Extrachromosomal DNA in eucaryotes

SARS-CoV-2 nsp13 suppresses hepatitis B virus replication by targeting cccDNA transcription

SARS-CoV-2 nonstructural protein 13 (nsp13) has been shown to selectively suppress the transcription of episomal DNA while sparing chromosomal DNA. Hepatitis B Virus (HBV) harbors covalently closed circular DNA (cccDNA), a form of viral episomal DNA found within infected hepatocyte nuclei. The persistence of cccDNA is the major cause of chronic HBV infection. In this study, we investigated the impact of SARS-CoV-2 nsp13 on HBV replication, particularly in the context of cccDNA. Our findings demonstrate that nsp13 effectively hinders HBV replication by suppressing the transcription of HBV cccDNA, both in vitro and in vivo. Additionally, we observed that SARS-CoV-2 nsp13 binds to HBV cccDNA and its NTPase and helicase activities contribute significantly to inhibiting HBV replication. Furthermore, our screening identified the interaction between nsp13 and structural maintenance of chromosomes 4, opening new avenues for future mechanistic inquiries. This study presents the evidence suggesting the potential utilization of SARS-CoV-2 nsp13 as a strategy to impede HBV replication by specifically targeting cccDNA. These findings provide a proof of concept for exploring nsp13 as a prospective approach in combating HBV infection.

IMPORTANCE

To effectively combat hepatitis B virus (HBV), it is imperative to develop potent antiviral medications targeting covalently closed circular DNA (cccDNA). Our investigation aimed to assess the impact of SARS-CoV-2 nsp13 on HBV replication across diverse HBV models, confirming its ability to significantly reduce several HBV replication markers. Additionally, our identification of the interaction between nsp13 and SMC4 opens the door for further mechanistic exploration. This marks a paradigm shift in our approach to HBV antiviral therapy, introducing an entirely novel perspective. Our findings propose a novel strategy for developing anti-HBV drugs that specifically target HBV cccDNA.

An analytical method to connect open curves for modeling protein-bound DNA minicircles

We introduce an analytical method to generate the pathway of a closed protein-bound DNA minicircle. We develop an analytical equation to connect two open curves smoothly and use the derived expressions to join the ends of two helical pathways and form models of nucleosome-decorated DNA minicircles. We find that the simplest smooth connector which satisfies the boundary conditions at the end points and the length requirement for such connections to be a quartic function on the xy-plane and linear along the z-direction. This is a general method which can be used to connect any two open curves with well defined mathematical definitions as well as pairs of discrete systems found experimentally. We used this method to describe the configurations of torsionally relaxed, 360-base pair DNA rings with two evenly-spaced, ideal nucleosomes. We considered superhelical nucleosomal pathways with different levels of DNA wrapping and allowed for different inter-nucleosome orientations. We completed the DNA circles with the smooth connectors and studied the associated bending and electrostatic energies for different configurations in the absence and presence of salt. The predicted stable states bear close resemblance to reconstituted minicircles observed under low and high salt conditions.

Near-Random Distribution of Chromosome-Derived Circular DNA in the Condensed Genome of Pigeons and the Larger, More Repeat-Rich Human Genome

Extrachromosomal circular DNA (eccDNA) elements of chromosomal origin are known to be common in a number of eukaryotic species. However, it remains to be addressed whether genomic features such as genome size, the load of repetitive elements within a genome, and/or animal physiology affect the number of eccDNAs. Here, we investigate the distribution and numbers of eccDNAs in a condensed and less repeat-rich genome compared with the human genome, using Columba livia domestica (domestic rock pigeon) as a model organism. By sequencing eccDNA in blood and breast muscle from three pigeon breeds at various ages and with different flight behavior, we characterize 30,000 unique eccDNAs. We identify genomic regions that are likely hotspots for DNA circularization in breast muscle, including genes involved in muscle development. We find that although eccDNA counts do not correlate with the biological age in pigeons, the number of unique eccDNAs in a nonflying breed (king pigeons) is significantly higher (9-fold) than homing pigeons. Furthermore, a comparison between eccDNA from skeletal muscle in pigeons and humans reveals ∼9-10 times more unique eccDNAs per human nucleus. The fraction of eccDNA sequences, derived from repetitive elements, exist in proportions to genome content, that is, human 72.4% (expected 52.5%) and pigeon 8.7% (expected 5.5%).

Overall, our results support that eccDNAs are common in pigeons, that the amount of unique eccDNA types per nucleus can differ between species as well as subspecies, and suggest that eccDNAs from repeats are found in proportions relative to the content of repetitive elements in a genome.

Overlooked: Extrachromosomal DNA and Their Possible Impact on Whole Genome Sequencing

Extrachromosomal (ec) DNA in eukaryotic cells has been known for decades. The structures described range from linear double stranded (ds) DNA to circular dsDNA, distinct from mitochondrial (mt) DNA. The sizes of circular forms are described from some hundred base pairs (bp) up to more than 150 kbp. The number of molecules per cell ranges from several hundred to a thousand. Semi-quantitative determinations of circular dsDNA show proportions as high as several percentages of the total DNA per cell. These ecDNA fractions harbor sequences that are known to be present in chromosomal DNA (chrDNA) too. Sequencing projects on, for example the human genome, have to take into account the ecDNA sequences which are simultaneously ascertained; corrections cannot be performed retrospectively. Concerning the results of sequencings derived from extracted whole DNA: if the ecDNA fractions contained therein are not taken into account, erroneous conclusions at the chromosomal level may result.

