Large inverted duplications are associated with gene amplification

Amplified DNA can be found in arrays of large repeated units, with each repeat unit containing a marker gene and surrounding DNA sequences. Amplified DNA sequences from established cell lines were assessed for the presence of repeat units in the form of inverted duplications. Inverted duplicated DNA was detected by virtue of its concentration-independent resistance to S1 hydrolysis after denaturation and rapid renaturation. Using this assay, inverted duplications were detected in amplified DNA (both DM and HSR configurations) containing the myc gene (16-50 copies/cell) in four human tumor cell lines and in amplified DNA containing the CAD gene (30-200 copies/cell) in three PALA-resistant BHK cell lines. The widespread association of inverted duplications with amplified DNA must bear on the amplification mechanism.     

Two distinct amplification events of the c-myc locus in a colorectal tumour

Southern hybridisation of genomic DNA extracted from a human primary colorectal carcinoma revealed amplification of a fragment containing the wild-type c-myc locus. Two additional rearranged DNA fragments, lying upstream of c-myc, fused to distant non-contiguous sequences from the same chromosome, with an opposite configuration (head to head vs. head to tail), were also found to be amplified. Sequences analysis suggested that these rearrangements resulted from illegitimate recombination at two distinct points within the DNA sequence just upstream of the c-myc ORF and further that these events triggered two different amplification mechanisms, only one of which, involving a strand invasion event following DNA double strand breaks, increased the copy number of the c-myc ORF.     

The multicopy appearance of a large inverted duplication and the sequence at the inversion joint suggest a new model for gene amplification.

The amplified DNA of HC50474, a Chinese hamster fibroblast cell line selected in three steps for high resistance to coformycin, consists chiefly of 150 copies of a large inverted duplication including the adenylate deaminase gene. Most if not all of these units are more than 2 x 120 kb long. The inverted duplication was first detected in the cells recovered from the second selection step, at the same chromosomal location as the first step amplified units. Its formation and amplification appear to be coupled since the second step cell line already contained 40 copies of this novel structure. Reamplification of the inverted duplication occurred at the third step of selection concomitant with the loss of amplified DNA acquired during the first step. The head-to-head junction has been formed by recombination within a recombinational hotspot described previously [Hyrien, O., Debatisse, M., Buttin, G. and Robert de Saint Vincent, B. (1987) EMBO J., 6, 2401-2408]. Sequences at the joint and in the corresponding wild-type region reveal that the crossover sites, one of which occurs in the putative promoter region of B2 repeat, are located at the top of significant stem-loop structures and that patchy homologies between the parental molecules on one side of the breakpoints allow alignment of these crossover sites. We present a model which explains the formation and amplification of this and other large inverted duplications by errors in DNA replication.     

Hairpin structures are the primary amplification products: a novel mechanism for generation of inverted repeats during gene amplification.

Early events of DNA amplification which occur during perturbed replication were studied by using simian virus 40 (SV40)-transformed Chinese hamster cells (CO60) as a model system. The amplification is observed shortly after carcinogen treatment, and the amplified sequences contain molecules organized as inverted repeats (IRs). SV40 amplification in vitro was studied by using extracts from carcinogen-treated CO60 cells. In the amplified DNA the SV40 origin region was rereplicated, while more distal sequences were not replicated even once. Using several experimental procedures such as sucrose gradients, "snap-back" assay, and two-dimensional gel electrophoresis, we show that the overreplicated DNA contains IRs which are synthesized de novo as hairpins or stem-loop structures which were detached from the template molecules. The fully replicated SV40 molecules synthesized by the HeLa extracts do not contain such IRs. We propose "U-turn replication" as a novel mechanism for gene amplification, accounting for the generation of extrachromosomal inverted duplications as a result of perturbed replication and template switching of the DNA polymerases.     

Long terminal repeat (LTR)-derived recombination of retroviral DNA: sequence analyses of an aberrant clone of baboon endogenous virus DNA which carries an inversion from the LTR to the gag region.

