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     

Analysis of the autonomous replication behavior in human cells of the dihydrofolate reductase putative chromosomal origin of replication.

Chinese hamster genomic DNA sequences from the region downstream of the dihydrofolate reductase (DHFR) gene reported to contain a chromosomal origin of bidirectional DNA replication (OBR-1) were tested for their ability to support autonomous DNA replication in human cells. A 13.3 kilobase fragment containing OBR-1 and surrounding sequences supported replication in short-term and long-term replication assays, while a 4.5 kb fragment containing OBR-1 did not support substantial replication in either assay. These results are consistent with our previous observations that large fragments of human DNA support replication, while smaller fragments are less efficient. The replication activities of plasmids containing OBR-1 were no greater than those of randomly chosen human fragments of similar size. Furthermore, two-dimensional gel analysis of plasmids containing OBR-1 indicated that initiation does not preferentially occur within the OBR-1 region. These results suggest that in the context of autonomous replication, the DHFR sequences tested do not contain genetic information specifying site-specific replication initiation. Possible implications of these results for chromosomal replication are discussed.     

Autonomous replication in Drosophila melanogaster tissue culture cells

This study addresses the ability of DNA fragments from various sources to mediate autonomous DNA replication in cultured Drosophila melanogaster cells. We created a series of plasmids containing genomic DNA fragments from the Ultrabithorax gene of Drosophila and tested them for autonomous replication after transfection into Schneider line 2 cells. We found that all plasmids containing Drosophila DNA fragments were able to replicate autonomously, as were plasmids containing random human and Escherichia coli genomic DNA fragments. Most of the plasmids were detectable 18 days after transfection in the absence of selection, suggesting that transfected DNA is maintained in Drosophila cells without rapid loss or degradation. The finding that all plasmids containing Drosophila, human, or bacterial DNA replicate autonomously in Drosophila cells suggests that the signals that direct autonomous replication in Drosophila contain a low degree of sequence specificity. A two-dimensional gel analysis of initiation on one of the plasmids was consistent with many dispersed initiation sites. Low sequence specificity and dispersed initiation sites also characterize autonomous replication in human cells and Senopus eggs and may be general properties of autonomous replication in animal cells.     

Autonomous replication in human cells of multimers of specific human and bacterial DNA sequences.

Using modules of a specific 2,712-bp human DNA sequence and a specific 2,557-bp Escherichia coli DNA sequence, we created plasmids containing between 1 and 12 modules of single or chimeric sequence composition and tested them in human cells for their autonomous replication ability. We found that replication efficiency per generation increased with successive addition of human modules, to essentially 100% by six copies. Although a single copy of the bacterial module had negligible replication ability, the replication efficiency per generation of 12 bacterial modules was 66%. Chimeras composed of human and bacterial modules displayed intermediate replication levels. We also used two-dimensional gel electrophoresis to physically map where replication initiated on a half human-half E. coli plasmid. Our results suggest that autonomous replication in human cells is stimulated by simple sequence features which occur frequently in human DNA but are more rare in bacterial DNA.     

Isolation of human sequences that replicate autonomously in human cells.

We have isolated a heterogeneous collection of human genomic sequences which replicate autonomously when introduced into human cells. The novel strategy for the isolation of these sequences involved cloning random human DNA fragments into a defective Epstein-Barr virus vector. This vector alone was unable to replicate in human cells, but appeared to provide for the nuclear retention of linked DNA. The human sequences persist in a long-term replication assay (greater than 2 months) in the presence of the viral nuclear retention sequences. Using a short-term (4-day) assay, we showed that the human sequences are able to replicate in the absence of all viral sequences. The plasmids bearing human sequences were shown to replicate based on the persistence of MboI-sensitive plasmid DNA in the long-term assay and the appearance of DpnI-resistant DNA in the short-term assay. The human sequences were shown to be responsible for the replication activity and may represent authentic human origins of replication.     