Sequencing the extrachromosomal circular mobilome reveals retrotransposon activity in plants

Retrotransposons are mobile genetic elements abundant in plant and animal genomes. While efficiently silenced by the epigenetic machinery, they can be reactivated upon stress or during development. Their level of transcription not reflecting their transposition ability, it is thus difficult to evaluate their contribution to the active mobilome. Here we applied a simple methodology based on the high throughput sequencing of extrachromosomal circular DNA (eccDNA) forms of active retrotransposons to characterize the repertoire of mobile retrotransposons in plants. This method successfully identified known active retrotransposons in both Arabidopsis and rice material where the epigenome is destabilized. When applying mobilome-seq to developmental stages in wild type rice, we identified PopRice as a highly active retrotransposon producing eccDNA forms in the wild type endosperm. The mobilome-seq strategy opens new routes for the characterization of a yet unexplored fraction of plant genomes.

Identification of Extrachromosomal Circular DNA in Hop via Rolling Circle Amplification

During a survey for new viruses affecting hop plants, a circular DNA molecule was identified via rolling circle amplification (RCA) and later characterized. A small region of the 5.7-kb long molecule aligned with a microsatellite region in the Humulus lupulus genome, and no coding sequence was identified. Sequence analysis and literature review suggest that the small DNA molecule is an extranuclear DNA element, specifically, an extrachromosomal circular DNA (eccDNA), and its presence was confirmed by electron microscopy. This work is the first report of eccDNAs in the family Cannabaceae. Additionally, this work highlights the advantages of using RCA to study extrachromosomal DNA in higher plants.

Engineered plant minichromosomes

The advent of transgenic technologies has met many challenges, both technical and political; however, these technologies are now widely applied, particularly for crop improvement. Bioengineering has resulted in plants carrying resistance to herbicides, insects, and viruses, as well as entire biosynthetic pathways. Some of the technical challenges in generating transgenic plant or animal materials include: an inability to control the location and nature of the integration of transgenic DNA into the host genome, and linkage of transformed genes to selectable antibiotic resistance genes used in the production of the transgene cassette. Furthermore, successive transformation of multiple genes may require the use of several selection genes. The coordinated expression of multiple stacked genes would be required for complex biosynthetic pathways or combined traits. Engineered nonintegrating minichromosomes can overcome many of these problems and hold much promise as key players in the next generation of transgenic technologies for improved crop plants. In this review, we discuss the history of artificial chromosome technology with an emphasis on engineered plant minichromosomes.

c-Myc-induced extrachromosomal elements carry active chromatin

Murine Pre-B lymphocytes with experimentally activated MycER show both chromosomal and extrachromosomal gene amplification. In this report, we have elucidated the size, structure, and functional components of c-Myc-induced extrachromosomal elements (EEs). Scanning electron microscopy revealed that EEs isolated from MycER-activated Pre-B+ cells are an average of 10 times larger than EEs isolated from non-MycER-activated control Pre-B- cells. We demonstrate that these large c-Myc-induced EEs are associated with histone proteins, whereas EEs of non-MycER-activated Pre B- cells are not. Immunohistochemistry and Western blot analyses using pan-histone-specific, histone H3 phosphorylation-specific, and histone H4 acetylation-specific antibodies indicate that a significant proportion of EEs analyzed from MycER-activated cells harbors transcriptionally competent and/or active chromatin. Moreover, these large, c-Myc-induced EEs carry genes. Whereas the total genetic make-up of these c-Myc-induced EEs is unknown, we found that 30.2% of them contain the dihydrofolate reductase (DHFR) gene, whereas cyclin C (CCNC) was absent. In addition, 50% of these c-Myc-activated Pre-B+ EEs incorporated bromodeoxyuridine (BrdU), identifying them as genetic structures that self-propagate. In contrast, EEs isolated from non-Myc-activated cells neither carry the DHFR gene nor incorporate BrdU, suggesting that c-Myc deregulation generates a new class of EEs.

Spontaneous mobilization of integrated recombinant adenoassociated virus in a cell culture model of virus latency

A cell line containing integrated recombinant adenoassociated virus (AAV) was investigated for spontaneous mobilization of vector sequence. Detection of these rare events was facilitated by using a vector design that allowed the circular rescue product (cAAV) to be individually scored by bacterial transformation. Restriction and sequence analysis of captured clones revealed five highly ordered classes of cAAV, each of which contained a defined segment of the integrated vector locus. A common feature of all cAAV classes was the presence of a modified inverted terminal repeat that joined the ends of the liberated sequence. Assembly of extrachromosomal vector genomes was accompanied by deletions in the integration locus that could be mapped to one of the five cAAV classes, suggesting an excision-type mechanism. We propose that the spontaneous deletion and mobilization of vector sequence from the recombinant adenoassociated virus (rAAV) integration locus is mediated by a recombination event between the inverted terminal repeats that define the boundaries of the individual genome subunits.