Nucleotide sequences of a cloned proviral DNA of baboon endogenous virus M7 were analyzed, which carried an internal inversion. The inversion of 2.2 kilobase pairs was occurred between the junction of two tandem LTRs and a site locating in the p30 region of the gag gene. The ATAA sequence was a target for recombination generating the inversion, which was duplicated at both ends of the inverted segment. AAA and CA were lost at the 5'- and 3'-ends of the LTRs by the inversion, respectively. On both sides of the target sequence, long AG-rich stretches were detected, which may specify the site of recombination together with the target sequence. The characteristic base changes in the inversion are concluded to result from an illegitimate recombination associated with LTRs, as well as in case of provirus integration into the host cell DNA. We propose and discuss models to explain the processes of recombination to generate both inversion and integration.     

Direct and inverted DNA repeats associated with P-glycoprotein gene amplification in drug resistant Leishmania.

The H circle of Leishmania species contains a 30 kb inverted duplication separated by two unique DNA segments, a and b. The corresponding H region of chromosomal DNA has only one copy of the duplicated DNA. We show here that the chromosomal segments a and b are flanked by inverted repeats (198 and 1241 bp) and we discuss how these repeats could lead to formation of H circles from chromosomal DNA. Selection of Leishmania tarentolae for methotrexate resistance indeed resulted in the de novo formation of circles with long inverted duplication, but two mutants selected for arsenite resistance contained new H region plasmids without such duplications. One of these plasmids appears due to a homologous recombination between two P-glycoprotein genes with a high degree of sequence homology. Our results show how the same DNA region in Leishmania may be amplified to give plasmids with or without long inverted duplications and apparently by different mechanisms.     

Analysis of IS1236-mediated gene amplification events in Acinetobacter baylyi ADP1

Recombination between insertion sequence copies can cause genetic deletion, inversion, or duplication. However, it is difficult to assess the fraction of all genomic rearrangements that involve insertion sequences. In previous gene duplication and amplification studies of Acinetobacter baylyi ADP1, an insertion sequence was evident in approximately 2% of the characterized duplication sites. Gene amplification occurs frequently in all organisms and has a significant impact on evolution, adaptation, drug resistance, cancer, and various disorders. To understand the molecular details of this important process, a previously developed system was used to analyze gene amplification in selected mutants. The current study focused on amplification events in two chromosomal regions that are near one of six copies of the only transposable element in ADP1, IS1236 (an IS3 family member). Twenty-one independent mutants were analyzed, and in contrast to previous studies of a different chromosomal region, IS1236 was involved in 86% of these events. IS1236-mediated amplification could occur through homologous recombination between insertion sequences on both sides of a duplicated region. However, this mechanism presupposes that transposition generates an appropriately positioned additional copy of IS1236. To evaluate this possibility, PCR and Southern hybridization were used to determine the chromosomal configurations of amplification mutants involving IS1236. Surprisingly, the genomic patterns were inconsistent with the hypothesis that intramolecular homologous recombination occurred between insertion sequences following an initial transposition event. These results raise a novel possibility that the gene amplification events near the IS1236 elements arise from illegitimate recombination involving transposase-mediated DNA cleavage.     

Sequence repeats in a polyoma virus DNA region important for gene expression.

The sequenced prototype strains (A2 and A3) of polyoma virus lack sequence duplications characteristic of other papovaviruses. However, we found that five polyoma virus strains (P16, Toronto large plaque, MV, Ts 48, and NG59R) contain tandemly duplicated sequences in a region near the late RNA leader. Although the duplications vary in size (31 to 84 base pairs) and location (between nucleotide [nt] 5068 and nt 5185), the sequence between nt 5114 and nt 5137 is contained within all five duplicated segments. This region is known to be important in polyoma virus early gene expression, and it contains sequences capable of enhancing the expression of nonviral genes. Inspection of the sequences at and around the ends of the repeats indicated that the duplications do not arise by homologous recombination, and there was no indication that a sequence-specific mechanism results in their formation. However, the variation in the structure of the repeats among different polyoma virus strains suggests that these sequence duplications are a recent evolutionary occurrence. The potential biological significance of this variation is discussed.     

Mutant din-21, a variant of polyoma virus containing a mouse DNA sequence in the viral genome.

