Michele P. Calos

Analysis of mutation in human cells by using an Epstein-Barr virus shuttle system.

We developed highly sensitive shuttle vector systems for detection of mutations formed in human cells using autonomously replicating derivatives of Epstein-Barr virus (EBV). EBV vectors carrying the bacterial lacI gene as the target for mutation were established in human cells and later returned to Escherichia coli for rapid detection and analysis of lacI mutations. The majority of the clonal cell lines created by establishment of the lacI-EBV vector show spontaneous LacI- frequencies of less than 10(-5) and are suitable for studies of induced mutation. The ability to isolate clonal lines represents a major advantage of the EBV vectors over transiently replicating shuttle vectors (such as those derived from simian virus 40) for the study of mutation. The DNA sequence changes were determined for 61 lacI mutations induced by exposure of one of the cell lines to N-nitroso-N-methylurea. A total of 33 of 34 lacI nonsense mutations and 26 of 27 missense mutations involve G X C to A X T transitions. These data provide support for the mutational theory of cancer.

On the formation of spontaneous deletions: the importance of short sequence homologies in the generation of large deletions.

Using lacl-Z fusion strains of Escherichia coli we have devised systems that detect deletions of varying lengths. We examined deletions 700-1000 base pairs long, and genetically characterized over 250 spontaneous deletions. Of these, we analyzed 24 by direct DNA sequencing and 18 by inspection of restriction fragment patterns. Deletions of this size occur almost exclusively at short repeated sequences in both (recA+ and recA- strain backgrounds, but are detected 25-fold more frequently in a recA+ background. The frequency of deletion formation correlates with the extent of homology between the short repeated sequences, although other factors may be involved. The largest hotspot, which accounts for 60% of the deletions detected, involves the largest homology in the system (14 of 17 base pairs). Altering a single base pair within this homology reduces deletion incidence by an order of magnitude. We discuss possible mechanisms of deletion formation and consider its relationship to the excision of transposable elements.

Site-specific genomic integration in mammalian cells mediated by phage phiC31 integrase.

ABSTRACT We previously established that the phage φC31 integrase, a site-specific recombinase, mediates efficient integration in the human cell environment at attB and attP phage attachment sites on extrachromosomal vectors. We show here that phageattP sites inserted at various locations in human and mouse chromosomes serve as efficient targets for precise site-specific integration. Moreover, we characterize native “pseudo”attP sites in the human and mouse genomes that also mediate efficient integrase-mediated integration. These sites have partial sequence identity to attP. Such sites form naturally occurring targets for integration. This phage integrase-mediated reaction represents an effective site-specific integration system for higher cells and may be of value in gene therapy and other chromosome engineering strategies.

Site-specific genomic integration produces therapeutic Factor IX levels in mice

We used the integrase from phage φC31 to integrate the human Factor IX (hFIX) gene permanently into specific sites in the mouse genome. A plasmid containing attB and an expression cassette for hFIX was delivered to the livers of mice by using high-pressure tail vein injection. When an integrase expression plasmid was co-injected, hFIX serum levels increased more than tenfold to ∼4 μg/ml, similar to normal FIX levels, and remained stable throughout the more than eight months of the experiment. hFIX levels persisted after partial hepatectomy, suggesting genomic integration of the vector. Site-specific integration was proven by characterizing and quantifying genomic integration in the liver at the DNA level. Integration was documented at two pseudo-attP sites, native sequences with partial identity to attP, with one site highly predominant. This study demonstrates in vivo gene transfer in an animal by site-specific genomic integration.

Mammalian genomes contain active recombinase recognition sites.

Recombinases derived from microorganisms mediate efficient site-specific recombination. For example, the Cre recombinase from bacteriophage P1 efficiently carries out recombination at its loxP target sites. While this enzyme can function in mammalian cells, the 34bp loxP site is expected to be absent from mammalian genomes. We have discovered that sequences from the human and mouse genomes surprisingly divergent from loxP can support Cre-mediated recombination at up to 100% of the efficiency of the native loxP site in bacterial assays. Transient assays in human cells demonstrate that such pseudo-lox sites also support Cre-mediated integration and excision in the human cell environment. Pseudo sites for Cre and other recombinases may be useful for site-specific insertion of exogenous genes into mammalian genomes during gene therapy and other genetic engineering processes.

