Recombining overlapping BACs into a single larger BAC

Background  

BAC clones containing entire mammalian genes including all the transcribed region and long range controlling elements are very useful for functional analysis. Sequenced BACs are available for most of the human and mouse genomes and in many cases these contain intact genes. However, large genes often span more than one BAC, and single BACs covering the entire region of interest are not available. Here we describe a system for linking two or more overlapping BACs into a single clone by homologous recombination.     

Bacterial delivery of large intact genomic-DNA-containing BACs into mammalian cells

Efficient delivery of large intact vectors into mammalian cells remains problematical. Here we evaluate delivery by bacterial invasion of two large BACs of more than 150 kb in size into various cells. First, we determined the effect of several drugs on bacterial delivery of a small plasmid into different cell lines. Most drugs tested resulted in a marginal increase of the overall efficiency of delivery in only some cell lines, except the lysosomotropic drug chloroquine, which was found to increase the efficiency of delivery by 6-fold in B16F10 cells. Bacterial invasion was found to be significantly advantageous compared with lipofection in delivering large intact BACs into mouse cells, resulting in 100% of clones containing intact DNA. Furthermore, evaluation of expression of the human hypoxanthine phosphoribosyltransferase (HPRT) gene from its genomic locus, which was present in one of the BACs, showed that single copy integrations of the HPRT-containing BAC had occurred in mouse B16F10 cells and that expression of HPRT from each human copy was 0.33 times as much as from each endogenous mouse copy. These data provide new evidence that bacterial delivery is a convenient and efficient method to transfer large intact therapeutic genes into mammalian cells.     

Parameters influencing high-efficiency transfection of bacterial artificial chromosomes into cultured mammalian cells

Although bacterial artificial chromosomes (BACs) provide a well-characterized resource for the analysis of large chromosomal domains, low transfection rates have proven a significant limitation for their use in cell culture models. Using TP53 BAC clones that contain expression cassettes for enhanced green fluorescent protein or red fluorescent protein, we have examined conditions that promote BAC transfection in hamster, human, and mouse cell lines. Atomic force microscopy shows that BAC transfection efficiency correlates with the generation of small, highly condensed but dispersed lipid: BAC DNA transfection complexes. BAC DNA purity and concentration are critical for good transfection; debris from purification columns induces the formation of large aggregates that do not gain entry into the cell, and DNA concentrations must be optimized to promote intramolecular condensation rather than intermolecular linking, which also causes aggregation and diminished transfection efficiency. The expression of both markers and genes within BACs initially occurs at lower levels than observed with plasmids, requiring 3-5 days to evaluate the transfection results. We also show that BACs can be co-transfected with other BACs, which provides for increased experimental flexibility.     

Construction of a rice bacterial artificial chromosome library and identification of clones linked to the Xa-21 disease resistance locus

A bacterial artificial chromosome (BAC) library consisting of 11 000 clones with an average DNA insert size of 125 kb was constructed from rice nuclear DNA. The BAC clones were stable in E. coli after 100 generations of serial growth. Transformation of the BAC clones by electroporation into E. coli was highly efficient and increased with decreasing size of the DNA inserts. The library was evaluated for the presence of organellar, repeated, and telomeric sequences. A very low percentage (<0.3%) of the library consisted of chloroplast and mitochondrial clones. Eighteen BACs were identified that hybridized with an Arabidopsis telomere repeat. Sixteen BACs hybridized with the AA genome-specific repetitive sequence pOs48. Twelve clones were isolated that hybridized with three DNA markers linked to the Xa-21 disease resistance locus. The results indicate that the BAC system can be used to clone and manipulate large pieces of plant DNA efficiently.     

BACFinder: genomic localisation of large insert genomic clones based on restriction fingerprinting

We have developed software that allows the prediction of the genomic location of a bacterial artificial chromosome (BAC) clone, or other large genomic clone, based on a simple restriction digest of the BAC. The mapping is performed by comparing the experimentally derived restriction digest of the BAC DNA with a virtual restriction digest of the whole genome sequence. Our trials indicate that this program identified the genomic regions represented by BAC clones with a degree of accuracy comparable to that of end-sequencing, but at considerably less cost. Although the program has been developed principally for use with Arabidopsis BACs, it should align large insert genomic clones to any fully sequenced genome.     

