Molecular dissection of an extrachromosomal amplicon reveals a circular structure consisting of an imperfect inverted duplication

Antigenic diversity in malaria parasites is maintained on extrachromosomal DNA

Sequence variation among antigenic var genes enables Plasmodium falciparum malaria parasites to evade host immunity. Using long sequence reads from haploid clones from a mutation accumulation experiment, we detect var diversity inconsistent with simple chromosomal inheritance. We discover putatively circular DNA that is strongly enriched for var genes, which exist in multiple alleles per locus separated by recombination and indel events. Extrachromosomal DNA likely contributes to rapid antigenic diversification in P. falciparum.

Extrachromosomal DNA amplifications in cancer

Extrachromosomal DNA (ecDNA) amplification is an important driver alteration in cancer. It has been observed in most cancer types and is associated with worse patient outcome. The functional impact of ecDNA has been linked to its unique properties, such as its circular structure that is associated with altered chromatinization and epigenetic regulatory landscape, as well as its ability to randomly segregate during cell division, which fuels intercellular copy number heterogeneity. Recent investigations suggest that ecDNA is structurally more complex than previously anticipated and that it localizes to specialized nuclear bodies (hubs) and can act in trans as an enhancer for genes on other ecDNAs or chromosomes. In this Review, we synthesize what is currently known about how ecDNA is generated and how its genetic and epigenetic architecture affects proto-oncogene deregulation in cancer. We discuss how recently identified ecDNA functions may impact oncogenesis but also serve as new therapeutic vulnerabilities in cancer.

A unifying model for extrachromosomal circular DNA load in eukaryotic cells

Extrachromosomal circular DNA (eccDNA) with exons and whole genes are common features of eukaryotic cells. Work from especially tumours and the yeast Saccharomyces cerevisiae has revealed that eccDNA can provide large selective advantages and disadvantages. Besides the phenotypic effect due to expression of an eccDNA fragment, eccDNA is different from other mutations in that it is released from 1:1 segregation during cell division. This means that eccDNA can quickly change copy number, pickup secondary mutations and reintegrate into a chromosome to establish substantial genetic variation that could not have evolved via canonical mechanisms. We propose a unifying 5-factor model for conceptualizing the eccDNA load of a eukaryotic cell, emphasizing formation, replication, segregation, selection and elimination. We suggest that the magnitude of these sequential events and their interactions determine the copy number of eccDNA in mitotically dividing cells. We believe that our model will provide a coherent framework for eccDNA research, to understand its biology and the factors that can be manipulated to modulate eccDNA load in eukaryotic cells.

Novel role for non-homologous end joining in the formation of double minutes in methotrexate-resistant colon cancer cells

Background

Gene amplification is a frequent manifestation of genomic instability that plays a role in tumour progression and development of drug resistance. It is manifested cytogenetically as extrachromosomal double minutes (DMs) or intrachromosomal homogeneously staining regions (HSRs). To better understand the molecular mechanism by which HSRs and DMs are formed and how they relate to the development of methotrexate (MTX) resistance, we used two model systems of MTX-resistant HT-29 colon cancer cell lines harbouring amplified DHFR primarily in (i) HSRs and (ii) DMs.

Results

In DM-containing cells, we found increased expression of non-homologous end joining (NHEJ) proteins. Depletion or inhibition of DNA-PKcs, a key NHEJ protein, caused decreased DHFR amplification, disappearance of DMs, increased formation of micronuclei or nuclear buds, which correlated with the elimination of DHFR, and increased sensitivity to MTX. These findings indicate for the first time that NHEJ plays a specific role in DM formation, and that increased MTX sensitivity of DM-containing cells depleted of DNA-PKcs results from DHFR elimination. Conversely, in HSR-containing cells, we found no significant change in the expression of NHEJ proteins. Depletion of DNA-PKcs had no effect on DHFR amplification and resulted in only a modest increase in sensitivity to MTX. Interestingly, both DM-containing and HSR-containing cells exhibited decreased proliferation upon DNA-PKcs depletion.

Conclusions

We demonstrate a novel specific role for NHEJ in the formation of DMs, but not HSRs, in MTX-resistant cells, and that NHEJ may be targeted for the treatment of MTX-resistant colon cancer.

