yeast DNA fragments was comparable to that of similarly sized human DNA fragments and better than that of bacterial DNA. This result suggests that yeast genomic DNA contains sequence information needed for replication in human cells. To examine whether DNA replication in human cells would initiate specifically at a yeast origin of replication, we monitored initiation on a plasmid containing the yeast 2-micron autonomously replicating sequence (ARS) in yeast and human cells. We found that while replication initiates at the 2-micron ARS in yeast, it does not preferentially initiate at the ARS in human cells. This result suggests that the sequences that direct site specific replication initiation in yeast do not function in the same way in human cells, which initiate replication at a broader range of sequences.by J.A. Huberman     

Identification of cis-acting elements that mediate the replication and maintenance of human papillomavirus type 16 genomes in Saccharomyces cerevisiae

Papillomaviruses contain small double-stranded DNA genomes that are maintained in persistently infected mammalian host epithelia as nuclear plasmids and rely upon the host replication machinery for replication. Papillomaviruses encode a DNA helicase, E1, which can specifically bind to the viral genome and support DNA synthesis. Under some conditions in mammalian cells, E1 is not required for viral DNA synthesis, leading to the hypothesis that papillomavirus DNA can be replicated solely by the host replication machinery. This machinery is highly conserved among eukaryotes. We and others found that papillomavirus DNA could replicate in a simple eukaryote, Saccharomyces cerevisiae. Specifically, papillomavirus DNA could substitute for the function of the autonomously replicating sequence (ARS) and centromere (CEN) elements that are normally both required for the stable replication of extrachromosomal DNAs in yeast. Furthermore, this form of replication in yeast was E1 independent. In this study, we map the elements in the human papillomavirus type 16 (HPV16) genome that can substitute for yeast ARS and CEN elements. A single element, termed rep, was identified that can substitute for ARS, and multiple elements, termed mtc, could substitute for CEN. The location of one of these mtc elements overlaps the location of rep, and this approximately 1,000-bp region of HPV16 was sufficient to support stable replication of a bacterial-yeast shuttle plasmid deleted of both ARS and CEN elements.     

Fine-structure analysis of the DNA sequence requirements for autonomous replication of Saccharomyces cerevisiae plasmids.

An autonomously replicating segment, ARS, is located 293 base pairs downstream from the histone H4 gene at the copy-I H3-H4 locus. The sequences needed for autonomous replication were defined by deletion analysis to include an ARS consensus sequence and an additional 3'-flanking region. External deletions into the 3'-flanking yeast sequences resulted in a loss of replication function. However, disruptions of the required 3'-flanking domain by either 10-base-pair linker-scanning substitutions or larger internal deletions did not impair autonomous replication. Thus, replication is dependent upon a flanking chromosome domain, but not an exact DNA sequence. The extent of the yeast sequences required in the 3'-flanking domain is variable depending on the nature of neighboring plasmid vector sequences. That is, there are certain vector sequences that prohibit replication when they are placed too close to the ARS consensus. These results suggest that the functional 3'-flanking domain of the H4 ARS is a specific DNA or chromatin structure or both.     

Replication analysis of plasmid DNAs injected into Drosophila embryos

From a shotgun collection of DNA fragments, isolated from Drosophila melanogaster, we selected sequences that function as autonomously replicating sequences (ARS) in the yeast Saccharomyces cerevisiae. To investigate the replicative potential of such sequences in Drosophila, five of these ARS elements and also the Adh gene of D. melanogaster, which has been described earlier to have ARS function in yeast, were microinjected into developing Drosophila eggs and analysed after reisolation from first instar larvae. As an assay for DNA replication, we determined the sensitivity of recovered plasmid DNA to restriction enzymes that discriminate between adenine methylation and nonmethylation. within the limits of detection our results show that none of the plasmids replicated two or more rounds. However, a fraction of all injected plasmid DNAs, including vector DNA, seems to replicate once. The same result was obtained for a DNA sequence from mouse that had been reported to have replication origin function in mouse tissue culture cells. We excluded the possibility that methylation of the plasmids is the reason for their inability to replicate. These results demonstrate that homologous and heterologous DNA sequences that drive replication of plasmids in cells of other species are not sufficient to fulfil this function in Drosophila embryos.by J.A. Huberman     

Genomic organization of two families of highly repeated nuclear DNA sequences of maize selected for autonomous replicating activity in yeast

Maize nuclear DNA sequences capable of promoting the autonomous replication of plasmids in yeast were isolated by ligating Eco RI-digested fragments into yeast vectors unable to replicate autonomously. Three such autonomously replicating sequences (ARS), representing two families of highly repeated sequences within the maize genome, were isolated and characterized. Each repetitive family shows hybridization patterns on a Southern blot characteristic of a dispersed sequence. Unlike most repetitive sequences in maize, both ARS families have a constant copy number and characteristic genomic hybridization pattern in the inbred lines examined. Larger genome clones with sequence homology to the ARS-containing elements were selected from a lambda library of maize genomic DNA. There was typically only one copy of an ARS-homologous sequence on each 12–15 kb genomic fragment.     