Simple, fast, tissue-specific bacterial artificial chromosome transgenesis in Xenopus

We have developed a method of injecting bacterial artificial chromosome (BAC) DNA into Xenopus embryos that is simple and efficient, and results in consistent and tissue-specific expression of transgenes cloned into BAC vectors. Working with large pieces of DNA, as can be accommodated by BACs, is necessary when studying large or complex genes and conducive to studying the function of long-range regulatory elements that act to control developmentally restricted gene expression. We recombineered fluorescent reporters into three Xenopus tropicalis BAC clones targeting three different genes and report that up to 60% of injected embryos express the reporter in a manner consistent with endogenous expression. The behavior of these BACs, which are replicated after injection, contrasts with that of smaller plasmids, which degrade relatively quickly when injected as circular molecules and generally fail to recapitulate endogenous expression when not integrated into the Xenopus genome.     

Counter-selection recombineering of the baculovirus genome: a strategy for seamless modification of repeat-containing BACs

Recombineering is employed to modify large DNA clones such as fosmids, BACs and PACs. Subtle and seamless modifications can be achieved using counter-selection strategies in which a donor cassette carrying both positive and negative markers inserted in the target clone is replaced by the desired sequence change. We are applying counter-selection recombineering to modify bacmid bMON14272, a recombinant baculoviral genome, as we wish to engineer the virus into a therapeutically useful gene delivery vector with cell targeting characteristics. Initial attempts to replace gp64 with Fusion (F) genes from other baculoviruses resulted in many rearranged clones in which the counter-selection cassette had been deleted. Bacmid bMON14272 contains nine highly homologous regions (hrs) and deletions were mapped to recombination between hr pairs. Recombineering modifications were attempted to decrease intramolecular recombination and/or increase recombineering efficiency. Of these only the use of longer homology arms on the donor molecule proved effective permitting seamless modification. bMON14272, because of the presence of the hr sequences, can be considered equivalent to a highly repetitive BAC and, as such, the optimized method detailed here should prove useful to others applying counter-selection recombineering to modify BACs or PACs containing similar regions of significant repeating homologies.     

Cryptic loxP sites in mammalian genomes: genome-wide distribution and relevance for the efficiency of BAC/PAC recombineering techniques

Cre is widely used for DNA tailoring and, in combination with recombineering techniques, to modify BAC/PAC sequences for generating transgenic animals. However, mammalian genomes contain recombinase recognition sites (cryptic loxP sites) that can promote illegitimate DNA recombination and damage when cells express the Cre recombinase gene. We have created a new bioinformatic tool, FuzznucComparator, which searches for cryptic loxP sites and we have applied it to the analysis of the whole mouse genome. We found that cryptic loxP sites occur frequently and are homogeneously distributed in the genome. Given the mammalian nature of BAC/PAC genomic inserts, we hypothesised that the presence of cryptic loxP sites may affect the ability to grow and modify BAC and PAC clones in E. coli expressing Cre recombinase. We have observed a defect in bacterial growth when some BACs and PACs were transformed into EL350, a DH10B-derived bacterial strain that expresses Cre recombinase under the control of an arabinose-inducible promoter. In this study, we have demonstrated that Cre recombinase expression is leaky in un-induced EL350 cells and that some BAC/PAC sequences contain cryptic loxP sites, which are active and mediate the introduction of single-strand nicks in BAC/PAC genomic inserts.     

Transposon mediated BAC transgenesis via pronuclear injection of mouse zygotes

Pronuclear microinjection of bacterial artificial chromosomes (BACs) is the preferred way to generate transgenic mice because the transgene accurately recapitulates expression of the endogenous gene. However, the method is demanding and the integrity and copy number of the BAC transgene is difficult to control. Here, we describe a simpler pronuclear injection method that relies on transposition to introduce full‐length BACs into the mouse genome. The bacterial backbone of a hPAX6‐GFP reporter BAC was retrofitted with PiggyBac transposon inverted terminal repeats and co‐injected with PiggyBac transposase mRNA. Both the frequency of transgenic founders as well as intact, full‐length, single copy integrations were increased. Transposition was determined by a rapid PCR screen for a transpositional signature and confirmation by splinkerette sequencing to show that theBACs were integrated as a single copy either in one or two different genomic sites. BAC transposons displayed improved functional accuracy over random integrants as evaluated by expression of the hPAX6‐GFP reporter in embryonic neural tube and absence of ectopic expression. This method involves less work to achieve increased frequencies of both transgenesis and single copy, full‐length integrations. These advantages are not only relevant to rodents but also for transgenesis in all systems. genesis 51:135–141, 2013. © 2012 Wiley Periodicals, Inc.     

