Pradeep K. Chatterjee

Using PAC nested deletions to order contigs and microsatellite markers at the high repetitive sequence containing Npr3 gene locus.

Highly polymorphic di- and tetranucleotide repeats in and around Npr3, a potential candidate gene for hypertension, have been identified using a novel approach. Because this chromosomal site is rich in repetitive DNA and difficult to sequence, P1 artificial chromosomes were retrofitted with a loxP transposon to map the gene sequence within a clone using a series of nested deletions. Sequences from ends of deletions 1-3 kb apart identified a (CA)(20) and a (TA)(18)-(CA)(8) repeat 8 kb upstream and within an intron of Npr3, respectively. DNA from 17 individuals was analyzed for length polymorphisms in these and eight additional repeats identified in 200 kb of working draft sequence from this region in GenBank. The sequence contigs and microsatellite repeats from GenBank were ordered using the P1-derived artificial chromosome deletion series. Several of these repeats were found to vary considerably in length in the set of genomic DNA tested. Since this site in chromosome 5p has recently been implicated in disease in studies with genetically hypertensive rats, the microsatellite markers reported here will be useful for genetic analysis and may even be implicated in the disease process in humans. We discuss how these types of data are useful for interpreting draft DNA sequence coming out of the genome projects, and the utility of deletion clones as a resource for ordering contigs and gap filling.

Context dependent function of APPb enhancer identified using enhancer trap-containing BACs as transgenes in zebrafish.

An enhancer within intron 1 of the amyloid precursor protein gene (APPb) of zebrafish is identified functionally using a novel approach. Bacterial artificial chromosomes (BACs) were retrofitted with enhancer traps, and expressed as transgenes in zebrafish. Expression from both transient assays and stable lines were used for analysis. Although the enhancer was active in specific nonneural cells of the notochord when placed with APPb gene promoter proximal elements its function was restricted to, and absolutely required for, specific expression in neurons when juxtaposed with additional far-upstream promoter elements of the gene. We demonstrate that expression of green fluorescent protein fluorescence resembling the tissue distribution of APPb mRNA requires both the intron 1 enhancer and ∼28 kb of DNA upstream of the gene. The results indicate that tissue-specificity of an isolated enhancer may be quite different from that in the context of its own gene. Using this enhancer and upstream sequence, polymorphic variants of APPb can now more closely recapitulate the endogenous pattern and regulation of APPb expression in animal models for Alzheimers disease. The methodology should help functionally map multiple noncontiguous regulatory elements in BACs with or without gene-coding sequences.

Generating libraries of iTol2-end insertions at BAC ends using loxP and lox511 Tn10 transposons

BackgroundBacterial Artificial Chromosomes (BACs) have been widely used as transgenes in vertebrate model systems such as mice and zebrafish, for a variety of studies. BAC transgenesis has been a powerful tool to study the function of the genome, and gene regulation by distal cis- regulatory elements. Recently, BAC transgenesis in both mice and zebrafish was further facilitated by development of the transposon-mediated method using the Tol2 element. Tol2 ends, in the inverted orientation and flanking a 1 kb spacer DNA (iTol2), were introduced into the BAC DNA within the bacterial host using recombination of homologous sequences. Here we describe experiments designed to determine if a simpler and more flexible system could modify BACs so that they would be suitable for transgenesis into zebrafish or mouse embryos using the Tol2 transposase.ResultsA new technique was developed to introduce recognition sequences for the Tol2 transposase into BACs in E. coli using the Tn10 transposon vector system. We constructed pTnloxP-iTol2kan and pTnlox511-iTol2kan to introduce the loxP or lox511 site and iTol2 cassette, containing the Tol2 cis-sequences in the inverted orientation, into BACs that have loxP and lox511 sites flanking genomic DNA inserts by Tn10-mediated transposition. The procedure enables rapid generation of a large collection of BACs ready for transgenesis with the iTol2 cassette at the new end of a progressively truncated genomic insert via lox-Cre recombination. The iTol2 ends are efficiently recognized by the Tol2 transposase, and the BACs readily integrate into zebrafish chromosomes.ConclusionThe new technology described here can rapidly introduce iTol2 ends at a BAC end of choice, and simultaneously generate a large collection of BACs with progressive deletions of the genomic DNA from that end in a single experiment. This procedure should be applicable to a wider variety of BACs containing lox sites flanking the genomic DNA insert, including those with sequence repeats. The libraries of iTol2 inserted BACs with truncations from an end should facilitate studies on the impact of distal cis-regulatory sequences on gene function, as well as standard BAC transgenesis with precisely trimmed genes in zebrafish or mouse embryos using Tol2 transposition.