An unusual non-defective mutant of polyoma virus with an anomalously large genome, designated din-21, has been isolated. The viral chromosome lacks 49 base pairs of the putative control region between the origin of replication and the initiation codon for the early proteins, the T-antigens. In their stead , 95 base pairs, with limited homology to the deleted sequence and apparently of mouse origin, have been inserted. The primary sequence of the insert DNA has been determined and some of the biological properties of the mutant examined. It transforms rat-1 cells slightly better than wild-type virus and grows slightly less well in lytically infected mouse cells. It does not interfere with the growth of wild-type polyoma virus. The properties of this mutant suggest that it is a natural isolate of mouse cells. The mutant was presumably generated by reciprocal recombination between polyoma DNA and mouse host DNA. This could be associated with the integration of a viral DNA sequence into the host chromosome during the viral replicative cycle.     

The DNA sequences of T-DNA junctions suggest that complex T-DNA loci are formed by a recombination process resembling T-DNA integration

After Agrobacterium-mediated plant transformation, multiple T-DNAs frequently integrate at the same position in the plant genome, resulting in the formation of inverted and direct repeats. Because these inverted repeats cannot be amplified and analyzed by PCR, Arabidopsis root cells were co-transformed with two different T-DNAs with distinct sequences adjacent to the T-DNA borders. Nine direct or inverted T-DNA border junctions were analyzed at the sequence level. Precise end-to-end fusions were found between two right border ends, whereas imprecise fusions and filler DNA were present in T-DNA linkages containing a left border end. The results suggest that end-to-end ligation of double-stranded T-DNAs occurs especially between right T-DNA ends and that illegitimate recombination on the basis of microhomology, deletions, repair activities and insertions of filler DNA is involved in the formation of left border T-DNA junctions. Therefore, a similar illegitimate recombination mechanism is proposed that is involved in the formation of complex T-DNA inserts as well as in the integration of the T-DNA in the plant genome.     

Novel rearrangements of herpes simplex virus DNA sequences resulting from duplication of a sequence within the unique region of the L component.

We constructed insertion mutants of herpes simplex virus type 1 that contained a duplication of DNA sequences from the BamHI-L fragment (map units 0.706 to 0.744), which is located in the unique region of the L component (UL) of the herpes simplex virus type 1 genome. The second copy of the BamHI-L sequence was inserted in inverted orientation into the viral thymidine kinase gene (map units 0.30 to 0.32), also located within UL. A significant fraction of the progeny produced by these insertion mutants had genomes with rearranged DNA sequences, presumably resulting from intramolecular or intermolecular recombination between the BamHI-L sequences at the two different genomic locations. The rearranged genomes either had an inversion of the DNA sequence flanked by the duplication or were recombinant molecules in which different regions of the genome had been duplicated and deleted. Genomic rearrangements similar to those described here have been reported previously but only for herpes simplex virus insertion mutants containing an extra copy of the repetitive a sequence. Such rearrangements have not been reported for insertion mutants that contain duplications of herpes simplex virus DNA sequences from largely unique regions of the genome. The implications of these results are discussed.     

Structural and biological analysis of integrated polyoma virus DNA and its adjacent host sequences cloned from transformed rat cells.

EcoRI fragments containing integrated viral and adjacent host sequences were cloned from two polyoma virus-transformed cell lines (7axT and 7axB) which each contain a single insert of polyoma virus DNA. Cloned DNA fragments which contained a complete coding capacity for the polyoma virus middle and small T-antigens were capable of transforming rat cells in vitro. Analysis of the flanking sequences indicated that rat DNA had been reorganized or deleted at the sites of polyoma virus integration, but none of the hallmarks of retroviral integration, such as the duplication of host DNA, were apparent. There was no obvious similarity of DNA sequences in the four virus-host joins. In one case the virus-host junction sequence predicted the virus-host fusion protein which was detected in the transformed cell line. DNA homologous to the flanking sequences of three out of four of the joins was present in single copy in untransformed cells. One copy of the flanking host sequences existed in an unaltered form in the two transformed cell lines, indicating that a haploid copy of the viral transforming sequences is sufficient to maintain transformation. The flanking sequences from one cell line were further used as a probe to isolate a target site (unoccupied site) for polyoma virus integration from uninfected cellular DNA. The restriction map of this DNA was in agreement with that of the flanking sequences, but the sequence of the unoccupied site indicated that viral integration did not involve a simple recombination event between viral and cellular sequences. Instead, sequence rearrangements or alterations occurred immediately adjacent to the viral insert, possibly as a consequence of the integration of viral DNA.     