Red-Mediated Transposition and Final Release of the Mini-F Vector of a Cloned Infectious Herpesvirus Genome

Bacterial artificial chromosomes (BACs) are well-established cloning vehicles for functional genomics and for constructing targeting vectors and infectious viral DNA clones. Red-recombination-based mutagenesis techniques have enabled the manipulation of BACs in Escherichia coli without any remaining operational sequences. Here, we describe that the F-factor-derived vector sequences can be inserted into a novel position and seamlessly removed from the present location of the BAC-cloned DNA via synchronous Red-recombination in E. coli in an en passant mutagenesis-based procedure. Using this technique, the mini-F elements of a cloned infectious varicella zoster virus (VZV) genome were specifically transposed into novel positions distributed over the viral DNA to generate six different BAC variants. In comparison to the other constructs, a BAC variant with mini-F sequences directly inserted into the junction of the genomic termini resulted in highly efficient viral DNA replication-mediated spontaneous vector excision upon virus reconstitution in transfected VZV-permissive eukaryotic cells. Moreover, the derived vector-free recombinant progeny exhibited virtually indistinguishable genome properties and replication kinetics to the wild-type virus. Thus, a sequence-independent, efficient, and easy-to-apply mini-F vector transposition procedure eliminates the last hurdle to perform virtually any kind of imaginable targeted BAC modifications in E. coli. The herpesviral terminal genomic junction was identified as an optimal mini-F vector integration site for the construction of an infectious BAC, which allows the rapid generation of mutant virus without any unwanted secondary genome alterations. The novel mini-F transposition technique can be a valuable tool to optimize, repair or restructure other established BACs as well and may facilitate the development of gene therapy or vaccine vectors.     

Relevance of BAC transgene copy number in mice: transgene copy number variation across multiple transgenic lines and correlations with transgene integrity and expression

Bacterial artificial chromosomes (BACs) are excellent tools for manipulating large DNA fragments and, as a result, are increasingly utilized to engineer transgenic mice by pronuclear injection. The demand for BAC transgenic mice underscores the need for careful inspection of BAC integrity and fidelity following transgenesis, which may be crucial for interpreting transgene function. Thus, it is imperative that reliable methods for assessing these parameters are available. However, there are limited data regarding whether BAC transgenes routinely integrate in the mouse genome as intact molecules, how BAC transgenes behave as they are passed through the germline across successive generations, and how variation in BAC transgene copy number relates to transgene expression. To address these questions, we used TaqMan real-time PCR to estimate BAC transgene copy number in BAC transgenic embryos and lines. Here we demonstrate the reproducibility of copy number quantification with this method and describe the variation in copy number across independent transgenic lines. In addition, polymorphic marker analysis suggests that the majority of BAC transgenic lines contain intact molecules. Notably, all lines containing multiple BAC copies also contain all BAC-specific markers. Three of 23 founders analyzed contained BAC transgenes integrated into more than one genomic location. Finally, we show increased BAC transgene copy number correlates with increased BAC transgene expression. In sum, our efforts have provided a reliable method for assaying BAC transgene integrity and fidelity, and data that should be useful for researchers using BACs as transgenic vectors.     

Isolating large nested deletions in bacterial and P1 artificial chromosomes by in vivo P1 packaging of products of Cre-catalysed recombination between the endogenous and a transposed loxP site.

A general approach for isolating large nested deletions in P1 artificial chromosomes (PACs) and bacterial artificial chromosomes (BACs) by retrofitting with a loxP site-containing Tn10 mini-transposon is described. Cre-mediated recombination between the loxP site existing in these clones and one introduced by transposition leads to deletions and inversions of the DNA between these sites. Large deletions are selectively recovered by transducing the retrofitted PAC or BAC clones with P1 phage. The requirement that both loxP sites in the cointegrate be packaged into a P1 head ensures that only large deletions are rescued. PCR analyses identified these deletions as products of legitimate recombination between loxP sites mediated by Cre protein. BACs produce deletions much more efficiently than PACs although the former cannot be induced to greater than unit copy in cells. Mammalian cell-responsive antibiotic resistance markers are introduced as part of the transposon into genomic clone deletions for subsequent functional analysis. Most importantly, the loxP site retrofitting and P1 transduction can be performed in the same bacterial host containing these clones directly isolated from PAC or BAC libraries. These procedures should facilitate physical and functional mapping of genes and regulatory elements in these large plasmids.     

Instability of bacterial artificial chromosome (BAC) clones containing tandemly repeated DNA sequences.

