Recombinant protein expression by targeting pre-selected chromosomal loci

Background  

Recombinant protein expression in mammalian cells is mostly achieved by stable integration of transgenes into the chromosomal DNA of established cell lines. The chromosomal surroundings have strong influences on the expression of transgenes. The exploitation of defined loci by targeting expression constructs with different regulatory elements is an approach to design high level expression systems. Further, this allows to evaluate the impact of chromosomal surroundings on distinct vector constructs.     

Location of crossovers during gene targeting with insertion and replacement vectors.

Gene targeting was used to introduce nonselectable genetic changes into chromosomal loci in mouse embryo-derived stem cells. The nonselectable markers were linked to a selectable marker in both insertion- and replacement-type vectors, and the transfer of the two elements to the Hprt locus was assayed. When insertion vectors were used as substrates, the frequency of transfer was highly dependent upon the distance between the nonselectable marker and the double-strand break in the vector. A marker located close to the vector ends was frequently lost, suggesting that a double-strand gap repair activity is involved in vector integration. When replacement vectors were used, cotransfer of a selectable marker and a nonselectable marker 3 kb apart was over 50%, suggesting that recombination between vector and target often occurs near the ends of the vector. To illustrate the use of replacement vectors to transfer specific mutations to the genome, we describe targeting of the delta F508 mutation to the CFTR gene in mouse embryo-derived stem cells.     

Stringent and reproducible tetracycline-regulated transgene expression by site-specific insertion at chromosomal loci with pre-characterised induction characteristics

Background  

The ability to regulate transgene expression has many applications, mostly concerning the analysis of gene function. Desirable induction characteristics, such as low un-induced expression, high induced expression and limited cellular heterogeneity, can be seriously impaired by chromosomal position effects at the site of transgene integration. Many clones may therefore need to be screened before one with optimal induction characteristics is identified. Furthermore, such screens must be repeated for each new transgene investigated, and comparisons between clones with different transgenes is complicated by their different integration sites.     

Virulence-associated chromosomal loci of Shigella flexneri identified by random Tn5 insertion mutagenesis

Shigellae are the causative agents of bacillary dysentery and are capable of invading epithelial cells, multiplying therein and spreading into adjacent cells. To identify genes on the chromosome associated with the virulence phenotype, 9114 independent Tn5 insertion mutants were isolated in a virulent strain of Shigella flexneri. By using an in vitro assay for intercellular spread or an animal infection model, the Serény test, 50 chromosomal Tn5 mutants with reduced virulence were identified. The 50 mutants were characterized with respect to their virulence phenotypes, including three different mutations that affect invasion of epithelial cells, bacterial metabolism and structure of lipopolysaccharide. Mutants with reduced invasive ability were further characterized and it was found that two of them had decreased levels of IpaB, C and D antigens as well as the mRNA for the ipaBCD operon encoded by the large virulence plasmid, suggesting that positive regulatory elements for the ipaBCD operon are encoded by the chromosome. Assignment of the 50 Tn5 insertions of the mutants to the 19 NotI restriction fragments of the chromosomal DNA has permitted the identification of at least nine virulence-associated chromosomal loci.     

Viral vector targeting.

The field of viral vector targeting is advancing rapidly. Recent advances include the successful use of bifunctional crosslinkers to target adenoviral and retroviral vectors, elucidation of the crystal structures of an adenoviral and a retroviral receptor-binding domain, and definition of strategies for inserting short targeting peptides and larger polypeptide-binding domains into the coat proteins of a number of different viral vectors. Novel targeting strategies based on host range restriction and protease activation have been developed, targeted replication-competent vectors have shown promise as anti-cancer agents and the possibility of selecting targeted vectors from vector display libraries has been established.     

Common organization of chromosomal loci for production of different capsular polysaccharides in Haemophilus influenzae.