Ori-somes, nucleoprotein complexes descending from origin regions of animal chromosomal DNA replication. A micromorphological study

Micromorphology of nucleoprotein (NP) complexes designated according to their descent and shape as Ori-somes is presented. These NP complexes of three different types harbor molecules of cytoplasmic "small" polydisperse DNA, which descend from origin regions of chromosomal DNA replication and are equipped, as shown previously, with early DNA-synthesizing activities. By negative staining the Ori-somes are visualized as particles of irregular shape, sometimes of a subunit-like structure. Micromorphological differences in size and structural compactness noted among individual Ori-somes are dependent on their type similarly as earlier shown physico-chemically and biochemically. Such differences were also confirmed by two different spreading techniques. The most unravelled structures with electron diffuse centers belong to Ori-somes of component B associated with most active DNA synthesis. In contrast, the Ori-somes of components A and C, associated with pronounced RNA synthesis, revealed large electron-dense centers. The incidence of replicative structures present in Ori-somes corresponds with the level of their DNA-synthesizing activities.

DNAs with unusual properties revealed by field inversion gel electrophoresis of agarose-encapsulated DNA from mammalian cells

Distinct DNA fractions (fr-DNAs), moving separately from bulk DNA, were revealed by field inversion gel electrophoresis of DNA from intact cells lysed and deproteinized in agarose plugs. These fr-DNAs (approximately 2% of the total DNA) were ubiquitously present in nuclei of all mammalian cells studied, including human normal and tumor tissues, and showed a typical electrophoretic pattern (three bands with constant mobilities termed a-, b-, and c-DNA). Characteristic mobility shifts induced by gamma irradiation of a- and b-DNAs suggest their non-linear conformation. In fact, electron microscopy of a- and b-DNAs from Namalwa cells revealed rosette-like structures stabilized by a central protease-resistant knob. Comparative PCR analysis revealed qualitative differences between genomic fingerprints of a- and b-DNAs on the one hand and chromosomal DNA on the other. The results obtained suggest that fr-DNAs originate either from some specific chromatin regions due to non-random cleavages or from an autonomous intranuclear structure, not identified as yet.

Micromorphology of cytoplasmic nucleoprotein complexes harboring an extrachromosomal DNA closely related to avian myeloblastosis virus core-bound DNA

Nucleoprotein (NP) complexes constituting the three basic components (A, B, C) of the postmicrosomal sediment (POMS) of chicken leukemic myeloblasts (CHLMs) which contain extrachromosomal DNA closely related to avian myeloblastosis virus DNA were analyzed electron microscopically. It was shown that these NP complexes resemble micromorphologically, depending on the origin of their POMS components, NP structures involved in three successive stages of early DNA synthesis. Nucleic acids harbored in these NP complexes exhibited micromorphological features typical for replicative structures. It was confirmed electron microscopically that the extrachromosomal DNA of CHLMs replicative in nature and of three length classes is organized into special NP complexes, each of which, as demonstrated, represents a unique reaction machinery of early DNA synthesis.

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.

Analysis of recombination junctions in extrachromosomal circular DNA obtained by in-gel competitive reassociation

Essentially all eukaryotic cells contain circular extrachromosomal DNA as a result of excision from the chromosomes. To obtain insight into the nature of recombination associated with the occurrence of such DNA species and its biological significance, we analyzed a library enriched in recombination junctions which was constructed by a novel DNA subtraction technique; in-gel competitive reassociation (IGCR). Furthermore, we also introduced inverse PCR to characterize chromosomal DNA fragments containing the recombination junctions. At least 45% of the clones in the library constructed by the IGCR procedure comprised DNA with recombination junctions. Nucleotide sequence analysis of the recombination junctions indicated that three of four extrachromosomal DNAs thus analyzed were produced through recombination between sequences with a 3-5 bp homology in the chromosomes. One extrachromosomal DNA was apparently generated through non-homologous recombination, possibly by end-to-end joining. These results have demonstrated the usefulness of IGCR in concentrating recombination junctions, which provide the most direct evidence for the mechanism of the recombinational events involved, from highly complex genomes.

Polydnavirus-facilitated endoparasite protection against host immune defenses

The polydnavirus of Campoletis sonorensis has evolved with an unusual life cycle in which the virus exists as an obligate symbiont with the parasite insect and causes significant physiological and developmental alterations in the parasite's host. The segmented polydnavirus genome consists of double-stranded superhelical molecules; each segment is apparently integrated into the chromosomal DNA of each male and female wasp. The virus replicates in the nucleus of calyx cells and is secreted into the oviduct. When the virus is transferred to the host insect during oviposition, gene expression induces host immunosuppression and developmental arrest, which ensures successful development of the immature endoparasite. In the host, polydnavirus expression is detected by 2 hr and during endoparasite development. Most of the abundantly expressed viral genes expressed very early after parasitization belong to multigene families. Among these families, the "cysteine-rich" gene family is the most studied, and it may be important in inducing host manifestations resulting in parasite survival. This gene family is characterized by a similar gene structure with introns at comparable positions within the 5' untranslated sequence and just 5' to a specific cysteine codon (*C) within a cysteine motif, C-*C-CC-C-C. Another unusual feature is that the nucleotide sequences of introns 2 in the subfamily WHv1.0/WHv1.6 are more conserved than those of the flanking exons. The structures of these viral genes and possible functions for their encoded protein are considered within the context of their endoparasite and virus strategy for genetic adaptation and successful parasitization.