Drosophila ARSs contain the yeast ARS consensus sequence and a replication enhancer.

A number of restriction fragments that function as autonomously replicating sequences (ARSs) in yeast have been isolated from Drosophila melanogaster DNA. The behaviour in yeast of plasmids containing Drosophila ARS elements was studied and compared to that exhibited by the archetypal yeast ARS-1 plasmid. ARS functions were localised by subcloning and BAL-31 deletion analysis. These studies demonstrated the structural and functional complexity of Drosophila ARSs. Each Drosophila ARS element has at least two domains, one essential for replication (the replication sequence, RS) and a second (the replication enhancer, RE) which is essential for maximum function of the RS. The RS of three Drosophila ARSs was shown to contain a sequence identical to an 11 bp yeast ARS consensus sequence (5' A/T TTTATPuTTT A/T 3'). These observations lend support to the hypothesis that heterologous ARS elements may be of biological significance.     

Yeast ARS function and nuclear matrix association coincide in a short sequence from the human HPRT locus

Summary A sequence that supports extrachromosomal replication of plasmids in yeast has been identified within the first intron of the human hypoxanthine-guanine phosphori bosyltransferase (HPRT) gene. This represents the first isolation of such an autonomously replicating sequence (ARS) from an exactly known position in the human genome. This ARS shares similarities of imparted yeast phenotype and DNA sequence with other heterologus ARSs. In addition, this sequence is found to be a matrix association region (MAR) on the basis of specific binding to nuclear matrices prepared from several mammalian cell types. It also exhibits anomalous electrophoretic behavior, characteristic of bent DNA, on polyacrylamide gels. The coincidence of these properties supports the possibility that this region may play a role in DNA replication within its normal chromosomal context.     

DNA replication initiates at multiple sites on plasmid DNA in Xenopus egg extracts.

Cell-free extracts of Xenopus eggs will replicate plasmid DNA molecules under normal cell cycle control. We have used the neutral/neutral 2-D gel technique to map the sites at which DNA replication initiates in this system. Three different plasmids were studied: one containing the Xenopus rDNA repeat, one containing single copy Xenopus genomic DNA, and another containing the yeast 2 microns replication origin. 2-D gel profiles show that many potential sites of initiation are present on each plasmid, and are randomly situated at the level of resolution of this technique (500-1000 bp). Despite the abundance of sites capable of supporting the initiation of replication, pulse-chase experiments suggest that only a single randomly situated initiation event occurs on each DNA molecule. Once initiation has taken place, conventional replication forks appear to move away from this site at a rate of about 10nt/second, similar to the rate observed in vivo.     

The in vivo replication origin of the yeast 2 microns plasmid

We have used two-dimensional neutral/alkaline agarose gel electrophoresis to separate the nascent strands of replicating yeast 2 micron plasmid DNA molecules according to extent of replication, away from nonreplicating molecules and parental strands. Analysis of the lengths of nascent strands by sequential hybridization with short probes shows that replication proceeds bidirectionally from a single origin at map position 3700 +/- 100, coincident with the genetically mapped ARS element. The two recombinational isomers of 2 microns plasmid (forms A and B) replicate with equal efficiency. These results suggest that ARS elements may prove to be replication origins for chromosomal DNA.     

Chromosome replication in cell-free systems from Xenopus eggs

Cell-free systems from eggs of the frog Xenopus laevis are able to perform most of the acts of eukaryotic chromosome replication in vitro. This now includes the crucial regulatory step of initiation, which had only been achieved for viral systems previously. Purified DNA or nuclei are able to initiate and complete semi-conservation replication in egg extracts in vitro (Blow & Laskey, Cell 47, 557-587 (1986). Replication does not require specialized DNA sequences either in vitro or in microinjected eggs, but in both systems large templates replicate more efficiently than small templates. In some cases replication can re-initiate, excluding the possibility that replication is primed by preexisting primers in the template preparations. When nuclei are replicated in vitro, only one round of replication is observed in a single incubation resembling the single round of replication observed for purified DNA after micro-injection. The mechanism that prevents re-initiation of replication within a single cell cycle is discussed and certain models are eliminated. Nucleosome assembly from histones and DNA has also been studied in cell-free systems from Xenopus eggs. Fractionation has led to the identification of two acidic proteins called nucleoplasmin and N1, which bind histones and transfer them to DNA. The sequences of both proteins have been determined by cDNA cloning and sequencing. Both proteins are found as complexes with histones in eggs.     