On the mechanism of gene amplification induced under stress in Escherichia coli

Gene amplification is a collection of processes whereby a DNA segment is reiterated to multiple copies per genome. It is important in carcinogenesis and resistance to chemotherapeutic agents, and can underlie adaptive evolution via increased expression of an amplified gene, evolution of new gene functions, and genome evolution. Though first described in the model organism Escherichia coli in the early 1960s, only scant information on the mechanism(s) of amplification in this system has been obtained, and many models for mechanism(s) were possible. More recently, some gene amplifications in E. coli were shown to be stress-inducible and to confer a selective advantage to cells under stress (adaptive amplifications), potentially accelerating evolution specifically when cells are poorly adapted to their environment. We focus on stress-induced amplification in E. coli and report several findings that indicate a novel molecular mechanism, and we suggest that most amplifications might be stress-induced, not spontaneous. First, as often hypothesized, but not shown previously, certain proteins used for DNA double-strand-break repair and homologous recombination are required for amplification. Second, in contrast with previous models in which homologous recombination between repeated sequences caused duplications that lead to amplification, the amplified DNAs are present in situ as tandem, direct repeats of 7–32 kilobases bordered by only 4 to 15 base pairs of G-rich homology, indicating an initial non-homologous recombination event. Sequences at the rearrangement junctions suggest nonhomologous recombination mechanisms that occur via template switching during DNA replication, but unlike previously described template switching events, these must occur over long distances. Third, we provide evidence that 3′-single-strand DNA ends are intermediates in the process, supporting a template-switching mechanism. Fourth, we provide evidence that lagging-strand templates are involved. Finally, we propose a novel, long-distance template-switching model for the mechanism of adaptive amplification that suggests how stress induces the amplifications. We outline its possible applicability to amplification in humans and other organisms and circumstances.     

Chromosomal destabilization during gene amplification.

Acentric extrachromosomal elements, such as submicroscopic autonomously replicating circular molecules (episomes) and double minute chromosomes, are common early, and in some cases initial, intermediates of gene amplification in many drug-resistant and tumor cell lines. In order to gain a more complete understanding of the amplification process, we investigated the molecular mechanisms by which such extrachromosomal elements are generated and we traced the fate of these amplification intermediates over time. The model system consists of a Chinese hamster cell line (L46) created by gene transfer in which the initial amplification product was shown previously to be an unstable extrachromosomal element containing an inverted duplication spanning more than 160 kilobases (J. C. Ruiz and G. M. Wahl, Mol. Cell. Biol. 8:4302-4313, 1988). In this study, we show that these molecules were formed by a process involving chromosomal deletion. Fluorescence in situ hybridization was performed at multiple time points on cells with amplified sequences. These studies reveal that the extrachromosomal molecules rapidly integrate into chromosomes, often near or at telomeres, and once integrated, the amplified sequences are themselves unstable. These data provide a molecular and cytogenetic chronology for gene amplification in this model system; an early event involves deletion to generate extrachromosomal elements, and subsequent integration of these elements precipitates a cascade of chromosome instability.     

Amplified inverted duplications within and adjacent to heterologous selectable DNA.

Plasmids containing a dihydrofolate reductase (DHFR) expression unit were transfected into DHFR-deficient Chinese hamster ovary (CHO) cells. Methotrexate exposure was used to select cells with amplified DHFR sequences. Three cell lines were isolated containing amplified copies of transfected DNA that had integrated into the Chinese hamster genome. Plasmid DNA was found to co-amplify with flanking hamster sequences that were repetitive (2 cell lines) and unique (1 cell line). Fragments comprising the junctions of amplified plasmid and CHO DNA were found to exist as inverted duplications in all three cell lines. These observations provide evidence that inverted duplication occurred prior to DNA amplification, thus underscoring the importance of inverted duplication in the DNA amplification process.     