DNA binding properties of the adenovirus DNA replication priming protein pTP

The precursor terminal protein pTP is the primer for the initiation of adenovirus (Ad) DNA replication and forms a heterodimer with Ad DNA polymerase (pol). Pol can couple dCTP to pTP directed by the fourth nucleotide of the viral genome template strand in the absence of other replication proteins, which suggests that pTP/pol binding destabilizes the origin or stabilizes an unwound state. We analyzed the contribution of pTP to pTP/pol origin binding using various DNA oligonucleotides. We show that two pTP molecules bind cooperatively to short DNA duplexes, while longer DNA fragments are bound by single pTP molecules as well. Cooperative binding to short duplexes is DNA sequence independent and most likely mediated by protein/protein contacts. Furthermore, we observed that pTP binds single-stranded (ss)DNA with a minimal length of approximately 35 nt and that random ssDNA competed 25-fold more efficiently than random duplex DNA for origin binding by pTP. Remarkably, short DNA fragments with two opposing single strands supported monomeric pTP binding. pTP did not stimulate, but inhibited strand displacement by the Ad DNA binding and unwinding protein DBP. These observations suggest a mechanism in which the ssDNA affinity of pTP stabilizes Ad pol on partially unwound origin DNA.     

Specific initiation at an origin of replication from Schizosaccharomyces pombe.

Using a genetic assay for efficient autonomous replication, we have isolated from Schizosaccharomyces pombe a 6.2-kb fragment which shows the properties expected of an origin of DNA replication in S. pombe. A 2.8-kb subclone of the fragment has the same replication properties. Two-dimensional gel analysis of replication intermediates throughout plasmids carrying the 6.2- or 2.8-kb fragments shows that replication initiates only in a specific region, which can be localized to within several hundred base pairs, in the fragments. This region is also a site of replication initiation in the S. pombe chromosome where the fragments normally reside. These results provide strong evidence that initiation of replication in S. pombe is localized and mediated by specific DNA sequence signals.     

Identification of initiation sites for DNA replication in the human dnmt1 (DNA-methyltransferase) locus

Vertebrates have developed multiple mechanisms to coordinate the replication of epigenetic and genetic information. Dnmt1 encodes the maintenance enzyme DNA-methyltransferase, which is responsible for propagating the DNA methylation pattern and the epigenetic information that it encodes during replication. Direct sequence analysis and bisulfite mapping of the 5' region of DNA-methyltransferase 1 (dnmt1) have indicated the presence of many sequence elements associated with previously characterized origins of DNA replication. This study tests the hypothesis that the dnmt1 region containing these elements is an origin of replication in human cells. First, we demonstrate that a vector containing this dnmt1 sequence is able to support autonomous replication when transfected into HeLa cells. Second, using a gel retardation assay, we show that it contains a site for binding of origin-rich sequences binding activity, a recently purified replication protein. Finally, using competitive polymerase chain reaction, we show that replication initiates in this region in vivo. Based on these lines of evidence, we propose that initiation sites for DNA replication are located between the first intron and exon 7 of the human dnmt1 locus.     

Identification of a cis-element that determines autonomous DNA replication in eukaryotic cells

A 36-bp human consensus sequence (CCTMDAWKSGBYTSMAAWTWBCMYTTRSCAAATTCC) is capable of supporting autonomous replication of a plasmid after transfection into eukaryotic cells. After transfection and in vitro DNA replication, replicated plasmid DNA containing a mixture of oligonucleotides of this consensus was found to reiterate the consensus. Initiation of DNA replication in vitro occurs within the consensus. One version, A3/4, in pYACneo, could be maintained under selection in HeLa cells, unrearranged and replicating continuously for >170 cell doublings. Stability of plasmid without selection was high (> or =0.9/cell/generation). Homologs of the consensus are found consistently at mammalian chromosomal sites of initiation and within CpG islands. Versions of the consensus function as origins of DNA replication in normal and malignant human cells, immortalized monkey and mouse cells, and normal cow, chicken, and fruit fly cells. Random mutagenesis studies suggest an internal 20-bp consensus sequence of the 36 bp may be sufficient to act as a core origin element. This cis-element consensus sequence is an opportunity for focused analyses of core origin elements and the regulation of initiation of DNA replication.     