Cloned mouse DNA fragments can replicate in a simian virus 40 T antigen-dependent system in vivo and in vitro.

Mouse liver DNA was cut out with BamHI and cloned into YIp5, which contained the URA3 gene of Saccharomyces cerevisiae in pBR322. Of the several plasmids isolated, two plasmids, pMU65 and pMU111, could transform S. cerevisiae from the URA- to the URA+ phenotype and could replicate autonomously within the transformant, indicating that mouse DNA fragments present in pMU65 or pMU111 contain autonomously replicating sequences (ARS) for replication in S. cerevisiae. Furthermore, to determine the correlation between ARS function in yeast cells and that in much higher organisms, we tried to challenge these plasmids with the simian virus 40 (SV40) DNA replication system. Of the two plasmids tested, the EcoRI-BglII region of pMU65 could be hybridized with a chemically synthesized 13-nucleotide fragment corresponding to the origin region of SV40 DNA. Both pMU65 (the EcoRI-BglII region cloned in pBR322) and its subclone pMU65EB could replicate semiconservatively, and initiation of DNA replication started from the EcoRI-BglII region when the replicating activity of these plasmids was tested in the in vitro SV40 DNA replication system we have established before. Furthermore, pMU65 and pMU65EB could replicate autonomously within monkey Cos cells which produce SV40 T antigen constitutively. These results show that a 2.5-kilobase fragment of the EcoRI-BglII region in pMU65 contains the ARS needed for replication in the SV40 DNA replication system.     

Initiation of DNA replication in yeast chromosomes

A family of DNA fragments from the yeast genome has properties that suggest that chromosome replication starts at specific DNA sequences. These elements (autonomously replicating sequences: ARS) have a bipartite structure: a small (less than 20 base pairs) AT-rich region essential for function, flanked by larger regions important for maximal activity of the replicator. In an attempt to identify proteins involved in initiation of replication, yeast mutants that show an enhanced ability to replicate minichromosomes with defective ARSS have been isolated.     

Localization and sequence analysis of chloroplast DNA sequences of Chlamydomonas reinhardii that promote autonomous replication in yeast

Four distinct chloroplast DNA segments from Chlamydomonas reinhardii of 400, 415, 730 and 2300 bp which promote autonomous replication in yeast have been mapped on the chloroplast genome. Plasmids carrying these chloroplast DNA fragments are unstable in yeast when the cells are grown under non-selective conditions. Sequence analysis of three of these chloroplast ARS regions (autonomously replicating sequences in yeast) reveals a high AT content, numerous short direct and inverted repeats and the presence of at least one element in each region that is related to the yeast ARS consensus sequence. A/T TTTATPuTTT A/T. These three chloroplast regions share, in addition, two common elements of 10 and 11 bp which may play a role in promoting autonomous replication.     

ARS replication during the yeast S phase

A 1.45 kb circular plasmid derived from yeast chromosome IV contains the autonomous replication element called ARS1. Isotope density transfer experiments show that each plasmid molecule replicates once each S phase, with initiation depending on two genetically defined steps required for nuclear DNA replication. A density transfer experiment with synchronized cells demonstrates that the ARS1 plasmid population replicates early in the S phase. The sequences adjacent to ARS1 on chromosome IV also initiate replication early, suggesting that the ARS1 plasmid contains information which determines its time of replication. The times of replication for two other yeast chromosome sequences, ARS2 and a sequence referred to as 1OZ, indicate that the temporal order of replication is ARS1 leads to ARS2 leads to 1OZ. These experiments show directly that specific chromosome regions replicate at specific times during the yeast S phase. If ARS elements are origins of chromosome replication, then the experiment reveals times of activation for two origins.     

Initiation of DNA replication in nuclei and purified DNA by a cell-free extract of Xenopus eggs

We demonstrate that cell-free extracts prepared from activated eggs of X. laevis by a method similar to that of Lohka and Masui initiate and complete semiconservative DNA replication of sperm nuclei and plasmid DNA. The efficiency of replication is comparable to that in the intact egg. Under optimal conditions 70%-100% of nuclei, and up to 38% of naked DNA molecules replicate completely. Genuine initiation of replication occurs rather than elongation of preformed primers or priming of irreversibly denatured templates. Rereplication of templates is observed under certain conditions. In addition to replicating DNA, these extracts also assemble nucleus-like structures from naked DNA.     