Herpes simplex virus type 1 variant a sequence generated by recombination and breakage of the a sequence in defined regions, including the one involved in recombination.

A herpes simplex virus type 1 clone, GN29, having exclusively the variant a sequence was isolated. This a sequence was composed of unique (U) and directly repeated (DR) elements DR1, Ub, (DR2)14, Ucd, Ubd, (DR2)5, DR4n2, and Uc and was assumed to be generated by recombination between sites in Ub and Uc. Unusual DNA fragments containing parts of the a sequence, present in the DNA preparations of GN29, were molecularly cloned. Almost all termini of the cloned unusual DNA fragments were situated in defined regions assumed to be recombinogenic: (i) a site in the inverted repeat of the L component, (ii) DR1, (iii) DR2, (iv) the DR4 stretch, and (v) the novel recombination stretch in the variant a sequence of GN29. The termini of unusual DNA fragments, possibly produced by strand breaks, can serve as free DNA ends to initiate recombination of the a sequence. These results support the model of double-strand-break repair for recombination of the a sequence. Sequence-specific enhancement of the recombination of the a sequence probably depends on the presence of recombinogenic elements apt to break, such as DR2 repeats and the DR4 stretch.     

Resolution of a polyomavirus-mouse hybrid replicon: release of genomic viral DNA.

RmI is a circular chimera containing 1.03 copies of polyomavirus DNA and 1,628 base pairs of mouse DNA, joined through direct and inverted repeat sequences. It is excised from the chromosome of a transformed cell via a site-specific recombination event that is dependent on the activation of the viral gene coding for large T antigen. RmI is shown here to be highly infectious for normal mouse cells. This infectivity reflects the ability of RmI to effectively yield unit-length viral DNA via intramolecular recombination. The effectiveness with which infectious viral DNA is produced from RmI is consistent with the idea that the underlying recombination event is site specific, rather than homologous or illegitimate.     

A topoisomerase II cleavage site is associated with a novel mitochondrial DNA deletion

Mitochondrial myopathies and encephalopathies can be caused by nucleotide substitutions, deletions or duplications of the mitochondrial DNA (mtDNA). In one such disorder, Kearns-Sayre Syndrome (KSS), large-scale hetero-plasmic mtDNA deletions are often found. We describe a 14-year-old boy with clinical features of KSS, plus some additional features. Analysis of the entire mitochondrial genome by the polymerase chain reaction and Southern blotting revealed a 7864-bp mtDNA deletion, heteroplasmic in its tissue distribution. DNA sequencing established that the deletion was between nucleotides 6238 and 14103, and flanked by a 4-bp (TCCT) direct repeat sequence. Deletions between direct repeats have been hypothesised to occur by a slipped-mismatching or illegitimate recombination event, or following the DNA cleavage action of topoisomerase II. Analysis of the gene sequence in the region surrounding the mtDNA deletion breakpoint in this patient revealed the presence of putative vertebrate topoisomerase II sites. We suggest that direct repeat sequences, together with putative topoisomerase II sites, may predispose certain regions of the mitochondrial genome to deletions.     

Type I restriction enzyme with RecA protein promotes illegitimate recombination

Illegitimate (non-homologous) recombination requires little or no sequence homology between recombining DNAs and has been regarded as being a process distinct from homologous recombination, which requires a long stretch of homology between recombining DNAs. However, we have found a type of illegitimate recombination that requires an interaction between long homologous DNA sequences. It was detected when a plasmid that carried 2-kb-long inverted repeats was subjected to type I (EcoKI) restriction in vivo within a special mutant strain of Escherichia coli. In the present work, we analyzed genetic requirements for this type of illegitimate recombination in well-defined genetic backgrounds. Our analysis demonstrated dependence on RecA function and on the presence of two EcoKI sites on the substrate DNA. These results are in harmony with a model in which EcoKI restriction enzyme attacks an intermediate of homologous recombination to divert it to illegitimate recombination.