De novo-generated small palindromes are characteristic of amplicon boundary junction of double minutes

Double minutes (DMs) are hallmarks of gene amplification. However, their molecular structure and the mechanisms of formation are largely unknown. To elucidate the structure and underlying molecular mechanism of DMs, we obtained and cloned DMs using microdissection; and degenerated oligonucleotide primed polymerase chain reaction (DOP-PCR) from the ovarian cancer cell line UACC-1598. Two large amplicons, the 284 kb AmpMYCN, originating from locus 2p24.3 and the 391 kb AmpEIF5A2, from locus 3q26.2, were found co-amplified on the same DMs. The two amplicons are joined through a complex 7 kb junction DNA sequence. Analysis of the junction has revealed three de novo created small palindromes surrounding the six breakpoints. Consistent with these observations, we further found that 70% of the 57 reported DM junction sequences have de novo creation of small palindromic sequences surrounding the breakpoints. Together, our findings indicate that de novo-generated small palindromic sequences are characteristic of amplicon boundary junctions on DMs. It is possible that the de novo-generated small palindromic sequences, which may be generated through non-homologous end joining in concert with a novel DNA repair machinery, play a common role in amplicon rejoining and gene amplification.

Extrachromosomal amplification mechanisms in a glioma with amplified sequences from multiple chromosome loci

Accumulation of extrachromosomal DNA molecules (double minute) is often responsible for gene amplification in cancers, but the mechanisms leading to their formation are still largely unknown. By using quantitative PCR, chromosome walking, in situ hybridization on metaphase chromosomes and whole genome analysis, we studied a glioma containing four extrachromosomally amplified loci (7p11, 1q32.1, 5p15 and 9p2). Complex extrachromosomal DNA molecules were formed by the fusion of several syntenic or non-syntenic DNA fragments from 7p11, 5p15 to 9p2. Fragments ranged from a few base pairs to megabase pairs. Scars of the amplification process remained at the original locus in the form of deletions or chromosome rearrangements. Chromosome fragmentation, due to replication stress, could explain this complex situation. In contrast, at 1q32.1, the initial extrachromosomal DNA molecule resulted from the circularization of a single fragment associated with an intrachromosomal deletion including, but larger than, the amplified sequence. The nature of the sequences involved in these rearrangements suggests that a V(D)J-like illegitimate recombination contributes to its formation.

Palindromic gene amplification--an evolutionarily conserved role for DNA inverted repeats in the genome

The clinical importance of gene amplification in the diagnosis and treatment of cancer has been widely recognized, as it is often evident in advanced stages of diseases. However, our knowledge of the underlying mechanisms is still limited. Gene amplification is an essential process in several organisms including the ciliate Tetrahymena thermophila, in which the initiating mechanism has been well characterized. Lessons from such simple eukaryotes may provide useful information regarding how gene amplification occurs in tumour cells.

Negative implication of C-MYC as an amplification target in esophageal cancer

Chromosomal aberrations (amplifications and deletions) underlie the genesis or development of cancer. Amplification of 8q24 is one of the most frequent events in esophageal cancer. To define whether C-MYC is the target gene for 8q24 amplification, we performed fluorescence in situ hybridization using a MYC (8q24.12 approximately q24.13) probe in esophageal cancer from southern China. Furthermore, we detected the expression status of several genes including C-MYC, TRIB1 (alias C8FW), and FAM84B (alias NSE2) in the regions of 8q24 via reverse transcriptase-polymerase chain reaction or immunohistochemical analysis (or both). Distinct amplification of 8q24 was found in esophageal carcinomas. Only 4 of 46 cases showed obvious protein expression in part of the esophageal cancerous nest. In particular, increased protein expression of C-MYC was shown only in a small part of a cancerous nest in the four cases. Positive C-MYC staining was detected mainly in the cytoplasm of esophageal cancer cells. No expression of TRIB1 was detected in esophageal squamous cell carcinomas. Of 59 cases, 39 (66%) cases showed increased expression of FAM84B in esophageal carcinomas. The results suggest that C-MYC and TRIB1 may not be the amplification target of 8q24 in esophageal cancer. FAM84B might be involved in the genesis or development of esophageal cancer in southern China. Whether FAM84B is the amplification target of esophageal cancer awaits further investigation.