Formation of extrachromosomal circular DNA in HeLa cells by nonhomologous recombination

Extrachromosomal circular DNA (eccDNA) generated from chromosomal DNA is found in all mammalian cells and increases with cell stress or aging. Studies of eccDNA structure and mode of formation provide insight into mechanisms of instability of the mammalian genome. Previous studies have suggested that eccDNA is generated through a process involving recombination between repetitive sequences. However, we observed that approximately one half of the small eccDNA fragments cloned from HeLa S3 cells were composed entirely of nonrepetitive or low-copy DNA sequences. We analyzed four of these fragments by polymerase chain reaction and nucleotide sequencing and found that they were complete eccDNAs. We then screened a human genomic library with the eccDNAs to isolate the complementary chromosomal sequences. Comparing the recombination junctions within the eccDNAs with the chromosomal sequences from which they were derived revealed that nonhomologous recombination was involved in their formation. One of the eccDNAs was composed of two separate sequences from different parts of the genome. These results suggest that rejoining of ends of fragmented DNA is responsible for the generation of a substantial portion of the eccDNAs found in HeLa S3 cells.

Increased amount and contour length distribution of small polydisperse circular DNA (spcDNA) in Fanconi anemia

Small polydisperse circular DNA (spcDNA) in Fanconi anemia (FA) was analyzed from cultured fibroblast-like cells by electron microscopy. Application of the mica-press adsorption technique for the semi-quantitative determination of spcDNA amounts to three FA and three normal control skin-derived fibroblast strains revealed 85-fold increased levels of spcDNA in the FA cells. An even higher excess over controls was suggested when the FA fibroblasts were propagated for up to 11 serial in vitro passages, consistent with the short replicative life-span of primary FA cells and their rapid transition into a poorly dividing state, in which spcDNA reportedly further increases. In addition, contour length distributions of gradient-purified spcDNA preparations from five FA fibroblast strains were compared with those from five normal control strains. Mean spcDNA contour lengths were significantly greater in the FA than in the control cells. The reported findings of increased spcDNA amounts and sizes in FA coincide with a similar association of chromosome instability and abnormal spcDNA formation previously observed in cultured cells derived from angiofibromas in tuberous sclerosis. Circumstantial evidence from the present study in the paradigmatic chromosome breakage syndrome FA further supports the suggestion that a common mechanism underlies chromosome instability and the surplus generation of spcDNA. Notably, this apparent mechanism is functional in homonuclear primary cell strains with a distinct inherited basis of their chromosome instability, and is not restricted to heteroploid and neoplastoid cell lines.

Preferential extrachromosomal localization of exogenous DNA in transgenic silkworm Bombyx mori L

Transgenic silkworms (Bombyx mori L.) were obtained by microinjection of plasmid pPrC-LTR1.5, which carris 1.5 DNA copies of Rous sarcoma virus (RSV) long terminal repeats (LTRs) inserted in the vector pBR322. The transgene was transmitted over the three generations obtained up to now. Most of the exogenous DNA failed to integrate into the genome and persisted as an extrachromosomal element that is subject to rearrangements. Plasmids carrying only part of the input DNA together with fragments of silkworm DNA were rescued from the transgenic animals. One of the rescued plasmids contained a sequence which belongs to a family of evolutionarily conserved repeated sequences.

Macroevolution of plasmids: a model for plasmid speciation

A new evolutionary model for diversification in plasmid incompatibility groups (plasmid speciation) is suggested. The model is based on the formation of plasmid cointegrates from two compatible plasmids. The existence of plasmid cointegrates is well known, however, their potential key role in plasmid macroevolution has not yet been recognized. In a hypothesis presented here, one of the rep genes is supposed to be relaxed from selection in plasmid cointegrates and thus becomes free to accumulate mutations. These mutations can lead to a change in incompatibility specificity. Evidence supporting this hypothesis comes from the common occurrence of multi-replicon plasmids in nature as well as from experimental studies on plasmid cointegrate formation. A more speculative extension of this model hypothesizes an evolutionary scenario for origin of the eubacterial single-replicon genome and the eukaryotic multi-replicon genome, as well as the place of plasmids and viruses in this picture.

Extrachromosomal circular DNAs and genomic sequence plasticity in eukaryotic cells

The ability of eukaryotic organisms of the same genotype to vary in developmental pattern or in phenotype according to varying environmental conditions is frequently associated with changes in extrachromosomal circular DNA (eccDNA) sequences. Although variable in size, sequence complexity, and copy number, the best characterized of these eccDNAs contain sequences homologous to chromosomal DNA which indicates that they might arise from genetic rearrangements, such as homologous recombination. The abundance of repetitive sequence families in eccDNAs is consistent with the notion that tandem repeats and dispersed repetitive elements participate in intrachromosomal recombination events. There is also evidence that a fraction of this DNA has characteristics similar to retrotransposons. It has been suggested that eccDNAs could reflect altered patterns of gene expression or an instability of chromosomal sequences during development and aging. This article reviews some of the findings and concepts regarding eccDNAs and sequence plasticity in eukaryotic genomes.