The cloning and propagation of large DNA fragments as bacterial artificial chromosomes (BACs) has become a valuable technique in genome research. BAC clones are highly stable in the host, Escherichia coli, a major advantage over yeast artificial chromosomes (YACs) in which recombination-induced instability is a major drawback. Here we report that BAC clones containing tandemly repeated DNA elements are not stable and can undergo drastic deletions during routine library maintenance and DNA preparation. Instability was observed in three BAC clones from sorghum, rice, and potato, each containing distinct tandem repeats. As many as 46% and 74% of the single colonies derived from a rice BAC clone containing 5S ribosomal RNA genes had insert deletions after 24 and 120 h of growth, respectively. We also demonstrated that BAC insert rearrangement can occur in the early stage of library construction and duplication. Thus, a minimum growth approach may not avoid the instability problem of such clones. The impact of BAC instability on genome research is discussed.     

A BAC-based STS-content map spanning a 35-Mb region of human chromosome 1p35-p36

We have devised a mapping method for rapid assembly and ordering of bacterial artificial chromosome (BAC) clones on a radiation hybrid (RH) panel, using sequence-tagged sites (STSs) and PCR. The protocol consists of two rounds of two-dimensional screening from a limited number of BACs to correspond each to an STS. In the first round, STSs are assembled in the RH bins and ordered according to PCR signals derived from 384-well microtiter plates (MTPs) in which BAC clones have been arrayed. In the second round, individual BAC clones are isolated from the MTPs to build a contig. We applied this method to a 35-Mb region spanning human chromosome 1p35-p36 and assembled 1366 BACs in 11 contigs, the longest being about 20 Mb. The working draft sequences of the human genome have been integrated into the contigs to validate the accuracy.     

PhiC31-mediated cassette exchange into a bacterial artificial chromosome

The use of bacterial artificial chromosomes (BACs) modified via homologous recombination in Escherichia coli has become a powerful tool in the transgenic field. Homologous recombination allows the manipulation of BACs in very different ways. However this process can be cumbersome and problematic when using large targeting constructs containing several repeated elements. In order to address this problem, we have established a phiC31 integrase-mediated cassette exchange into a BAC. As an example of this technique, we have exchanged a cassette previously recombined into a BAC containing the Rosa 26 locus, by a 16.5-kb incoming construct containing several repeated elements. The combination of homologous recombination in E. coli and cassette exchange should expand the tools for manipulating BACs, thus facilitating the generation of constructs with higher complexity.     

Construction of a Festuca pratensis BAC library for map-based cloning in Festulolium substitution lines

Introgression in Festulolium is a potentially powerful tool to isolate genes for a large number of traits which differ between Festuca pratensis Huds. and Lolium perenne L. Not only are hybrids between the two species fertile, but the two genomes can be distinguished by genomic in situ hybridisation and a high frequency of recombination occurs between homoeologous chromosomes and chromosome segments. By a programme of introgression and a series of backcrosses, L. perenne lines have been produced which contain small F. pratensis substitutions. This material is a rich source of polymorphic markers targeted towards any trait carried on the F. pratensis substitution not observed in the L. perenne background. We describe here the construction of an F. pratensis BAC library, which establishes the basis of a map-based cloning strategy in L. perenne. The library contains 49,152 clones, with an average insert size of 112 kbp, providing coverage of 2.5 haploid genome equivalents. We have screened the library for eight amplified fragment length polymorphism (AFLP) derived markers known to be linked to an F. pratensis gene introgressed into L. perenne and conferring a staygreen phenotype as a consequence of a mutation in primary chlorophyll catabolism. While for four of the markers it was possible to identify bacterial artificial chromosome (BAC) clones, the other four AFLPs were too repetitive to enable reliable identification of locus-specific BACs. Moreover, when the four BACs were partially sequenced, no obvious coding regions could be identified. This contrasted to BACs identified using cDNA sequences, when multiple genes were identified on the same BAC.     

Construction of a bacterial artificial chromosome (BAC) library of Coprinus cinereus

A bacterial artificial chromosome (BAC) library of the genomic DNA of Coprinus cinereus strain MP#2 was constructed using the BAC vector pBACTZ, which carries the C. cinereus trp1 gene. The library consists of 1536 clones. Analysis of inserts in some of the clones suggested that the library covers five times the C. cinereus genome. Screening of the BAC clones using ten markers mapped on nine different chromosomes also indicated that the library is likely to cover the whole length of the genomic DNA. We show an example of transformation of C. cinereus with BACs containing inserts of longer than 170kb.