Size distribution of DNA replicative intermediates in bacteriophage P4 and in Escherichia coli.

We have tested the hypothesis that Okazaki fragment replicative intermediates have defined termini using as a model system the in vivo DNA replication of the tiny bacteriophage P4. The kinetics of formation of intermediates in P4 DNA replication have been investigated. P4 DNA replication in DNA polymerase I-deficient mutants generates Okazaki fragments with a size distribution similar to that in uninfected cells. When P4-derived Okazaki fragments are resolved by agarose gel electrophoresis, no discrete size classes appear. This finding is incompatible with sequence-specific models of Okazaki fragment formation but supports the view that these replication intermediates are initiated and terminated at random locations on the P4 chromosome.     

Cloning and integration of DNA fragments in human cells via the inverted terminal repeats of the adeno-associated virus 2 genome.

In current systems for molecular cloning of eukaryotic genes, bacterial cells are routinely utilized as intermediate hosts. We investigated the possibility of using a viral system for cloning DNA fragments independent of bacterial cell usage. In this report, we provide an alternative approach for molecular cloning of DNA fragments in eukaryotic cells by utilizing the inverted terminal repeats (ITRs) of the genome of a nonpathogenic human parvovirus, the adeno-associated virus 2 (AAV). We constructed a series of chimeric linear duplex DNA molecules, ranging in length from 1.8 to 7.2 kb, containing the cruciform structures of AAV-ITRs at both ends. These 'no-end' (NE) DNA structures, when transfected into adenovirus-infected human cells in the presence of AAV replication proteins (Rep), underwent DNA replication. Furthermore, in the presence of AAV capsid proteins (Cap), all replicated DNA molecules of less than 5.0 kb were packaged into mature, biologically active AAV progeny virions. When a chimeric NE DNA (NE-neo) containing a gene (neo) encoding resistance to neomycin was transfected into human cells, neoR clones could be readily isolated in the presence of G418 (Geneticin). Southern-blot analysis of genomic DNA of several independently isolated neoR clones suggested stable integration of the NE-neo DNA into the host chromosomal DNA. AAV-ITRs, therefore, offer an alternative system for molecular cloning, as well as packaging of DNA fragments in mammalian cells independent of bacterial cell usage.     

Nuclear targeting of a bacterial integrase that mediates site-specific recombination between bacterial and human target sequences

TrwC is a bacterial protein involved in conjugative transfer of plasmid R388. It is transferred together with the DNA strand into the recipient bacterial cell, where it can integrate the conjugatively transferred DNA strand into its target sequence present in the recipient cell. Considering that bacterial conjugation can occur between bacteria and eukaryotic cells, this protein has great biotechnological potential as a site-specific integrase. We have searched for possible TrwC target sequences in the human genome. Recombination assays showed that TrwC efficiently catalyzes recombination between its natural target sequence and a discrete number of sequences, located in noncoding sites of the human genome, which resemble this target. We have determined the cellular localization of TrwC and derivatives in human cells by immunofluorescence and also by an indirect yeast-based assay to detect both nuclear import and export signals. The results indicate that the recombinase domain of TrwC (N600) has nuclear localization, but full-length TrwC locates in the cytoplasm, apparently due to the presence of a nuclear export signal in its C-terminal domain. The recombinase domain of TrwC can be transported to recipient cells by conjugation in the presence of the helicase domain of TrwC, but with very low efficiency. We mutagenized the trwC gene and selected for mutants with nuclear localization. We obtained one such mutant with a point A904T mutation and an extra peptide at its C terminus, which maintained its functionality in conjugation and recombination. This TrwC mutant could be useful for future TrwC-mediated site-specific integration assays in mammalian cells.     

Species-specific replication of simian virus 40 DNA in vitro requires the p180 subunit of human DNA polymerase alpha-primase.