Molecular structure of double-minute chromosomes bearing amplified copies of the epidermal growth factor receptor gene in gliomas

Amplification of the epidermal growth factor receptor gene on double minutes is recurrently observed in cells of advanced gliomas, but the structure of these extrachromosomal circular DNA molecules and the mechanisms responsible for their formation are still poorly understood. By using quantitative PCR and chromosome walking, we investigated the genetic content and the organization of the repeats in the double minutes of seven gliomas. It was established that all of the amplicons of a given tumor derive from a single founding extrachromosomal DNA molecule. In each of these gliomas, the founding molecule was generated by a simple event that circularizes a chromosome fragment overlapping the epidermal growth factor receptor gene. In all cases, the fusion of the two ends of this initial amplicon resulted from microhomology-based nonhomologous end-joining. Furthermore, the corresponding chromosomal loci were not rearranged, which strongly suggests that a postreplicative event was responsible for the formation of each of these initial amplicons.

Replication initiation patterns in the beta-globin loci of totipotent and differentiated murine cells: evidence for multiple initiation regions

The replication initiation pattern of the murine beta-globin locus was analyzed in totipotent embryonic stem cells and in differentiated cell lines. Initiation events in the murine beta-globin locus were detected in a region extending from the embryonic Ey gene to the adult betaminor gene, unlike the restricted initiation observed in the human locus. Totipotent and differentiated cells exhibited similar initiation patterns. Deletion of the region between the adult globin genes did not prevent initiation in the remainder of the locus, suggesting that the potential to initiate DNA replication was not contained exclusively within the primary sequence of the deleted region. In addition, a deletion encompassing the six identified 5' hypersensitive sites in the mouse locus control region had no effect on initiation from within the locus. As this deletion also did not affect the chromatin structure of the locus, we propose that the sequences determining both chromatin structure and replication initiation lie outside the hypersensitive sites removed by the deletion.

Inverted repeats as genetic elements for promoting DNA inverted duplication: implications in gene amplification

Inverted repeats are important genetic elements for genome instability. In the current study we have investigated the role of inverted repeats in a DNA rearrangement reaction using a linear DNA substrate. We show that linear DNA substrates with terminal inverted repeats can efficiently transform Escherichia coli. The transformation products contain circular inverted dimers in which the DNA sequences between terminal inverted repeats are duplicated. In contrast to the recombination/rearrangement product of circular DNA substrates, which is exclusively one particular form of the inverted dimer, the rearrangement products of the linear DNA substrate consist of two isomeric forms of the inverted dimer. Escherichia coli mutants defective in RecBCD exhibit much reduced transformation efficiency, suggesting a role for RecBCD in the protection rather than destruction of these linear DNA substrates. These results suggest a model in which inverted repeats near the ends of a double-strand break can be processed by a helicase/exonuclease to form hairpin caps. Processing of hairpin capped DNA intermediates can then yield inverted duplications. Linear DNA substrates containing terminal inverted repeats can also be converted into inverted dimers in COS cells, suggesting conservation of this type of genome instability from bacteria to mammalian cells.

Suppression of gene amplification and chromosomal DNA integration by the DNA mismatch repair system

Mismatch repair (MMR)-deficient cells are shown to produce >15-fold more methotrexate-resistant colonies than MMR normal cells. The increased resistance to methotrexate is primarily due to gene amplification since all the resistant clones contain double-minute chromosomes and increased copy numbers of the DHFR gene. In addition, integration of linearized or retroviral DNAs into chromosomes is also significantly elevated in MMR-deficient cells. These results suggest that in addition to microsatellite instability and homeologous recombination, MMR is also involved in suppression of other genome instabilities such as gene amplification and chromosomal DNA integration.

Targeted integration of a dominant neo(R) marker into a 2- to 3-Mb human minichromosome and transfer between cells

The physical and genetic characterization of a stable human minichromosome in a Chinese hamster hybrid cell is described. The minichromosome is 2-3 Mb in size, is linear, and contains a complementing SDHC gene. It is derived from a human chromosome 1, including the centromere, some pericentric heterochromatin from 1q12, and 1-2 Mb of 1q21. Genomic DNA surrounding the SDHC gene was used to construct a targeting vector with a selectable drug resistance marker (neo(R)); the marker was then successfully integrated into the minichromosome. With the new selectable marker, the 8.2.3 minichromosome could be transferred into mouse LMTK(-) and 3T3 TK(-) cells.