Purification of eucaryotic extrachromosomal circular DNAs using exonuclease III

A method for the isolation of eucaryotic extrachromosomal circular (ecc) DNA is described. Exonuclease III was used to preparatively digest linear and open circular forms of DNA; the resultant exonuclease-resistant molecules were then characterized by buoyant density gradient sedimentation and were found to be essentially covalently closed circular DNA. The efficiency of the exonuclease method was compared to ultracentrifugation techniques and was found to give yields greater than those obtained by two or more equilibrium density gradients. The utility of the exonuclease III technique was determined by purifying eccDNAs from mouse liver, brain, heart, and kidney tissues. The results showed that there are tissue-related differences in eccDNA content.

Tissue-specific and age-related variations in repetitive sequences of mouse extrachromosomal circular DNAs

Extrachromosomal circular (ecc) DNA was isolated from mouse brain, liver, and heart tissues at different ages. To determine the abundance of repetitive sequences in eccDNAs, preparations were probed for short-interspersed (B1 and B2), long-interspersed (L1), endogenous retroviral-like (IAP), and tandemly repeated satellite sequences (SAT) of the mouse genome. Together these sequence families comprise approximately 15% of the mouse genome. The hybridization results showed that each tissue had a characteristic pattern of repetitive sequence elements in eccDNAs, and the abundance of repetitive sequences changed as a function of age. Repetitive sequences decreased in liver and brain eccDNAs from 1 month to 8 months of age but appeared to remain stable thereafter. In contrast, repetitive sequence families in heart eccDNAs were constant from 1 month to 16 months of age but declined in 24-month-old mice. The present studies indicate that extrachromosomal sequences exhibit greater flexibility than chromosomal sequences.

Characterization of a conserved extrachromosomal element isolated from the avian malarial parasite Plasmodium gallinaceum

We have identified a conserved, repeated, and highly transcribed DNA element from the avian malarial parasite Plasmodium gallinaceum. The element produced multiple transcripts in both zygotes and asexual blood stages of this parasite. It was found to be highly conserved in all of five malarial species tested and hybridized at reduced stringency to other members of the phylum Apicomplexa, including the genera Babesia, Eimeria, Toxoplasma, and Theileria. The copy number of the element was about 15, and it had a circularly permuted restriction map with a repeat unit length of about 6.2 kilobases. It could be separated from the main genomic DNA by using sucrose gradients and agarose gels, and it migrated separately from the recognized Plasmodium chromosomes on pulse-field gels. In the accompanying paper (S. M. Aldritt, J. T. Joseph, and D. F. Wirth, Mol. Cell. Biol. 9:3614-3620, 1989), evidence is presented that element contains the mitochondrial genes for the protein cytochrome b and a fragment of the large rRNA. We postulate that this element is an episome in the mitochondria of the obligate parasites belonging to the phylum Apicomplexa.

Sequence identification of cytochrome b in Plasmodium gallinaceum

We have identified a gene that encodes the polypeptide cytochrome b in the avian malarial parasite Plasmodium gallinaceum. The gene containing the open reading frame was found to be located on a 6.2-kilobase multimeric extrachromosomal element. The amino acid translation from this gene demonstrated significant similarities to cytochrome b sequences from yeast, mammal, and fungus genomes. We present evidence that the P. gallinaceum cytochrome b transcript is part of a larger primary transcript from the element that is subsequently processed. The message for P. gallinaceum cytochrome b was found to be 1.2 kilobases in size. This is the first report identifying a mitochondrial nucleic acid sequence in malaria-causing organisms and suggests that a functional cytochrome system may exist in these parasites.

Recombination mediates production of an extrachromosomal circular DNA containing a transposon-like human element, THE-1

An abundant class of HeLa extrachromosomal circular DNA containing the transposon-like element, THE-1, is shown to arise via site specific recombination. The chromosomal locus from which these circles are derived, however, is single-copy. Northern blot analysis detects homology to two polyadenylated RNAs in HeLa cells. The possible presence of an origin of replication and its role in generating these small polydisperse circles is discussed.

Sequence identification of cytochrome b in Plasmodium gallinaceum

We have identified a gene that encodes the polypeptide cytochrome b in the avian malarial parasite Plasmodium gallinaceum. The gene containing the open reading frame was found to be located on a 6.2-kilobase multimeric extrachromosomal element. The amino acid translation from this gene demonstrated significant similarities to cytochrome b sequences from yeast, mammal, and fungus genomes. We present evidence that the P. gallinaceum cytochrome b transcript is part of a larger primary transcript from the element that is subsequently processed. The message for P. gallinaceum cytochrome b was found to be 1.2 kilobases in size. This is the first report identifying a mitochondrial nucleic acid sequence in malaria-causing organisms and suggests that a functional cytochrome system may exist in these parasites.

