The Tandem Inversion Duplication in<i>Salmonella enterica</i>: Selection Drives Unstable Precursors to Final Mutation Types

Kugelberg, Elisabeth; Kofoid, Eric; Andersson, Dan I.; Lu, Yong; Mellor, Joseph; Roth, Frederick P.; Roth, John R.

doi:10.1534/genetics.110.114074

Cited by 45 publications

(71 citation statements)

References 47 publications

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“…Chromosomal copy-number variations (CNVs) are generally detected well after their establishment, leaving only the final CNV structure as evidence of the mechanism that generated the variation 1,2 . Detecting and recovering extrachromosomal circular DNA (eccDNA) in earlier stages of CNV formation might elucidate ongoing processes in genomic rearrangements.…”

Section: Introductionmentioning

confidence: 99%

Genome-wide Purification of Extrachromosomal Circular DNA from Eukaryotic Cells

Møller

Bojsen

Tachibana

et al. 2016

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Extrachromosomal circular DNAs (eccDNAs) are common genetic elements in Saccharomyces cerevisiae and are reported in other eukaryotes as well. EccDNAs contribute to genetic variation among somatic cells in multicellular organisms and to evolution of unicellular eukaryotes. Sensitive methods for detecting eccDNA are needed to clarify how these elements affect genome stability and how environmental and biological factors induce their formation in eukaryotic cells. This video presents a sensitive eccDNA-purification method called Circle-Seq. The method encompasses column purification of circular DNA, removal of remaining linear chromosomal DNA, rolling-circle amplification of eccDNA, deep sequencing, and mapping. Extensive exonuclease treatment was required for sufficient linear chromosomal DNA degradation. The rolling-circle amplification step by φ29 polymerase enriched for circular DNA over linear DNA. Validation of the Circle-Seq method on three S. cerevisiae CEN.PK populations of 10 10 cells detected hundreds of eccDNA profiles in sizes larger than 1 kilobase. Repeated findings of ASP3-1, COS111, CUP1, RSC30, HXT6, HXT7 genes on circular DNA in both S288c and CEN.PK suggests that DNA circularization is conserved between strains at these loci. In sum, the Circle-Seq method has broad applicability for genome-scale screening for eccDNA in eukaryotes as well as for detecting specific eccDNA types.

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Section: Introductionmentioning

confidence: 99%

Genome-wide Purification of Extrachromosomal Circular DNA from Eukaryotic Cells

Møller

Bojsen

Tachibana

et al. 2016

JoVE

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“…Indeed, stalled forks have recently been shown to produce DSB-independent fusions of nearby inverted-repeats, which lead to the formation of palindromic chromosomes (Mizuno et al 2009;Paek et al 2009). The mechanisms by which these fusions take place remain a subject of debate, and three distinct possibilities have been proposed: faulty template switching, tandem inversion duplications, and replication U-turns (Mizuno et al 2009(Mizuno et al , 2013Paek et al 2009;Kugelberg et al 2010;Seier et al 2012).…”

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Organelle DNA rearrangement mapping reveals U-turn-like inversions as a major source of genomic instability in Arabidopsis and humans

et al. 2015

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Failure to maintain organelle genome stability has been linked to numerous phenotypes, including variegation and cytosolic male sterility (CMS) in plants, as well as cancer and neurodegenerative diseases in mammals. Here we describe a next-generation sequencing approach that precisely maps and characterizes organelle DNA rearrangements in a single genome-wide experiment. In addition to displaying global portraits of genomic instability, it surprisingly unveiled an abundance of shortrange rearrangements in Arabidopsis thaliana and human organelles. Among these, short-range U-turn-like inversions reach 25% of total rearrangements in wild-type Arabidopsis plastids and 60% in human mitochondria. Furthermore, we show that replication stress correlates with the accumulation of this type of rearrangement, suggesting that U-turn-like rearrangements could be the outcome of a replication-dependent mechanism. We also show that U-turn-like rearrangements are mostly generated using microhomologies and are repressed in plastids by Whirly proteins WHY1 and WHY3. A synergistic interaction is also observed between the genes for the plastid DNA recombinase RECA1 and those encoding plastid Whirly proteins, and the triple mutant why1why3reca1 accumulates almost 60 times the WT levels of U-turn-like rearrangements. We thus propose that the process leading to U-turn-like rearrangements may constitute a RecA-independent mechanism to restart stalled forks. Our results reveal that short-range rearrangements, and especially U-turn-like rearrangements, are a major factor of genomic instability in organelles, and this raises the question of whether they could have been underestimated in diseases associated with mitochondrial dysfunction.