Inversion/dimerization of plasmids mediated by inverted repeats

In contrast with earlier studies on the lambda and Escherichia coli genomes, recombination between inverted repeats on plasmids is highly efficient and shown to be recA-independent. In addition, the recombination product is exclusively a head-to-head inverted dimer. Here, we show that this recombination/rearrangement event can occur on different plasmid replicons and is not specific to the particular sequence within the inverted repeats. Transcription readthrough into the inverted repeats has little effect on this event. Genetic analysis has also indicated that most known recombination enzymes are not involved in this process. Specifically, single or double mutants defective in Holliday junction resolution systems (RuvABC and/or RecG/RusA) do not abolish this recombination/rearrangement event. This result does not support the previous models (i.e. the reciprocal-strand-switching and the cruciform-dumbbell models) in which intermediates containing Holliday junctions are proposed. Further analysis has demonstrated that the recombination/rearrangement frequency is dramatically (over 1000-fold) reduced if mismatches (2.8 %) are present within the inverted repeats. Mutations in dam, mutH and mutL genes partially or completely restored the recombination/rearrangement frequency to the level exhibited by the perfect inverted repeats, suggesting the formation of heteroduplexes during recombination/rearrangement. Sequencing analysis of the recombination/rearrangement products have indicated that the majority of the products do not involve crossing-over. We discuss a possible mechanism in which blockage of the lagging strand polymerase by a hairpin triggers recombination/rearrangement mediated by inverted repeats.

Chromosome breakpoints near CpG islands in double minutes

Double minute chromosomes (DMs) are the principal genetic vehicles for amplifying oncogenes in human tumors and drug resistance genes in cultured mouse cells. Mouse EMT-6 cells resistant to methotrexate (MTX) generally contain circular DMs, approximately 1 megabase (Mb) in size, that amplify the dihydrofolate reductase (DHFR) gene. The 1 Mb DMs generally have CpG islands located 500 kb upstream of the DHFR gene. The purpose of this study was to determine the relationship between CpG islands and chromosomal breakpoints giving rise to the DM. We show that EMT-6 cells growing in very low levels of MTX that do not yet contain the 1 Mb DHFR-amplifying DM, develop a NotI/EagI site 500 kb upstream of the DHFR gene. This NotI site is close to, if not identical with, one of the chromosomal breakpoints giving rise to the DM. We show that 500 kb of DM DNA from upstream of the DHFR gene is derived from 500 kb of chromosomal DNA upstream of the chromosomal DHFR gene. The downstream breakpoint maps to a region approximately 200 kb downstream of the DHFR gene near a chromosomal SstII/EagI site. Therefore, approximately 700 kb of DM DNA was derived from the genomic region surrounding the DHFR gene. To confirm the organization of the DM DNA, we isolated DNA probes from the 1 Mb DM. Using pulsed field gel electrophoresis and Southern hybridization, we determined the approximate location of each probe with respect to the CpG island in both the DM and the chromosome. Approximately 300 kb of chimeric DNA from a region unrelated to the DHFR gene was incorporated during DM formation. Implications for the mechanism of DM formation are discussed.

CpG islands and double-minute chromosomes

Double-minute chromosomes (DMs) amplify oncogenes in human tumors. The organization of genomic DNA in four independently isolated DMs amplifying the DHFR (dihydrofolate reductase) gene has been compared by mapping locations of CpG islands. When cleaved with methylation-sensitive rare-cutting restriction endonucleases, three hypomethylated GC-rich DNA sequences were frequently found in specific regions in these DMs. One such zone was in the CpG island containing the divergently transcribed promoter separating the DHFR and the Rep-3 genes. The other two sites were approximately 500 kb upstream and 300 kb downstream of the DHFR gene. An approximately 800-kb amplified core genomic region containing the DHFR gene using DM-specific probes has been identified in this study. All the DMs consisted of the core amplified region combined with additional DNA fragments. These additional fragments are different for each DM. Therefore, while the DNAs in each of the DMs are different, they have common hypomethylated regions in similar locations. These results suggest a role for the location of hypomethylated GC-rich sites such as the CpG islands in genesis of DMs.