Minimal cross-recombination between wild-type and loxP511 sites in vivo facilitates truncating both ends of large DNA inserts in pBACe3.6 and related vectors

Contrary to several earlier reports, we find that cross-recombination between wild-type and the mutant loxP511 sites is <0.5% of that between two wild-type sites if Cre protein is expressed by phage P1 during an infection. The finding enabled us to develop a procedure to truncate DNA progressively from both ends of large genomic inserts flanked by these two loxP sites in pBACe3.6 and related vectors with transposons carrying either a wild-type or a loxP511 sequence. Newly constructed loxP511 transposons contained either a kanamycin resistance gene or no marker. Insert DNA ends in deletions were sequenced with primers unique to each transposon-end remaining after the respective recombination. End-sequencing 223 deletions confirmed that the low level of cross-recombination, observed between those sites during the P1 transductions, does not complicate the procedure: truncations from the unintended end of genomic inserts did not occur. Multiple BACs pooled together could also be processed in a single tube to make end-deletions. This deletion technology, utilizing the very minimal cross-recombination between the mutant and wild-type loxP sites of most BAC clones in the public domain and a heterologous one inserted as a transposon, should facilitate functionally mapping long-range gene regulatory sequences and help to isolate genes with defined functional boundaries in numerous projects including those of therapeutic interest.

Using BAC transgenesis in zebrafish to identify regulatory sequences of the amyloid precursor protein gene in humans

BackgroundNon-coding DNA in and around the human Amyloid Precursor Protein (APP) gene that is central to Alzheimer’s disease (AD) shares little sequence similarity with that of appb in zebrafish. Identifying DNA domains regulating expression of the gene in such situations becomes a challenge. Taking advantage of the zebrafish system that allows rapid functional analyses of gene regulatory sequences, we previously showed that two discontinuous DNA domains in zebrafish appb are important for expression of the gene in neurons: an enhancer in intron 1 and sequences 28–31 kb upstream of the gene. Here we identify the putative transcription factor binding sites responsible for this distal cis-acting regulation, and use that information to identify a regulatory region of the human APP gene.ResultsFunctional analyses of intron 1 enhancer mutations in enhancer-trap BACs expressed as transgenes in zebrafish identified putative binding sites of two known transcription factor proteins, E4BP4/ NFIL3 and Forkhead, to be required for expression of appb. A cluster of three E4BP4 sites at −31 kb is also shown to be essential for neuron-specific expression, suggesting that the dependence of expression on upstream sequences is mediated by these E4BP4 sites. E4BP4/ NFIL3 and XFD1 sites in the intron enhancer and E4BP4/ NFIL3 sites at −31 kb specifically and efficiently bind the corresponding zebrafish proteins in vitro. These sites are statistically over-represented in both the zebrafish appb and the human APP genes, although their locations are different. Remarkably, a cluster of four E4BP4 sites in intron 4 of human APP exists in actively transcribing chromatin in a human neuroblastoma cell-line, SHSY5Y, expressing APP as shown using chromatin immunoprecipitation (ChIP) experiments. Thus although the two genes share little sequence conservation, they appear to share the same regulatory logic and are regulated by a similar set of transcription factors.ConclusionThe results suggest that the clock-regulated and immune system modulator transcription factor E4BP4/ NFIL3 likely regulates the expression of both appb in zebrafish and APP in humans. It suggests potential human APP gene regulatory pathways, not on the basis of comparing DNA primary sequences with zebrafish appb but on the model of conservation of transcription factors.

Directing Enhancer-Traps and iTol2 End-Sequences to Deleted BAC Ends with loxP- and lox511-Tn10 Transposons

A step-by-step detailed procedure is presented to progressively truncate genomic DNA inserts from either end in BACs. The bacterial transposon Tn10 carrying a loxP or a lox511 site is inserted at random into BAC DNA inside the bacterial cell. The cells are then infected with bacteriophage P1. The Cre protein expressed by phage P1 generates end-deletions by specifically recombining the inserted loxP (or lox511) with the loxP (or lox511) endogenous to and flanking insert DNA in BACs from the respective end. The Cre protein also helps phage P1 transduce the BAC DNA by packaging it in P1 heads. This packaging by P1 not only recovers the rare BAC clones containing Tn10 insertions efficiently but also selects end-truncated BACs from those containing inversions of portions of their DNA caused by transposition of Tn10 in the opposite orientation. The libraries of end-deleted BACs generated by this procedure are suitable for numerous mapping studies. Because DNA in front of the loxP (or lox511) arrowheads in the Tn10 transposon is retained at the newly created BAC end, exogenous DNA cassettes such as enhancer-traps and iTol2 ends can be efficiently introduced into BAC ends for germline expression in zebrafish or mice. The methodology should facilitate functional mapping studies of long-range cis-acting gene regulatory sequences in these organisms.