Human cell extracts efficiently support replication of simian virus 40 (SV40) DNA in vitro, while mouse cell extracts do not. Since human DNA polymerase alpha-primase is the major species-specific factor, we set out to determine the subunit(s) of DNA polymerase alpha-primase required for this species specificity. Recombinant human, mouse, and hybrid human-mouse DNA polymerase alpha-primase complexes were expressed with baculovirus vectors and purified. All of the recombinant DNA polymerase alpha-primases showed enzymatic activity and efficiently synthesized the complementary strand on an M13 single-stranded DNA template. The human DNA polymerase alpha-primase (four subunits [HHHH]) and the hybrid DNA polymerase alpha-primase HHMM (two human subunits and two mouse subunits), containing human p180 and p68 and mouse primase, initiated SV40 DNA replication in a purified system. The human and the HHMM complex efficiently replicated SV40 DNA in mouse extracts from which DNA polymerase alpha-primase was deleted, while MMMM and the MMHH complex did not. To determine whether the human p180 or p68 subunit was required for SV40 DNA replication, hybrid complexes containing only one human subunit, p180 or p68, together with three mouse subunits (HMMM and MHMM) or three human subunits and one mouse subunit (MHHH and HMHH) were tested for SV40 DNA replication activity. The hybrid complexes HMMM and HMHH synthesized oligoribonucleotides in the SV40 initiation assay with purified proteins and replicated SV40 DNA in depleted mouse extracts. In contrast, the hybrid complexes containing mouse p180 were inactive in both assays. We conclude that the human p180 subunit determines host-specific replication of SV40 DNA in vitro.     

An initiation zone of chromosomal DNA replication located upstream of the c-myc gene in proliferating HeLa cells.

Studies on origins of DNA replication in mammalian cells have long been hampered by a lack of methods sensitive enough for the localization of such origins in chromosomal DNA. We have employed a new method for mapping origins, based on polymerase chain reaction amplification of nascent strand segments, to examine replication initiated in vivo near the c-myc gene in human cells. Nascent DNA, pulse-labeled in unsynchronized HeLa cells, was size fractionated and purified by immunoprecipitation with anti-bromodeoxyuridine antibodies. Lengths of the nascent strands that allow polymerase chain reaction amplification were determined by hybridization to probes homologous to amplified segments and used to calculate the position of the origin. We found that DNA replication through the c-myc gene initiates in a zone centered approximately 1.5 kilobases upstream of exon I. Replication proceeds bidirectionally from the origin, as indicated by comparison of hybridization patterns for three amplified segments. The initiation zone includes segments of the c-myc locus previously reported to drive autonomous replication of plasmids in human cells.     

Modeling DNA methylation in a population of cancer cells

Little is known about how human cancers grow because direct observations are impractical. Cancers are clonal populations and the billions of cancer cells present in a visible tumor are progeny of a single transformed cell. Therefore, human cancers can be represented by somatic cell ancestral trees that start from a single transformed cell and end with billions of present day cancer cells. We use a genealogical approach to infer tumor growth from somatic trees, employing haplotype DNA methylation pattern variation, or differences between specific CpG sites or "tags," in the cancer genome. DNA methylation is an epigenetic mark that is copied, with error, during genome replication. At our tags, neutral copy errors in DNA methylation appear to occur at random, and much more frequently than sequence copy errors. To reconstruct a cancer tree, we sample and compare human colorectal genomes within small geographic regions (a cancer fragment), between fragments on the same side of the tumor, and between fragments from opposite tumor halves. The combined information on both physical distance and epigenetic distance informs our model for tumor ancestry. We use approximate Bayesian computation, a simulation-based method, to model tumor growth under a variety of evolutionary scenarios, estimating parameters that fit observed DNA methylation patterns. We conclude that methylation patterns sampled from human cancers are consistent with replication errors and certain simple cancer growth models. The inferred cancer trees are consistent with Gompertzian growth, a well-known cancer growth pattern.