Organization, generation and replication of amphimeric genomes: a review

Genomes comprising a pair of separated inverted repeats and called 'amphimers' are reviewed. Amphimeric genomes are observed in a large variety of different organisms, ranging from archaebacteria to mammals. The widespread existence of amphimeric genomes in nature could be due to their particular dynamic structure. Amphimeric genomes containing long inverted segments may provide the only form in which a duplicated segment is stably retained in genomes. Amphimers are often found in amplified subgenomes, indicating that they could promote a special mechanism of DNA replication and amplification. The possible mechanisms of generation, isomerization and replication/amplification of different types of amphimeric genomes are discussed. The study of amphimeric mitochondrial petite genomes of yeast could be a good model system for the study of the role of inverted repeat sequences in genome dynamics.

Autonomous plasmid replication in Aspergillus nidulans: AMA1 and MATE elements

With few exceptions, in eukaryotic organisms the presence of a chromosomal replicator on a circular vector molecule is not sufficient to confer on it the ability to persist and replicate extrachromosomally. However, it is possible to isolate from genomes of some filamentous fungi DNA fragments which can provide extrachromosomal maintenance of plasmids. In Aspergillus nidulans, two functional classes of such sequences can be distinguished: effective plasmid replicators (e.g., AMA1) and transformation enhancers (e.g., ANS1 or MATEs), which apparently are able to initiate aberrant replication, leading to vector rearrangement and multimerization and eventually resulting in chromosomal integration. We discuss the similarity of these events to DNA amplification in other eukaryotes. A model is suggested which accounts for the formation of effective replicating plasmids as a result of sequence amplification. The model is based on the observation that in some organisms, including A. nidulans and Schizosaccharomyces pombe, duplication of an inefficient replicator enhances its efficiency dramatically. Some structural traits of transformation enhancers in A. nidulans imply a role for topoisomerases in amplification and replication of circular DNA molecules. We discuss practical applications of replicative vectors for gene cloning and expression studies.

Bacterial artificial chromosome cloning and mapping of a 630-kb human extrachromosomal structure

We have cloned and mapped a circular 630-kb human extrachromosomal structure (termed amplisome) using the bacterial artificial chromosome (BAC) cloning system. Twenty-one BACs were isolated from an amplisome-enriched library by colony hybridization. The insert sizes range from 25 to 143 kb, with an average size of 82 kb. The coverage of the amplisome in clones is approximately 2.7-fold. To construct a physical map of the amplisome, we used three different but complementary methods: hybridization, STS content mapping, and fingerprinting. In addition, we compared the advantages and the drawbacks of these techniques in mapping the amplisomal BACs. The 21 BACs were grouped into two contigs and the two small gaps (3.5 and 26.5 kb) were filled by screening of a human genomic BAC library. The organization of the amplisome revealed by the BAC-based physical map is consistent with the long-range restriction map reported previously. Our results demonstrate that a 630-kb region can be rapidly cloned and mapped into contigs by use of the BAC system. Because of the low frequency (<0.1%) of chimerism and rearrangement, these BAC clones are ready for DNA sequencing and functional analysis.

Induction of circles of heterogeneous sizes in carcinogen-treated cells: two-dimensional gel analysis of circular DNA molecules

Extrachromosomal circular DNA molecules are associated with genomic instability, and circles containing inverted repeats were suggested to be the early amplification products. Here we present for the first time the use of neutral-neutral two-dimensional (2D) gel electrophoresis as a technique for the identification, isolation, and characterization of heterogeneous populations of circular molecules. Using this technique, we demonstrated that in N-methyl-N'-nitro-N-nitrosoguanidine-treated simian virus 40-transformed Chinese hamster cells (CO60 cells), the viral sequences are amplified as circular molecules of various sizes. The supercoiled circular fraction was isolated and was shown to contain molecules with inverted repeats. 2D gel analysis of extrachromosomal DNA from CHO cells revealed circular molecules containing highly repetitive DNA which are similar in size to the simian virus 40-amplified molecules. Moreover, enhancement of the amount of circular DNA was observed upon N-methyl-N'-nitro-N-nitrosoguanidine treatment of CHO cells. The implications of these findings regarding the processes of gene amplification and genomic instability and the possible use of the 2D gel technique to study these phenomena are discussed.