Isolation of human sequences that replicate autonomously in human cells.

We have isolated a heterogeneous collection of human genomic sequences which replicate autonomously when introduced into human cells. The novel strategy for the isolation of these sequences involved cloning random human DNA fragments into a defective Epstein-Barr virus vector. This vector alone was unable to replicate in human cells, but appeared to provide for the nuclear retention of linked DNA. The human sequences persist in a long-term replication assay (greater than 2 months) in the presence of the viral nuclear retention sequences. Using a short-term (4-day) assay, we showed that the human sequences are able to replicate in the absence of all viral sequences. The plasmids bearing human sequences were shown to replicate based on the persistence of MboI-sensitive plasmid DNA in the long-term assay and the appearance of DpnI-resistant DNA in the short-term assay. The human sequences were shown to be responsible for the replication activity and may represent authentic human origins of replication.

Phage R4 integrase mediates site-specific integration in human cells.

The R4 integrase is a site-specific, unidirectional recombinase derived from the genome of phage R4 of Streptomyces parvulus. Here we define compact attB and attP recognition sites for the R4 integrase and express the enzyme in mammalian cells. We demonstrate that R4 integrase functions in human cells, performing efficient and precise recombination between R4 attB and attP sites cloned on an extrachromosomal vector. We also provide evidence that the enzyme can mediate integration of an incoming plasmid bearing an attB or attP site into endogenous sequences in the human genome. Furthermore, when R4 attB and attP sites are placed into the human genome, either by random integration or at a specific sequence by using the phi C31 integrase, they act as targets for integration of incoming plasmids bearing R4 att sites. The R4 integrase has immediate utility as a site-specific integration tool for genome engineering, as well as potential for further development.

DNA sequence at the integration sites of the insertion element IS1

We have detected two independent occurrences of insertion mutations in the lacl gene of E. Coli, and have used small plasmids carrying the l gene to purify large amounts of DNA containing these insertions. Analyses with restriction endonucleases and DNA sequencing techniques establish that both insertions involve the previously characterized element IS1. In each case, the integration of IS1 into the l gene DNA is associated with a directly repeated sequence of 9 nucleotides appearing at each end of the insertion element. Since one of these sequences was present in the wild-type gene, the second sequence either preexisted in the IS1 before integration, or else was generated by the process of insertion itself. The 9 base repeat is different in both cases. We discuss the relevance of these findings to the mechanism of integration of transposable elements.

Autonomous DNA replication in human cells is affected by the size and the source of the DNA.

We previously developed short-term and long-term assays for autonomous replication of DNA in human cells. This study addresses the requirements for replication in these assays. Sixty-two random human genomic fragments ranging in size from 1 to 21 kb were cloned in a prokaryotic vector and tested for their replication ability in the short-term assay. We found a positive correlation between replication strength and fragment length, indicating that large size is favored for efficient autonomous replication in human cells. All large fragments replicated efficiently, suggesting that signals which can direct the initiation of DNA replication in human cells are either very abundant or have a low degree of sequence specificity. Similar results were obtained in the long-term assay. We also used the same assays to test in human cells a random series of fragments derived from Escherichia coli chromosomal DNA. The bacterial fragments supported replication less efficiently than the human fragments in the short-term and long-term assays. This result suggests that while the sequence signals involved in replication in human cells are found frequently in human DNA, they are uncommon in bacterial DNA.

Genetic and sequence analysis of frameshift mutations induced by ICR-191☆

Abstract A genetic and sequence analysis of 373 ICR-191-induced mutations in the lacI gene of Escherichia coli reveals that 365 of the mutations (97·9%) are frameshifts involving the addition or deletion of a single base-pair from a sequence including, in one case, a sequence. Some of the remaining eight mutations (2·1%) represent the loss or gain of a base-pair from a sequence. Certain mutational sites are relative hotspots for ICR-191-induced mutations, and we have analyzed the role of surrounding sequences on relative mutation rates. The preference for +1 frameshifts or −1 frameshifts is site-specific, so that at some sites +1 frameshifts predominate by a 10:1 ratio, whereas at other sites −1 frameshifts are favored by an approximately 2:1 ratio. The characterized frameshift mutations in lacI described here are useful for constructing systems to detect other frameshift and deletion mutations.