Characterization of a conserved extrachromosomal element isolated from the avian malarial parasite Plasmodium gallinaceum

We have identified a conserved, repeated, and highly transcribed DNA element from the avian malarial parasite Plasmodium gallinaceum. The element produced multiple transcripts in both zygotes and asexual blood stages of this parasite. It was found to be highly conserved in all of five malarial species tested and hybridized at reduced stringency to other members of the phylum Apicomplexa, including the genera Babesia, Eimeria, Toxoplasma, and Theileria. The copy number of the element was about 15, and it had a circularly permuted restriction map with a repeat unit length of about 6.2 kilobases. It could be separated from the main genomic DNA by using sucrose gradients and agarose gels, and it migrated separately from the recognized Plasmodium chromosomes on pulse-field gels. In the accompanying paper (S. M. Aldritt, J. T. Joseph, and D. F. Wirth, Mol. Cell. Biol. 9:3614-3620, 1989), evidence is presented that element contains the mitochondrial genes for the protein cytochrome b and a fragment of the large rRNA. We postulate that this element is an episome in the mitochondria of the obligate parasites belonging to the phylum Apicomplexa.

Extrachromosomal circular DNAs in Drosophila melanogaster: comparison between embryos and Kc0% cells

We established the size distribution of extrachromosomal covalently closed circular DNA molecules from embryos of various Drosophila melanogaster strains and from Kc0% tissue culture cells. In embryos, more than 80% of the circular DNA molecules are smaller than 2.5 kb and all the distributions show a peak of molecules of between 200 and 400 bp. The Kc0% cell distribution differs mainly from that of embryos in that 48% of the molecules have a size between 4 and 8 kb. Correlating with this, circular molecules homologous to copia, 412 and 297 were detected only in Kc0% cells. The three tandemly repeated families containing the 5S genes, the histone genes and the 240 bp repeat of the ribosomal DNA intergenic spacer, which had previously been identified in circular DNAs from embryos, were also found in cultured cells. A fourth tandemly repeated family corresponding to the 1.688 g/cm3 satellite DNA was detected, both in embryos and Kc0% cells. It consists of circular multimeric molecules containing multiple copies of the 359 bp repeated unit. No circular DNA molecules homologous to the actin genes, the type I ribosomal DNA insertion, or the F and I transposable elements were found in embryos or Kc0% cells. Thus it appears that the extrachromosomal circular DNA molecules from embryos and from tissue culture cells differ mainly in the presence of circular copies of the copia-like transposable elements.

Cytoplasmic localization of human repetitive DNA revealed by in situ hybridization

Previously, we showed that a human repetitive DNA sequence (Sau3A family) belonging to a satellite DNA is unstable and constantly excised from the chromosomes (R. Kiyama, H. Matsui, and M. Oishi, 1986, Proc. Natl. Acad. Sci. USA 83, 4665). The unusual property of the repetitive DNA, along with another repetitive DNA (Alu sequence), was further investigated by in situ hybridization in several different human cells including HeLa, bone marrow, and peripheral blood cells. We found that the excised repetitive DNA sequences are localized not only in nuclei, but also in cytoplasm. These results have confirmed the instability of these DNA sequences in the chromosomes and further suggest that the alpha satellite DNA and the Alu sequence which were excised from the chromosomes are released from nuclei to cytoplasm.

Restriction analysis of chromosomal sequences homologous to single-copy fragments cloned from small polydisperse circular DNA (spcDNA)

Restriction fragments from the fraction of small polydisperse circular DNA (spcDNA) were cloned in pBR322. The spcDNA was prepared from cell cultures derived from an angiofibroma of a patient with tuberous sclerosis (TS). Such cultures have been shown previously to contain increased amounts of spcDNA. Four cloned spcDNA fragments containing single-copy sequences were chosen to characterize the homologous chromosomal DNA segments by restriction analysis. When used as hybridization probes, these four fragments generate well-defined nonvariable patterns in the chromosomal DNA from healthy donors. The restriction patterns obtained with one of the fragments (D-C4) can best be interpreted by assuming the presence of two copies of the homologous sequences in chromosomal DNA. A second sequence, A-B4, occurs at least 30-50 times in the haploid human genome. In both cases the duplicated regions span relatively large segments of DNA.

DNA electrophoresis

The migration of a series of supercoiled plasmids ranging in size from 4 to 91 kilobases (kb) has been analyzed by orthogonal-field-alternation gel electrophoresis (OFAGE). These circular DNAs enter OFAGE gels and are resolved over the same region of the gel as linear DNAs from 260 to 2200 kb. Furthermore, a distinct triphasic migration pattern was observed for the supercoiled DNAs. The migration of plasmids between 6 and 20, and 60 and 91 kb is inversely proportional to size, whereas the mobilities of plasmids between 20 and 60 kb increase with size. Unlike linear DNA molecules, the relative mobilities of these plasmids are constant over a broad range of pulse times, from 10 to 120s. Electrophoresis of supercoiled, relaxed, and nicked open circular forms as well as topoisomers of small plasmids shows that the extent of supercoiling has a dramatic effect on plasmid migration on OFAGE. Several practical applications for exploiting the different migration properties of circular and linear DNA molecules on OFAGE are presented.