A palindromic structure in the pericentromeric region of various human chromosomes

The primate-specific multisequence family chAB4 is represented with approximately 40 copies within the haploid human genome. Former analyis revealed that unusually long repetition units ( > 35 kb) are distributed to at least eight different chromosomal loci. Remarkably varying copy-numbers within the genomes of closely related primate species as well as the existence of human specific subfamilies, which most probably arose by frequent sequence exchanges, demonstrate that chAB4 is an unstable genomic element, at least in an evolutionary sense. To analyze the chAB4 basic unit in more detail we established a cosmid contig and found it to be organized as inverted duplications of approximately 90 kb flanking a noninverted core sequence of approximately 60 kb. FISH as well as the analysis of chromosome-specific hybrid cell lines revealed a chromosomal localization of chAB4 on chromosomes 1, 3, 4, 9, Y, and the pericentromeric region of all acrocentrics. Furthermore, we can detect chAB4 sequences together with alpha satellites, beta satellites, and satellite III sequences within a single chromosome 22-specific YAC clone, indicating that chAB4 is located in close proximity to the centromere, at least on the acrocentrics. Hence, chAB4 represents an unstable genomic structure that is located just in the chromosomal region that is very often involved in translocation processes.

DNA rearrangement mediated by inverted repeats

Inverted repeats of DNA are widespread in the genomes of eukaryotes and prokaryotes and can mediate genome rearrangement. We studied rearrangement mediated by plasmid-borne inverted repeats in Escherichia coli. We show that inverted repeats can mediate an efficient and recA-independent recombination event. Surprisingly, the product of this recombination is not that of simple inversion between the inverted repeats, but almost exclusively an unusual head-to-head dimer with complex DNA rearrangement. Moreover, this recombination is dramatically reduced by increasing the distance separating the repeats. These results can be readily explained by a model involving reciprocal switching of the leading and lagging strands of DNA replication within the inverted repeats, which leads to the formation of a Holliday junction. Reciprocal strand switching during DNA replication might be a common mechanism for genome rearrangement associated with inverted duplication.

A YAC-based contig of 1.5 Mb spanning the human multidrug resistance gene region and delineating the amplification unit in three human multidrug-resistant cell lines

A contig of 21 nonchimeric yeast artificial chromosomes (YACs) has been assembled across 1.5 Mb of the multidrug resistance (MDR) gene region located at 7q21, and formatted with four previously reported probes, six newly isolated probes, and three sequence-tagged sites (STSs) from internal and end fragments of YACs. A physical map of rare cutter restriction enzyme sites across the region was also constructed by pulsed-field gel electrophoretic (PFGE) analysis of four overlapping YAC clones. The amplification unit of this region in different cell lines was then determined by Southern blot analysis on the basis of the physical map and probes. Amplified DNA was located in extrachromosomal elements in human MDR cell lines studied here, and the size of the amplification unit was determined to be discrete in one MDR amplification but variable in others.

Amplification of a circular episome carrying an inverted repeat of the DFR1 locus and adjacent autonomously replicating sequence element of Saccharomyces cerevisiae

Lack of suitable amplification markers has hindered the use of the yeast system for investigating the mechanism of gene amplification in a eukaryote with a simple genome and well defined genetic system. Recently, methotrexate has been used to select for Saccharomyces cerevisiae mutants with de novo amplification of the dihydrofolate reductase gene (DFR1) (Huang, T. (1993) In Vivo Disruption and de Novo Amplification of the DFR1 Gene Encoding Dihydrofolate Reductase in Saccharomyces cerevisiae. Ph. D. thesis, University of Alberta, Edmonton, Canada). We report here the detailed structure of a DFR1 episome amplified in methotrexate-resistant strain 25-1. The extrachromosomal DNA is found predominantly as a single 11-kilobase circular molecule. It consists of a 5.5-kilobase inverted duplication that contains the DFR1 locus and adjacent ARS (autonomously replicating sequence) element. This molecular configuration mimics the inferred structure of double minute chromosomes observed in a number of mammalian amplification systems and suggests that mechanisms that generate amplified DNAs are conserved from yeast to mammals.

