Foreign DNA introduced by calcium phosphate is integrated into repetitive DNA elements of the mouse L cell genome.

Kato, Shingo; Anderson, Richard A.; Camerini‐Otero, R. Daniel

doi:10.1128/mcb.6.5.1787

Cited by 68 publications

(29 citation statements)

References 51 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…This mechanism has been suggested by numerous investigators, and this model receives the most support from the reviewed data. 42,58 According to this model, a genomic lesion, either single-or doublestranded, would attract repair factors. Any DNA with free ends, which happened to be in the vicinity or be recruited to the lesion by repair factors, could become part of the 'healing' process and be integrated (see Figure 3).…”

Section: Proposed Mechanisms Of Illegitimate Dna Integrationmentioning

confidence: 99%

“…44 However, more complex insertion patterns are frequently observed (see Figure 2b). The recipient genomic locus can undergo extensive physical rearrangements at the site of integration, 45,50,51,58,59 including deletions (as much as tens of kb), duplications, and translocations, among others. 43,52,60 Another consequence is that the integrated material can interrupt coding sequences.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Illegitimate DNA integration in mammalian cells

2003

View full text Add to dashboard Cite

Foreign DNA integration is one of the most widely exploited cellular processes in molecular biology. Its technical use permits us to alter a cellular genome by incorporating a fragment of foreign DNA into the chromosomal DNA. This process employs the cell's own endogenous DNA modification and repair machinery. Two main classes of integration mechanisms exist: those that draw on sequence similarity between the foreign and genomic sequences to carry out homology-directed modifications, and the nonhomologous or 'illegitimate' insertion of foreign DNA into the genome. Gene therapy procedures can result in illegitimate integration of introduced sequences and thus pose a risk of unforeseeable genomic alterations. The choice of insertion site, the degree to which the foreign DNA and endogenous locus are modified before or during integration, and the resulting impact on structure, expression, and stability of the genome are all factors of illegitimate DNA integration that must be considered, in particular when designing genetic therapies.

show abstract

Section: Proposed Mechanisms Of Illegitimate Dna Integrationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Illegitimate DNA integration in mammalian cells

2003

View full text Add to dashboard Cite

show abstract

“…In rodent cells, integration often involves * Corresponding author. large amounts of tandemly arranged DNA (35,38) and has been reported to be accompanied by large rearrangements in the surrounding cell DNA (19,38). However, the amount of DNA integrated into human cells is generally much less (9,17,22,23,29), and integration commonly occurs without major rearrangements in the cell DNA (33).…”

mentioning

confidence: 99%

“…DNA transfected into mammalian cells most often integrates at random locations in the genome (19,33,35,38), although a small fraction can integrate into homologous sequences (16,37). In rodent cells, integration often involves * Corresponding author.…”

mentioning

confidence: 99%

Acquisition of telomere repeat sequences by transfected DNA integrated at the site of a chromosome break.

Murnane

1993

Mol. Cell. Biol.

View full text Add to dashboard Cite

Previous analysis of plasmid DNA transfected into 108 cell clones demonstrated extensive polymorphism near the integration site in one clone. This polymorphism was apparent by Southern blot analysis as diffuse bands that extended over 30 kb. In the present study, nucleotide sequence analysis of cloned DNA from the integration site revealed telomere repeat sequences at the ends of the integrated plasmid DNA. The telomere repeat sequences at one end were located at the junction between the plasmid and cell DNA. The telomere repeat sequences at the other end were located in the opposite orientation in the polymorphic region and were shown by digestion with BAL 31 to be at the end of the chromosome. Telomere repeat sequences were not found at this location in the plasmid or parent cell DNA. Although the repeat sequences may have been acquired by recombination, a more likely explanation is that they were added to the ends of the plasmid by telomerase before integration. Comparison of the cell DNA before and after integration revealed that a chromosome break had occurred at the integration site, which was shown by fluorescent in situ hybridization to be located near the telomere of chromosome 13. These results demonstrate that chromosome breakage and rearrangement can result in interstitial telomere repeat sequences within the human genome. These sequences could promote genomic instability, because short repeat sequences can be recombinational hotspots. The results also show that

show abstract

“…Mammalian cells integrate foreign DNA widely throughout the genome in a process often referred to as random integration (27,58). The integration of DNA into the mammalian genome is efficient, with up to 20% of cells integrating microinjected DNA (10).…”

mentioning

confidence: 99%

High-Frequency Illegitimate Integration of Transfected DNA at Preintegrated Target Sites in a Mammalian Genome

Merrihew

Marburger

Pennington

et al. 1996

Molecular and Cellular Biology

View full text Add to dashboard Cite

To examine the mechanisms of recombination governing the illegitimate integration of transfected DNA into a mammalian genome, we developed a cell system that selects for integration events in defined genomic regions. Cell lines with chromosomal copies of the 3 portion of the adenine phosphoribosyltransferase (APRT) gene (targets) were established. The 5 portion of the APRT gene, which has no homology to the integrated 3 portion, was then electroporated into the target cell lines, and selection for APRT gene function was applied. The reconstruction of the APRT gene was detected at frequencies ranging from less than 10 ؊7 to 10 ؊6 per electroporated cell. Twenty-seven junction sequences between the integrated 5 APRT and its chromosomal target were analyzed. They were found to be randomly distributed in a 2-kb region immediately in front of the 3 portion of the APRT gene. The junctions fell into two main classes: those with short homologies (microhomologies) and those with inserted DNA of uncertain origin. Three long inserts were shown to preexist elsewhere in the genome. Reconstructed cell lines were analyzed for rearrangements at the target site by Southern blotting; a variety of simple and complex rearrangements were detected. Similar analysis of individual clones of the parental cell lines revealed analogous types of rearrangement, indicating that the target sites are unstable. Given the high frequency of integration events at these sites, we speculate that transfected DNA may preferentially integrate at unstable mammalian loci. The results are discussed in relation to possible mechanisms of DNA integration.Mammalian genomes undergo many dynamic events and modifications. Chromosomal alterations under genetic control in normal cells include immune system rearrangements (31) and transposition events (75). In addition, genomic instability is a hallmark of tumor cell progression (24). Chromosomal deletions, translocations, and gene amplification are rearrangements commonly resulting from illegitimate (or nonhomologous) recombination in cancer cells. Although the processes that govern these rearrangements remain largely undefined, analysis of the DNA sequences at illegitimate recombination junctions has provided important information concerning the mechanisms involved (35).The dynamic properties of mammalian chromosomes are evident in the illegitimate (nonhomologous) integration of exogenously introduced DNA. Mammalian cells integrate foreign DNA widely throughout the genome in a process often referred to as random integration (27,58). The integration of DNA into the mammalian genome is efficient, with up to 20% of cells integrating microinjected DNA (10). Furthermore, integration events are usually associated with major chromosomal rearrangements that remain largely undefined (62). Fully characterized rearrangements include a 22-kb deletion (33) and a 5-kb duplication of the chromosomal sequence flanking the integrated DNA (76). Additional analysis of random integrants may provide insights into the processes involv...

show abstract

Foreign DNA introduced by calcium phosphate is integrated into repetitive DNA elements of the mouse L cell genome.

Cited by 68 publications

References 51 publications

Illegitimate DNA integration in mammalian cells

Illegitimate DNA integration in mammalian cells

Acquisition of telomere repeat sequences by transfected DNA integrated at the site of a chromosome break.

High-Frequency Illegitimate Integration of Transfected DNA at Preintegrated Target Sites in a Mammalian Genome

Contact Info

Product

Resources

About