Cloned Haemophilus influenzae type b capsulation genes were used as hybridization probes to isolate DNA from the capsulation loci (cap) of other serotypes of H. influenzae. Mapping of the resulting clones and Southern hybridization analysis of chromosomal DNAs from type a, b, c, and d strains showed that in each strain cap was organized in the same way: a central DNA segment specific to each serotype flanked by DNA segments of common structure. We infer that enzymes necessary for the synthesis of specific capsular polysaccharide are encoded in the central segment of cap, while proteins involved in a more general way in the process of capsulation are encoded in the flanking segments. Studies of the function of the DNA in one of these non-serotype-specific flanking segments (J. S. Kroll, I. Hopkins, and E. R. Moxon, Cell 53:347-356, 1988) have previously identified a gene encoding a protein necessary for polysaccharide export, an event now deduced to proceed by a mechanism independent of the nature of the disaccharide subunit in the polysaccharide. The near-total duplication of cap that has been found in most type b strains was not found at the analogous locus in the other serotypes. This reinforces our previous hypothesis, based on study of type b strains alone, that while such a duplication is unnecessary for capsulation, it confers some unexplained survival advantage on the widely prevalent strains with this clinically important serotype.     

The molecular basis of multiple vector insertion by gene targeting in mammalian cells

Gene targeting using sequence insertion vectors generally results in integration of one copy of the targeting vector generating a tandem duplication of the cognate chromosomal region of homology. However, occasionally the target locus is found to contain >1 copy of the integrated vector. The mechanism by which the latter recombinants arise is not known. In the present study, we investigated the molecular basis by which multiple vectors become integrated at the chromosomal immunoglobulin mu locus in a murine hybridoma. To accomplish this, specially designed insertion vectors were constructed that included six diagnostic restriction enzyme markers in the Cmu region of homology to the target chromosomal mu locus. This enabled contributions by the vector-borne and chromosomal Cmu sequences at the recombinant locus to be ascertained. Targeted recombinants were isolated and analyzed to determine the number of vector copies integrated at the chromosomal immunoglobulin mu locus. Targeted recombinants identified as bearing >1 copy of the integrated vector resulted from a Cmu triplication formed by two vector copies in tandem. Examination of the fate of the Cmu region markers suggested that this class of recombinant was generated predominantly, if not exclusively, by two targeted vector integration events, each involving insertion of a single copy of the vector. Both vector insertion events into the chromosomal mu locus were consistent with the double-strand-break repair mechanism of homologous recombination. We interpret our results, taken together, to mean that a proportion of recipient cells is in a predetermined state that is amenable to targeted but not random vector integration.     

A bacterial model system for chromosomal targeting.

A system that permits efficient site-specific chromosomal targeting of foreign DNA on the Escherichia coli chromosome has been developed, using the FLP site-specific recombination system derived from the yeast 2 mu plasmid. The system demonstrates the feasibility of using site-specific recombination for this purpose, and provides a means to gather information on parameters that may affect chromosomal targeting to guide efforts to establish similar systems in higher eukaryotes. In this model system, the efficiency of integration of foreign DNA is affected by the location of the target site in the chromosome, and the structure of the recombination sites.     

Targeted chromosomal insertion of large DNA into the human genome by a fiber-modified high-capacity adenovirus-based vector system

A prominent goal in gene therapy research concerns the development of gene transfer vehicles that can integrate exogenous DNA at specific chromosomal loci to prevent insertional oncogenesis and provide for long-term transgene expression. Adenovirus (Ad) vectors arguably represent the most efficient delivery systems of episomal DNA into eukaryotic cell nuclei. The most advanced recombinant Ads lack all adenoviral genes. This renders these so-called high-capacity (hc) Ad vectors less cytotoxic/immunogenic than those only deleted in early regions and creates space for the insertion of large/multiple transgenes. The versatility of hcAd vectors is been increased by capsid modifications to alter their tropism and by the incorporation into their genomes of sequences promoting chromosomal insertion of exogenous DNA. Adeno-associated virus (AAV) can insert its genome into a specific human locus designated AAVS1. Trans- and cis-acting elements needed for this reaction are the AAV Rep78/68 proteins and Rep78/68-binding sequences, respectively. Here, we describe the generation, characterization and testing of fiber-modified dual hcAd/AAV hybrid vectors (dHVs) containing both these elements. Due to the inhibitory effects of Rep78/68 on Ad-dependent DNA replication, we deployed a recombinase-inducible gene switch to repress Rep68 synthesis during vector rescue and propagation. Flow cytometric analyses revealed that rep68-positive dHVs can be produced similarly well as rep68-negative control vectors. Western blot experiments and immunofluorescence microscopy analyses demonstrated transfer of recombinase-dependent rep68 genes into target cells. Studies in HeLa cells and in the dystrophin-deficient myoblasts from a Duchenne muscular dystrophy (DMD) patient showed that induction of Rep68 synthesis in cells transduced with fiber-modified and rep68-positive dHVs leads to increased stable transduction levels and AAVS1-targeted integration of vector DNA. These results warrant further investigation especially considering the paucity of vector systems allowing permanent phenotypic correction of patient-own cell types with large DNA (e.g. recombinant full-length DMD genes).     