High resolution microscopic mapping of DNA using multi-color fluorescent hybridization

We describe a procedure for microscopically mapping the relative positions of DNA probes along extended strands of DNA. The procedure referred to as direct visual hybridization (DIRVISH) DNA mapping involves the simultaneous hybridization of multiple probes and the fluorescent colors, red green and blue to produce images that convey high-resolution mapping information. The images appear as long strings of fluorescent signals positioned as they are in the genome. A visual multi-color map is generated within 2 days. Cosmid probes span a distance of 10 microms or more and have been observed to contain patterns within the strings of signals. We have developed computer imaging programs to scan through the strings of signals and plot the intensities. Scans through multiple signal strings for one cosmid probe revealed consistent patterns. We have interpreted the patterns as the result of suppression of repetitive DNA sequence hybridization. These patterns may prove useful as fingerprints for regions of DNA.

Structure and organization of a stable extrachromosomal element in human cells

We have determined the structure and organization of a 630-kb extrachromosomal element (amplisome) containing the dihydrofolate reductase-encoding gene (DHFR) in a methotrexate (MTX)-resistant human cell line, HeLa-Bu25-10B3. The size and copy number of amplisomes have previously been found to remain remarkably stable with or without selection. Both linear and open circular 630-kb amplisomes are present in these cells. We have been able to isolate the linear amplisomes after pulsed-field gel electrophoresis (PFGE), and transfect the amplisomes into MTX-sensitive recipient cells by electroporation, thus demonstrating that DNA as large as 630 kb can be transfected into mammalian cells. The NotI restriction site immediately upstream from DHFR on the circular amplisome is devoid of methylation, suggesting that it is transcriptionally active. Restriction mapping by PFGE reveals that there is only one copy of DHFR per amplisome and no repetitive structure is observed. The small size of the amplisomes, their stability and our ability to transfect large DNA molecules provide the necessary ingredients for the development of mammalian cloning vectors for large DNA fragments.

Analysis of a replication initiation sequence from the adenosine deaminase region of the mouse genome

A 4-kb HindIII fragment that supported the efficient autonomous replication of plasmid vector pDY-, a replication-defective construct based on Epstein-Barr virus sequences, in human K562 cells was rescued from amplified double-minute chromosomes containing the murine adenosine deaminase locus. Polymerase chain reaction assays of size-fractionated nascent strands demonstrated that replication initiation occurred within the same 1- to 2-kb region of this fragment in autonomously replicating plasmids containing the sequence in either orientation, in double-minute chromosomes, and in the single-copy locus at its normal chromosomal location. The complete sequence of this fragment was determined; it contains a 248-bp polypurine tract and consensus binding site sequences for several putative transcription and replication factors.

Analysis of a replication initiation sequence from the adenosine deaminase region of the mouse genome

A 4-kb HindIII fragment that supported the efficient autonomous replication of plasmid vector pDY-, a replication-defective construct based on Epstein-Barr virus sequences, in human K562 cells was rescued from amplified double-minute chromosomes containing the murine adenosine deaminase locus. Polymerase chain reaction assays of size-fractionated nascent strands demonstrated that replication initiation occurred within the same 1- to 2-kb region of this fragment in autonomously replicating plasmids containing the sequence in either orientation, in double-minute chromosomes, and in the single-copy locus at its normal chromosomal location. The complete sequence of this fragment was determined; it contains a 248-bp polypurine tract and consensus binding site sequences for several putative transcription and replication factors.

Developmentally regulated processing and replication of the Tetrahymena rDNA minichromosome

The ribosomal DNA locus of Tetrahymena thermophila undergoes a dramatic series of developmentally regulated processing events to generate the amplified rDNA minichromosome during formation of the somatic macronucleus. DNA transformation and classical genetic approaches have identified cis-acting elements that regulate rDNA processing in the developing macronucleus and subsequent vegetative rDNA maintenance.