Physical and biological characterization of linear DNA plasmids of the yeast Pichia inositovora

Three cryptic DNA plasmids have been identified in a strain of the yeast Pichia inositovora that are 18, 13, and 10 kbp in size. All are sensitive to digestion by DNase I, restriction endonucleases, and exonuclease III, but are resistant to the activities of RNase A and lambda exonuclease. These results indicate that each plasmid is a linear DNA molecule whose 5' ends are protected. A restriction map has been developed for each of the plasmids, demonstrating that each is unique and confirming their linear nature. The plasmids are a major constituent of DNA prepared from whole cells, but are absent from DNA preparations of purified mitochondria and nuclei, indicating that the plasmids are located in the cytoplasm. These plasmids share many of the physical characteristics described for the linear plasmids of the yeasts Kluyveromyces lactis and Saccharomycopsis crataegensis. Unlike the linear plasmids of K. lactis, however, they appear not to be capable of killer toxin production.

Estimation of circular DNA size using gamma-irradiation and pulsed-field gel electrophoresis

A method is described for estimating the size of large circular DNAs found within complex chromosomal DNA preparations. DNAs are treated with low levels of gamma-irradiation, sufficient to introduce a single double-stranded break per circle, and the resulting linear DNA is sized by pulsed-field electrophoresis and blot hybridization. The method is fast, reproducible, and very conveniently applied to the agarose-enclosed chromosomal DNA preparations commonly used in pulsed field electrophoresis.

Increase of extrachromosomal circular DNA in mouse 3T6 cells on perturbation of DNA synthesis: implications for gene amplification

We have analyzed the amount of extrachromosomal double-stranded covalently closed circular nonmitochondrial DNA in mouse 3T6 cells by Southern blotting and electron microscopy. Treatment with 7,1-dimethylbenz[a]anthracene, known to promote amplification of integrated SV40 genomes, elevated the amount of circular DNA. Inhibition of DNA synthesis with hydroxyurea, earlier shown to enhance amplification of the cellular dihydrofolate reductase gene, resulted in yet higher levels. Thus, elevation of the frequency of gene amplification and generation of extrachromosomal circular DNA seem to accompany each other in the situations studied in this paper. Two other DNA synthesis inhibitors, aphidicolin and thymidine, had markedly lesser effects on circular DNA. The significance of these findings for the mechanism of gene amplification is discussed.

Illegitimate recombination in the histone multigenic family generates circular DNAs in Drosophila embryos

From extrachromosomal covalently closed circular DNA molecules purified from Drosophila melanogaster embryos, we have isolated 24 clones homologous to the histone tandemly repeated gene family. Some of the clones harbor one of the two main types of genomic repeated units of 4.8 and 5.0 kb. and probably result from homologous recombination. The remaining clones have a size ranging from 0.2 to 2.5 kb. and most of them carry a single fragment of the repeated unit. Nucleotide sequences of the junction region of six of these clones indicate they are generated by illegitimate recombination between short (8-15 bp.) imperfect direct repeats. The data suggest that most of the histone homologous circular DNA molecules are deleted histone units.

Increased amounts of small polydisperse circular DNA (spcDNA) in angiofibroma-derived cell cultures from patients with tuberous sclerosis (TS)

Much greater amounts of small polydisperse circular DNA (spcDNA) have been detected, in cell cultures derived from angiofibromas of six patients with tuberous sclerosis (TS) than in those from the skin of these patients or from the skin of 11 healthy donors. This observation could be confirmed by spreading the DNA of appropriate fractions from CsCl density gradients. The findings suggest the existence of a relationship between the chromosomal instability observed in angiofibroma cultures and the mobilization of spcDNA.

Characterization of repetitive sequence families in mouse heart small polydisperse circular DNAs: age-related studies

Using alkaline denaturation-renaturation, exonuclease III digestion and density gradient centrifugations, we have isolated covalently closed circular DNA (cccDNA) molecules from 1-, 8-, 16-, and 24-month C57BL/6 mouse heart tissues. Electron microscopic analyses demonstrated that all these preparations contained small polydisperse circular DNAs (spcDNAs). spcDNAs showed similar size distributions at all ages, but more discrete size classes and slightly larger circles were observed in the 24-month heart spcDNA preparations. Based upon the final yields of spcDNAs, there appeared to be no age-related changes in the quantity of these circular molecules in vivo. Furthermore, [3H]-pBR322 recovery studies revealed no endogenous factors that might have affected the yield of spcDNAs from young and old tissues. To determine if there were any age-related changes in the quantity of repetitive sequences in spcDNAs, we probed heart spcDNAs with B1, B2, IAP, L1 and satellite sequences of the mouse genome. The hybridization results showed that these sequence families were differentially represented at all ages in spcDNAs. B2 sequences were the highest across all the age groups while L1 sequences were the lowest. The quantity of B1-, B2-, IAP-, and L1-spcDNAs appeared to decrease at 24-months. Satellite sequences appeared to decrease from 1-month to 8-months, but no change beyond 8-months.

