Integration of exogenous DNA into mouse embryonic stem cell chromosomes shows preference into genes and frequent modification at junctions.

Chromosomal integration of exogenous DNA in mammalian cells allows stable gene expression for a variety of biological applications. Although it is presumably mediated by DNA repair machinery, little is known regarding site preferences and other characteristics. We isolated and analyzed 256 chromosomal-plasmid DNA integration junctions from 158 plasmid integrants after electroporation in mouse embryonic stem (ES) cells. The frequency of integrations in transcription units (40%) showed a slight but significant increase over the frequency estimated by computer simulation of random events (30%), suggesting preferential integration into genes. Microarray analysis revealed preference into genes, which are expressed in mouse ES cells. In contrast, bias toward integrations around transcriptional start sites, CpG islands and repeat elements was not observed. Furthermore, all host chromosome sequences as well as the majority of plasmids (96%) at the integration junctions were modified by deletions and/or insertions of additional nucleotides. Detailed analyses revealed frequent stem loop/hairpin formation mediated by weak homologies near plasmid ends before integration. Our study sheds light on a natural fate of exogenous DNA, which preferentially integrates into transcriptionally active chromosomal sites and by an imprecise end-joining pathway, associated with highly frequent modification of the end sequences.

Correction of mutant Fanconi anemia gene by homologous recombination in human hematopoietic cells using adeno-associated virus vector.

BACKGROUND: Adeno-associated virus (AAV) vectors have been shown to correct a variety of mutations in human cells by homologous recombination (HR) at high rates, which can overcome insertional mutagenesis and transgene silencing, two of the major hurdles in conventional gene addition therapy of inherited diseases. We examined an ability of AAV vectors to repair a mutation in human hematopoietic cells by HR. METHODS: We infected a human B-lymphoblastoid cell line (BCL) derived from a normal subject with an AAV, which disrupts the hypoxanthine phosphoribosyl transferase1 (HPRT1) locus, to measure the frequency of AAV-mediated HR in BCL cells. We subsequently constructed an AAV vector encoding the normal sequences from the Fanconi anemia group A (FANCA) locus to correct a mutation in the gene in BCL derived from a FANCA patient. RESULTS: Under optimal conditions, approximately 50% of BCL cells were transduced with an AAV serotype 2 (AAV-2) vector. In FANCA BCL cells, up to 0.016% of infected cells were gene-corrected by HR. AAV-mediated restoration of normal genotypic and phenotypic characteristics in FANCA-mutant cells was confirmed at the DNA, protein and functional levels. CONCLUSIONS: The results obtained in the present study indicate that AAV vectors may be applicable for gene correction therapy of inherited hematopoietic disorders.

Correction of chromosomal mutation and random integration in embryonic stem cells with helper-dependent adenoviral vectors.

For gene therapy of inherited diseases, targeted integration/gene repair through homologous recombination (HR) between exogenous and chromosomal DNA would be an ideal strategy to avoid potentially serious problems of random integration such as cellular transformation and gene silencing. Efficient sequence-specific modification of chromosomes by HR would also advance both biological studies and therapeutic applications of a variety of stem cells. Toward these goals, we developed an improved strategy of adenoviral vector (AdV)-mediated HR and examined its ability to correct an insertional mutation in the hypoxanthine phosphoribosyl transferase (Hprt) locus in male mouse ES cells. The efficiency of HR was compared between four types of AdVs that contained various lengths of homologies at the Hprt locus and with various multiplicities of infections. The frequency of HR with helper-dependent AdVs (HD AdVs) with an 18.6-kb homology reached 0.2% per transduced cell at a multiplicity of infection of 10 genomes per cell. Detection of random integration at DNA levels by PCR revealed extremely high efficiency of 5% per cell. We also isolated and characterized chromosomal sites where HD AdVs integrated in a random manner. In contrast to retroviral, lentiviral, and adeno-associated viral vectors, which tend to integrate into genes, the integration sites of AdV was distributed randomly inside and outside genes. These findings suggest that HR mediated by HD AdVs is efficient and relatively safe and might be a new viable option for ex vivo gene therapy as well as a tool for chromosomal manipulation of a variety of stem cells.

Detachment analysis of the translocated W chromosome shows that the female-specific randomly amplified polymorphic DNA (RAPD) marker, female-218, is derived from the second chromosome fragment region of the translocated W chromosome of the sex-limited p(B) silkworm (Bombyx mori ) strain.

The sex chromosomes of the silkworm, Bombyx mori, are designated ZW for the female and ZZ for the male. We previously characterized a female-specific randomly amplified polymorphic DNA (RAPD) marker, designated Female-218, from the translocation-bearing W chromosomes. These W chromosomes contain a region of the second chromosome, which carries visible larval markers of the p loci. We used strain TWPB in which female larvae have black skin due to the p(B) gene (T(W;2)p(B), +p/+p) while male larvae have whitish skin (+p/+p). To determine whether the Female-218 RAPD marker is derived from the "W region" or a "second chromosome fragment", we induced a detachment of the translocated W chromosome, T(W;2)p(B), by treating the eggs with hot water at an early developmental stage. After hot water treatment, we obtained 27 white female larvae out of 4850 female larvae. The Female-218 RAPD marker was not amplified in 26 out of 27 white female larvae, and was amplified from one white female larva. Moreover, we obtained 11 black male larvae out of 5377 male larvae. Eight out of 11 black male larvae became adult moths, and the Female-218 RAPD marker was amplified from all eight male moths. Examination of the genetic relationship between the Female-218 RAPD marker and the second chromosome fragment of the translocated W chromosome strongly indicates that the Female-218 RAPD marker is amplified from the region of second chromosome fragment of the T(W;2)p(B) chromosome.