Identifying Distal cis-acting Gene-Regulatory Sequences by Expressing BACs Functionalized with loxP-Tn10 Transposons in Zebrafish

Bacterial Artificial Chromosomes (BACs) are large pieces of DNA from the chromosomes of organisms propagated faithfully in bacteria as large extra-chromosomal plasmids. Expression of genes contained in BACs can be monitored after functionalizing the BAC DNA with reporter genes and other sequences that allow stable maintenance and propagation of the DNA in the new host organism. The DNA in BACs can be altered within its bacterial host in several ways. Here we discuss one such approach, using Tn10 mini-transposons, to introduce exogenous sequences into BACs for a variety of purposes. The largely random insertions of Tn10 transposons carrying lox sites have been used to position mammalian cell-selectable antibiotic resistance genes, enhancer-traps and inverted repeat ends of the vertebrate transposon Tol2 precisely at the ends of the genomic DNA insert in BACs. These modified BACs are suitable for expression in zebrafish or mouse, and have been used to functionally identify important long-range gene regulatory sequences in both species. Enhancer-trapping using BACs should prove uniquely useful in analyzing multiple discontinuous DNA domains that act in concert to regulate expression of a gene, and is not limited by genome accessibility issues of traditional enhancer-trapping methods.

Automated Purification of Dye Terminator Sequencing Reactions: An Approach to High-Throughput Capillary Electrophoresis Sequencing of Large Templates

Demands for higher quantity and quality of sequence data during genome sequencing projects have led to a need for completely automated reagent systems designed to isolate, process, and analyze DNA samples. While much attention has been given to methodologies aimed at increasing the throughput of sample preparation and reaction setup, purification of the products of sequencing reactions has received less scrutiny despite the profound influence that purification has on sequence quality. Commonly used and commercially available sequencing reaction cleanup methods are not optimal for purifying sequencing reactions generated from larger templates, including bacterial artificial chromosomes (BACs) and those generated by rolling circle amplification. Theoretically, these methods would not remove the original template since they only exclude small molecules and retain large molecules in the sample. If the large template remains in the purified sample, it could understandably interfere with electrokinetic injectio...

Long range gene-regulatory sequences identified by transgenic expression of bacterially-engineered enhancer-trap BACs in zebrafish

Abstract Large pieces of DNA from the chromosomes of numerous organisms, including the human, are faithfully propagated in bacteria as large extra-chromosomal plasmids known as Bacterial Artificial Chromosomes (BACs). Because they

Harnessing mobile genetic elements to explore gene regulation

Sequences that regulate expression of a gene in cis but are located at large distances along the DNA from the gene, as found with most developmentally regulated genes in higher vertebrates, are difficult to identify if those sequences are not conserved across species. Mutating suspected gene-regulatory sequences to alter expression then becomes a hit-or-miss affair. The relaxed specificity of transposon insertions offers an opportunity to develop alternate strategies, to scan in an unbiased manner, pieces of chromosomal DNA cloned in BACs for transcription enhancing elements. This article illustrates how insertions of Tn10 with enhancer-traps into BAC DNA containing the gene, and its germ-line expression in zebrafish, have identified distal regulatory elements functionally. Transposition of Tn10 first introduces the enhancer-trap with a loxP site randomly into BAC DNA. Cre-recombination between the inserted loxP and the loxP endogenous to a BAC-end positions the enhancer-trap to the newly created truncated end of BAC DNA. The procedure generates a library of integration-ready enhancer-trap BACs with progressive truncations from an end in a single experiment. Individual enhancer-trap BACs from the library can be evaluated functionally in zebrafish or mice. Furthermore, the ability to readily alter sequences in a small transposon plasmid containing a regulatory domain of the gene allows re-introduction of altered parts of a BAC back into itself. It serves as a useful strategy to functionally dissect multiple discontinuous regulatory domains of a gene quickly. These methodologies have been successfully used in identifying novel regulatory domains of the Amyloid Precursor Protein (appb) gene in zebrafish, and provided important clues for regulation of the gene in humans.