Replication of injected DNA templates in Xenopus embryos

We have analysed the replication of both exogenous frog DNAs and heterologous DNAs during development from the first cleavage through the blastula stage, by their microinjection into fertilized eggs of Xenopus laevis. The data show that various plasmids increase to different extents and that the differences cannot be attributed to size alone. Plasmids containing the Xenopus ribosomal gene repeat unit do not replicate efficiently, and they also inhibit the replication of co-injected DNA templates. This inhibitory effect may be due to DNA sequences contained in the intergenic ribosomal gene spacers.     

Deletion mutations affecting autonomously replicating sequence ARS1 of Saccharomyces cerevisiae.

DNAs that contain specific yeast chromosomal sequences called ARSs transform Saccharomyces cerevisiae at high frequency and can replicate extrachromosomally as plasmids when introduced into S. cerevisiae by transformation. To determine the boundaries of the minimal sequences required for autonomous replication in S. cerevisiae, we have carried out in vitro mutagenesis of the first chromosomal ARS described, ARS1. Rather than identifying a distinct and continuous segment that mediates the ARS+ phenotype, we find three different functional domains within ARS1. We define domain A as the 11-base-pair (bp) sequence that is also found at most other ARS regions. It is necessary but not sufficient for high-frequency transformation. Domain B, which cannot mediate high-frequency transformation, or replicate by itself, is required for efficient, stable replication of plasmids containing domain A. Domain B, as we define it, is continuous with domain A in ARS1, but insertions of 4 bp between the two do not affect replication. The extent of domain B has an upper limit of 109 bp and a lower limit of 46 bp in size. There is no obvious sequence homology between domain B of ARS1 and any other ARS sequence. Finally, domain C is defined on the basis of our deletions as at least 200 bp flanking domain A on the opposite side from domain B and is also required for the stability of domain A in S. cerevisiae. The effect of deletions of domain C can be observed only in the absence of domain B, at least by the assays used in the current study, and the significance of this finding is discussed.     

A reorganized Candida albicans DNA sequence promoting homologous non-integrative genetic transformation

In order to develop plasmids adequate for non-integrative genetic transformation of Candida albicans, a DNA fragment of 15.3 kb was cloned from this organism on the basis of its capacity to convert the integrative Saccharomyces cerevisiae vector YIp5 into a non-integrative one. Southern hybridization analysis, carried out with a labelled DNA probe of 3.6 kb derived from the cloned fragment, showed that it consisted of C. albicans DNA, the hybridization pattern indicating that the corresponding sequences were homologous to several chromosomal regions. The size of the C. albicans DNA promoting autonomous replication in S. cerevisiae was substantially reduced by subcloning. A 5.1 kb subfragment, defined by BamHI and SalI restriction sites, retained autonomous replication sequences (ARS) functional in the heterologous S. cerevisiae system and in C. albicans, when inserted in plasmid constructions that carried a S. cerevisiae trichodermin-resistance gene (tcm1) as selection marker. C. albicans transformants were both of the integrative and the non-integrative type and the plasmids recovered from the latter very often carried a reorganized ARS, indicating that recombination of the inserted ARS DNA had occurred in the homologous host. Successive reorganizations of the ARS insert in C. albicans eventually led to a more stable and much smaller fragment of 687 bp that was subsequently recovered unchanged from transformants. Sequence analysis of the 687 bp fragment revealed four 11-base blocks, rich in A+T, that carried the essential consensus sequence considered relevant for yeast ARS elements in addition to other features also described as characteristic of yeast replication origins.     

Sequence analysis of three fragments of maize nuclear DNA which replicate autonomously in yeast

There maize nuclear DNA fragments were isolated on the basis of their ability to confer replication on chimeric plasmids in yeast. These Eco RI fragments of 2.5, 2.8 and 5.5 kb are repeated elements within the maize genome. The 2.5 and 2.8 kb fragments represent a family of elements repeated 11 000 times in the maize haploid genome, while the 5.5 kb fragment is part of another family of 28 000 elements. These fragments were subcloned to further define the unique region of ARS activity. The sequence of each 550–650 bp ARS subclone is reported here, and compared to the flanking regions which do not show ARS activity. The ARS elements are 65–70% A+T as compared to 50–55% for the maize genome as a whole. There is approximately 15% sequence divergence, as well as variation of ARS efficiency, among family members. ARS subclones contain the proposed yeast consensus sequence.