Characterization of the 'unusual' mobility of large circular DNAs in pulsed field-gradient electrophoresis

Large circular amplified DNAs (30 and 85 kb) present in methotrexate-resistant Leishmania major appear to migrate anomalously in pulsed field-gradient electrophoresis (PFGE), exhibiting pulse time-dependent mobility and migrating along a different apparent path relative to the large linear chromosomal DNAs. Quantitative studies indicate that the relative pulse-time dependence is actually conferred by the mobility properties of the large linear DNAs. One contributing factor to the difference in migration path is variability in the intrinsic voltage-dependence of mobility of supercoiled and linear DNAs, in combination with the asymmetrical/inhomogeneous voltage gradients. Certain linear chromosomes exhibit a previously undescribed pulse-time dependence in the voltage-dependence of mobility. When enzymatically relaxed or physically nicked the large circular DNAs fail to leave the well using any pulse time, a property also observed in conventional electrophoresis. These findings are relevant to PFGE theory, and its application to the study of circular DNA amplification in Leishmania and other species.

Sequence organization of repetitive sequences enriched in small polydisperse circular DNAs from HeLa cells

A total of 36 clones were randomly selected from a recombinant DNA library of small polydisperse circular DNA (spcDNA) molecules from HeLa cells and were shown to contain repetitive sequences of different reiteration frequencies that ranged from several hundred to several hundred thousand per genome. Sequencing of representative clones revealed tandem repeats of alphoid (alpha) satellite DNA, clustered repeats of the Alu family, KpnI family sequences, tandem repeats of an alpha satellite DNA specific to the X chromosome (alpha X), and A + T-rich segments carrying short stretches of poly(A) or poly(T). DNA rearrangement was frequently found in the repetitive sequences enriched in these spcDNA clones. Short regions of homology that were patchy and inverted were often found, especially at the novel joint where spcDNA sequences are circularized. The presence of these inverted repeats suggests that HeLa spcDNAs are formed by a mechanism that involves looping out of the spcDNA region and joining of the flanking DNA by illegitimate recombination.

rRNA genes of Naegleria gruberi are carried exclusively on a 14-kilobase-pair plasmid

An extrachromosomal DNA was discovered in Naegleria gruberi. The 3,000 to 5,000 copies per cell of this 14-kilobase-pair circular plasmid carry all the 18S, 28S, and 5.8S rRNA genes. The presence of the ribosomal DNA of an organism exclusively on a circular extrachromosomal element is without precedent, and Naegleria is only the third eucaryotic genus in which a nuclear plasmid DNA has been found.

Pulse-labeled, small closed circular DNA in cultured mouse and human cells

Mouse (erythroleukemia, TSA8, and FM3A) cells and human (HeLa and HL-60) cells were pulse-labeled with [3H]thymidine and covalently closed circular DNA in the extrachromosomal fraction was analyzed by fluorography following polyacrylamide gel electrophoresis. Two discrete bands for mouse and at least one, different, band for human cells emerged in the position to which small circular DNA (less than 1 kb) migrate, suggesting there to be species-specific, preferentially labeled, small circular DNA in mammalian cells. The incorporation of [3H]thymidine into the DNA was inhibited by cycloheximide but unaffected by aphidicolin. Restriction enzyme (AluI) digestion of the DNA fraction from MEL cells produced approximately 120-, 100-, and 50-bp labeled DNA fragments. The origin of the pulse-labeled DNAs is discussed.

rRNA genes of Naegleria gruberi are carried exclusively on a 14-kilobase-pair plasmid

An extrachromosomal DNA was discovered in Naegleria gruberi. The 3,000 to 5,000 copies per cell of this 14-kilobase-pair circular plasmid carry all the 18S, 28S, and 5.8S rRNA genes. The presence of the ribosomal DNA of an organism exclusively on a circular extrachromosomal element is without precedent, and Naegleria is only the third eucaryotic genus in which a nuclear plasmid DNA has been found.

Cloned extrachromosomal circular DNA copies of the human transposable element THE-1 are related predominantly to a single type of family member

The 2300 base-pair transposon-like human element, THE-1, has been identified in the extrachromosomal circular DNA of the established human cell line HeLa as a relatively homogeneous population of covalently closed 1900 base-pair molecules. THE-1, which has been classified tentatively as a retroviral-like transposable element (a retrotransposon), is present in the extrachromosomal circular DNA of African green monkey (BSC-1) and human lymphoblastoid (Jurkat) cell lines. The 1900 base-pair extrachromosomal elements isolated and cloned from HeLa cells (1) appear to contain only THE-1-specific nucleotide sequences, (2) are circularized versions of the linear chromosomal sequence, and (3) are related predominantly to a single, or single type of, family member.

Taenia hydatigena: isolation of mitochondrial DNA, molecular cloning, and physical mitochondrial genome mapping

Mitochondrial DNA was isolated from Taenia hydatigena, T. crassiceps, and Echinococcus granulosus using a cetyltrimethylammonium bromide precipitation technique. The technique is simple, rapid, reproducible, and does not require extensive high speed ultracentrifugation. The advantage of using mitochondrial DNA from taeniid cestodes for comparative restriction analysis was demonstrated. Mitochondrial DNA of T. hydatigena was isolated as covalently closed circular molecules. These were linearized by single digestion with BamHI and the molecular weight was estimated from the linear form of 17.6 kb. The mitochondrial DNA of T. hydatigena is therefore similar in size and structure to that of many other animal species. The entire mitochondrial genome was cloned into pBR322 in Escherichia coli and a restriction map of the recombinant molecule was constructed. The potential of using the cloned mitochondrial genome as a probe in speciation studies as well as for providing functional information on the role of the cestode mitochondrion is discussed.