Comparison of targeted-gene replacement frequencies in Drosophila melanogaster at the forked and white loci.

P element-induced gene conversion has been previously used to modify the white gene of Drosophila melanogaster in a directed fashion. The applicability of this approach of gene targeting in Drosophila melanogaster, however, has not been analyzed quantitatively for other genes. We took advantage of the P element-induced forked allele, f(hd), which was used as a target, and we constructed a vector containing a modified forked fragment for converting f(hd). Conversion frequencies were analyzed for this locus as well as for an alternative white allele, w(eh812). Combination of both P element-induced mutant genes allowed the simultaneous analysis of conversion frequencies under identical genetic, developmental, and environmental conditions. This paper demonstrates that gene conversion through P element-induced gap repair can be applied with similar success rates at the forked locus and in the white gene. The average conversion frequency at forked was 0.29%, and that at white was 0.17%. These frequencies indicate that in vivo gene targeting in Drosophila melanogaster should be applicable for other genes in this species at manageable rates. We also confirmed the homolog dependence of reversions at the forked locus, indicating that P elements transpose via a cut-and-paste mechanism. In a different experiment, we attempted conversion with a modified forked allele containing the su(Hw) binding site. Despite an increased sample size, there were no conversion events with this template. One interpretation (under investigation) is that the binding of the su(Hw) product prevents double-strand break repair.     

Gene targeting with a replication-defective adenovirus vector.

Wide application of the gene-targeting technique has been hampered by its low level of efficiency. A replication-defective adenovirus vector was used for efficient delivery of donor DNA in order to bypass this problem. Homologous recombination was selected between a donor neo gene inserted in the adenovirus vector and a target mutant neo gene on a nuclear papillomavirus plasmid. These recombinant adenoviruses allowed gene transfer to 100% of the treated cells without impairing their viability. Homologous recombinants were obtained at a level of frequency much higher than that obtained by electroporation or a calcium phosphate procedure. The structure of the recombinants was analyzed in detail after recovery in an Escherichia coli strain. All of the recombinants examined had experienced a precise correction of the mutant neo gene. Some of them had a nonhomologous rearrangement of their sequences as well. One type of nonhomologous recombination took place at the end of the donor-target homology. The vector adenovirus DNA was inserted into some of the products obtained at a high multiplicity of infection. The insertion was at the end of the donor-target homology with a concomitant insertion of a 10-bp-long filler sequence in one of the recombinants. The possible relationship between these rearrangements and the homologous recombination is discussed. These results demonstrate the applicability of adenovirus-mediated gene delivery in gene targeting and gene therapy.     

Molecular evidence that the genes for dioecism and monoecism in Spinacia oleracea L. are located at different loci in a chromosomal region