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“…Replicative transpositions with one novel sequence junction ( Figure 2) underlie some gene amplifications in Acinetobacter (Reams and Neidle 2003;Reams and Neidle 2004a) and on the E. coli F9 plasmid (Kugelberg et al 2006;Kugelberg et al 2010), but they are rare and have been detected only after long-term selection for increased copy number. Extremely rare amplified duplications have been seen with novel sequence junctions at both ends of a transposable element at the duplication junction (Reams and Neidle 2003;E.…”

Section: Duplication By Transpositionmentioning

confidence: 99%

“…Following prolonged growth under selection for increased gene copy number, amplifications (more than two copies) whose structure differs from the duplication types that predominate in unselected cultures are recovered (Kugelberg et al 2006;Kugelberg et al 2010). Selected amplifications have tiny junction sequences (0-10 bp) that seem unlikely to form by recombination (Reams and Neidle 2004a;Kugelberg et al 2006Kugelberg et al , 2010. 8.…”

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“…Some selected amplifications (20%) have repeated tandem inversion duplications (TID), in which a parental sequence element (e.g., ABCD) is repeated three times in alternating orientation ABCD-D9C9B9A9-ABCD and amplified by exchanges between flanking direct repeats. The parent sequence ABCD can be .10 kb and the initial TID junctions are flanked by extensive perfectly complementary sequences that can be rendered asymmetric (ABCD-C9B9A9-BCD) by junction deletions (Kugelberg et al 2010;Lin et al 2011). …”

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Multiple Pathways of Duplication Formation with and Without Recombination (RecA) in Salmonella enterica

et al. 2012

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Duplications are often attributed to "unequal recombination" between separated, directly repeated sequence elements (.100 bp), events that leave a recombinant element at the duplication junction. However, in the bacterial chromosome, duplications form at high rates (10 23 -10 25 /cell/division) even without recombination (RecA). Here we describe 1800 spontaneous lac duplications trapped nonselectively on the low-copy F9 128 plasmid, where lac is flanked by direct repeats of the transposable element IS3 (1258 bp) and by numerous quasipalindromic REP elements (30 bp). Duplications form at a high rate (10 24 /cell/division) that is reduced only about 11-fold in the absence of RecA. With and without RecA, most duplications arise by recombination between IS3 elements (97%). Formation of these duplications is stimulated by IS3 transposase (Tnp) and plasmid transfer functions (TraI). Three duplication pathways are proposed. First, plasmid dimers form at a high rate stimulated by RecA and are then modified by deletions between IS3 elements (resolution) that leave a monomeric plasmid with an IS3-flanked lac duplication. Second, without RecA, duplications occur by singlestrand annealing of DNA ends generated in different sister chromosomes after transposase nicks DNA near participating IS3 elements. The absence of RecA may stimulate annealing by allowing chromosome breaks to persist. Third, a minority of lac duplications (3%) have short (0-36 bp) junction sequences (SJ), some of which are located within REP elements. These duplication types form without RecA, Tnp, or Tra by a pathway in which the palindromic junctions of a tandem inversion duplication (TID) may stimulate deletions that leave the final duplication. G ENE duplications are among the first mutations for which a physical basis was known. The Bar-Eye mutation of Drosophila was discovered in 1914 (Tice 1914) and shown genetically and cytologically in 1936 to be a duplication (Bridges 1936;Muller 1936)-well before the Watson-Crick model for DNA. The attached-X mutation was discovered even earlier and is essentially an inversion duplication (Morgan 1925). Recently, duplications have been shown to be exceedingly common polymorphisms in human populations (Conrad et al. 2010) and somatic amplifications play an important role in origins of malignancy and resistance to cancer therapies (Lu et al. 2008;Zhang et al. 2009;Conrad et al. 2010). Gene duplications also play a major role in the evolution of new genes (Ohno 1970;Bergthorsson et al. 2007). Despite the high frequency and biological importance of duplications, the process by which they form remains uncertain.Distinct models have been suggested for duplication formation in various genetic systems. In Drosophila, duplications often have transposable elements between copies (Green 1985;Tsubota et al. 1989). In humans, duplications most commonly arise between extensive sequence repeats (Redon et al. 2006) and are sometimes promoted by palindromic sequence elements (Conrad et al. 2010). A major question is how...

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The Tandem Inversion Duplication inSalmonella enterica: Selection Drives Unstable Precursors to Final Mutation Types

Cited by 45 publications

References 47 publications

Genome-wide Purification of Extrachromosomal Circular DNA from Eukaryotic Cells

Genome-wide Purification of Extrachromosomal Circular DNA from Eukaryotic Cells

Organelle DNA rearrangement mapping reveals U-turn-like inversions as a major source of genomic instability in Arabidopsis and humans

Multiple Pathways of Duplication Formation with and Without Recombination (RecA) in Salmonella enterica

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