Spinach (Spinacia oleracea L.) is widely known to be dioecious. However, monoecious plants can also occur in this species. Sex expression in dioecious spinach plants is controlled by a single gene pair termed X and Y. Our previous study showed that a single, incompletely dominant gene, which controls the monoecious condition in spinach line 03–336, should be allelic or linked to X/Y. Here, we developed 19 AFLP markers closely linked to the monoecious gene. The AFLP markers were mapped to a 38.2-cM chromosomal region that included the monoecious gene, which is bracketed between flanking markers with a distance of 7.1 cM. The four AFLP markers developed in our studies were converted into sequence-characterized amplified region (SCAR) markers, which are linked to both the monoecious gene and Y and are common to both populations segregating for the genes. Linkage analysis using the SCAR markers suggested that the monoecious gene (M) and Y are located in different intervals, between different marker pairs. Analysis of populations segregating for both M and Y also directly demonstrates linkage of the genes at a distance of ∼12 cM. The data presented in this study may be useful for breeding dioecious and highly male monoecious lines utilized as the pollen parents for hybrid seed production, as well as for studies of the evolutionary history of sexual systems in this species, and can provide a molecular basis for positional cloning of the sex-determining genes.     

Efficiency of homologous DNA recombination varies along the Bacillus subtilis chromosome.

Structures consisting of a genetic marker (erythromycin or kanamycin resistance, thymidylate synthetase) flanked by 3.4-kilobase direct repeats (pBR322 sequences) were inserted in 12 different locations of the Bacillus subtilis chromosome. Recombination between the repeats was followed by the loss of the genetic marker. Recombination frequencies found in different locations varied from 1.2 X 10(-5) to 40 X 10(-5) per cell generation. Such differences were highly significant (P less than 0.001).     

Gene conversion during vector insertion in embryonic stem cells.

Recombination of an insertion vector into its chromosomal homologue is a conservative event in that both the chromosomal and the vector sequences are preserved. However, gene conversion may accompany homologous recombination of an insertion vector. To examine gene conversion in more detail we have determined the targeting frequencies and the structure of the recombinant alleles generated with a series of vectors which target the hprt gene in embryonic stem cells. We demonstrate that gene conversion of the introduced mutation does not significantly limit homologous recombination and that gene conversion occurs without a sequence specific bias for five different mutations. The frequency of the loss of a vector mutation and the gain of a chromosomal sequence is inversely proportional to the distance between the vector mutation and the double-strand break. The loss of a chromosomal sequence and the gain of a vector mutation occurs at a low frequency.     

Tn5 mutagenesis and insertion replacement in Azotobacter vinelandii.

Tn5 insertion mutants of Azotobacter vinelandii were isolated using vectors pJB4JI (IncP) and pGS9 (IncN). A procedure to replace Tn5 (Kmr) by its nontransposing derivative Tn5-131 (Tcr) was developed. For the replacement, a ColEl derivative harboring Tn5-131 (pRZ131) was conjugally mobilized by the IncN plasmid pCU101 into A. vinelandii strains containing Tn5. Both plasmids are unable to be maintained in A. vinelandii, but the transient presence of pRZ131 allows recombination between the incoming and the resident Tn5 elements. Genetic and physical analysis showed that insertion replacements result in lower frequencies of Tn5-associated genomic rearrangements, thereby increasing the stability of Tn5-containing strains.     

Linkage analysis of "necessary" disease loci versus "susceptibility" loci.

The association of some diseases with specific alleles of certain genetic markers has been difficult to explain. Several explanations have been proposed for the phenomenon of association, e.g. the existence of multiple, interacting genes (epistasis) or a disease locus in linkage disequilibrium with the marker locus. One might suppose that when marker data from families with associated diseases are analyzed for linkage, the existence of the association would assure that linkage will be found, and found at a tight recombination fraction. In fact, however, linkage analyses of some diseases associated with HLA, as well as diseases associated with alleles at other loci located throughout the genome, show significant evidence against linkage, and others show loose linkage, to the puzzlement of many researchers. In part, the puzzlement arises because linkage analysis is ideal for looking for loci that are necessary, even if not sufficient, for disease expression but may be much less useful for finding loci that are neither necessary nor sufficient for disease expression (so-called susceptibility loci). This work explores what happens when one looks for linkage to susceptibility loci. A susceptibility locus in this case means that the allele increases risk but is neither necessary nor sufficient for disease expression. It might be either an allele at the marker locus itself that is increasing susceptibility or an allele at a locus in linkage disequilibrium with the marker. This work uses computer simulation to examine how linkage analyses behave when confronted with data from such a model.(ABSTRACT TRUNCATED AT 250 WORDS)